EPA/904-9-78-007
APPENDICES TO
TECHNICAL SUPPORT DOCUMENT
VOLUME II
D-F
United States Steel Corporation
Number 8 Blast Furnace
Fair-field, Alabama
UNITED STATES
ENVIRONMENTAL PROTECTION AGENCY
REGION IV
345 Courtland Street
Atlanta, Georgia 30308
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APPENDICES TO THE
TECHNICAL SUPPORT DOCUMENT
U. S. STEEL No. 8 BLAST FURNACE
VOLUME 2
D-F
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TABLE OF CONTENTS
Appendix D Water Quality
D-l GC/MS Analysis of Water and Sediment Samples
D-2 QUAL - II Computer Program
D-3 Model Calibration
D-4 Model Verification
D-5 Model Projections
D-6 Long Term BOD Data
Appendix E Toxic Substances
Appendix F Residuals Composition and Disposal Sites
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ANALYSIS OF WATER AND SEDIMENT SAMPLES
FOR THE PRESENCE OF SPECIFIC HYDROCARBONS AND PHENOLS
by
David Rosenthal, Ph.D.
Chemistry and Life Sciences Division
Research Triangle Institute
Research Triangle Park, North Carolina 27709
Prepared for
AWARE, Inc.
P. 0. Box 40284
Nashville, Tennessee 37204
D-l-1
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Eight samples, four each in duplicate, were sent by AWARE to RTI
for analysis for the presence of a selected list of hydrocarbons and
phenols. The samples consisted of two water samples and two sediment
samples collected under the conditions shown in Table 1.
The samples were analyzed for the presence of the following com-
ponents :
Neutral Components
Indene
Naphthalene
Me thyInaph thalenes
Biphenyl
Dimethylnaphthalenes
Biphenylene
Acenaphthene
Dibenzofuran
Fluorene
Chrysene
Phenanthrene
Anthracene
Methylindene
Acid Components
Phenol
2,4,6-trichlorophenol
p-chloro-m-cresol
2-chlorophenol
2,4-dichlorophenol
2-nitrophenol
4-nitrophenol
2,4-dinitrophenol
4,6-dinitro-o-cresol
0-,m-,p-cr'esol
D-l-2
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Table 1
Sample Number
and Type
1 Water
2 Water
3 Water
4 Water
5 Sediment
6 Sediment
7 Sediment
8 Sediment
Location
Highway 23
Highway 23
Valley Creek
Valley Creek
Highway 23
Highway 23
Valley Creek
Valley Creek
Collection Time
3:30
3:32
2:15
2:15
3:35
3:37
2:16
2:17
Volume
1 gal.
1 gal.
1 gal.
1 gal.
Broken in shipment
1 qt.
1 qt.
1 qt.
D-l-3
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The analysis was carried out by gas chromatography-mass spectro-
metry, which provided both qualitative and semi-quantitative analyses of
the components sought. Qualitative identification of the components was
carried out by the examination of the individual spectra in the region
where the sought for unknowns were expected to be eluted from the column.
Semi-quantitative identification of the individual compounds was carried
out by the comparison of the intensities of key ions associated with
specific components of the mixture with the intensity of a standard.
The standards used in this analysis were d --anthracene, used for the
neutral fractions, and p-bromophenol, used for the acidic components.
EXTRACTION METHODS
A. Water Samples
A 2,000 ml aliquot of sample was spiked with 119.5 micrograms of p-
bromophenol dissolved in 10 microliters of inethanol. The pH of the
sample was adjusted to 11 with 50% NaOH solution. It was then placed in
a separatory funnel and extracted three times with 500 ml aliquots of
methylene chloride, shaking 15 minutes each time. The combined neutral
extracts were then concentrated under reduced pressure to ca. 50 ml.
The aqueous phase was then acidified to pH 2 with 6N sulfuric acid and
the acidic components were extracted with 3 x 500 ml of methylene chloride.
The neutral extracts were then evaporated to ca. 5 ml using a
Kuderna-Danish (K-D) apparatus, and then further reduced to 100 yl
under nitrogen. The organic acid extracts were treated similarly and
also reduced to 100 yl. The two extracts were then individually subjected
to g.c.-m.s. analysis.
D-l-4
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B. Sediment Extraction
A 300 g aliquot of the wet sediment was adjusted to pH 11 with 50%
sodium hydroxide solution. The sample was extracted with a 150 ml
portion of reagent chloroform, and then reextracted with 2 additional
200 ml portions. The combined extracts were dried over sodium sulphate
and then concentrated to 10 ml using a K-D apparatus.
Another 300 g aliquot was adjusted to pH 2 with 6M sulfuric acid.
This sample was extracted with chloroform as the previous sample. The
acidic extracts were reduced to near dryness, and 1 ml of diazomethane
solution in ether was added and the mixture was allowed to stand over-
night. The excess diazomethane was then removed by evaporation and the
volume of each sample was adjusted to 10 ml and submitted to g.c.-m.s.
MASS SPECTROMETRY
The extracted samples were subjected to analysis using a Finnigan
3300 quadrupole mass spectrometer operating in the electron impact mode
at 70 electron volts. The instrument was interfaced to a gas chromato-
graphy column by means of a single stage glass jet separator. The
column employed was a glass U shaped column, with dimensions 1.5 m x 2
mm id packed with 2% OV-17 on Supelcoport. The helium flow was set to
15 ml/min. The temperature was initially at 100° with temperature
programming at 8°/min to 270°. Full mass spectral scans, were made at
five second intervals.
DISCUSSION
The water samples and the sediment samples differed dramatically in
the concentration of their organic components. Initial extractions of
the water samples using smaller volumes than finally chosen showed no
D-l-5
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components whatsover. On the other hand, the concentration levels for
the sediment samples were very high indeed. They were so concentrated
in organics, that the original amount of standard added for quantitation
purposes proved to be so small that it was entirely overshadowed by the
presence of sample components. Accordingly, the sediment samples were
spiked with larger amounts of standards for purposes of quantitation.
Semi-quantitative analysis on these and subsequent samples was carried
out by comparison of the intensity of the standard substance with that
of the base peak of each components, identified previously by quali-
tative studies. Although this does not give precise results, order of
magnitude concentration of components can be very reasonably assumed.
For the sediment samples, the very high levels of hydrocarbons present
make it impossible to identify the acidic components, which had been
converted from free phenols to their corresponding anisols for the
purposes of improved GC resolution. In spite of this, it can be stated
that the presence of large amounts of chlorinated phenols was largely
excluded by virtue of the absence of the very strong and characteristic
peaks of these compounds.
The water samples were separated out into neutral and acidic compo-
nents, and independently analyzed. Since in this case the amount of
material present was substantially lower, the analysis proved considerably
easier to carry out.
In no case did any of the water samples show any of the compounds
sought for at a level in excess of 10 p.p.b. Some very low concentra-
tions of some hydrocarbons were found, and one sample showed a small
amount of xylene at a level of 52 p.p.b. No phenols were detected in
the water samples.
D-l-6
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Several characteristic printouts of the analyses are included as an
appendix to this report to give some idea of the nature of the samples
and some of the difficulties encountered, particularly with the sediment
samples. The results of the analyses are shown in the next section.
D-l-7
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ANALYTICAL RESULTS
Sample //2
WH23332NA - Water sample collected at Highway 23
No compounds found at 10 p.p.b. level or higher.
D-l-8
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Sample #4
WVC215NA - Water sample collected at Valley Creek
Combined results of two analyses.
Ret.
Time Rel. Cone.
(min) Formula Name MW Area ng/yl (ppb)
0.6 C8H1Q Dimethyl-benzene 106 18.91 1040 52
1.5 C6H4C12 Dichloro-benzene 146 2.11 116 5.8
1.92 CgH^Cl Chlorocyclohexanol 134 .74 42 2.1
3.8 C1QH8 Naphthalene 128 2.18 120 6
12.5 C14D d1Q-Anthracene (std) 188 1 55 2.75
12.5 C14H10 Anthracene 178 .26 14.3 0.7
15.4 ci5HiiON Diphenyl-oxazole 221 3.49 192 9.6
16.6 C16H10 Diphenyl diacetylene 202 .16 9 0.44
D-i-g
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Sample #6
SH23337NA - Sediment sample collected at Highway 23
Combined results of two analyses.
Ret.
Time Rel . Quant .
fining Formula Name MW Area in nj>.
1.42
1.75
2.333
2.166
3.58
5.11
6.42
6.75
7.66
7.83
8.08
8.41
9.42
9.92
11.16
13.58
14.0
14.41
15.66
16.33
16.83
20.75
C9H10
C9Hg
C14D10
C14H10
C10H8
C11H10
C12H10
C12H12
C8H8°3
C13H12
C12H10
C12H8°
C13H10
C13H10°
C15H12
C15H10
C10H12
C16H10
C16H10
C17H12
C18H12
Indane
Indene
d. -.-Anthracene (std)
Anthracene
Naphthalene
Methylnaphthalene
Diphenyl
Ethyl-naphthalene
Vanillin
2-Methyl-biphenyl
Acenaphthene
Dibenzofuran
Fluorene
Hydroxyfluorene
?
Methyl-phenanthrene
Methylene-phenanthrene
Dibenzohepta-fulvene
Diphenyl diacetylene
Isomer
1-Methylpyrene
Chrysene
118
116
188
178
128
142
154
156
152
168
154
168
166
182
196
192
190
204
202
202
216
228
0,13 3.2
-0.72 18,1
10 25
>36.8 >960
5.62 140.5
1.73 43.3
0.34 8.5
0.28 7.0
6.06 151.7
0.4 . 10.1
2.7 67.9
5.85 146.2
4.65 116.3
1.91 47.85
—
— —
— —
— —
— —
—
>42.8 >1071
Cone.
(ppm)
0.2
1.2
1.7
>61.3
9.4
14.4
2^ 8
2.3
50.6
3.37
22.6
48.7
38.8
16
—
—
—
—
—
—
>71
D-l-10
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Sample #8
SVC216NA - Sediment sample collected at
Combined results of two analyses
Ret.
Time
(miri) Formula Name
1
1
3
3
5
6
6
6
7
8
8
9
9
9
11
12
12
13
14
14
16
.67
.83
.11
.58
.11
.42
.5
.8
.83
.08
.41
.08
.42
.66
.2
.33
.25
.58
.0
.49
.41
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
9H10
9H8
10H10
10H8
11H10
12H10
12H12
12H12
13H12
12H10
12H8°
13H10
13H10°
14D10
14H10
15H12
C15H10
C16H12
C16H10
Indane
Indene
Methyl-indene
Naphthalene
Methylnaphthalene
Diphenyl
1-Et hy Inaphthalene
2-Ethylnaphthalene
2-Methyl-biphenyl
Acenaphthene
Dibenzofuran
Unknown
Fluorene
Hydroxyf luorene
Unknown
d10-Anthracene (std)
Anthracene
Methyl-phenanthrene
Me thy lene-phenanthr ene
Dibenzohepta-fulvene
Diphenyl diacetylene
Valley
MW
118
116
130
128
142
154
156
156
168
154
168
182?
166
182
196
188
178
192
190
204
202
Creek
Rel.
Area
.97
.45
.4
>36.9
25.3
6.88
2.11
2.75
1.49
>25.86
20.54
>27-7
1.22
1
>52.5
7.8
—
—
21.4
Quant .
in ng.
53.4
24.8
22.0
>2028.6
1392
378.5
116.3
151
82
>1422
1130
>1524
67.2
55
>2887
429
—
—
>1178
Cone.
(pom)
17
8
7
>676
464
121
38
50
27
>474
377
>508
22
18
>960
143
-
-
393
.8
.3
.3
.8
.4
.3
-
-
D-i-n
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Sample #8 - continued
Ret.
Time
(min)
Formula
Name
Rel. Quant. Cone.
MW Area in ng. (ppm)
17.49
18.66
20.08
1-Methylpyrene
Benzanthrone
Chrysene
216
230 0.83
228 8.22
46
454
15.3
151
D-l-12
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APPENDIX D-2
QUAL II COMPUTER PROGRAM
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QUO
A
b
C
0
£
F
b
H
A
b
A
b
C
A
B
C
U
A
t)
C
U
i.
SUBROUTINE ALGAES
COMMON A(SOO) ,0(500) ,C(500)-,X(5of.i) ,3(500) ,Z(500) , h(500) ,G(500)
CUM'-ION /BLK1/ ICLi)KiJ(75,20) , CllEFO V ( 75 J , EXPPQ V (75) , CL'EF till ( 7 5) ,
EXPO'JH(7S) ,EXPIJK2(75) ,RCHIO(75,5) , k-1 HGK ( 75 ) . kkTEf.'R ( 75) ,
C.-U,MN(/5) ,CK1 (75) ,CK3(75) ,K2('PT(75) ,CK?(75) , CUE UK 2 ( 75) ,
TAPGi»l»(7S) , rAl.ir;ijH(7S;f>) , NCFLRn(75) / I FLAG (7 5, 20) ,ALPHAO(75) ,
C K 'i ( 7 5 ) , C K 5 ( 7 ';> ) , C KMri'< ( 7 5 ) , C K Ml.) 2 ( 7 5 ) , CK NO? ( 7 5 ) , Sr,.H 3 ( 7 5 ) ,
C:JLIW(75) , ALRl (/5) fPHUSK /SO ,Ci'lH3I(/5i) ,CM)2I (75) ,i-'H75) ,T1(75) ,
Oi)I (75),riUDI(75), C'ONSI(75) , ALGSfcT (75) , SPMOS ( 75) ,CH6(75),
EXCiJFF(75),i103( 15) ,HHRAI)N( 15) ,
0 A TOT ( 1 5 ) , HwH'JO (15) , H'/,Ci)hiS ( 1 5 ) , VHv« ( 1 5 ) , !)E PH^ ( 1 5 ) , ULH'Ai (15),
JU.-oCID( 15,5) ,nH")HAH(lb),H.VCOLI (15) ,H'A'ALGf 15) , H'A'HCi\ ( 1 5) ,HWPHL(15)
COMMliiM XflLK'l/ FLLl\-(5'>0),l)EPTH(500),vEL(500),DTOVCL(500),K2(500),
Kl (50u) ,110(500) ,.»OD(5yO) ,COi'JS(500) ,HS'-Ef (500) ,OL(50U) , V(500) .
ALGAF (500) , PHOS(500) , CMH 5 (500 ) , CN02 ( 500 ) ,Ci'K.i3(500) , KMH3 (500) ,
K . MD2 ( SO 0 ) ,RESP:*R (SOO) ,COLI ('jflo) , GkOivTH (500) , RAIjN (500) ,
KK 1 (500) , KK2(50») ,HC'-J(500) , PHI. f 500)
CUM-HI'M /(5LKS/ MiiOMPT (12) ,0 (5) ,. ALPHA 1 , ALPHA2, ALPHAS, ALPHA4,CKIM,CKP,
CKL,i>Jtr/iT!r<,Uirj|),CLUUi/,30i.,'ET , i\ll , NJ ,TRLCD, TOFOA Y , NT, NC , TIME , wCS , L A 7 ,
L5M,LLM, £LEV, DA f , AE, 3E,0 A YOFY ,I)RYBLB , WET3LH ,OE'APT, PTI^F, TPRINT,
PELX,1SS, ALPHAS, ALI'HAf^GR'JMAXjWEiJPfM , K'CELLS,ILlSr,lKPTl,1 AUGOP,
T 1AX, iniJD'i, JSUM, IXPLr2,CKHTH,CKPTP
INITIALIZE COUNTERS
ivlHvJ = 0
N ft S = 0
LOOP THROUGH Wt ACHES AND COMP. ELEMENTS
162«
?.
3.
4.
5.
6.
7.
«j .
9.
10.
13.
15.
17.
IS.
19.
22.
?3 .
25.
29.
30.
31.
32.
35!
36.
3 / .
38.
39.
40.
C
C
C
C
C
C
n(J 100 £ = 1,MREACH
ALGU = 01 (D/C'VCELR «5,
I)U H'u J=l,MCELrf «6,
IUR = TCLuRO(I.J) '17,
C • «»«
C COMPUTE ALGAE GROWTH PATES 49.
C 50.
TC = 0.5c.f>*(T(IUW)-ft«.0) • -51.
UOK)=RESPW 1*1 .047**TC • 52.
= AL(iSET(r)/i)FPTri(IOR) 53.
54.
*tXPT)) 55,
Grill ATM ( [l.li<)=KKfi.-iTM( ICW)*1.0«i7**rC 57,
IF (;1l.inOPT (S) .E:J.o) GO TO So 5?,
D-2-1
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GKO-.TM ( IDK) - f^i'i.v M I IdK) *Ph(J3 ( Iln
REACT = GK(VTH(IO'O-KESPRK( mn)-ALSUJK 66.
P(IUK)=X(IUR)-kEACT*DlLT 6V.
S U OR )= ALGAE (IOR) f)8-
IF(ISS.GT.l) S(ILIiO=0.0 69.
JF( AL6IJ .iiT. 0.0 ) GO TU bO 70.
BtUJlO = B(IIIR) - ALGU * DTOVCL(inR) 71'.
GU Td 70 . • 72.
bO S(IOH) = S(IOK) + ALGIJ*ALGI (I)*DTOVCL(IOR) 73.
10 TF-L = IFLAG(I,J) 74.
C 75.
C MODIFY DIAGONAL AND/OR KNOWN TERRS 76.
C 77.
GO TO (101, 100, 100, 100, 100, 103f 104) , IFL 78.
C 79.
101 NrilvrNHwM 30.
SI I UK) = S(IOR) - A (IOR)*HWALG(NHvO 81.
GO I'O 100 82.
103 MA'S = NriS + l "3.
S(IOR) = S(IQR) + WSFLOW(NWS) *WSALG (NiriS) *DTOVCL (IOR) 84.
GO TO 100 85.
104 !J/,5 = M.\S-H 8b.
fl(IUR) = B(IOK) - -/JSFLO«'(i>JWS)*OTOVCL(IOR) B7.
100 CJNTI^IJE 88.
RETURN «9.
F,\iD 90.
E 300S 91.
CON ION A (500) ,8(500) ,C(500) , X (500) ,3(500)., Z (500) , i« (500) ,G (500) 93.
94.
COM'-iOM /RLK1/ ICLORO(75,30) ,COEFOV(75) ,EXPOQV(75) ,COEFOH(75) , 95.
A EXPO'JH(75) ,EXPQ"<2(75) , RCH IU (7 5 , 5 ) , RWTHnR ( 75 ) ,RNTEOR(75) , 96.
6 C.'iA-jr.J(75) ,CK1(75),CK5(75) , K2DPT(75) ,CK2(75),COEOK2(75), 97.
C TARGno(75) , I AUGUR (75,6) , fJCELRH (75) , J FLAG (75,20) , ALPHAO(75) , 98.
D C^4(75),C^5(75),CKNH3(75),CKNU?(75),CKrJ03(7b),SNH3(75), 99.
t COL !»-? (75) , ALGI (75) ,PHOSI ( 75) , C^H3I ( 7 5) ,CMIJ2J (75),i-)I(75),TI(75), 100.
f- D JI (75) ,6 00 I (75) ,CO.>:SI (75),ALGSET(75) , SPHOS175) ,CK&(75) ,
G EXCUF.F (/5) , iVAONI (75) , CNO'i I (75) , CKPHLl (75) ,C^PHL2(75) ,CKhCNl(75) ,
h CKHCN2C75) ,HCNI (75) ,PhLI (75)
103.
CO:"NO:g /BLKd/ /JS TEMP (90) , I'.SDO ( 90 ) , wSBOO ( 90 ) , WSCCNS(90) , ,\'SHCM(90) ,
A v"S»iH3(90) ,wS'"il?(90J , 1/.'SNi13(90) , i'iSCOLI (90) , '\SALG (90.) , ^SPHf.iS (90 ) , 105.
b i-vAS I ID (9 0,5) , TRFAC r (90) , A'SFLOW ( 90 ) , A'SRA!)M(90) ,hSPHL(90)
107.
CUM:10'N /HLK.?/ JOMC'( 15,3) ,HWTRIO(1 b,5) , hi-JFLOi-1 ( 15) ,HWIEMP(15) , 108.
A H.vDLKl?) , H'/jpHOSd S) , H/'MH3( 15), HAND? (15) , h,-jf«03 ( 1 5) , H/;R A DIM ( 1 5 ) , 109.
b R A TOT (15) , HMf-00(15) , H^CIJ^S ( 1 5) , MA ( 1 5 ) , OEPH.«.' ( 1 5 ) , DLH'/x ( 1 5) ,
C JU.'JC 10 (15, 5) , \'H,v«)AR(15) , H-JCOLI (15) , HWALG(15) , H'/.HCh' ( 1 5) ,HhPHL(15)
" 112.
CUi^'-lDW /BLK4/ FLU/j(500) ,nEPTH(5"0),VFL(500) ,DTOVCL(500) ,K2(500) , 113.
A K I (500) ,00(500) ,flGD (500) ,CD'\'S (500) ,HS^ET (500) ,Di. (500) ,T(500) ,
b AL'iAE(500) ,P'iuS(500) ,C'-iH3(500) ,CNU2(500) ,CWi.)3(500) , K>MH3(500) , 115.
C KNiTe? (500) , RESHhT"? (500 ) , CO'l. I (500) , R R f ) i'. T H (500) ,P/\(1N (500) ,
U KK1 (500) , ^K2(50u) , HCCU500) , PHL(bOO)
117.
COMMUN /BLK5/ N'UOUPT (12) ,0(5),ALPHAl,ALPHA2,ALPhA3,ALPHA4,CKM,CKP,
A C>\l-, NnwTRS, iM'X2 , (JT200X , 119.
b A f'-'ipk' , v'I«L>, CLsjUiV, .'ji)iiET,.-iI , MJ , TWLCI), TOP I) ft Y , MT,('\CS , L A T , 12o!
C L.cJf-',LLiV,ELE>y,uAl , AE,.^: , P A YOF Y , OR Yi.U.tf , *E TRLB , PE i<"HT , PT II-F , TPRiCj 1 , 121 ]
U DtLX, ISS, ALPHA 5, AL^HAiS, (iwow A x , PESPR T , r-iCELLS , IL I t-T , I wP T] , TAlJGDP, 12?]
D-2-2
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t TMAX, IfiUDb, J8JK, IXPLT2, C-lLr* (Kl (IOi<
148.
JF(ISS.GT.l) 3(IOR)=0.0 149.
IF( BOIUJ .GT. 0.0 ) (50 TO 90 150.
iMIQR) = B(IO.'<) - flUDIJ*nTOVCL(IOR) 151.
GU TO 95 152.
90 .SHOW) = SUOtf) •*• BODIJ*BO.DI ( I ) *DTOVCL ( IOR) 153.
95 IFL = IFLAGU,J) 154.
C 155.
C NiOOrFY DIAGONAL ANO/OK KNOWN TERMS 156.
C 157.
Gu TLI (101,100,100,100,100,103,104), IFL 158.
C 159.
101 NH'.'; = iVHi<\/-H 160.
SU-.)R)=S(in«)-A(irjR)*H'«BOOCNHW) 161 .
GO TO 100 - 162.
103 NrtS = r-KvS + l . 163.
SlinR)=S(IOR) f.MSFLOri(NwS) */'SBOn (NWS ) *DTU VCL ( I OR ) 164.
GO TO 10.0 165.
104 'M'.vS = W,MStl 166.
6 t IOW)=6(IOR)-:'iSFLn,MCl\iWS)*DTCVCL(IOR) 167.
JUO CONTINUE 168.
RETURN '169.
EM) 170.
SUBROUTINE HC.NS
C
COMMON A (500) ,8(500) ,C (500) ,X (500) ,5(500) ,Z (500) ,.•; (500), G (500)
C
COMMON /BLK1/ ICLORl)(75,20),COEFOV(75),£XPni3V(75) ,COEFOH(/5) ,
A f. XPOWH(75) ,EXPQK2(75) , RCH ID (7 5 , 5 ) , R^THOR ( 75 ) , R'-TEL'R ( 75 ) ,
13 C'lA;MN(75) ,CK1 (7b) ,CK3(75) ,K2IIPT(75) ,CK2(75) ,Cl;EGK2<75) ,
C TAH&D'.I(75), IAHG:.)R(75,6) , WCELRH ( 75 ) , I -FLAG ( 7 5 , ?. u ) ,ALPrtAO(75) ,
L» CK4(73),Ci\S(75),CKf-JH3l75) ,CKN02175) ,CKN03(75.1 , SWH3C75) ,
E COLIR(/5) , ALGI (75) ,PHOSI(75) ,CH,M3I(75) , CNU2 T ( 75 ) , (J I (7 5 ) , T I ( 7 5 ) ,
F U01 (75) ,BOI)i(75) ,CI"INSI(75) , ALGSET (75) ,'SPHUS ( 7b) ,CK6(75) ,
G EXCOEF(75),i AI.G I 90 ) ,iNSPHU
b 'A AS TIO (90, 5) , I HF ACT (90) , WSFLO-V ( 90 ) , .vSKAON (90 ) ,«bPhl. (90)
D-2-3
-------�
C J..1 ifi'M /t!LK:5/ JUi^C ( 1"5, 3) , H'.\TRID ( 1 S, 5) , HAFLU*( 1 5) , Hwl E >'.P ( 1 5) ,
A H,MDU(15) ,HWH>HUS( Irj) ,H'vNH3( 1 5) , H.vMG2( t S ) , hv\ '-10 3 11 5 ) , H'.vR ADN U 5 ) ,
ti UATOT C 15) , HABUO ( IS) , H.-.CQN3 ( 1 5) , VH,v( 15) , OEPHW ( 15) , L>LHw ( 1 b) /
C JUNG 10 ( 15,5) , iMH/MAR( Ib) , H.VCULI CIS) , HKiAL6(15) , HV.'HCN ( 1 5 )", HWPHL (15)
C
CG'-HON /RLK4X FL'JA'(500) ,0EPTH(5UO), VEL(500},DTOVCL(500),K2C500) ,
A Kl (500) , Oil (500) , Him (500) ,cn,M3(500) ,hSi\ET (500) ,DL (500) ,T 1500) ,
ti ALl7Af£(500) , PHOS(SOO) , CWH3 ( SOO) , CNU? (500) , Cr\'U"< (SOU ) ,KNH 1^(500) ,
C K.N02(500),RESPH!V(tiOO),CULI(50u),GROrtTri(500),RAOiM(500),
D KK1 (500) , Ki\2(500) , HCNC500) ,PML(500)
C
COMMON /RLK5/ MOO OPT (12) ,0(5)/ALPHAl, ALPHAS, ALPHA3, ALPHA a, CKN,CKP,
A CKL,il'V..vTRS,.MRl£ACH,N,vAST£,MJiJ^C, UELT , I) 1 LT , D2LT , D n..)t'X2 , 0 T20U X ,
b A TMPK , ;, I ND , CLUDO , SOME T , fvi I , IM.J , T RLCU , T HF 0 A Y , M , NC , T T KE , NC S , L A T ,
C L5M,LLM,ELEV,DAT, AE , BE , U A YOF Y , D^ YBL8 , i"ET3LB , OEWP.T , P T I ME , TPRIIMT,
LJ l)ELX,ISS, ALPHAS, ALPHA6,GROM-AX,RESPHT,:\iC£LLS,. I LIST, I«K'Tl,IAUbOP,
E THAX,IdU05,JSuM,IXPLT2,CKHrP,CKPTP
C
REAL KK1 ,KK3,K1,K3
C
C INITIALIZE COUNTERS
C
C
C LOOP THROUGH REACHES AND CUKP. ELEMF.MTS
C
DO 100 I = l,i\)REACH
HCMJ = OKI) / CNCELK
DO 100 J=1,NCELR
IUR=ICLORO(I, J)
C
C INITIALIZE DIAGONAL AND KNOWN TERMS
C
1 C = 0 . 5 56 * ( T ( I ijfv ) -Ml . 0 )
i^)l (T/*CKH1*P**TC
REACT =OILT*(KK1(I UK) +KK3)
B lTiJR)=x(IUW)+REACT
S(IUR)=HCfJ(IO«)
IF(ISS.GT.l) S(IOi<)=0.0
IFCHCUTJ .RT. 0.0 ) GO TO 90
B (IOK)=B(ItJiV) -HCI\'IJ*DTOVCL(IUK)
CU Til 95
90 S(IOR)= S(IOR) + HCNlJ*HCi'Ml ( I) *DTOVCL (IOR)
(>5 IFL = IFLAG(I,J)
C
C MODIFY DIAGONAL ANO/OR KNOWN TERMS
C
GO TO (101,100,100,100,100,103,104), 'iFL
C
101 NriW = NHV-'*-l
S( lUIOs.-i (I OR) -A (IOR) *HWHCN(MHW)
cb ro lou
105 NvjS = fJ.n'S+l
S(I.JR)=6(IO-R)-M';SFLO -V(NWS) *WSHCN (MwS ) *OTUVCL
Gu TO 100
1 u a N f, s = v w ,s + 1
B UuR) =>> ( IOK) -rtbFLOw (WWS) *DTOVCL ( I UK)
1UO CUNfl.JUE
RETURN
f.'E PHLS
D-2-4
-------�
ACaOO) ,H(5.lO) ,CC500) ,X(5UO) ,SCiUO) ,Z(500) ,.'i(bO(j) ,G(SCO)
CUMMUN /HLK1/ I CLUNI) ( 75 , 20 ) ,CUEFQV ( 7S J , E XPIit.; V ( 75 ) ,COEFQH(75) .
A EXPUQH(75) , EXPfJ*2(75) iRCHIO(7.5r5) » RMThOR-( 7 5 ) , WMTEUR ( 75) ,
B C.4AWU75) , CKl 175) ,CI<3(75) , K2UPU75) ,CK?(75) ,Ct'EOK2(75) ,
C TARGU'J(75) , I AuG<)iU73, b) , r,SO^ET,i\II,NJ-, TRLCf), TOFO A Y , MT , NC , T I ME , NCS ,L AT ,
C LSM,LLK,ELEV,OAT,AE,BE,i)AYOFY,ORYBLB,ftETBLP,nEWPT,PTIME, 1 PR I NT,
U OELX,ISS,ALPHf\5,ALPHAb,GRUMAX,RESPRT,NCELLS,ILIST,IRPTl,lAUGOP.
t T-1AX, IB005f JSlJM, I XPLT2 , CKHTP , CKPTP
C
REAL iO=0.0
IP ( PHLIJ .GT. U.O) GO TO 90
B(IU!<)= b(IOR) - PHLIJ*UTOVCL(IOR)
GO TU 95
90 sdJR) = sumo* PHLIJ*PHLI (I-)*UTUVCL(IOR)
95 TKL = IFLAG(IrJ) •
C
C WHOIFY DIAGDMAL AMD/OR KNOWM TERMS
D-2-5
-------�
c
GU TO (101,100,100,100,100,103,104), IFL
C
101 W H f) - N H I'v 1 1
S(IOR) = S(IOf<)-A (inR)*Hrt-pHL d'JHA')
GU ru 100
103 N»\'S = MrtS-t-l
SUL'lK) = S(inR)-f.\'5FLth'> (MAIS)* "\ISPHL (NWS)*DTOVCL (I OR)
GO TO 100
B ( TOR ) =B ( 1 OR) -'.NSFLOiN (M*iS) *0 TOVCL ( I OR )
1UO CONTINUE
RETURN
SUBROUTINE COLI3 171
C 172
COMMON A(500),B(500),C(500),X(500),S(500),Z(500),rt(500),G(500) 173.
C 171.
COMMON /BLKl/ ICL(JRO(75,20) ,CUEFOY(75) , EXPOUV (75 ) , COEFQH ( 7 5 )., 175.
A EXPUQh(75) , EXHfJ<2(75) , RCHID(75,5) , RMTH.li} ( 75) ,KMTEOR(75), 176.
b C'-1A(\-M(75) ,CK1 (75)rCK3(7^),K2UPT075)rCKa(75) ,COEQK2(75) , 177.
C TAR«0'J(75) , lAUGQ'U 75,6) , NCELRH ( 75) , I FLAG (75, 20) ,.ALPH AO ( 75) , 176.
I) CK4 (75) ,CK5(75) ,CKI-JH3(75) »CKW02(75) »CKNU3(75) ,Si\)H3(75) , 17').
fc COLI»(7S) ,ALGIC75J ,PHUSI (/5) ,ClvH3[ (75) ,C!VU2I (75), U I (75), Tl (75), IflO.
F HOT (75) , KOni (75),Cn.\)SI(75),ALGSET(.75),SPHQS(75),CK6(75),
G EXCUEF(75),RAO^I(/5),CKU3I(75),CKPhLl(75),CKPHL2(75),CKHCfJ1(75),
H CKHCN?(75) ,HC^I (75) ,PhLI (75)
C 193.
CUMMOM /PLK2/ wSTE^PC90) ,WSDO(90) , WSBOOC90) , WSCONS(90) , W5HCM (90 ) ,
A WSf'H3(9i» , v.'Srju2(90) , «SNU3(0 ) , VEL1500) , DTOVCL ( 500 ) ,K2(500) , 193.
A K I (500) ,00(500) ,8UI) (500) ,CO?JS (500) ,H3NET (500) , IL (500) ,T (500) ,
6 AI_GAE(500) ,PHCiS 1500) fCNH 3(500 ), CMOS (500) , Cl'.l.i? ( 500 ) , K MH3 ( 50 0) , 195.
L Kf-iri2(500) ,RESPRR(500) ,COLl (500) , G^OviTri (50 0 ) , RADM(500) ,
0 KK1 (500) ,KK2(500) , HCN(SOO) ,PHL(50u)
197.
CUMMON /BLK5/ MUO.OPf ( L2) , D ( 5 ) , ALPHA 1 , ALPHA 2 , ALPHA 3 , ALPHA H, CK N , CKP ,
A CKL,r-]i-)/JrRS,i\'REACH,Mi/.ASTe,.WJH^C,OELT,0 t L T , 02L T , DTODX2 , 0 T200X , 199.
b ATMPR,>virjU,CLUili>,30:>FT,i.ir,^J,TPLCO, rOFnftY,r.!T,,VT,TIMF. ,i\T.S,LAT, 200.
C I.3M,LLM,ELEV,OAT, AE,rtE,ljA YOF Y , OK YBlli , i',c T HL8 , OE^PT , P TI MF , TPK1 1 NT , '201.
t) OELX, lS3,ALPHA5,ALPHAfe,GRni-:AX,,?ESPRl , -\CELLS, IL I ST , I u'PT 1 , J AUGIJP , 202.
E MAX, I BUD 5, JSUM, I XPL T2 , CK H TP , CKP TP
204.
REAL K5
C 206.
C INITIALIZE COUNTERS 207.
C 208.
NrtW=0 209.
c 211.
C LOOP THROUGH REACHES Ai\0 CO.'iP. ELEMENTS 212.
C 213.
00 100 I=1,MR£4CH 214.
NCELR=MCELRH(I) j!
216.
CULIJ = UI (D/CMCELR 217!
DU 100 J=l,iViCELK 21^!
(I, J) 219]
220.
D-2-6
-------�
C INITIALIZE DIAGONAL AND KNOW,\ TERMS 221.
C 222.
TC=0.556*(T(IOK)-66.0) 22 5 ,
K5=CK5(I)*1.0/l7**rC 221.
REACT=01LT*K5 225.
fl(H)R)=x(inR) Kmo*) - CUL1J*DTUVCL(IOR) 210.
GO TO 95 231.
90 S(IOH) = S(tGK) + eOLIJ*COLIR(I)*DTC)VCL(IQR) 232.
V5 IFL = IFLAG(I,J) 233.
C 231.
C MOOIFY DIAGONAL AND/UK KNO/tN TERMS 235.
C • 235.
GO TO (101, 100, 100, 100,100, 103, 104) , IFL 237.
C 238.
toi NHW=NHW-H 239.
S(IOR)=S(IOR)-A(IOR)*HWCOLI (MHW) 210.
GO TO 100 211.
C 202.
103 N/JS = NWS + 1 213.
S(IQRJsS(inR)+WSFLO»il(NWS)*WSCOLl'(NWS)*DTOVCL(IOf<) 21'l.
GO TO 100 2«5.
C 216.
10'4 NirtS = NWS-M 217.
R ( I OR) =iHIOR) -WSFLOrt (NWS) *DTOVCL (IOR) 21 8 .
100 C DM T I Ml IE 219.
RETURN 250.
END 251.
SUBROUTINE COfMSVT 252.
C 253.
C CONSVT PERFORMS A CONSERVATIVE MINERAL 251.
c BALANCE FOK EACH COMPUTATIONAL ELEMENT 255.
C Ii\i THE SYSTEM. 256.
C • 257.
C ' " 253.
CUNHOiM A (500) ,8(500) ,C (500) , X (500) ,S (50 n) ,2(500), W (500) , C- (500) 259.
C 260.
CL'M.vlOM /ciLKl/ ICLURU(75,20) ,CuEFiOVt75) ,EXPOuV(75) ,Cl!EFQH(75) , 261.
A EXPOfJH(75) ,EXp;OK2(75) ,RCHID(75,5) ,RMTHUR(75) ,RMTEOR(75) , 262.
B CMAfJf!(75) , CK1 (7 '5) ,CK3(.75) ,K20Pf(7b) ,C!\2(7ti) , CljEOKg ( 75) , 263.
C TARGOOC75) , I A.J'iilR I7'j , 6 ) ,NCELRH(75) , IFL AG ( 7 5 , 2l> ) , ALPH AU ( 75) , 264.
D CK/4 (75), 0^5(75) , CKNH .< ( 75) , CKM02175) ,CKK'03(75) , S\H3(75) , 265.
t CilLTR(7b) , ALGI (/5) ,!JHOSI ( 7 5 ) , CNH? I ( 7 5) ,CNU2I(75) , t) I ( 7 S ) , T 1 ( 75) , 266.
F Oul (75) , ROD I (75) ,CU/-'SI (75) ,ALGSET(75) ,SPHUS(75) ,CK6(75) ,
G' E SPHUS (90 ) , 271,
(3 WA3IID(90,5),TRFACr(90) ,>MSFLO«(90) ,wSRADN(90) ,i'.SPHL(90)
C 273.
CLiMilOM /HLK3/ JllNC(15,3) ,HiMTHID(l5f 5) »HwFLnw(l5) ,H*iTEMP(15) » 274.
A H/vOO(l5) , HV\'PHOS(15) , H>/»MH3 ( 1 5 ) , H^i\!U2 ( 1 b)., HV.ND3 ( 1 5) , HftR AOl-i ( 1 5) , 275.
b fJATOT(15) ,HrtRODU5)/HwCONS(15)f VHft(l5) 'OEPH' ( 1 5 ) , DLHW ( t 5) ,
L JUNG ID (1 5 » 5) ,!\iH.VrtAR(15) , HivCOL I ( 15) , HWALG ( 15) ,H'/,HCi^(15) ,HViPHL(15)
C • -278.
COMMON /BLK1/ -FLOivCSOO) ,D£PTH(5no).VEL(500) , OTOVCL (500 ) ,K2(500). 279.
A Kl (500) f DIJCiOO) ,H.JU(500) ,cnrMSl5»0) ,HSkET(500) ,GL(50u),T(500),
U ALGAE(500) ,PHUS(500) ,CMh3(500) ,CWU2(500) ,CW03(500) ,KMH3(500) , 281 .
C K:JU2(bOO) ,RESPRR(5i>0) ,CUI.[ (500) , KROwTH ( 50 0 ) ,KAC'ii(500) ,
D KK I (50(i) ,-\K2('D(lO) , HC U500) ,PHL(50o)
C 283.
COMMON XHLK'i/ MUODPT ( .1 2 ) , I) ( 5 ) , ALPH A I , ALPH A2 / A L PH A3 , ALPH A/4 , CKN , CKP ,
D-2-7
-------�
A CKL,iVt'A I R3, .\!RbACH,N!.\ASTt, ••MJUNC, OELT , 01L1 , P2LT , 0 f IU)X2,0 r2UUX ,
ti AT^PR,nIND,CL01IJ, SOf.'ET , !\'T,NJ, CHLCD, T UFO A Y , NT , K'C , T I ME , "tCS , L A T , 286.
C LSM,LLN',ELEV,i>A I", AF. , BE , 0 A YOF Y , OR YrjLtt , wOBLR , OE ViPT , FT I ME , TPRIHT, 2«7.
0 DELX, ISS, ALPHAS, ALPHA6,GROM AX., RE SPRr,.\'C ELLS, fLli>T,[WPfl, I A HOOP,
t T«IAX, lbLil)5, JSiJM, IXPLT2,CKHTP,CKPTP
C
C INITIALIZE COUNTERS 291,
C ' 292.
MHW=0 293.
C
C LUUP THROUGH RtrtCHES AMD CUMP- ELEMENTS 296.
c
DO 100 1=1, BREACH
NCELR=NCELRH(I) 299.
Ci'MCELK = '\)CEL« 300.
CUNSIJ = UICI) / CNCELR 301.
00 100 J = 1,'-4CEL« 302.
IOR=ICLORO(I, J) 303.
C 30a.
C INITIALIZE DIAGONAL AND KNO^N TERMS 305.
C 306.
B(.IOR)=X(IDR) 307.
siiow)=cnr-is(iaw)
IF(ISS.GT.l) S(IOW)=0.0 309.
IF( CO.'iSIJ .Gl. 0.0 ) GO TO 90 310.
B(IUR) = ri(IOK) - CONSIJ * OTOVCL(IQR) 311.
GO TO 95 312.
90 S(T!JR)=S(IO>}) tCOMSIJ*CONSI (n*OTOVCL(inR)
95 IFL = IFLAG(I,J) 3 1 <4 .
C 31S.
C MODIFY DIAGONAL A'vJD/OR KNOrtM TERMS 316.
C 317.
GO TO (101, 10U, lUOf 100, 100, 103, 104>» iFL 31H.
C 319.
lUl NHWsNHrt-t-1 320.
S(iaR)=S(IOR)-A(IJR)+HWCOiMS(MKW)
GO TO 100 332.
C 323.
103 N,u.S = N«-S + l 324.
S ( IJin =5 ( IOR) +v\JSFLO!v (N'.'iS) *WSCONS (M/JS) +OTOVCL ( IOR)
GO TO 100 326.
C 327.
104 NA'S = N-TlS-fl 32q.
B tIQR)=;i(IO«)-w'SFLOA'(!\JWS)*DinvCL(iOR) 329.
1UO CUMri.'JUE ' 330.
RETURN 331.
END 332.
SUBROUTINE DOS 333.
C 334.
CUMi'lCM A C500) ,815003 ,C (500) ,X (500) ,3(500), Z (5(M)) ,« (500) ,G (500) 335.
C 336.
CLIMMOM /BLK1/ ICLORi:>(75,20) ,ClJEFQV(75) ,EXPQQV(75) ,CCEFQh(75) , 337.
A EXPUfni(75) ,EXPf)K2(7S) ,RCH.U)(75,5) ,RMTHOR(75) ,RMTEC.R(75) , 333.
ti CMAiMi-;(75) ,CK1(7S),CK3(75) ,K2UPT(75) , Ch.2 ( 75) , CuEOK 2 ( 7 5) , 339.
C TARGDiJC/5) , IAUGOrU75,6) ,MCELRH(75),JFLAG(75,20),ALPHAU(75), 340.
l> CK'J(75) ,C'N5(7'j) ,CKiMH3(75) , CKM.I2 ( 7 5 ) ,C^N03(75) , SMH3(75) , 341.
t CDLIR(75) ,ALGI(75) ,PHOSI ( 7 S ) , CMH3 I ( 7 5 ) ,C(MU?I(75) ,OI(75),TI(75), 342.
F l;.Jl (75) ,001)1 (75) , COHSI ( 75 ) , AUGSh'T ( 7 5 ) , SPHi.KS ( 7 5) , CKb ( 75 ) ,
G EXCl)KF(7S) , RAOi'JI (75) ,CNU3I (7S) ,CKPHL1 (75) ,CKPnL2(75) , CKHCN1 (75) ,
H CKHCri2(75) ,HO.'I (75) ,PriLI (75.)
C 345.
COMMON /HLK2/ WSTE"1P(90) , i-J S 0 0- ( <•' 0 ) ,WSHO(H90) , WSCONS (90 ) ,wSHCN(90) ,
A dSNHS (90) , iMSfHi? (9U) , NSN03 (qii) , 1'iSCOLl (90 ) , wSALG (90) , WiSPHUS (90) , 347 .
b WAST Tu (90, 5) ,1RFAC T (90) , -'JSFLOw (9u ) ,i<,Sk4iMM(90),hSHHL(90)
C 349.
D-2-8
-------�
/BLK3/ JUi'-ii; U4,3) , H'MiMlU t li,b) , H -.-, F i_ 1 1 .-.• ( 1 5 ) , MM H>,P ( 1 5) , 350,
A H, •([)()( 15) , Hftl->HuS(l5) , H,-:NH3(15) , H/VWU2 ( 1 5) ,H.-jMU3Ub) , HvvKAON ( 1 5) . 351 .
b 11 A TOT 1 15) ,HvvBUD( 15) , HwCOiJS( 1 5) , VHw (1 b ) , DEPH^ ( 1 5) , ULriW 1 1 5 ) ,
C JUMCIO(15,5) ,NHiVft'AH(l5) , HuCUL I ( 1 5) , HWALG ( 1 5) ,H*HCN(15) , HWPHL(lS)
C 35 a.
COMMON /[HLK4/ FLnv(500) ,DEPTH(500) , VEL(SOO) ,nmvCL-(50i)) ,K2(500) , 355.
A Kl (50U) ,DOCiOu) ,8110(500) , COMS(5uO) , HSiVFT ( 5 "I; ) iOL (50u) ,T(500) ,
8 ALGAF(SUO) ,PHOS(5uO) ,ct!HM500) ,0112(500) ,CN03(500),KNH3(500), 357.
C KiMU2(500) ,RESPKW(500) , CL'Ll (500) , GROWTH (500 ) ,KAP(j(500) ,
0 KK1 (5uO) ,KK^(b'iO) ,HCM(500) ,PHL(500)
C 359.
CUMMOW /BLK5/ MOOi)Pr(12) ,0(5),ALPHAl,ALPHA2,ALPHA3,ALPHAa,CKM,CKP,
A CKLfl-'HWTRSjNRfeAChfNwASTEfNJUMC.DFLTrnnLTfDPLT.PTODXa.DTatlDX, . 361.
H A TMPH , WIWI) , CLUUIJ , Slir»'ET , IM I , MJ , TRLCU , 1'OFD A Y , NT , .v'C , T [M£ , NCS > LAT , 362 .
C L3M,LLM,ELEV,UAT, AfjBE/DAYOFYfORYHLB.'^ErBLB.DEWPT/PTlf-'EfTPRlMT, 363.
U neLX, I5S, ALPHA 5, ALPHA6,G« UMAX, « ESP Rf,;\lCELLS, IL 1ST, IRPT1 , IAUGOP, 363.
t TMAX, U»0l)5, JSUW, IAPLT2,CKHTP,CKPTP
C 366.
CUM:'H.)N/3LK8/ALPHA7, ALPHAS
C
/BLKb/ ALPHA9,CKiVH2(75) , dvH2 I T ( 75) , CMn2 I ( 7 5 ) , HWNH2 ( 1 5) ,
,C-iH2(500) ,KHH2(500)
WEAL KO,K1 ,K2,Kf\'H j,KW03,KNH2 367.
368.
ON AM ASSUMED 369.
WRN ...... 370.
371.
372.
373.
374.
375.
376.
377.
378.
379.
3«0.
i«l.
382.
383.
38/1.
385.
386.
387.
388.
339.
390.
391.
\f
r
c
c
c
c
c
c
c
c
....CONVERT BFTWEEN ULTTMATF Ai\iH ^-OAY HDD BAS
....LAB DECAY RATE OF o
TF( T.BOU5 .EO. Q >
CFBill) = 1.0 - EXP(
IvERT = 0
10 IVERT = IVERT + 1
Ir( NrtwTNS .LE. 0 )
Du 20 J = 1 , IMHWTRS
HwfVJD(J) = Hfc'4CHJ(J).
20 CUiMTINUE
25 IF( N'AASTE .LE. 0 )
DO 30 J = 1, iMWASTE
X.\ = THFACT(J)
IF( TRFACT(J) .LT.
CF = 1.0 - EXP( -5.
IF( Ty/EHT .EO. 2 )
.'A'SROLK J )• = .VSHlli) (J)
30 cuwriMJE
35 DO 45 J = 1, NREACH
MuHUJ) = 8011 1 (J) /
r\)CELR = MCFiLRri(J)
DO 40 K = 1, ,JCELR
IUR = ICLORD(J,K)
ROO(IOW) = dOD(K)rf)
45 CUNriNME
IF( TVhRT .GE. 2 J
CFfiOO = 1.0 / CFBOf)
50 CONTINUE
MHVv = 0
FACT = 01LT / 2o.3
,23/DAY (BASE E )
GO TO 50
-5.0*0.23 )
GO TO 25
. / CFBOO
GO TO 35
0.001 ) XK = 0.23
0*XK )
CF = 1 .0 / CF
/ CF
CFBOO
/ CF300
RETURN
INITIALIZE COUNTERS
LOOP THROUGH REACHt
393.
394.
395.
396.
397.
398.
399.
400.
401.
402.
403.
404.
405.
406.
ND COf/.P. ELFMENTS 407.
408.
Du 100 l = l,.MKEACH 409.
D-2-9
-------�
id) 41 °•
DUIJ = ul(I)/CMCtLR 412'
DO 100 J = 1,>IC£LR at3'
IOR=ICLURD(I,J) 41q'
C 415.
C INITIALIZE DIAGONAL AMD KNOWN TERMS 416.
C •
S(.IOR)=DO(IOR) 418.
fit I OR) = 0.0 419.
IF CISS.GT.l) S(IOR)=0.0 420.
IF( IH>IJ ,GT. 0.0 ) GO 10 60 421.
BlfOP) = B(IOR) - I)OIJ*OTOVCL(IOR) 4?2.
GO TO f>5 423.
60 SHOW) = S(IUrt) + OOfJ*OOl(I)*rmJYCL(IOK) 424.
b5 VF( MOOOPTU) .LT. 1 ) GO JO .90 425.
AH'EACl=(ALPHA3*GRl)wTH(TOR)-ALPHA4*RESPRR(IOR))*01LT 426.
StIOR) = S(IOW) + AKEACT*ALGAE(IOR) 427.
90 IF (MOnUPTCe.).LT.l) GO TO 92
S(IJR) = S(IOR) - ( ALPHA5*K \H5( I UK) *CiMH3 (IOR) +
1 ALPHA tL r* (KO*L)OSAT-K H IOR) *^00 (TOR.) ) 442.
SlTOR) = S(IO^) > REACT - A ( IOR) *HvMDO (MHW) 443.
B(IOR) = tt('lOK) + XdOFO + Q1I.T*KO 444.
GO TO 100 .'J45.
C ' 446.
102 K(j=(0.5*(K2(lLW-l)+*2UL.i"0))*1.0159**TC 447.
RtACT=OlLT*(KU*L)C)SAT-^l CIOR ) *300 (IOR) ) 448.
SC10R) = S(IOR) + K15ACT 449.
WIIOK) = B(If)H) + X(IOR) -f OtLT*KO 450.
Gu TO 100 451.
c 452.
KD=(0.5*tK2(IOR-l)+K2(IOR)))*i.oi59**TC 454!
RtACT = Q1LT*(KO*UOSA T-K1t COR)*30'H TOR)) 455.
SlTuiO = S(IOR) + RtACT + /iSFLOVJ (iMA'S ).*^SI.n'J dxwS) *DTOVCL (IOR) 456.
'3(IOR) = S(IOR) + X(TOR) + D1LT*KO 457.
GO TO 100 45(3.
c 459.
1 U 4 I J 11 -g C = IJ 0 N C11 460.
M S =1 461.
Ku= (0 .25* (i<2 ( IOR-1) +K2 (••-lO) >2.0*K2 (IOR ) ) ) * 1 .0 159**TC
Si TOW) = S(Ii)«) + REACT 4^,5]
B(I:JR) = BCiOrO + X(IOrt) + OILT*KO 466.
GO TO 100 4^7(
c 463.
105 iM/VS = »l/»S+l 469,
KU=(O.S*(K2(ICJR-l) tK2(IOR) ) ) * I . 0 1 59* * T C 470,
PEAC l=niLT* (K:.)*i)nSAT-Kl (IOR) *flOO( IOR)) 471 ,
SlIOiO = S(IU.<) * REACT 473'
B(IOR) = U(IOK-) + X(IOH) t UlLT*Ki.l - wSFLOW (iViwS) *DTO VCL (IOR) 475,
1 00 CON TI -JOE 474,
D-2-10
-------�
IF( IBOD5 .EQ. 0 ) RETURN 475.
GO TO 10
END
SUBROUTINE FLOAIIG
C 479.
C . 480.
C FLOAUG SEARCHES THROUGH THE SYSTEM BY n&\.
C REACH TO DETERMINE THF MINIMUM DLI LEVEL 4rt2.
C WITHIN EACH REACH. EACH OF THESE MINIMUM 483.
C' OU LEVELS IS CHECKED AGAINST A SELECTED 484.
C WITHIM EACH REACH. EACH hF THESE MINIMUM 483.
c TARGET LEVEL. IF FLOW AUGMENTATION is 485.
C REQUIRED, THIS FLOW IS DISTRIBUTED 4fliV.
C EQUALLY AMONG THE - HEADWATER SOURCES THAT 487.
c ARE AVAILABLE TO A GIVEN K-EACH. 488.
c 4 n 9.
C 490.
COMMON A(500),B(500),C(500),X(500),S(500),Z(500),w(500),6(500) 491.
C 492.
COMMON /BLK1/ ICLORD ( 75 , 20 ) , CGEFfj V ( 75 ) , EXPfliJ V ( 75) , CUEFQH ( 75) , 493.
A EXPOQ.-K75) ,EXPQK2(7S) ,RCHID{75,5) , R«iTHI.iR (75) , RMTEOR (75) , 494.
b C*A.MN(75) ,-CiU (75) ,CK3(75) ,K20PT(73),CK2(750 , CUEiJK2 ( 75) , 495.
C TARGOiJ(75) , IAUGi.iK(75,6) ,NC£LRH(75),IFLAG(75,2u),ALPHAO(75), 496.
U ^4(7^) ,CKS(75) fCXNHS^1:)) ,CKNU2(75) ,CK!H,l3(7b) ,SMH3(75) , 497.
h CULIRC75) , ALGK75) ,PHQS[(75) , CNH3 I ( 75 ) , CM02 I ( 7 5 ) , U I ( 75) . T I (75 ) , 493.
F 001(75) , Bi.iOI (75) ,COiMSI(75) , ALGSET (75) , SPHUS ( 7 5 ) ,CK6(75),
li ExrOEF(75) ,-JCIiHl5,5) , SMH.VAAR(15) ,H.«COLI'( 15) , HfcALG (15) , HWHCN(15) ,HWPHL (15)
C 510.
COMMON /BLK4/ FLO/H500),DEPTH(500),VEL(500),01OVCL(500),K2(500), 511.
A Kl (500), DO (500) ,i300(500) , COiMS (5C-0 ) , HSNET (500 ) , OL ( 500 ) , T (500 ) ,
H ALGAF. (500),PHOS(500) , CMH3 ( 500 } , CNG2 (500 ) , CN03 (500 ) ,KMH3(500) , 513.
C K''Jt)2(500) , R£SPR!<(500) ,COLl (500) , RRCHu Tri (500 ) , WAOU(500) ,
D KK1(500),KK2(5DO),HCN(500),PHL(500)
515.
/HLK5/ MODUPTU2) ,0(5) , ALPHA 1 ,ALPHA2 , ALPHA 3 , ALPHA a , CKN , CKP ,
. i i_t -r it o ,i r» rr A r~ ^s ..i... A c T ir At i i i M i"> i-\ c: i T i'v 1 i T r\ ~i i T r\ T ri i . v —. c% T -»i M> v
TMAX,IB005,JSUM,IXPLT2,CKHTP,CKPTP
C 522.
C 523.
DIMENSION IIJfMIi>K75),RMIL£(75) , DOM IN (7 5) ,IORDtfU75) ,QAUG(15) 524.
C 525.
C 526.
C STEP 1-0 527.
c INITIALIZE ALIMENTATION FLOWS 528.
DO 5 wH*=l,m
-------�
REACH AMD IIS LOCATION BY RIVER
C
C
C
C
C
C
C
C
C
C
C
r
nil SO 1 = ] , MREACH
ouMU'(i) = ioo.o
IF(flll.'iA'AFUT) .EfJ.O) GO TO 50
NLELU=NCELRH(I)
DU 100 ,l = l,fJCHLR
IOR = rCLOivO(Ii J)
IF (Oll(IDK) .GE.Orr-iIN(I) ) GO TU 100
533.
539.
540.
511.
544.
545.
10R1IM(I)=TOR
RMlLEC I )=KMTHOR(I)-XMIN*DELX/5250.0
100 CUM r I:\IUE
50 CONTINUE
NbTARG=0
C
C
C
C
C
C
C
C
C
C
STEP 3-0
LOOP THROUGH NREACH REACHES TO S
MINIMUM DO LEVEL IS PtLLiW "TARGET
DO 25 I=1,NRE4CH
IF U'UMIN(I).6E.TARGOOCI)) GO TO 25
STEP 3-1
IF TARGET LEVEL IS MOT MET, CUMP
AMOUNT UF FLOW AUGMENTATION REUU
R :"i I L E ( N H T A a G ) = R M IL E ( I)
KI)-JOi"!llM(I)-l-0.1
JR) *(aOREl3D/TARGDO(I)
* CuURF.ulD/TARGDUl I)
ttSU -1 = 0.0
D U 5 S () J = 1 , 'M H \*i A R
NH;'i= [ AIJGOR ( I i J)
QSU •Is.JSUM + HAUG (NH'/J)
350 CONTINUE
0.15*
STEP 3-2
DIVIDE TOTAL AUGMENTATION REMUIR
EQUALLY AMUMC; THE UPSTREAM HEADlA'
SOURCES AVAILABLE TU A GIVEN REA
GIVEN REACH.
STEP 3-3.
CHECK TO SEE THAT A.M EXCESS OF F
HAS NOT BEEN USED.
TF (QWEMn.LT.ijSUM) GO TO 25
QAUG ("JH.-J) =UAl)D
375 C U !-J T I \ U t
25 CUNTI'-JHE
IF (WuTnRG.EM.O) jO TU 300
547.
548.
549.
550.
551.
552.
553.
551.
555.
556.
557.
558.
559.
560.
561.
562,
563.
564.
565.
566.
567.
568.
569.
570.
571.
572.
573.
574.
575.
576.
577.
578.
579.
5flO.
531.
582.
583.
584.
585.
5R6.
537.
583.
589.
590.
591.
592.
593.
59/4.
595.
596.
597.
WRITE SUMMARY UF FLIHM AUG'MT. RE
599.
600.
601 .
602.
60?.
D-2-12
-------�
WKIfK (fjJ,2uO)
300 FuR-IAT (1H1,3*X,"*9H* * * REACHES .JJTH DXYSEN DEFICIT * * *,//,23X, 605.
* 52H«F.ACrt iJi'J. REACH IDEi'j'f 1KICAI lUW MINIMUM 00., 606.
* 15H RIVER MILE,/) 807.
TIME=0.0 608.
DO 250 K = l ,.MPTA'?G 609.
1=IOROER(K) 610.
WRITE (MJ/255) I, CRCHID(I,J) , J=I,5) ,OOMIN( D ,RMILE(I) 611.
255 FORMAT (i?2X, 15, 1 0X,5A4,7X,F5.1,1 1 X,F6.1) 618.
2bO CUMriiMUE . 613.
WRITE (,>U,260) 614.
260 FUR-lAf (lHO,30Xr3.SH* * * FLOW AUGMENTATION REQUIRED * * *,//, 615.
* 5X , 10<)HriFAO";ATER NO. HEAO,-;ATEn IDENTIFICATION EXIS 616.
*TING riEAlUATF.R FLO-'J (CFS) AUG. REUUIRED (CF5),/) 617.
OU ?.!(} \Hw=l,fJHflTRS . 618.
WHITE CmJ,275j fJH/j, (h,vTK I0.( NH,\ , J) , J=l , 5) , HWFLOW (NHW) /QAUG (NHW) 619.
?75 FORMAT (8X,I5,12X,5A'4,16X,F10.1,20X,F10.1) 620.
270 CUfUIrtlJE 621.
DU 3tiO NH.-J = l,.-JH.vTi OUC ri!.l^, A NO fc V AHi.iR A T ION. 653.
C f>54.
C 655.
COM-iO.M A (500) ,3(500) ,C(50o) , XI.500) ,S(500) ,Z(500) ,t^(bOO) ,G(500) 656.
C 657.
CUHHOiM /BLK1/ ICLORD(75,20) ,COEFfJV(75) ,tXPOQV(75) ,COEFQH(75) , 658.
A EXPfiOrl(75),tXp),C*3(75),K20PT175),CK2(75),COEUK2(75) , 660.
C TAKi,L)n(7'5-) , I Ai!G J^ ( 75 , 6 ) , iMCF.L*H (75 ) , IF L AG ( 7 5 , ?(; ) ,ALPHAu(75), 661.
U CK4(75)/Ch.5(7r>) ,CKNH3(75) , CKMU2 (75) , CK N03 ( 75 ) ,S^H3(75), .662.
L CULIK(75) ,ALGl(75) , RHUS [ ( 7S.) , C^ri? I ( 75) , C?>-021 ( 75) , Q I ( 75) , TI (75) , 663.
F ni)[(75),rs'.l!H(75) ,CO',S1 (75) , .\LGSET (71:)) , SPnuS (75) , Ci\6l75) ,
G EXCnF.F(7S),'SNH3(90),4aMj2lSU>) i rt.-i'V 0^(90) ,'."3COLl (90) ,/jSALi;(90j , rtSPHllS ( 90 ) , 668.
D-2-13
-------�
b
ri!> (90, 5J , 1
A1 (<}0 J , ,j
, IvcjPHL (90)
c
c
C
c
c
c
CUMMT'! /HLK4/ JiJiYC ( 15, ?) , HUTRJOl 15,5) , HrtFLOM 15) ,HwTEMP(15) ,
A H .-,i.Ml (15) , ri-.VPHO>S( J 5) , H.M>J"H3U5) , H,vLHw(15) ,
C jn\'CIO(15,5),MH.,'W4RU5) , HriCUL t (15) , H.VALGU5) , h'.vHCk ( 1 5 ) , HiMPHL(l5)
COM-Hl.M /RLK'J/ FU> i(500) ,n£PTH(500) , VEL (500) ,OTOVCL (500) ,K2(50(i) ,
A K I (500) ,0'_l (bOO) , 900 (500) , CO-JS I5o<>) , riS:-jE I (500 ) ,DL (500) , T (500) ,
b ALGAE(5l>0) ,HHUS(500) , Cr.'n.3 ( 50 0 ) ,C'^'2(50«) , C\'U3 ( 50 0 ) ,KNH5(500) ,
C KNU2(bOO) ,4tSHR^(50u) , CULK500) ,G*UivTH(500) , R ADiV ( 500 ) ,
0 KX1 (500) ,M<JJf T«LCO, fGrHA Y , NT , NC , 1 IMt , :\iCS,LAT,
LSNi.LL^fELEVfOA r, /vE , BE , 0 A YOF Y , D« Yt^L ht , .''F'TBLP , DtwH T , PT I !-:E , TPR I MT ,
0£L X,1SS, ALPHAS* ALPHAS, 5' . 0-0 A YOF Y ) )
E L-i Tlf-it-Jsy.OO'l 121 -0.1 23 IS* SIM ('COM * ( D A YOF Y - 1 . 0 ) -0.0701 a)
* -0.l65'l9*S£"J(2.0*COUl*(OAYuFY-l .0)+0.3t>88)
705.
706.
707.
708.
709.
7!0.
711.
712.
713.
7i<».
715.
716.
717.
718.
719.
720 !
721.
*TAM(DECLOiO
IF (ACS.EJ.u.O) G'j TO «
ACS = i IAf'i(Sai
-------�
7 1U
SlR=12.u-CO'J6*ACS + DtLTSL 735
STS=Z4.o-srK+d.o*oF:LTSL 730
818=0.0 737
SlE=STB+D2Lr 73H
GU ro 7 a 739
740
7/Jl
C 743.
C STEP 2-4 744.
C COMPUTE VAPOR PRESSURES, DEft POI 745.
C DAMPENING EFFECT OF CLOUDINESS. 746.
C • 747.
VPHH=0.1001*EXP(0.03*rtETHLO)-0.0837 748.
VPAlR = VPW»-».0003f>7*ATJ-1PR*(i)RYHLB-dET&LB) 749.
* *(1.0+(WETdLU-32.0)/1571.0) 750.
Dt',VPr = ALOG((VPAIR-H).0837)/0.1001)/0.03 75 \.
CS=1 .0-0.65*CLOUD**2 753.
IK (CLUUU.Gr.0,9) CS=0.50 753.
CrnL = CLUUO*lO.O+l.O 754.
ML=CML ( 755.
02 CGNTIUUE 756.
TKLCi) = T^LCD+02LT 757.
IF (TKUCD.LT.2.9) RU TO 84 758.
TKLCD=0.0 754.
04 CUMTIf-JllE 760.
IF ISlS.LE.STw.MR.STR.GE.SlE) GO TO 35 761.
IFCSTK.GT.STh.AND.STR.LT.STE) GO TO 41 765.
IF (STS.LT.STE.ArjD.STS.6T.Sr8) GO TU 42 763.
C 764.
C STEP 2-5 765.
C COMPUTE HOUR ANGLES 76b.
C 767.
Tfi = srn-l2.0-OELTSL+EGTIN
-------�
C OUE TO ATMOSPHERIC CONDITIONS. dOO.
c 001.
P ,•; C = 0 . 0 0 6 1 4 * E X P ( 0 . 0 4 H 9 * 0 E >i P T ) 802.
OAM=ELEXP/ (61 -'U ALPHA)+0.1 5* (ALPHA*CON3+3.«85) •»*(-!. 253))' "'03.
4 1=EXP (-CO . 465 + U . 0408 + PivC ) * 10 . 12Q + 0 . 1 7 I *FXP (-0 . H80*LlAM) ) *l!AM) 804.
4 2 = £ X P ( - ( 0 . 4 6 ;> + u . V 4 0 8 * P v; C ) * ( 0 . 1 7 9 Ml . 4 2 1 * E X P ( - 0 . 7 2 1 * 0 A M) ) * 0 A M ) d 0 5 .
c 806.
C STEP 2-8 807.
C COMPUTE REFLECTIVITY COEFFICIENT 808.
C 809.
GO TO (30,31,31.31,31,31,32,32,32,32,33), NL 810.
30 A«=.1.18 811.
BK=-U.77 312.
GU TO 34 313.
31 Al»
GU TO 34 3.16.
32 AR=0.95 317.
flrt = -0.7 5 818.
GO TU 34 319.
33 AR=0.35 320.
Rn = -0.'-t5 3?1.
34 CONTINUE 322.
RS=AR*(cnrt3*ALPHA)**BR 823.
ArC=(A2*-0.5*(1.0~Al-OAT))/(1.0-0.5*RS*(1.0-AH-DAT)) 82/1.
C 825.
C STEP 2-9 826.
C COMPUTE (\.'ET SOLAR RADIATION AFTE 827.
C SCATTERING, ABSORPTION, AW) REFL 828.
C 829.
SONET=SULAR*ArC*CS*(l.O-RS) 830.
GU TO 36 831,
35 SO;MET = 0.0 832.
36 COWTI/iUE 833.
IF( ISS .GT. U ) RETURN (335]
105 CL'NTIMIE ' &36.
C 837.
C STEP 3-0 838.
C COMPUTE OTHER HEAT FLUXES AND PE 339.
C ENERGY BUDGET FOR EACH COMPUTATI 340.
C ELEMENT. 8/H .
C 842.
C , . .. 8/*2-
II j /O I = l,N>
-------�
C 865.
C HYORAU PE3FCltf,1«iS A HYPWilLPGIC BALANCE UN 866.
C THF SYSTEM UAbEO ON CONTINUITY. IT 867.
C CO-'ipijjES THt FLOW,. VELUCI TY , VOLUME, 868.
C r-EPTH, AND DISPERSION Ci-itFFlClEfJT FOR 869.
C EVE'?Y ELEMENT 11\ IHE SYSTEM. ' 870.
C 871 .
COMMON A (500) ,H(500) ,C(500) ,X(500) ,S(500) ,Z(500) , i«i (500) , G (500) 872.
C . 873.
COMMIT XHLK1/ ICLORO(75,20) , CUF.FQ >/(7 5 ) , E XP.OuV ( 75 ) ,COEF«MH(75) , 874.
A EXPOQ,)(75) ,EXPCK2(75) ,RCHIO(75,5) , RMTnOK ( 7 5 ) , *,XFEOR (75) , 875.
ti C>1AiM!\i(75) ,C<1 (75) ,CK3(75) , K20PT( ^),CK2(75),C01£UK2(75), 876.
C VARGnO(7S) , [ AI IGOR (7 5, b) , f-jCELHH ( 75) , 1FL A 05 ( 75 , 20 ) , ALPHAU ( 7 5 ) , 877-.
0 CK'I (75) ,CK5(75) , CKi'JHM75) > CKNO?(75) , CK*ii)3 (75) , SNH7? ( 75) , 878.
h CJLI1U7-D) , ALQH75) ,HHijSI ( 75) -, CNH3 I (75) , (>U21 ( 7 5) , RI (75),TI(75), 879.
F 001(75) ,8001 (75) , CO.MSI ( 75) , ALGSE f ( 75 ) ,SPHiJS(75) ,CK6(75) ,
S EXCUEF(7:>) , ^ADIvlI (75) ,CN03[ (75) , CKPHL 1 (75) , CKPHL2 (75) ,CKHC,M1(75) ,
H C''JPHOS(15) ,H,.'iWri}(15) ,HwN(.l2( 15) , HWNU3 ( I 5) , Hi^R AON ( .1 5) , 883.
b 0 A TOT (It)) ,H,-vr.CiO(15) ,H^CO'\'S( 1 5) , VHK ( 1 5) , OEPHv. (1 5) , ULHw ( 15) ,
C JiJUC 10(15,13) , ^H.-
-------�
c Ctjr'PU IE HYDRAULICS KUK AM ELEi-iEN <•)?>•).
c TYPE 1. 930.
C
101
FLU
VHi\i(nriiv)=CHEF^V(T} *iiA-KLO>v(MHW)**EXPUHV(I) 9 3 '4.
OhP lvniJ>Ki)=CntF,JH(n*ri.'.'FLO."v(N!-|W) **KXPC'QH(1) 935.
ULH v(.jH.O=22.'.> + C MA •••)•••!( I) *VH'i(MH,V) * DE PH.-v ( IVH*; ) * * 0 . 3 33 93-S.
VtL(Kl3)=COFF.,iVU)*rLOvmiJ>*) **EXPUI)V (I) 937,
DTUVCL (IDiO =n T2UOX/ (rift FLU A (,>!H.V) /VHiN (NHW) +F-LOIV UUK) /vEL ( I0rt) ) 933.
GO TU 105
C
c STEP 2-2 941.
c COMPUTE. HYDRAULICS FOR ELEMENTS 942.
C 2,3, OR 5. 9/13.
C
102
VEL ( 10W)=CO£F'JV (.1) *FLtJA'( IOW) **EXPQQ\/ ( I)
VEL ( TOR) =CMEFijV ( T ) *FLOrt ( I OR) **EXPUQV ( I ) 9 '46.
l)TOVCL(IH'<)=Or2ot>X/(FL().";(inK'-l)/Vt:L(lUW-l)+FLn'.UIOR)/'VEL(IOK)) 947.
GO ru 105 9'JO.
C 949.
C STEP 2-3 950.
C COMPUTE HYDRAULICS FOk AM ELEMEM 951.
C TYPE 4. 952.
C 953.
1U3 IJU;JC = IJUNC + 1 954.
Ho=l 955.
fMu = ,JlJ^iC (I JurjC.NS) 956.
FLU -I ( I OR j =FLf].'.' (lO'-e-l ) -t-FLO^C;vJN)>'JR 9S7.
VEL(in»)=COEF.-W(I)*FLLl-/J(tO«) **EXPUUV(l) 958.
DTnvCL(IOW)=iM2uOx/(FLO^(l!.iW-l)/VEL(TUK-l ) +FLH1/V ( I OR ) / VEL ( I UK ) + 959.
* FLI)A'(-JM) /VEL(.'JN) ) 960.
GO TO 105 961.
C 962.
C STEP 2-4 963.
C COMPUTE HYDRAULICS FOK ELEMENTS 964.
C b OR 7. 965.
C 966.
104 M;VS = M:MSM 967.
FLUvJ (IP.-?) =FLO.-.' ( [0«-1 ) +WSFLO.'! (i\!WS)i-OK 968.
VEL(IOR)=COEFMV U)*FLOA'(IO:n **E XPOQV ( I ) 969.
nnivCL(IfiK)=n(2iJOX/(FLU.v(lij.?-l)/VEL(ItJK-l)+FLOW(IOR)/VEL(IOR) ) 970.
1U5 OtP f H t Mn; ) =CiiEFi'jH (I ) *FLir.mGR) **EXPUQh ( I ) 971 .
nLCliiK)=.?.2.6*C?J.AM-i(I)*VEL(IOR)*UEPTH(IOR)**0.833 972.
100 CQ.M ri.JUt " 973.
975.
E INOATA 976,
C 977.
C 979.
C THIS SUdR'JUTI.Mt READS If, ALL DATA 979.
C 980.
C 981.
CUM -ION TITLE (20, 20) ,D<\TA(91 ,25) , TIM IT (75) ,DUIMT (75) , fctlilMIT (7 5) , 982.
A CJI.»TT(75) , nC >iIT(75) , PHLI TC75J , C13LI I T ( 75) , ALGITtTb) ,PHOSIT(75) ,
d C-JH3I7 (75) ,KAD!-UT(75) ,CM02IT( 75 j , C.M1.I3I T ( 7 5) , IRCHI",'0 ( 750 ) 984.
C 9B5.
CliMiHN /KLK1/ TCL'J^D(75,20') , CuEFlO V (75 ) , EXPfnJV(75) ,COEFQH(75) , 9fl6.
A EXiVjn(|(75) ,EXPfJN2(75) , RCH 1 D ( 7 5 , 51 , K'M rHHF< ( 7 5 ) , rfMfE(:Rl75) , 987.
H C -U!-JN(75) , C
-------�
H ClUiCiid(/5) ,MC -ill /•}) ,PHLI(75)
. 99a.
CUMMO.M /BUK2/ Wbre*!P(yO) ,nS00lQ -*SFLO <(90) jY'SRAijr.iCQO-) ,fc'SPhL(90)
998.
COMMON /HLKS/ .lUMCdS, 3) , HWTR ID ( 1 5 , 5) , K.'iFI.O* ( 1 5) , hrtTEi'lP ( I 5) , 999.
A H.'JLMJdS) , H'."PHt]S(rj) , HMMHM 15) , rUNi.i2 ( 1 5) , H-.Vi-.03 Cl 5 ) , H'Ak Afirj ( 1 5 ) , 1000.
b IHTGTU5) ,h/UHjOU5) ,HvPLT2=0
IAUGOP =0 1033.
ias=o io3a.
LAT=0.0 1035.
0 1036".
O 1037.
DAYOFY=0.0 1038.
AE=0.0 1039.
RE=0.0 1040.
FLEV=O.O loai.
UATsO.O 1042.
= 0 1043.
.0 D 2 19 1044.
-------�
c
c
c
c
31
JO
34
39
32
35
36
33
C
C
C
C
17UO
1710
1720
C
C
C
c
1730
C
C
C
C
C
c
c
c
THWIMT=0.0
TUFiJA Y = 0.0
TKLCD=O.O
C*L=0.0
NJ = 6
NT = 0
DO 30 1=1,17
READ (<\'I,3U (TITLECI, J) , J = l > 20)
FUKMA T (20A4)
IF (TITLhCI, 1)-ENOT) 30,35,30
CUNFL'JUE
f\!£K^OR = l
1 = 1 + 1
REA,) CUI, 31) (TITLE(.I,J) , J=l,20)
IF (T1TLEM, D-ENOT ) 34, 39,34
i>l=I->6
bKlTE (,JJ,32) r,'
FQR-tA F ( IHfl, 5X, 16H***** TOO MA'^r
GU Fll 33
IF U.KE.16) GO TO 33
fj £ ^ fl |) fl = I
>\=lfa-I
If1 K I T E ( I'M J , 3 6 ) f\:
FUWMAT C IHil, 5X, 15H***** TOO FEW (
COMFIrjUE
NTITLE=I
00 1700 1=1,9
MIJOOHT (i ) = o
IF ( ri n.E(3,3) ,EO; YES/ MODOPT ( i )
IF (TIILE(4,3) .EQ. YES) rODOPTCLO
TF(TITLE(5,3) .EQ. YES) NijnOPTUl
Ou 1710 I=b,9
IF ( FJFLEt 1,3) .Eli. YES) MOOOPTCI-
CONTI'MlJE
IF (TITLEC 10,3) .Ffg, YES) MOOOPTC6
DO 172'' 1 = 14,16
IF UITLF(I,3) .EU. YES) MODOPTCI
C U N f I :M U E
M C S = 0
IF( -iUDOHTCl) .LT. 1) Ljn TO 1730
r-'CS=l
CUNFIiMllE
IFC TITLE(7,6) ,N£. UrtOl) ) IBOD5
I D A T A = 0
FF ( ••aiiodpi i/j ) .r;r. o) IOATA = I
1045.
1046.
1047.
1049*
1050.
1051.
1052.
STEP 2-0 1053.
READ IN TITLES 1054.
1055.
1056.
1057.
1058.
1059.
1060.
1061.
1062.
1063.
1064.
1065.
1066.
C,I3,13H) TITLE CARDS READ) 1067.
1068.
1069.
1070.
1071.
1072.
,I3,16H) TITLE CARDS READ) 1073.
1074.
1075.
STEP 2-1 1076.
SET PARAMETER LIST TO BE SIMULAH077.
IfvTO KiuEL OPTION A!?KAY (i-OOOPI ) 1078.
1079.
1080.
1081.
=t 1082.
) = 1
) = 1
1083.
4)=1 1084.
1085.
)=1 1086.
-7) = 1
1089.
STEP 2-2 1090.
SET NCS fiMUN'BER OF CONSERVATIVE 1091.
CONST ITtJE;J PS 1092.
1093.
1094.
1095.
1096.
1099.
= 1 1 100.
1101.
STEP 3-0 1102.
READ 1C.' ALL DATA kEfJUIREO FOR DPI 103.
OF THE MODELS. l'l04.
1 105.
STEP 3-1 )106.
READ IN DATA TYPE 1 O-'OUEL CUiM 1 K" 1 1 0 / .
1 108,
1109.
1110.
D-2-20
-------�
JF ( •lilJUi-'H.SJ .M. 0) 10ATA=1
II- ( -iHUOHT (6J .01. 0) lOATAsl
IF(.-|OL)UPTU}) .GT. 0) lOATAsl.
no 20 .i = i
READ (NT, 21) C"<\T4d,!O ,K = 1, 16)
21 FUR'iAT (6A'l,Al,e 10.0, 10X,6A4/A1 , Fit). 0)
IF (i>ATrt I I, l)-E''!!)\)20,25,2<>
24 I = I + 1
KEAi) (MI, 21) (DATAd,K) ,K=l, 16)
IF (nATAd,l)-E!\H>A)24,29,24
WHITE (>AFAd,S)
DEUX = UATA (I ,16)
'Gu TO 16
12 TV,AX = l)ATA(I,(i)
PTIME = DATAd, 16)
GU TO 16
13 LAT = i)ATA(I,b)
LLM = DA FA( I,16)
GU FO 16
14 LSM = OATA(I,3)
HAYOFY = OAT Ad, 16)
GO TI'I 16
B F = n A T A ( 1 r I 6 )
GO FO lo
1111.
11 12.
1113.
1 115.
1 116.
1117.
ilia.
11 19.
t 120.
1121.
1122.
1123.
1124.
1125.
1126.
1 127.
1129.
1130.
1 131.
1132.
1133.
] 134.
1 135.
1136.
1137.
113ft.
1139.
1140.
1141 .
1142.
1143..
1144.
1 145.
1146.
1147.
1148.
1149.
1150.
1151.
1152.
1153.
1154.
1 155.
1156.
1 157.
1158.
1159.
1160.
1161.
1162.
1163.
1165.
1166.
1 167.
1 168.
1169.
1 170.
1171 .
1 172.
D-2-21
-------�
,iCL-/-r\rn(T ll 1 1173.
OAT = DA I A (I.- 16) 1174.
G Ll F 0 1 b 1175.
1 9 I S S = 0 1 t 7 6 .
I F ( li A T A (I , 1 6) . G T . 0 . 1 ) N T = 1 1177.
1 6 C U N T I -j U t 1178.
IF (Ur!J,502) 1197.
! (1HO, 10X,2'4HSSS (PRUtUEM TITLES) $$$,/) 1198.
WKirt. ('VJ,201J 1199.
201 Fi!R--)AT( 10X, 9HCArfO TYPE, 29X, 2?HQUAL II PROGRAM TITLES ) 1200.
'.'.'KlTF. l.-iJ,503) ( (TULECI, J) , J = l,2u) , 1 = 1 ,f)TITLE) 1201.
5o3 FjjR-'IAT (10X,20A4) 1202.
.vklTE (:-U,504) 1203.
504 FURtAf L1MO,loX,34HS3ffi DATA TYPE 1 (CONTROL DATA) $$£,/) 1204.
l-;krrE (.')J,203J 1205.
203 FL'K-IAT (10X,MHCA!<'J T YPE , 36 X , 9HC AP.D TYPE) 1206.
'.'KfTE r'!j,l>J3) ((('--'.TAd,,!) , J = l , 16J , 1 = 1 ,NCKl)S) 1207.
103 FuR"lAT (2(1.0X,6A4, A1,F10.5) ) 1208.
200 CUWriMUE . 1209.
TF( NT .r-T. 0 ) FLF.^ = 3.280B * ELEV 1210.
IF( NT ,GT. 0 ) DfiLX ="i)ELX / 1.609 1211.
^ 1212.
C STFP 3-1A 1213.
C READ IN DATA TYPE 1A tALGAE PRLTP1214.
C A.NO MITRfJGEM UXIOAriON COMST AtoTS 1 21 5.
c 1216.
DU 1003 1=1,9
1 0 0 1 F 0 <•( ••! A T ( « A 4 , F / . 0 , 2 X , R A 4 , F I . 0 ) 1219!
If- (DATACI, IJ-E-iOO 1003,1021,1003 122o!
1003 CuMT I'\il it" 1 2?1 !
M E ^ ^ I) K — 1 1 3 3 D
I f-C C. *
1005 I=r*l ^ _ ,223.
fF CDATA (I, 1 ) -E'MDA) 1005,1007,1005 122s!
10u7 M=I-8
'••kTTK (.-iJ,l020) M 1227>
1020 FLuV-.iAT ClliO,5<, 16ri***** TJG MAMY (,I3,20H) DAIA 1A CAK'DS READ) 1228
GU TO 100a 1?29.
1021 IF (I ,i;E. 9) GO TLI 1004.
IF(IDATA) 102-1,1024,1025 1231.
1024 fJCKUS = l 1232*
Gu TLI 1026 {&3l\
1025 NtR,
-------�
1240.
i=i,«
If- (DATA (I, l)-CODE2(l) )1006,100H,1006 1243.
10u« GO TO ( 1030,1009, 1010, 101 I/ 1012, 101?, 101 a,. 1031), I
1030
GO Til 1006
1009 ALPHAS-DATAU.,") 1245.
ALPHA6 = 'JAfA(I., t <)) 12'J6.
GU Til 1006 1247.
1010 ALPHA3=UATA(I,9) 1248.
ALPHA<4 = OATA(I, 1») 1249.
GO TO 1006 1250..
1011 ALPHAl=i)ATA(I,9)
GU CO 1006
1012 GKniAX=OATA(I,9) 1254.
RF;SPRT = i>ATA(I, 16) 1255.
GO TO 1006 1256.
1013 CK:M = l)ATA(I,9) 1257.
GO TO 1006 . 1259.
lOia CM_ = l)ATA(I,9) 1260.
SufJ£T=DATfl(I, Ifl) 1261.
GO TO 1006
1031 CKHTP=fMTA(I,9)
CKPTP=OATA(J, is)
1006 COMTIMJ£ 1262.
J026 IF (ILIST .EQ. 0) GO TO 1015 1263,
WrtlTK (iJJ,1016) 126 a.
1016 FUKMAT tlHO, 1 OX , bbHSSSOAT A TYPE 1A (ALGAE PRODUCTION AMD NITROGEN 1265.
*OXIOAT10M CUKSTANTS ,aH)S$S,/) 1266.
VMKITE (iJJ,1017) 1267.
1017 FGH-iAl tl()X,9HCA40 T YFE , 3oX , 9HC APO TYPE) 1263.
rtKlfE (UJ,UM8) (d)ATA(I,J),J = l,ia),I = 1,NCROS) 1269.
1018 FUH-lAT(2llOX,MA4,K10.a)) 1270.
1015 CUfMTlrtDE 1271.
C 1272.
C STEP 3-2 1273.
C READ IN DATA TYPE 2 (k'FACh IOENT1274.
C RIVER MILE AT HEAD AMU END OF RE1275.
C 1276.
II = NREACH+1 1277.
00 50 I = 1,.II 1278.
KfcA!) (l-il,.51) (0/>TA(I,J), J = l, 13) 1279.
51 FORMAT (3A^,3X,F5.0,5A«,3X, A 4 , 3X , F 1 0 ; 0 , « X , A2,1X,F10.0) 12flO.
!(• (DATA(I, D-E-^OA) 50,55,50 1261.
bO CONTJMlie 12^2.
NERi
-------�
IRCHi.unRCH) = l 1301.
T,VAX=v/'. XOU MAX, IRCH) 1 30.?.
1 ObO CuN f JMlE 1 303«
IUROEK=0 1304.
l)U 1055 JRCH=1, IMAX 1 30'j.
TF (I.-xTHfiuURCn) ) -1055, 1055, 1052 130b.
10b2 lURL)F.^ = lhKOEF< + l 1307.
TKCriN-.;i( IRCH) riOKOER 1508.
1055 CONTINUE 1309.
00 57 1=1 ,NHEACH 1310.
I K C H = I F I X (. 0 A T A U , 4 ) * 1 0 . 1 0 . 0 G 0 I ) 1311.
r>CH;-jO(lKCH) 1312.
OU 58 J=5,9 1313.
K = J-a 1314.
RCHID(MCH,K) = OATA(I,J) 1315.
53 CONTINUE 1316.
R,\lTHUR(MRCH) = DA f A (I, 11) 1317.
KtfTeOKHRCH) = UAfA(I,13) 13)8.
57 COMTIWUE 1319.
IF CTLIST.Ey.O) GU TO 125 1320.
WwITE (.MJ,5U5) 1321.
505 FORMAT (1HO, 10X,a2HS$S DATA TYPE 2 IKEACH IDENTIFICATION) SSS,/) 1322.
vJKlft (rjj,205) 1323.
205 FUR--1AT (10X,9nCARi3 T VPE , 1 1 X , 21 HRE ACH IJKUEH AND IDENT ) 1324.
WK'ITt (:jJ,101) I (QATA(I,J) ,.I = K 13J , I = l,i\CHDS) 1325,
401 FUK-1AT (10X,?5A4,3X,F5.1 ,2X,5A4,3X, A4,3X,F10.1 ,4X, A2,4X,F10.1) 1326.
<\25 CuNTlr-HJE 1327.
C 1328.
C STEP 3-3 1329.
C READ IN DATA TYf-'E 3 (TARGET LF.VE1330.
C AVAILABLE FLO'A AUGMENT A T I.UN SOUR 1331.
C 1332.
00 60 1=1,11 1333.
RtAQ U.'l,bl) (OAT,> (1,J) , J = l, 14) 1334.
bl FUR-IAC (5A4,5X,F5.0,5X,F5.0,F10.0,6F5.0) 1335.
TF (UAT.\(I, D-EfJUA) 60,b5,60 1336.
bO CuwriNUE 1337.
MEW'?OR = 1 1338.
b'\ 1 = 1 + 1 1339.
R E A 0 ( N i , b 1 ) ( f i A T A C I , J ) , J = 1 , 1 4 ) 1340.
IF IDATAU, l)-Eivil)A) 64,69,64 1341.
69 N=I-II 1342.
wKITE Cr,J,62) f\ 1343.
62 FORMAT c'iu»,5x , 16H***** TOO MANY (,I3,18H) OAT A3 CARDS READ) 1344.
GU TO 63 ' 1 545.
65 IF (l.KE.II) GO TJ 63 1346.
IF(IAUGOP) 6623, aD23, 0624 }347.
NCWDS=1 134y.
Gu TO B625 1349.
N=H-I 1351.
i-.VTTE ( iJ,66) H 1352.
06 FuW-lAl (liio, SX , 1 5rt***** TOO FE^ (,I3,18h) DATA3 CARDS READ) 1353.
h3 ClJfJTI.MUE ' 1354;
WCR-JS = I 1355.
Oi) 67 1 = 1 , iJREACn 1356.
Iri j=9,ia
K = -J"" 1363.
I All •;!•,!< (;-jk'CH,K ) = l.)ArA(I,JJ 1364.
68 CDNTI^UF. *
b7 CfjN[T.MIF.
D-2-24
-------�
if-' ULIST.K.J.U) GJ 10
506 FuR'lAT llMO, loX, 3nri.SS* DATA TYPt 3 (TARGET LEVEL 01) AND,
* 31H FLOW AUGMENTATION SOURCES) $$$,/)
WRITE (iMJ,206)
206 FOR1AT (li)X,«HCAl?0 f YPE , 1 dX , 24HRE ACH AVAIL HOWS TARGET,
* 5X,?2HOUnFR OF AVAIL SOURCES)
*KITE' (,MJ,4()2) ((JATA( I, J) , J = l, 1-4.) , 1 = 1 ,NCRDS)
4DP FORMAT (10X,5A4,5X,F5.0,5XrF5.0,K10.1,6F5.0)
426 CONTINUE
1367,
C
c
C
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
364.
370.
371 .
37?.
373.
71
70
7 i\
72
75
76
73
78
77
507
STEP 3-4
READ IN DATA
ELEMENT FLAG
1 =
2 =
3 =
4 =
5 =
6
7
DO 70 1=1,11
RtAO (f-Jl,71) (OATAd, J) , J = l ,25)
FORMAT (?A4,A2,5X,F5.0,5X,F5.0,10X,20F2.0)
IF (OAT A (I r 1 )-E-vinA) 70,75,70
CONTINUE
1375.
1376.
1377.
1378.
TYPE 4 (COMPUTATION) 379.
FIELD) 1380.
ELEMENT WHICH REPKESEN I 38 1 .
HtADP'ATER SOURCE. 13fi2.
AN ELEMENI MFM NU EXT13P3.
INPUTS DTHEH THAN lNCRJ3fi'4.
AiM ELEMfe-NT ON THE MAIN13fl5.
IMMEDIATELY UPSTREAM F13fi6.
JUNCTION. 1387.
AN ELEMENT WHICH KEPRE J3'«8 .
A STREAM JUNCTION. 1389.
AM ELEM(-MT ,Ml-HCH h?FPRE1390.
THE LAST COMPUTATIONAL) 391.
IN THE SYSTEM.
AN ELEMENT i.-ITH A
AN ELEMENT WITH A
(M,7U
(DATUI,J).,J = l-,
' 7^4,79,74
I = I f 1
READ
IF
M=T-II
WRITE (-MJ,72) N
FORMAT (1HO,5X, 16H*****
Gu TO 73
IF (I.GE.U) SO TO 73
= 1
TOO MANY (,13,1PH) DATA4 CARDS READ)
'•VrtlTE (NJ,7b) N
FOR-;AT (iHO,5x,i5H*****
CONTINUE
TOO FEW (,T3,18H) DATA4 CARDS READ)
DO
I=J,NR£ACH
= IFIX(UATA(I,'I)*10.+0.0001)
NCELR = OAT A (I, 5)
no /& J=6,25
l< = J-5
CONTINUE
IF (ILIST.FQ.U) GU TO 427
WRITE (r-IJ,507)
FORMAT ( 1 HO , 1 0 X ,
3bHSSS DATA TYPE 4 (COMPUTATIONAL
IhH FLAG FIELO) $$$,/)
REACH,
207 FORMAT
*
(JOX,9HCARo rYPE,PX,20Hk£ACH
J 3X, 1VHC0..1PUTATIONAL FLAGS)
ELE^ENTS/KEACH,
1392.
WAST1393.
WIT HI 394.
1395.
1396.
1397.
1398.
1399.
1400.
.1401 .
1402.
1403.
1404.
1405.
1406.
1407.
1408.
1409.
1 41 0 .
1411.
1412.
1413.
1414.
1415.
141b.
1417.
1 4 1 a .
1 '4 1 9 .
1420.
14?1 .
1422.
1423.
1 424.
1-425.
1426.
1 427.
142*.
1429.
143d.
1431 ,
1432.
D-2-25
-------�
WHITE (.-JJ,'J03J l(OATA(I,J),J = 1
404 FUWi.U( 10X, 2A4, A2, flX, F*.1, FlO.O, 10X, 20F2.0 ) 1434
427 CUNTIWUE I'
'
DO an 1 = 1 ,NRFIACH
NLFLR=NCFLRH(I)
00 20 ,! = 1
ICLORDU,J)=IOR |
28 CliUTIMHE *
IFUOR-500) 650,650,660 1445,
6D0 WKlfF. (bJ,517) ION 1'4"4'
517 FORMAT (1HO,5X, •*****' ,15, ' COMPUT AT I Ufv AL ELEMENTS EXCEED THE1 1445'.
* ' PROGRAM DIMENSIONS OF 500')
NERROR=1
6bO CONTINUE 1448.
NCELLS = IOR 14/19.
c 1450.
C STEP 3-5 1451.
C REAU IN DATA TYPE 5 (HYDRAULIC C1452.
r FOR CON'POTING VELOCITY AND DEPTH1453.
OU SO 1=1,11 1455.
REAO (i:l,»i1) (DATA (I,J) , J = l , 9) 1456.
ttl FURM/VT (?A«, A2, 5X , F5.0 , 10X , 5FIO.O) 1457.
IF (IUTA(I, D-E^(U() 80,85,80 1'I58.
bO CUNTIwUE 1459.
NERrtDR = 1 1460.
bi\ 1 = 1 + 1 1461.
RtAi.) (MI,»1) (DATACI,,)) , J = l ,9) 1462.
IF (DATAd, D-F.iMOA) 84,89,84 1463.
b9 W=I-II 1464.
«-;rvITR (\'J,82) N 1465.
S2 FOR-IAT ( IhO ,5x, ifert***** TOO MANY (,I3,18H) Ija'IAS CARDS READ) 1466.
G 1) T 1 1 8 5 1467.
65 IF (I.GE.II) Gf.l TU «3 1468.
MERr|KCH) = UAT/\(I,7) 1480.
= OA1A(I,H) 1481.
= DATA(I,9) 14P2.
IF( WT .FU. 0 ) RU TO H7 1483.
CvXX = 3.f>ai'iH/~«S. 31 3.<**t£XPll!gn expri«h C--IANW) 1495.
rtxITF. CJJ,4(i4) ( (,>ATA( I,.J) , J = l , 9) , 1 = 1 ,1'jCROS) 1496.
404 FOR.1AT( 10X, 2A4, A2, F12.1,9X, F10.7,4F10.4 )
4c« CUi'iTIriilF 1498.
D-2-26
-------�
c
c
c
c
c
5040
91
5000
97
509
SIEP 3-6
REAO IN DATA TYPE.
DEUX YGE;>J4TIUN AND
6 (KtACT
RtAERA TiOh)
10)
0)
TO
5001
90
94
99
92
95
96
93
DO 5040 1=1,17
P A R A .1 ( I ) = 1 .
DO 90 1=1,11
RtAO (MI,91) (OATA(I,J),J=l
FORMAT (2A4,A2,5X,F5.0,6F10
IF (DATA (1,1) .NE. MULT) GO
00 5000 J=5,10
P/u?AM(J)=OArA(I, J)
WEAD(41, 91) (DATA (I,J),J = 1,10)
DO 5001 J=5,10
OAlA(I,J)=OATA(I,J)*PARAM(J)
IF (OATA(I, D-EMDA) 90,95,90
CONTINUE
= 1
1 499,
1500.
CO 1501,
. 1502,
1503,
1504.
1505.
1506.
5002
RhAU (MI,91) (DATA(I,J),J=1,10)
IF (DATA(I, D.-EMDA) 94,99,94
WRITE C'IJ,92) N
FURMAF (1HO,5X, 16H***** TOO MANY (,I3,1BH) DATA6 CARDS READ)
GO TO 93
IF (I.GE.II) GO TO 93
NERRUR = 1
N=It-I
WHITE (i'U/96) N
FORMAT (1HO,5X,15H***** TOO FErt (,I3
CUNTIiMUE
MCROS=I
DO 97 I = 1,NRF.ACH
=IFIX(OATA(I,4)*10.+0.0001)
1UH) DATA6 CARDS READ)
C A 1 ( N R C H ) = D A T A ( 1 , 5 )
= DATA (I, 6)
= DATAC.C,7)
Ci<2(f!RCH) = OATA(I,8)
CUF!JK2( ^IRClD = DATA(I,9)
EXPUK2(i-iRCH) = OATA(I,10)
IF( NT .EU. 0 ) GO TO 97
COE.OK2(rgK'CH) = COEOK2 (NRCH)
CONTINUE
IF (iLlST.Ed.O) GO TO 429
* ( 1.0 / 35.3133 ) ** EXPQK2CNRCH)
(1HO, IOX,38H5>SS OATA
3Sri FOR
TYPE b
209
'129
WKITE
FuR'-!AT( 10X, *JOHCARO TYPE
K2 CUEUK2 EXPQK2
WKITE (NJ,405) ((DATA(T,J) ,J=1
fUR'-1AT( 10X, 2A4, A2, FtO.l
CONTINUE
C
C
c
c
c
1 1< t AC T HJ.M COEFFICIENTS,
O^ AMD REAERATIOM) S$$,/)
REACH Kl K3
)
1,10), I=1,NCRDS)
4F10.2, 2F10.3 )
STEP 3-6A
READ IN DATA TYPE 6A
A HI) PHOSPHOROUS COEF
17
5041
1101
DU 5041 1=1
P A R A M ( I ) = 1 .
OU 1100 I = J , I I
kbA;)(i«II, 1101) (UATAd, J) , J =
FuR'1AT(5A4,5X,F5.»,2X,flF6.0)
IK (DAFAd,!) ..NlE. MULT) GO TO 5003
13)
1507-
1500.
1509.
1'SIO.
151 1.
1512.
1513.
1514.
1515.
1516.
1517.
151H.
1519.
1520.
1521 .
1522.
1523.
1524.
1525.
15?6.
1527.
1528.
1529.
1530.
1531.
1532.
1533.
1.534.
1535.
1536.
1537.
3024.
3025.
1540.
K20PT1541.
1542.
1543.
1544.
1545.
1546.
1547.
IALGAE, MIT1548.
) 1549.
1550.
1551.
303/1.
3039,
D-2-27
-------�
DO 500-1 J=7,13
500') PARAM (J ) =OAT'A (I, J)
K t A 0 (M I , I 1 0 1 ) ( U A T A ( I , J ) , J = 1 , 1'3)
5003 DO 5005 J=7,13
5005 1) A T A (I , J ) =0 A T A ( I , J ) * P A R A M ( J )
IF (f)ATAd, D-tNOAO 1100,1105,1100
1100 COhdi'lUE
1104 1=1+1
Rt A'j U'l , 1 10 1 ) (DA FA (I, J) , J = l , 1 3)
IF (I.' 4 T A (1, 1) -E i JO A ) I I 0 4 , 1 1 0 9 , 1 1 0 4
1109 N=I-I1
w.'\ >\.
1559.
1560.
5561.
1562.
1565.
1564.
1565.
1566.
1567.
1568.
1569.
1570.
1571.
1572.
1573,
1 5 7 a .
1575.
1576.
1577.
1578.
1579.
1580.
1581.
1502.
1106 FORMAT (UIO,5X, 15H***** TOO FEW (,I3,19H) DATA6A CARDS READ)
1 103 CONTINUE
MCRDS=I
OtJ 1107 T=1,NR£ACH
lKCH = IFIX(DATAd,6)*lO. + 0.0001)
IM r\ C n = I i< C H ;JRCH) / 10.76365 1506.
1107 CuNdNUE 1587.
lloO IFtltlST .EG). 0) GO TO 1199 1588.
'/ni I , 11 0 1 ) (i) t\ F A (I , J ) , J = 1 , I 4 )
IF (HATad,!) .IME. MULT) GO TO 5006
5007 PAWA«(J)=0ArA(I,J)
R t A 0 (r. I , d 0 1 ) (i) A r A (I , J ) , J = 1 , 1 4 )
5006 DO 5004 J=7,14
5008 OArA(I,J)=i)ATA(I,J)*PARAM(,J)
IF (DATA(1,1)-E JO/O 1200,1205,1200 1605.
D-2-28
-------�
1200
12041=1+1
RtADOMl, 1101) (ijArA('I,J) , J = l, I/I)
IK 0)ATA(I,l)-E!il>A)12u'l, 1209, 1204
1209 N=I-II
KvRITE (;\iJ,1202) M
1202 FbR'iAT (1HO,5X, IbH***** TOO MANY (,I3,19H) DATA68 CARDS WF.AO)
GU TU 1203
1205 IFlHiE.Il) GO TO 1203
T.FUDATA) 1220,1220,1230
.1220 NCRDS=1
GU TU 1250
1230 NEKROR=1
N=Il-I
WRITE (fcJ,1206) N
1206 FUR-iAT tlHO,5X, 15H***** TOO FEW (,I3,19H) OATA60 CARDS READ)
1203 CONTINUE
NCWOS=I
DU 1207 I=1,NKEACH '
I«CH = IFIX(I.>ATA(I,»)*10.+0.0001)
CK4CwRCri)=OATA(I,7)
EXCOEF(!\tRCH)=i')ATA(I,9)
Ci\6(i>.'RCH)=OATA(I, 10)
C(\HC!Ml CiJHCH)=l)ATA IT, 11)
C(VriCfl2(M«CH)=l;A FA (I, 12)
CKPrlLl(.1f«'CH)=OATAtI,13)
CKr'iiL2O-IRCH)=OAT A (.1 , l«)
Tf- C TJT .ECO. 0 ) GO TQ 1207
CK'HHRCH) = CK/it-MKCH) / 10.76365
F.XCJFF(.'4f?ai) = EXCDEF(NRCH) / 3.2600
12u7 CUNflMUE
I2b0 IFCiLIST.EU.O) fiU TU 1299
C
C
C
C
C
1210 FUH.--IA r(lHO, IOX,41H$:BS DATA TYPE 6H (UIHER CUEFF 1C IENTS) SSS,/)
'.-.•HI TECNJ, 1211) .
1211 FjfMAU 10X, 110HCARO TYPE REACH 8-UXY KCOLI
* LITE rx KKADIO KHCW1 KHCN2 KPliLl KPHL2 )
ft'KlfE CiJ,1212) ((RA'TA(I,J), J = l,14), 1 = 1 , MCRUS)
1212 FJ«-1AT ( 10X, SA^J, F10.1, 8F10.2 )
1299 .CCJN'TIIMUF..
STEP 3-7
WEAL) IN DATA TYPE 7 (STREAM Jl.lNC
IDENTIFICATION AND THE ORDER OF
CONNECTING ELEMENTS TAKEN CLUCKl"
AROUND THE JUNCTION).
H=.-JJUMC-H
DU 130 1=1, -I I
RtAO (M,131) (DAT A(I,J) , J = l, 13)
131 FORMAT (3Aa,Ai,5X,F5.0,5X,5A4,3C5X,F5.0))
IF (f)ATA(I, D-Ei'vU«) 130,135,130
130 CUNTINUE
NfcRRUR=l
134 1=1+1
RtAD (MI, 131) (!.)ATA(I,J) , J = l, 13)
IF (OAT*(I,1)-ENOA) 134,139,134
139 ^=1-11
WRITE (NJ,142) N
132 FORMAT (ino,5x, I&H***** THU MANY (,I3,18H) DATA? CARDS READ)
GL. TO 133
135 IF (I.GE.m GH TO T33
1608.
1609.
1610.
161 1.
1612.
1613.
1614.
1615.
1616.
1617.
1618.
1619.
1620.
1621 .
1622.
1623.
1624.
1625.
1626.
1627.
1628.
1629.
1630.
1631.
1632.
1633.
1634.
1635.
1636.
1637.
1636.
1639.
1644.
1361.
1.862.
1H65.
1666.
1(167.
1869.
1870.
1871 .
1872.
1375.
1874.
1875.
1876.
1H77.
1878.
1879.
IflflO.
1881 .
D-2-29
-------�
1H83.
iXJ 1 H 8 4 .
FORMAT (1H0.5X,15h***** TOO FEW (,I3,tttH) OATA7 CARDS READ)
133 C 0 MT I N U E
NCHOS=I
OU 137 l=l,NJUNC
IJUNC = DATA(I,5) 1889.
f)U 13* J = 6,10 'H<™-
K = J-5 1891.
JuliCIUUJUNC,i<)=f>AlA(I, J) 1892.
139 CONTIr-JUE 1893.
JUMCUJU'IC, 1) = DATAU, 11) 189/1.
JUNG (I JUMCf c;) = OATA(I,12) 1895,
JuMC C.I J J.NCt 3) = DATA (I, 13) 1396.
137 CONTINUE 1897.
IF (ILI3T.EQ.OJ GO TO 432 1H98,
'WRITE (NJ.512) 189«).
512 FORMAT (1riO,10X,33H:5SS DATA TYPE 7 (STREAM JUNCTIONS) $$$,/) 1900.
WRITE (nJ,2 12) 1901.
212 FuR'tAT (10X,9HCARi) \ YPE, 1 4X , 24H JUNG T ION ORDER AND IOENT, 1902.
* 9X,25HUPSTKM JUNCTION TRIB) 1903.
hRITE (-1J,4U4) ( (OATAd, J) , J = l, 13)", 1 = 1, NCROS) 1904.
408 FQKMAI (10X,3A4,A3,5X,F5,U,5X,5A4,5X,F5.0,5X,F5.0,5X,F5.0) 1905.
452 COMTINUIZ 1906.
C 1907.
C 1761.
C STEP 3-8 1762.
C READ IN DATA TYPE 8 (INCREMENTAL1763.
C CONOI[IONS). 1764.
C 1765.
Du 5043 1=1,17
5043 PARAM(I)=1.
Du 120 1 = 1,11 1766.
RtAD (;JI,121) (;>ATA(I, J),J=1, 13) 1767.
121 FijR-tAT (5<\4 , 5x , b^t). 0 , 3F 1 0 . 0) 1768.
IF (OATAU, 1) .NE. I'lULT) GO TO 5009
Ou 5010 J=7,13
5010 PARAN(J)=OATA.(T, J)
R E A 0 ( "J I , 121) f U A-T A (I, J ) , J s 1 , l 3 )
bOu9 F)u 5011 J = 7,13
501 1 rUTA(l,J)=l>ATA(I,J)*PARAM(J)
IF (OATfld, l)-h.\OA) 120,125,120 1769.
120 CONTINUF.' 1770.
rJtRROR = l 1771.
lc'\ T = H-1 1772.
READ (Ml,121) (uATA(l,J),J = l,13) YllI.
Tr (iiATA(I,l)-fc,JOA) 124,129,124 1774.
129 M=J-H 1775.
WKITE CNJ,122) "J 1776.
122 FuR-.AT (Hin,bX, IhH***** TIJU MANY (,I3,ldH) DATAH CARDS READ) 1777.
GU TU 123 1778.
125 IF (I.Re.II) GO Tl-i 123 1779.
Nif.RRuR = 1 1780.
N=II-I 1781.
WHITE dJjf!26) N 1782.
126 FORMAT (iHO,5x, ISH***** TI": ->: =,r?i,i8H) DATAS CARDS READ) r/83.
123 CUMTI'NiUt J784.
NCROS=I ,785.
00 12? 1=1, JktACH 1?8b.
TRCri = HrlX(DATA(T,6)* 10. + 0.0001) 1787.
T'
-------�
S I IN>JJ,511)
511 FuKMAT (1HO, lv)X, S^HSSS DATA TYPE 8 (RUNOFF CONDITIONS) $SS,/)
211 FORi;lAT( 10X,
*P U.O.
IfiOHCARD
600
TYPE
COMS
407
C
c
C
c
c
-c
1408
IN KITE 0\iJ,407)
FOW-iAT( 10X,
cown^ue
C(DATA(I,J),J=i,13),I=l,MCRDS)
5F10.1,3F]0.3)
STEP
READ
1796.
179/.
1 79S.
1799.
1800.
1801.
1802.
1803.
FLOW TEM1804.
)
1806.
1807.
1808.
1809.
3-8A 18*10.
IN DATA TYPE 8A U NCRFf-'t'NTA 1 8 1 1 .
IIONS FOR CHLOROPHYLL, NITR1812.
PHOSPHOROUS, COLIFORM AND iUni()M813.
HCN
REACH
PHENOL
DO 5044 1=1,17
1401
5013
5012
5014
1400
1403
1404
1405
140?
1420
14.50
1407
1406
PO 1400 1=1,11
READfWI,1401) (OATA(I,J), J=1,13)
FuH.'iA F (5A4, A?,5X,F5.0,9F6.0)
IF ll)ATA(I,l) ,,-JE. .ilJLT) GO TO 5012
DO 5013 J=6,13
PARA'^(J)=DATA (I, J)
REAOC=MI»1401) (DATA(I,J),J = 1,13)
DO 5014 J=6,13
OftTA(I,J)=OATA(I,J)*PARAM(J)
IP (UAf A(I,l)-£r.'DA) 1400,1402,1400
CUNTI^UE
II- (OATAdr D-E.viOA) 1403,1404,1403
N=I-Il
FORMAT ( 1HO , 5X , 1 bH * **** TOO MANY (,I3,20H) DATA 8A CARDS READ)
GO TD 140f>
IF (I. RE. II) GO TO 1406
IF010ATA) 1/120,1420., 1430
RU TO 1450
WHITE (i'JJ,1407) N
FORMAT C1HO,5X, 15rf***** TOO FEW (,T3,20H) DATA 8A CARDS READ)
DO 1406 1=1, BREACH
IHCH=IKIX(DATA(1,5)*10. +0.0001)
=()Af A(I,6)/ALPHAO(tMRCH)
(K'RCH)=UATA( f ,7)
CiM02I I M.-VCH )•=!)* TA CI »«)
CivO.SI (MIATA(I, 13)
TFULISf .EU.O) GO TO 1409
WRITE (U.I,1410)
3272.
3273.
3274.
1818.
1819.
1820.
1821.
3279.
1323.
1826.
1827.
1328.
1829.
1830.
1831.
1832.
1833.
1834.
1835.
1836.
1037.
1838.
1839.
1841.
1842.
1843.
1344.
1845.
1846.
1347.
3305.
1848.
1849.
1850.
D-2-31
-------�
1410 FuR -I A f (1HO, l()X,4*n:S$5 OAF A TYPE HA ( I ivJC^ErEiM F AL FLIU-, CONDITIONS F01851.
* 23rik rilTKDGKiJf PHilSPHURuUS, /,29X,3uHCOLIFURM AMD R AO ItlNHCL I OK ) S$ld52.
* S , / )
A N I f E ( ,1 J , 1 4 1 1 )
1411 FUk'iAF (IOX,9HCARD F Y PE , 1 5 X , 5HWE ACH , 1 X , 6HCHLOR A , 4 X , 3HNH3 , 5 X ,
* 5X,3Hr,,u?,5x,3nPO,2X,5HORG-N).
i'.nITfc.(Nj, 14123 ( (')AT A(I,J), J = l,13), I=l,i\iCKOS)
1-!AlflOX,3A4,A?,HX,F6.0,2X,Fb.l,F6.2,3Fa.2,F10.1,F6.2,F6.2)
OU 5045 1=1,17
b 0 4 5 P A K A K ( I ) = 1 .
DO 110 1=1,11
(M,lll) (DATA II, J) , J = l, 12)
1H54.
,3313.
3314.
3315.
3316.
J859.
1645.
STEP 3-9 164h.
REAO IN DATA TYPE 9 (INITIAL UJN1647.
t 6 4 ft .
1649.
1650.
1651.
IF (UATA(I,1) .ME. MULT) GO TO 5015
0 1' 5 0 1 b J = 7 , 1 2
5016 P'vRA,'J(J)=UATA(I, J)
P.EAIHNI, 111) (OATA(J,,I) ,J = 1 , 12)
5015 DU 5017 J=7,12
5017 l>ATft(I,J)=l)ATA(I,J)*PARAM(J)
IF (DATAd, 1)-F.NDA) 110,115,110
no COM riNUE
1 14 I = I-fl
KtAiJ IN1,111) (l)ATA(I, J) , J = l, 12)
II- (DATA (I, !)-£.'.,'!; A) 1 1 '1 , 1 1 9 , 1 1 4
119 N = I - 1 I
.-KITE l'-U,U2) ,-j
112 F 04 MAT (. 1HO, 5X, 16H***** TOO MANY (,13,16H) OAFA9 CAkDS REAO)
G ..i r U 113
115 If- (\ .t,h.II) liG TlJ 113
= 1
,v = 1 1 - i
lit)
113
(1HO,5X, 15H***** TOO
(,I3,18H) DATA9 CARDS REAO)
MCR?)S = I
DU U/ I = l,
I 4 C H = I F f X C 0 A T A ( I , b 3 * 1 0 . + 0 . 0 0 0 1 )
= n»vTA(l,7)
Dul-JlT C.JRCH) = »ATA(I/8)
CL)T Jl r ( JUCH) =JATA (I , lu
HLNIT il\'tMCH)=0<\TA(I, 12)
ri"iHE
1 1 7
IF (ILIST.F.U.o) R'J TO 430
.vklTE (.J, I, 5HU
510 FUW-lAf (1HO, 10X,4UHS3S DATA TYPE 9 (INITIAL CONDITIONS) S$$,/)
1652.
1653.
1654.
1655.
1656.
1657.
1650,
1659.
1660.
1661 .
1662.
1663.
1664.
1665.
1666.
1667.
1668.
1669.
1670.
1671.
1672.
1673.
1674.
1678.
1679.
210 FuR-IAT( 10X, 90,-tCARi) TYPE REACH
* rtUD CO.JS I HCM PHENOL )
rtxTTE ('JJ,4U6) ( (iJATAtl, JJ , J = l, 12) , I = l,i\jCROS)
406 Fj^ur( lyx, bAq, 'IF 1 u . 1 , 3F 1 0 . 3)
TEMP
C
C
C
C
C
C
1681 .
1682.
0.0.1683.
1685.
1686.
1687.
STEP 3-9A lf)f,9.
READ IN DATA TYPE9A (INITIAL CON1690.
FUR ChLLIRi.iPHYLL , i.'l TRdGFi'N , PHi ISPHO 1 69 1 .
COL IFijRM, AIJU K AtH UWUCL IL»F ) 1692.
D-2-32
-------�
13ol
i)U 'jiinn 1 = 1,17
PAKA;.|(T)=1.
DO 1302 1 = 1,I I
REAJllIfHOl) (l;AfA(I,J), J=l,13)
F LI R 1A T ( 3 A 4 , A 2 , 5 X , F 5 . 0 , 9 F 6 . 0 )
IF (I)ATA(I,1) .HE. :1ULT) GO TO 5018
nu 5019 J=6,13
5019 PAR,V1(JJ=i)A fACI, J)
RtAi)('.'jJ,13i'l) (DArUI,J) ,J = 1 ,13)
bitlfl hi) 5020 J=6,13 .
0 A T A ( I , . J ) = i) A T A ( i , J ) * P A W A i«l ( J )
IF ,(DATA( I, l)-E>JRCH)=OATA(lf 9)
PHnslT(iJKCM)=l)ATA (1,10)
CULI1 f (:lK'Ch)=Ofl I'A (1 , 11)
PAD.'il rii-JiVCH)=OA7 A II, 12)
Ci«(-*2IT(N!.'CH)=tJA T A (1,13)
1?09
1310
1311
IF (ILIST.E'4.0) GO- I'D 1320
F u R •' A T (1 H 0 , 1 0 X , 4
1694.
3175.
3176.
* JOHMYLL A, NITKfJGEUr
*0fc) «*s ,/)
WK'ITfe (i.U,1311)
FIJR1AT (1(!X,9'1CAK:) TYPE , 1 5X , 5riRE
DATA TYPE «A (INITIAL CCJNO II ILiiMS
PHOSPHOROUS, /,29X,30HCCiLIFC)heM AN
131?
1320
C-
C-...
C-
*3X,3h,'.'f:i<,3X,3HPO'4,2Xf 4HCOLI , 4X , a
(-.'KlTfC!'!J,1312) (('lAFACI ,J) , J=l,13),
FURMAT( tf'X,3A'l,A2,8X,F6.0,?X,F5.1 ,«F6
CUfiTJ'MllE
, lX,6r,CHI.OPA, 2X,3H^;H3
5X,5HURG-N)
= 1 ,NCROS)
2,F10.1,F8.2,F6.2)
. I M I T A L I Z t
•)U 1333 1 =
SYSTEM STATE VAKIAHLES,
1697.
1698.
1699.
1700.
3181.
17.02.
1703.
1704.
1705.
1706.
1707.
1708.
1709.
1710.
1711.
1712.
1713.
1714.
1715.
1716.
1717.
1718.
1719.
1720.
1721.
1722.
1723.
1724.
1725.
1726.
3207.
1727.
1 728 .
1729.
FHR CHLDROP1730.
RAOJf_INUCLI1731 .
1732.
1733.
3,3X,3HN02,3215.
3216.
3217.
3218.
1733.
1739.
1740.
1741.
13.S3 ,I = l,nCFL»
CLuWfj(I, J)
Tll!JIO = l IMT(I)
IF( 'ir ,GT. 0 ) T(MR) =
DU(I(iiN')=UUl-lIT (I)
P.UO(lUKj=bOU:l HI)
in.<)=cui.,ir (i)
1-743.
1744.
1745.
1746.
1747.
1 7 '18 .
1749.
D-2-33
-------�
HCr.'tlli«)=HC'Jl I" (I)
rnl. ( luu) = KHI_I f (JJ
1333
1 43
1 (I
1 -)7
SI
i ii>K) =Pnos i r (i)
r m
r (i)
T ( I)
Cfvi'Ui()iv)=c:M(.Mi rm
CbLi UOR)=Cul.IIT (1)
STEP 3-10
IM DATA TYPE 10 (HEADWATER
TriEIR CHARACTERISTICS).
IF C I5S .EM. 0 ) GO TO 1750
II = NHvvTRS-t-1
OU 5047 1=1,17
5047
141
bOi?
bOeil
b023
1 40
1 £} /t
149
1 U?.
1 «S
00 1 4 'J i = 1 , 1 1
A f C2Aa,/\^,5X,FS.O,5A4,F10.0,bF5«0)
TF Cf)ATA(I,l) .i^E. >iULT) liO TO 5021
00 15u2'2 J = l 0, Ih
PAf-f A;-. ( J) =UAT A (I , J )
UATA (I/ J)=OA TACI, J)*PARAMU)
TF (DATA ( I , 1) -fi>inO 140,1^5,140
cun rii-iuE
(OATA(I,J), J = l,
I = I -H
Kt
IF
FUK-!,\| (]HO, 5X,
G 0 f 1 1 1 a 3
IF (I.6E.II) GO TO 143
** TtJO MANY (I3,19h) OATA10 CAkOS KEAD)
M = 1 1 - t
'/.'KFTE (rij,l'lb) M
Fl.Ki-l'VT (1HO,5X, 15rl***** TOO FEW (,!:>,
CUNTII'IUE
OATA10 CARDS HEAD)
Do 147 1 = 1 ,,MH>'v TRS
hi-,.-; = DATA (1,4)
D U 1 'i £ J = 5 , 9
K = J - 4
H.',T: 11)
TF( i;T .r,T. 0 ) H,'.FLUA(K'H-v) = 35.3133 * HwFLUrt (WH'/O
TF ( 'iT .RT. 0 ) H-;TE:-ip(,xiHi-O = 1.8 * H A'TEMP dMHiv) + 32.0
Hi-.Oud-iH.i) = DATA (I, 12)
H^.h'lDtr.n:';) .= ,JAIA(I,13)
Hv hC"M^"i-.)=DA FA (I, IS)
H.,PML(K'MvO=UATA (I, to)
nATi)T(r'.'iV')=ri'.-jPl.ir:;(f
IF ULIoT.E'J.'i) GU Tf)
hKTTE (JJ,513)
FLiNMAf (IHO, KiX^iOHSSS DAM TYPE 10 (HEAOrtATEK SOURCES) »:t>$,/)
1753.
1754.
1755.
1756.
1757.
1758.
1759.
1760.
1860.
1908.
1909,
1910.
1911.
1912.
1913.
1 9 1 U .
1915.
1916.
1917.
1918.
1919.
1920.
1921.
1922.
1923.
1924.
1925.
1926.
1927.
1928.
1929.
1930.
1931.
1932.
1933.
1934.
1935.
1936.
1937.
1938.
1939.
1940.
194J.
1942.
1943.
1944.
1945.
1949.
1950.
1951.
1952.
1953.
D-2-34
-------�
?13 Fui^lATC li)X, U2HCARO FYPE HEADWATER OKDER AND IDEuT
*Lurt FE'-tP D.O. QUO CO^S I HCM PHENOL
W*ITE C'JJ,409) ((UAFACI, J) , J = l, 16) , I = 1 , iMCRDS)
40" Ff5K.-iAT( 10X, 2A4, A3, F H) . 0 , d X , 5A4, 4F 1 0 . 1 , 3F 1 0 . 3 )
CONTINUE
F1955.
1957.
195d.
C
C
C
C
C
C
I960.
1961.
OU 5'ja8 1 = 1,17
STEP 3-10A
READ lh DATA TYPE IOA
CHLOROPHYLL, NITROGEN, PHOSPHORU1963.
CGLIFURM AND RADIUNUCLIDE CONDIT1964.
1965.
(UI,1'J01) (JA!A(I,J), J=1>13)
IF (DATACI, 1)-F. -IDA) 1503,1504,1503
• 4 fv = I-II
WrtlTE (-Mr 1505) M
AT llUOrSX,IftH***** TOO MANY (,I3,21H) DATA IOA CARDS READ)
GO TO 150&
1502 If- tl.GE.II) GO TU 1506
IF(I"AFA) 15?d,1520,1530
1S20 MLROSsl
GO rn
1530
'.•fArA(I, 10)
H,- CiJLI (• MM •.<')=("> A T/\ (1,11)
HAfUO* ( .JHfl ) =i) AT A ( 1 , 1 2)
Hv.^ridtKni- )=L'ATA(I, 13)
1508 Cur
1550 IMILIST .E;J. 0) GO TO 1509
l)u 1500 1 = 1,II 1966.
PcA!)(Nl,1501 ) (DATACI,J), .J = 1.,13) 3431.
1501 FijK 1A F (3A4, A2,5X , F5 . 0 , 9F6 . 0) 3432.
IF (DATA (I, I) .;,-£. i-1'JLT) GO TU 5024
DJ 5025 J=6,13
5025 PAKAM(J)=UATACI, J)
K k A s.) (N 1, I 5 0 1) (DArA(I,J),J = l,13>
5024 QLi 502B J = fj, 1 "i
5026 OAT A Cl,J)=OATA(I,J)*PARAM(J)
IF CDAT^CI, D-E.JDA) 1500,1502,1500 19&9.
1500 Cui'lTlNLIE 1970.
1971 .
1972.
3437.
1974,
1975.
1976.
1977.
1970.
1979.
19HO.
1982.
1983.
1984.
1935.
19P&.
19A7.
1988.
1989.
1990.
J991 .
1992.
1993.
1994.
1995.
1996.
1997.
3470.
1998.
1999.
•AJKlTE ("Jj,1510) . 3473.
1510 FOR-lAT( IMu, 10X,44tiS?$ DATA TYPE IOA (hEAO/.-ATEft COMOlTinNS FOR 2001.
* 3 A FA 11, .1) , J=l,li), l = l,HCRDS) 34ttO.
J512 FLJi
-------�
c
c
c
c
.3 1 E P 3 - 1 1 2011.
H'tAU IiM DATA TYPE 11 (WASTE INPU2012.
rt'l THDWAALS AND THEIR CHAKAC1EKIS2015.
2014.
Ou 5049 1=1,17
HO 150 1 = 1 , II
iU A ij (r 11, 1 5 1) (J A T A ( I, J ) , J = 1 , 1 7 )
151 Ft'KMAT C2A4 , A2,F5.0, SA4,FS.o , F 1 0 ,0,6F5.0)
IF CHATAU,!) .••'£. MULT) GO TJ 5027
01' p('2H J = 1 U , 1 7
5028 P«K'AM(J)=OAT A U,*I)
K E A J ( IM T , 151) C'.) A T A (I , J ) , J = 1 , 1 7 )
5027 Ou 5(>29 ,1 = 10, 17
bO<^ OATAU, J)=DA.TA( I, J)*PAHAM(.J) .
IF (DATAC1, l)-Er,'OA) '150,155,150
150 cur'TiwuE
k b A n ( >\< 1 , l 5 1 ) f:.) A T A (I, J ) , J = 1 , 1 7 )
If COA U(I, i)-E.'!DA) 154,159,154
159 M=I-II
/.KITE (:)J,152J '•)
1b2 FoKi-i*r UnOj'SX, 16H***** TOO MANY (,I3,19H) OAfAll CARDS HEAD)
PC' TO 153
155 II- (l.GE.II) GO Tu 153
N = 11 -1
-MklTE (-'.(,156) \
156 F(..!<•'!AT (irlO, 5X , 15H***** TlJQ F
153 Ciii-'TIi-iliE
(,I3,19H) OATAU LAkOS READ)
IF ( M-.vASTE .feu. 0 ) GIJ TO 161
00 157 1 = 1 , .gWrtSTE
N»>b = I
no 158 J=5,9
K = J-'l
l«:ASriU("i!r;S,X)=OATA (I, J )
15«
TKF^CT(-II.-S) = DrtTA(T,m)
IvSFLd/. ( J'.' S) = OATA ( r , 1 1 )
fc?TEMP(:-Ji-.-S) = DATA (I, 12)
S) = L' A T A ( I , I 3 )
•j.S) = OAT l\ (I , 14)
,( -!i-S)=OA TACI, 15)
i(hi.vS)=OATA( [ , Ih)
'\SPi-iL ('-. ',vS)=OA FA (T, 17)
TF( n r .EIO. o ) GO ro 157
•AbFLUM juS) = 35.3133 * USF'LU.M (MwS)
A'hTEhP(-n-.S) = 1.8 * 1.VSTEMP (M'/JS) + 32.0
157 CONTIf.MJE
Ib1 TF( II.TST ,£(J. 0 J GO TO 434
(,37HS.'S,S DATA TYPE 11 (wASTE LOADINGS) SSS,/)
EFF,
5 1 y F u K -I A f (1 H 0 ,
•/;|
-------�
1)0 -1(150 1 = 1 , 17
bObO HAMAM(T)=l.
DO 1602 1=1,11
REAlXMJ, 1601) (.OAFAU.J), .1=1,13)
1601 FURMA FI 3A 4,A ?.5 X,F 5.0,9F 6.0)
IF (DATA (1.1) ,.\iE. MULT) GO TO 5030
Pu r-j(.'31 J = 6, 1 3
5031 PARAf-'(J)=OAFA(I, J)
Kt4'J(.MI,lbUl) (OAf A (I, J) ,J = 1, 13)
b030 Du 3032 .1 = ^,13
b032 DATA(I,J)=OAT<\(I,J)*PAKAM(J)
IF (OATAU, 1)-E:-JI)A) 1602, 16.M , 1602
1602
CULIFOKMS
1605 1=1*1
K c A 0 (iJI , 1 6 0 1 ) ( D A IA ( I , J ) , J = 1 , 1 3)
TF (DATA(1,1)-E40A) 1605,1607,1605
1607 N=I-II
wrtlTH (*J,1620) iM
162') FLJK.-IAF (1HO,5X,16H***** TOO MANY (,I3,21H) DATA 11A CARDS READ)
GO Til 1604
1621 IK (I.Gt.lt) GO TD 1604
IF(IlJATA) 1630,1630,1640
1630 NCROti = l
6LI TO Ib50
1640 r-!tR!JJ , 1622) M
1622 FLWIAf (1HO,5X, I5rt***** TOO FEW (,I3,2lH) DATA 11A CARDS READ)
1604 CiJNrirMlJE
IF( ,'^AJiTt .EQ. 0 ) GO TO 1650
Dlj 1606 T = l,N'ATA (1,6) /ALPHAUll)
«5hi^3lM-.VS)=f)A FA (1,7)
A-SN.J2 ('••!";S ) =D A f A ( I ,'S )
2070.
3534.
2072.
2073.
2074.
2075.
2076.
3545.
?07«.
2079.
2080.
V'bPHflS (! .'Vi3 ) =0 A T A ( 1, 1 0 )
AhCiJL 1 ( Ml'.S) =0ATA ( 1 , 1 1 )
wSKADij (•>)»•.•;>) =OA r A (i, 12)
»l S N ri 2 ( N .v S ) = 0 A f ft (I , 13)
1606 CUHTTl'JllE
16bO IHdLl'Sl .EM. OJ GO TO 1699
V.'KIFF (ijJ,1610)
1610 FoKciAT (1HU, 10X,4flii.$>S DATA TYPE 11 A (rt'flSTE LOAD CHARACTER IST TCS - 2106.
*2fcrl ALGAh ,'nTKO(iE:';,PH(i.SPHU',H3,aX,4h f-i(J2,4X,/4h N03,4X,4H PO" , 4 X , 4HCOL 1, 6X , 1 OMH ADN ORG3579.
2083.
2084.
2085.
2086.
2087.
2088.
2089.
2090.
2091.
2092.
2093.
2094.
2095.
2096.
2097.
2098.
2099.
2100.
2101.
2102.
3570.
2103.
2104.
2105.
*-«)
00 1615 I=1,NCKOS
1,5)
vxl riZfr.'J, 1612) (iJATACI, J); J =
* UMFA([,J), J=6,l3)
1615 Cu^FIMUc
16S9 CUNflrtUE
c-
C- INPUT .-iTEAJY SlAlE LEATHER DATA.....
C-
TK( ••1iJD(jPT(2) .Eu. 0 ) GO TO 1727
K'tAlHiJT, 1 707)
t=1f5),
3580.
2113.
2114.
2115.
2116.
3587.
3588.
2119.
2120.
2121.
2122.
2123.
2124.
2125.
D-2-37
-------�
1707 FUR-IAU ;K>X, 5Frt.:j ) 2126.
IF( ILTST .GT. 0 ) MWlTEdvJ, 1 709) CLOUD , OK1 Y HLo , .\E T hi. H , A P-.HK , W T Nl> 2127.
I7u9 FuK"IAT( // 11X, y9H.t,:RS L/ATA .TYPt 12 UVtKAGE ".tAThtH C(.MU ITI Oi'JS) S2128.
I Si. // 10X, HHCLOIIO CUVF.K = , FlO.l, / IOX, 13HORY t'tlLH = , 2129.
2 FlO.l / IOX, iSrtWET OUL8 = , FlO.l / IOX, 13HATMOS PKESS = , 2130.
i FlO.l/ IOX, IJH.'.'lNf) SPEED = , F10.2 ) 2131.
IF( MT .EUi. 0 ) PD TO 1727 2132.
DKYriLh = l.H * O^YBLti + 32.0 2133.
wt-TuLb = l.tt * .".ETrtLH + 32.0 2134.
O I •? C,
vj I ivi t ^ — 1 . 9 4 2 rt * /•' I I') *
1727 REAOOMJ, Ifaol) ('"UT A (I , J) , J = 1, 3 )
Ir( DAI A (1,1) .''IE. ErtUA ) GO TO 1727
IF( ILI3T .GT. 0 ) wRITECiMJ, 171 1) (D A T A (I , J ) , J = 1, 3 )
1711 FORMAT ( / IOX, 3A4 )
1750 CONTINUE 2146.
2140.
STEP 4-0 2141.
IF THE COKRECT NO. OF DATA CAKDS2142.
NOT BEEN KEAO IN, THE PROGRAM w]2143,
2144.
2145.
c
c
c
c
c
c
CONTINUE
IF (
si OP
RtT
EiVD
2147.
2148.
2066 FORMAT (Iri 1 , 1 5X , IS^H* ****************, 2149.
2150.
2151.
2152.
2153.
2154.
2155.
2156.
2157.
2153.
2159.
2160.
2161.
r. 2162.
2163.
C 2164.
2165.
2166.
2167.
2168.
990.
i) ,Al_i; L (75) , PHUSK75) ,CWHM(75) ,0021 C 75 ) , 'J I ( 7 5 ) , T I ( 7 5 ) , 991.
L)nl(75) , tUHH (75) , Ct'^Sl (75) , AL&ScTl7rj) ,SPhOS(75) ,C«6(7S) ,
EXCUEF (/5) , RAii.Mf ( /S) , CNQ.'il (75) ,CKPhL1 (75) , CKPKL2 ( 7 5 ) , CKhCiMl (75) ,
CKHCriS (75) , HC^Jl (7'j) , PHLI (75)
2173.
COM'-ION /RLK2/ '.N 5 TEMP (90) , « S D l.l ( Q 0 ) , WSBOO (Qu ) , A'SCHNS (90 ) , rtSHCN (90 ) ,
A i-;fti-j,-m9(i) ,-.'S •:u2i.'*o) . NohO 3 ( 9o ) ,^'SCiil.l (90) ,,-, S A Lb ( 9 0 ) , viSPrif.'S (9 G ) , 2175.
6 '/0( 1 5) , H^PMOS ( 15) , M-M,Mn3 ( 1 5) , H.vi\!02 t 15) ,hv,UU3 ( 15) , H,\RAI)M( 15) , 2179.
B UATOT(IS) , HAS? i.i!) (I j) ,H;i CO use 15) , VH«( 15) ,DEPH/ (15) ,ULHW(15) ,
C JijriCH.'(15,S) , .^ r/.A«(lb) ,H;\CDH (15) f n^ALG ( 1 5) , HwHCil ( 1 5) ,HWPHL(15)
2.182.
Cu,i-li)f; /iiLi<4/ FLU ;(500) ,OEPTH(500) , VKL(500) ,l)TO\/CL(500) ,K2(500) , 21«3.
A Kl CJOj) ,!Vj('ii)-j) , .-AiiO(SuO) ,CO;-i3(500) , HSr-EI (b(/0) ,I)L(500) ,T (500) ,
b ALGAE('ioO) ,PV03(500) ,KMH3(500) , 2185.
C
0
2107.
V.EO.d) GO TO 88
(lril,15X,:SaH* * * * * * * * * * * * * * * * * ,
33K* *************** *,//,
lbX,J54ri*£XECUTIUi.M ft A S T E ,
3iHK f-i I IM A r E 0 BECAUSE*,//,
IbX, IH*,31X,3HO F,31X,IH*,//,
16X,34H* ErfROKS IN ,
3 SHI N P U r DATA *,//,
16 x, 3 ;t n * * * * * * * * * * * * * * * * * ,
33i~i* *************** *)
ME INOYiJ (ISX)
C DM •Jin.M A ( 5 0 0 ) , fU 5 0 0 ) , C ( 5 0 0 ) , X ( 5 0 0 ) , S ( 5 0 0 ) , Z (5 0 0 ) , to (5 0 0 ) , G ( 5 0 0 )
COMMON /bLKl/ TCLU^i)(75,20) ,COEFiJV (75) , EXPOui V ( 75) ,CuEFQH(75) ,
ft EXPOrin(75) , cXHijK, 2 (75) , KCH J 0 (75, 5) ,K'-nHOpJ (75) ,hMTEOP(75) ,
b UiMA'.jt.'r/b) ,CA 1 (. 7b) ,C^3 175) , K20PT (.75) ,CK2 175) ,COEOK2 (75) ,
C TARf,i)ij(75) , I AUR 0^(7^,6) ,'MCELPH(/S) , IFI. AG ( 75 , 2u) , ALPHAU(75) ,
I.)
ti
f-
H
(-3 HO) , K'ESPWrJ (5')0) ,C.JL I (500) , i^U/, TH (500) ,1^0^: (500) ,
,PHL (500)
Ki\l(500) ,
Ji-f-Hl.J /HLK5/ M
r ( 12) , I) (S) , ALP HA1, ALPHAS, ALPHAS, ALPHA «,CKM,CKP,
D-2-38
-------�
A CKI., N;mH3, E
FUR"1AT( 815 )
INK I TE(NJ,6020) fJTA,K|TB,NTC, I N THrt , IN TI^.'L, !NrM.[,MODE
FuR.''IAT( Ihl // 10X, 49HOYNA.--1IC wATEn QUALITY SIMULATION
1ULAFED //
//
TO
c-
c-
c-
2
3
b
7
0 X ,
OX,
ux ,
ox,
ox,
OX,
8 1 0 X ,
9 1 0 X ,
INPUT
35nRUh Cur*
2*Hl -JPIJT 'F
2BHI-MPiJT F
2KHHUU <
28HHJOR
2ftHHLHl«
2HHFILE
liUAL ITY
I'J
1:1
IM
SO
IROL IS SPECIFIED AS FOLLOWS
ILEUASTt LOADS) = , 17 /
1LEUEATHER) = , 17 /
T E rt V A L
FERVAL
1 EKVAL
j ,j £ jr r p
REcnwDS.
(WASTE
?)
=
LOADS) =
(ftEATHER) =
OS=0,Mf
.PLACE
1UN1
ON
r=i)
MTC
=
,
,
i
,
THEN
17 /
17 /
17 /
17
H:IVE
TO NTX,
-MTA
75
iNlTC
= 0
= DELT t 0.5
IF( MODE -EQ. 1 ). RETURN
KOUi-ATA(I),1 = 1, 8 )
GU TO 100
C-
C-,
C-
IdO
.LJE3I.J IMPOT OF SECil'-JD DATA -SET .. CHECK FOR NULL SET
R EH I Ml) NTC
WtAi.)(.Ml,5040) Itf, t l>Ar*k([), 1= 9 , 16 )
IF( 10 .Ea. IENU ) GO TO 175
( PATA(I),1= 1, ft )
2195.
2196.
2197.
2198.
2199.
2200.
2201.
2202.
2203.
?20a.
2205.
2206.
2207.
2208.
2209.
2210.
BE CAI.CP211.
2212.
2213.
2214.
2215.
2216.
2217.
2218.
2219.
2220.
2221.
2222.
2223.
2224.
2225.
2226.
2227.
2228.
2229.
2230.
2231.
2232.
2233.
?23'J.
2235.
2236.
?237.
2238.
2239.
2240.
2241.
2242.
2243.
2244.
2245.
2246.
2247.
224H.
2249.
22SO.
2251.
D-2-39
-------�
\->., SFrt.O )
IFC 10 .EiJ. lEMO ) GO TO 250
i-.-il rfc'Cf'TC) I HATA CI) , I = 1, 5 )
GO TO 210
C.jr-.TI.vUE
PEi'-.' I MO JTA
REMIND
i-VIC INPUTS . .BF.G LIM V-ITH HEADWATER VALUES....
IX, IMTH'A') .NE. 0 ) GO TU 320
P252.
2253.
C-
C- HEAD DYM/
C-
?00 IK'EAO = 0
IFC f- U D t N
I HEAD = 1
r>u ii-.j j = i,
READ c-iTA) x xx , H -,FLU-/. CJ ) ,H.« T t-^P (J ) , H.vim (J) ,HwbuO CJ) .hwcows C J),
IH/HC'JU) , H'/.PHL CD , H AALGCJ3 ,riA',vH3CJ) ,Hi'.MJ2CJ) , hk1. !\'03 C J ) , HXPhOSCJ) ,
2H,'-Ci.'LI C J) , H.-..H AD . C J) , H/viMH2 CJ )
IFC ALPHAUCl) .GT. 0.0 ) Hf,ALGCJ) = Hw ALG C J ) / AI.PH AO C 1 )
IFC NT . F: j. 0 ) GO F 0 310
H,,FLO/;(J) = 35.313-4 * H^FLOrt(J)
H.',T£Mp(j) - i.* * >KTE'-iP(J) +.32.0
310 CONTINUE
c-
C- INPUT ,<;A5jTELJAO VALUES
c-
320 TF( MODCMTHJUK1, IM'-NL) .^E. 0 ) GO TU 34u
IFC f-iA'ASTE ,LT. 1 ) GU TO 340
I«EAO = 1
1.1 i.i 330 J = 1, f^ASTE
XXX,,' -SFL(.i''(J) , WST£MP(J) , i\.'SDfj(,l) , i%ShUO(J) , if.SCUNS ( J ) ,
J 1 , ".'S4LG C J ) ,;'. S'-.'H3( J ) , W5fv02( J) , ,\S^03C J) , h'SPHUS CJ) ,
'HCJ) , i-.lSis)H2C,!)
TKFACTC.I) = xxx
IFC ALPHAilCl) .UT. D.u ) -MSALG(J) = W3ALGIJ) / ALPHAO(l)
IF ( <»T ,F(J. 0 ) Gu TO 330
2257.
2258.
?259.
2260.
2261.
2262.
2263.
2264..
2265.
2266.
2267.
2268.
2269.
2270.
2271.
2272.
2273.
2274.
2275.
2276.
2277 .
2278.
2279.
2260.
2281.
2282.
2283.
2284.
2235.
2286.
2287.
2288.
2289.
2290.
2291.
2292.
2293.
2294.
2295.
2296.
2300.
2301.
2302.
2303.
2304.
2305.
2306.
2307.
2308.
2309.
2310.
2311.
2315.
2316.
2317.
D-2-40
-------�
J) = 35.3134 * IMFLUA(J)
HrtTtMHU) = l.ft * H.vTEHP(J) * 32.0
330 CONTINUE
C-
c-
c-
INPUT /.'EATHEU
340 IF( !',OIHMTHl)U«, INH-iI) .ME. 0 ) GO Hi 360
Ot.AOCMTC) CLOUD, Cm HLb,wET BLR, ATMPK,wIND
IF C Wf .EU. 0 J GU TO 345
= l.JJ * DRY^LB + 32.0
= l.ii * ,'jETiiLB + 32.0
1.942R * ft £ NO
345 CUNCIiMUE
rt(NO = Wl«0 * 1.151
360 IF( NTHUUH .GT. 0 ) GU TO 420
C-
C-
C-
C-
C-
C-
INCTALIZe FOR DYNAMIC SIMULATION,
,SET UPSTREAM ELE.MErOS TU HEADWATER VALUES,
365 J = 0
0(J 370 1 = 1, M«EACH
fF( IFLAGlI,!} .Cl£.
K = ICLOKIHI,!)
J = J * 1
T(K) = HwTEMPU)
OU(K) = HrtDO(J)
flUD(K) = HiVrJUOCJ)
Cuiv.3 CK)=H',ii corpse J)
) GO TO 370
PhL(K)=!-ti'iPHLCJ)
ALUAE(K) = Hv;ALG(J)
370
PHDS(K) = H/.'Pnn3(J)
CuLI(K) = HrtCOLKJ)
KAO'\l(lO = ri;KWA!).M(J)
CUNTINUE
o
c-,
c-
.HEGIN LOOP TO INTERPOLATE VALUES,
DO 410 1=1, MREACH
LU« = C
NCELR = NCELRH(I)
IF( IFLAG(I,NCELW) .EiJ. 5 ) RO TO 390
IF( WJU.-iC ,E(J. 0 ) <;0 TO 330
DU 375 J = 1, NJU. = III*
NX s NCELK - 1
TF( NX . £ U. 0 ) NX = 1
ox = ;>jx
orox = i TCIIO - TCIAJ ) / ox
000 X = ( OiHI'O - U'J(IA) ) / OX
= ( HUU(IM) - ydU(IA) ) ./ OX
23 I ft.
2319.
2320.
23?1.
2322.
2323.
2324.
232b.
2327.
2328.
2329.
2330.
2331.
2332.
2333.
2334.
2335.
2336.
2337.
2333.
2339.
2340.
2341.
2342.
2343.
2344.
2345.
2346.
2350.
2351.
2352.
2353.
2354.
2355.
2356.
2357.
2358.
2359.
2360.
2361 .
2362.
2363.
?364.
2365.
2366.
2367.
2368.
2369.
2370..
2371.
2372.
2373.
2374.
2375.
2376.
2377.
237d.
2379.
2380.
2381.
?3fl2.
D-2-41
-------�
OCll>X=(CljMtJ(M)-C JMS(IA) )/OX
OC2i>X=(,-)CMUH)~)Ol(IAn /OX
l)C30X=(PHL(lti)-PHLUA) )/DX
1.) A 0 X
0>J 1 i)
IV-12D
r)i\i3!j
—
X =
y =
x =
f).V4QX- =
C-
£ _
c-
D POX
o c D x
D K 0 X
—
—
-
CHECK
Ih (
OU 3
MCEU
DO 3
IF(
IK(
LO'/<
9/
(
(
(
(
(
(
(
I
AL
c
c
c
c
GA£
N H
3
:MH2
Nil
.\'H
PHUS
CtlLI
R
A
L 0 '-'J
.
II
Q
^
= i4CEL
ICL
JJ
URD
-
(
5
a
(
(
(.
FOR
.
I
! r i G
) GO
^ K r A
ii)
\CEL
JJ) .
- ALGAt
- Ci'IH3(
- CMORl
- CKli?l
- C-ih2(
PUDS (I
CttL I ( I
RADivi (1
(
I A) ) / DX
I A ) ) / D X
I
I
r
A
A
A
A) ) / DX
A) ) / DX
A) ) / OX
) ) / DX
) ) / DX
) ) / OX
LE ELEMFNT
TO 398
ME. LOW
) GO TO 396
1 ) LOW = 0
GO TO 39a
396
397
398
C-
C-
C-
CUl'lf
COiVT
CLINT
I'MUE
INUE
IMUE
c n ft P u i
DO 405
DX =
K =
IF(
IF(
TlK)
Du(K
J
IA
J .
K .
=
) =
E
J
+
En
En
r c
i\
=
J
m
•
r
00
\ft
A
(
1,
1C
u
)
I A
RtjO (K ) = nOU (
cu-vs
HCl-i (
PhL (
( i\ ) = C 0 'V
K) =
K) =
• i c r-i
(
S(
IA
3 T 1 1 W P
t
)
+
)
I
I
)
P H L ( 1 A )
A L G A E U ) =
r: iv H i
Cwfl 2
Ci\,n3
C I'M 1 1 2
(K)
(iO
(K)
(K. )
=
z
=
—
C
c
c
c
AL
G
i-:h3
.\IU
;ui
.'iH
2
5
J
P H I .' ,S ( l\ ) = P H 1 1 'j
CilLI
R«U-J
(K)
U)
= COL
=
R
Ail
I
.-!
.'JCELR
LR )
THE I M 1
,< = LO-,-1
ERPHIATFl") UAl llFS
GO TO 405
i ) T D X
+ L)0
A) •*•
A) +OC
* DX
iJ X * OX
OHDX *
DX
1 1) X * D X
+ UC2UX * I)X
+ D C 3 D X * 0 X
A li ( i A
(IA)
(IA)
(UJ
(IA)
(IA)
(IA)
UA)
) t DAOX
+ DD10X
•t- Uil2Dx
+ i)M3!)X
+ 1) f\ 4 0 X
+ DPOX
t OCDX
+ 030X
*
*
*
* OX
* DX
* OX
* DX
* OX
OX
DX
OX
'HO Cb^fl'^UE
IF( ISS .GT. •j )
r.]THUUK = M
CUK"-lOiJ AC 500) ,!HbOO) ,01500) , X I50uj , 5l50u) , ZCiOO) , in 500) ,G(5()0)
U XPLK1/ rCL')RO(7S,?u) ,COEFQV (75) , F.XPUfJ V I 7'.?) , COEFQH ( 7 5 ) ,
A EXPOUH( /5) , EXPNA?i75) ,RCHIO(75,5) , R>1 TH(JR ( 75 ) , i^-'TEOR ( 7 5) ,
b C-UrJij(75) , CKl (7b) /Ci%3l7b) rK^UPI ( 7^>) , CK? 175) , CUt UK2 ( 75) ,
C T ARGi>M ( 75) , I'. JGo/V ( 75 » 6) r'nCELRH ( ?5) , IFL^b ( 75, 20 ) , ALPHAU ( 75) ,
D C<4 (75) , Ci\5 (75) , C'<"iM.5(75) , CKM02 (75) , C,\r-iu3 (75) , S'>'i»'5 (75) ,
E COL 1*175) ,ALGJ (/5) ,i3HOSI(75) , C\M i i ( 7 5 ) , CMC2 1 ( 75 ) , U J ( 7 5) , T I ( 75 ) ,
F 1.1 JU75) , HuiM (75) ,CD"SI (75) , ALUSEU75) ,SPHi'S(75) .CCM75) ,
G EXCOFF (7S) ,,ik of-'I ( TS) , UNO 3 I (75) ,CKHHL1 (75) /C^PHL2(75) , CKHCN1 (75)
H C K H C I1- 2 ( 7 5) , d C, j I 1 7 j ) , P H L I ( 7 5)
(90
23H6.
?357.
2388.
2390.
2391.
2392.
2393.
2394..
2395.
239fe.
2397.
2399.
2402.
2404.
2405.
2406.
2407.
2408.
2409.
2410.
24U.
2412.
2413.
2414.
2415.
2416.
2420.
2421.
2422.
2423.
2424,
2425.
2426.
2427.
242S,
2429.
2430.
2431.
2432.
1.
2'435.
2436.
2437.
2438.
2439.
2 4 4 0.
2441.
2442.
2445.
D-2-42
-------�
A KSrJHJ(90) , v\SFLO'.'U vO ) fwSKAUN(Oy),fcSPHL(90)
COM--iS(500J , HSNET ( 50u ) , HL (5f»o ) , r (500 ) ,
b AI.RAE(500J,HnnS(500),CNH3(500),CN02(500),CMu3(500),KNH3(500), 2457 .
C K.HI2 (500) , KcSr'RR (5i'0) , COL I (500) , GrtUrtTH (500 ) , K'AON (500 ) ,
!J KK 1 (500) , *K2('50u) ,HCN (500) , PHL (500)
C . 2459.
CUi-K-lON /HLK5/ MOOilPT ( 12) ,0(5) , ALPHA1 , ALPHA2, '«LP^ A X , ALPMA4 , CKM , CKP ,
A CKL,^.li'JTRS,:j-;iiAt:M,M!«ASTt,'\i.IUrJCrOELT,DlLr,U2Lr,DTuuX2,UT2i.lOX, 2461.
b A frlPR , ..-.'I IMU , CLOUIJ , SONET , M I , \ J , 1 RLCU , TOFD« Y , iJ T , ivC , T PIE , ''.CS , L AT , 2462 .
C LSM,LL!'',fiLEV,:>A! , .\E , BE , 0 A YOF Y , Dk Y i^LH , fit \ RLU , Dt A PT , P 1 It ,£ , TPR I NT , 2463.
u DF.LX,ISS, ALPHAS, ALPHA&,GSOMAX,PESPRT,NCELLS, ILIST , I( TO 100 69.
C 70.
104 N/vS = NMS-H 71.
b ( MR) =S ( IMR) -uSFLM/v ( NVMS) *DTO\/CL ( I OR) 73.
D-2-43
-------�
C
C
H E T U K N
EM)
75.
CuM-iOM A(500),fa(500),C(500),X(500),S(50o),Z(500),lv(50o),G(5(>0)
CUM'-ION /I'.LKl/ ICLf)ku(75,20) , CCiHFQV(75) , t X POU V ( 7 5 ) , CHEF OH (75) ,
ExPil!OH(75) , EXPUi\2(75) , RCHIP(75,5) r K'MTHnm75) , KViTtljR(75) ,
B
2440.
2441.
CHA:v,w(75) ,CiU (75) , C .< 5 ( 7 3 ) , MOT (75) , C*2 ( 75) , CUE IOK2 (75) ,
C IARGOU(75) , 14UGim7S,6) ,NCEL^H( 75) , IFLAG(75,20) , ALPHAO(75) ,
E CJLlK(75),ALGl(/5) , PHUSI ( 75) , CWH3I (7 5-) , CMi.l?! ( 7 5 ) , U I ( 75 ) , T 1 ( 7 5 ). ,
f tfiJl (75) , BOIJi (75) , C'J.MSi (75.I,ALGSET(75) , SPHUt>(75) , CKM75) ,-
G EXCJEF(75),KAL)'Jl(7d),C'-JQ3I(75),CKPHLl(75),CKPhL2(75),CKHCM(75),
ri CKHC;M2 ( 75) , HCi-U ( 75) , PHL [ ( 75)
2445.
CUM^Divj /rJLK2/ 'liSTEMH (90 ) , ,\SD(J ( 90 ) , rtSHuD (90 ) , IftSCUNS (90 ) , ASHCW (90 ) ,
A rt3i (500) ,CO.MS (500) ,HSi\-E F (50U ) ,OL (bOO) , T'(500) ,
A
b
C JUNCIU(15,5),.
CUM -ID-l
A K 1
b ALGAE(SOO) ,PhJS( SOU) ,C'M.i3( 500) ,CWO?(500) , CMC 3 ( 500 ) , K hH3 ( 500 ) ,
C K -jri2(5;>0) • HESP^,<(50u) , CUL1 (500) , GKO'.'. TH (500) , RAOM (500) ,
0 KKI
,KK2(50U) ,HCN(500) ,PH|_(500)
2457.
2459.
CUMMIU /HLK5/ M!;iOMPT(12) ,0(5) , ALPHA I , ALPHAS, A LPHA3,ALPHA4,CKW,CKP,
A C^L,^m/.• r*S, .JKt ACri^.ivASTE »|N) JU!\iC , UELT ,C 1LT , i>2L T , OT("il'X2 , OT200X , 2461 .
b A FMpR, -.liifiO, CLuUJ, SO,\j£T, ;M I , MJ , f «LC 0 , TOFD A Y , i\ T , KC., 7 1 f-;i£ , i-,C S , L A T , 2462.
C L.SM,LL'",t'Lf V,UA f, AE,HE,UAYnFY,r^Y8LH,».EIBLH,OEKKT,PTI^e, TPKlfJT, 246 J.
D OELX, 1SS, ALPHAS, ALPHA6,G«JMAX,kESPtn /i^CELLS, ILIST, IkPT 1 , IAUGOP, 2464.
E
T-1AX, I
rt, IXPLT<£,CKH1P,CKPTP
CuM'iUivi /HLKb/ ALPHAS,CKr^HS(75) , C -JH2IT (75) ,CMH2I (75) ,1
1(15) ,
2466.
C
C
C
N M W = 0
N A1 3 = 0
FACT = D1LT
28.3
OU 100 1=1, BREACH
OU 100 Jrl,
, J)
INITIALIZE COU.'MTEWS
LOOP THROUGH PEACHES A»iO CO^F. ELEMENTS
OIAGUiMAL AMD KMOWh TERMS
TF (M;jouPT(4) .E J.O) ALGAE(TL)W)=0.0
TC = l).55o*(T(IijR)-(i>».0)
K;;H3( l(j.-<)=CK."ri?(n *l.047**TC
KEAC1 = ALPHA t *i
-------�
c
c
c
c
c
C
C
S( [iik)=C*'H3( fijR)
IF (I.SS.GT.O) S(IilR)=0.0
1F( CNH3IJ .Gl. 0.0 ) GO TO 90
RO TO 95
VO S(IOR) = SlIflR) + C.MH3TJ*CNh??I(I)*OTOVCL(IPH)
95 SHOW) = 3( IL;K) + RtAC F
B ( I , J )
? '1 9 U ,
?495.
2496.
MODIFY DIAGONAL Ai-iO/OR KfcGwN TERMS
GO TO (101 , 100, 100, 100, 100, 10'j, 10A r,rtt-:,'it,OAYiJFY,nRYiiL^,i"F F ttLH , Dt "!P T , P VI r-t, THW 1 f>, T , ?54H.
U OtLX,lSS,=»LPHA5,ALPHA6,SRON;AX,RtSPRT,i'jCELLS,ILIST,lKPTl,IAUGnP. 2549.
E T.-1AX, i»'JU05, JSij:-!, IxPL F2 , CK HTP , CK PTP
2551.
REAL KM02/ KNH3 2552.
2553.
IMTIALI^E CUOi>iTERS 2554.
D-2-45
-------�
C
c
C
C
C
M rt S = 0
DLI 100 1 = 1,.'IREACH
LOOP THROUGH REACHES 4\l> CUMP. ELEMENTS
= '01 ID/CNCELR
Du 1UO J = l , :-*CtiLH
I, J)
INITIALIZE DIAGONAL AMD
^ TEKMS
TC=0.55o*(T(IUR)-68.0)
K Nf)2 ( I UK ) =C rf MI 2 CI ) * V . 0 4 7 * * TC
90
95
FHIJfOsx UCi.Of01LT*KiMi)2(IQR)
IF CIoS.Gl .0) S( I OK)=0.0
IF( C.JU2IJ .Gf. 0.0 ) GU TO 90
Bd'JK) = ti(IUri) - C:\1U2IJ*OTOVCL (IUR)
GU rri 95
SH'.)H) = SdCKO + CM02I J*CND21 (I) *OTUVCL (I0r<)
S(Ii)R) = S(IC)K) t- REACT
. = IFLAf;(I, J)
1 U 1
03
DIAGONAL AiMD/OR KNO^N TERMS
GO TO ( 101 , 100, 100, 1 00, 100, 103, 10<4) , IFL
N H t*l = (i iH w + ]
G U T11 100
S (IlJIO =3 (I(iK')
G U TII 100
('•;.' 3) *.KS,x'U5
*n T 0 VCL C I. OR )
(i.i'\'3}*DTOvCL(IOH)
100
SURROUTINE .
2557.
2559.
2560.
?561.
2563.
256'4.
2565.
2566.
2567.
256H.
256-).
2570.
25/1.
2572.
2573.
257-'4.
2575.
2576.
2577.
2573.
2579.
2580.
25«1.
2582.
25fl3.
nC5ij(U ,C (500) , X 1500) ,S (500) , I C5i;0) ,/;(l500) , n (500)
l/ ICLuWL)(75,20) ,COEFOV(7SJ , E XPljuV ( 75) ,CUEFQH(75) ,
) , EXr-ro*? (75) , KCHID (75, 5) ,iwiTHO^tVSj ,RWTEUR(75) ,
,CK1 l 75) rCl-. .<(75) ,K<£npT 175J,CK?(75) , CuEuK2 17 fi ) ,
I AH GOO (7 5) , I AuUJ^(75,n) ,ivCtLRM(75) , I FL AG ( 7 '3 , £0 ) , ALfJMAOC75) ,
CK" (75) ,C!H3 ( 75) ,
CULlfU75K AL(U (75) ,PHOSI (75) ,C'VH3T (/?) ,C^UdI ( 7 5 ) , ',' I t 7 lb ) , T I C 7 5 ) ,
0:11 I7b) ,*uni (7SJ ,CQ iST ( 7 5 ) , ALGSt T 17 5 ) ,SPH!.)S(75) ,C.K6175) ,
EXCDEFC75J , RAlMv[ (/5j ,C.N03I (75) ,CKPHLl (75) , CKPHL2 (75) , CKHCN1 (75)
CKHCf.2(7S) , HCi.T (75)., PHLI (75)
CU'-V-KI.-J
A WS;-ln3(°i» ,i-.'SHU.'P ( 1 5 ) ,
A H-JHHU5) , Hi-IPHLi.Sdt.)', H.vi'lM3(15) , H.vNu^US) ,H,%^u3(l5) , Hv^ ALH'I ( 1 S) ,
tJ .-I A Fi)T ( 1 5) , H.-IH JU ( 1st , H.vCU:'jS ( 1 S) , vH'.-j ( 15) ,OEPH>\ ( 15) , DLhw ( 15) ,
2585.
2586.
2507.
2586.
25«9.
2590.
2591.
2592.
2593.
259/4.
2595.
2596.
2597.
259(3.
2599.
2600.
2601.
2602.
2603.
2604.
2605.
2606.
2607.
2608.
2609.
2612.
26ia.
2616.
261 7.
26 1«.
D-2-46
-------�
C
C
C
C
C
C
C
C
C
C
C
C JuMCIOl 15,5) ,i«jHrt/iArUl'5) ,H.\CuLI ( 1-5) ,h«ALG( 15) , ri.';HCii( 15) ,hrtPHL(l5)
CLHMI.IN /H|,K4/ FLO*(500) , OEPT H (50 0 ) , vEL ( 500 ) , I.HOVCL (SOU ) , K2 ( 500 ) ,
A K I (50o) , DO (500) , 3UIHSOO) ,CONS(500) , hS'ME T ( 50(1) , UL (50 0 ) / T (500 ) ,
b ALGAE (500) , PHtlSCSO'l) ,CNH3C500) ,CwJ2(500) ,CNU3(500),KMHU500),
C K "11)2(500) ,RESPR><('500) ,COLI (500) ,G*(U\TH(500) ,RAD>M(500) ,
0 KK1(5UO),KK2(500),HCN(500),PHL(500)
2626.
CUMMU.M /HLK5/ MUOOPTU2) ,0(5) , ALPHA 1, ALPHA2 , ALPnA3 , ALPHA4 , CK iM , CKP,
A' CiREACH,r>;-,vASTE,1'Jj'UNC,DELT,01Lr,U2LT,OTuDX2,UT20DX, 2623.
b AlMPi<,vMMD,CLiJUL>,3UiMET,'-Ml , rJJ, TRLCU, TOFOAY.;«i7 , f-iC , T IM£ , I^CS , L A T , 2t>29.
U DELX, ISS, ALPHAS, A LPHA6,GR'.'JM AX, RESPRT.KC ELLS, ILI ST , I4PT 1 , I AUGOP . 2631.
2633.
2634.,
26.35.
2636.
2637.
2638.
2639.
2640.
2641.
2642.
2643.
2644.
2645.
2646.
2647.
2643.
2649.
2650.
2651.
IF (MOIKiPT(4) .EiJ.O) M.GAE(IOR)=0.0 2652.
REACT=UlLT*.rtfJb2(lJH) *C^t)2 ( I :U3IJ = l
UJ 100. ,I =
INITIALIZE DIAGOiMAL ANL> KNOWN TERMS
r-lOOIFY OlAGUNAL AMO/OW KMOIA.N TERMS
BU TO (101,100,100,100,100,103,104), IFL
S(IQR)=S(IOR)-A(IOR)
GU TO 1UO
101
tU.i5
GU TO 100
104 N»S-N.MS*1
KlIiJW)=H(
100 CuMTlMUE
RETURN
2656.
2657.
265H.
2659.
2660.
2b61 .
2662.
2663.
2664.
2665.
2666.
2667.
2b63.
2669.
(r«/WS) *DTOVCL ( I Ok)
2672.
2673.
2674.
2676.
2-677.
267tt.
C
C
SUBRUUTI!-JE PGRAPH
.
COMMUN A (500) ,H(500) ,C(500) ,X(500) ,S(500) , Z (500 ) , I'; ( 500) ,G(50<>)
26HO.
2681 .
2683.
?6H4.
D-2-47
-------�
CUMi'lu X'.'LKl/ [CL'JKM(75,2'J) ,CUEFOV (75) , F. XPflJ V ( 7 5 ) , CUEFUH ( 75) ,
A F. XPuO-i ( 75) , E XPi.ivr? ( 75) , RCH 10 (.75, 5) , K'/iTrliiK ( 75) , KM! t:i)R (75) ,
a C'-iAMi-'l75) ,CM (7S) ,CK3(75) ,K20PT (75) ,CK2(75) ,CUi:iJK2(75) ,
C TARGI'hj( 75) , I Aii^UK (75, b) , I'iCELR'H ( 75) , LFLAG (75, 20) , ALPHAD-(75) ,
U CMi (75) ,CK5(75) ,CKh!H.U7S) ,CKt\.U2(75) ,CKN03(75) ,S.\'H3( 75) ,
t COLI* (75) , ALGI (75) , PHOSI (75) ,CNH31 (75) ,CN02I (75),-J 1(75),
I- GUI (7L->) , S'JO I (75) , CUM SI (75) , ALGSET (75) , SPHuS I 7 5 ) , Ct\6 (75) ,
G E -2(75) ,HCA'U75) ,PHLI (75)
COMMON / ;*> .M U ? ( 9 0 ) , >V S M i J 3 ( 9 0 ) , ft S C 0 L I ( Sf 0 ) , * 5 A L G ( 9 0 ) »rtSPH03(90) ,
0 WASTIi)(90,5) , IRFACT(90) , ;vSFI.()W (90 ) , ViSKAON(90) ,WSPHL(90)
...... / JOiMCll5,3) ,H'.'JTRID(15,5) , HrtFLU* (15) , HWTE^P ( 1 5 ) ,
A H ;i)U( 15) , .l'.vPM05(15) , H.-;^n3( 1.5) , H ,M\U2 11 5) , HWMU3(15') , Hv\'RAI.ii'l(15) ,
U tfrtTUT (15) , H.M.iiji.H 15) , H'ACUf\.S ( 15) , VH/. (15) ,OEPn^ (15) , (JLHrt ( 15) ,
C JU(.;CIu( 15,5) ,^H.Vi\AK(15) , Hi'.CiJH (15) ,H'AAL6(15) , HwHCM(15) , HV/PHLC15)
2697.
(75), 2690.'
2b93.
2695.
2697.
2690.
2699.
)H^OiM /HLKa/ FLO.'J.(SOO) ,0£PrH(500),VEL(500),OTUVCL (500),K2(500),
Kl (500) ,00(50.)) ,«i)l) (500) ,CLhviS (.500) /HSrviET (500) ,DL (500) , T (500) ,
ALGAC (.5uO) ,PHuS(500) ,CNH3(500) ,CK02(500) ,CMJ3(500) ,KNH3(500) ,
K-KJ2 (500) , Kt-SPRR (500) , COL 1 (500)-, GK'Llw fh (500) , I
K!;rRS,:.,"?EACH,(>n\ASTE,XiJUMC,OELr,OlLT,D2LT,OTUDX2,OT200X,
A fiM(-)iv,i"ilrg[),CLiJlJIJ,Sil,\ET, vi I, '-I J , 1 RLCU , T('FO A Y , Ml , !;C , 1 1 i^iE , iiC S , L A T ,
LStf ,Ll.t!,ELEtf ,i_-Ar, AE,BE,OAYnFY,ORYHLB,ftEfBLe,Dt>'PT,PTlME, TPRIfiT,
OELX,lS5,ALPMA5,ALPHA6,GWLlr-1AX,^tSPRT,!\CtLLS,ILI51,(RPTt,IAUGUP.
T"IAX,i»UI):>,JSUX,IXPi_T2,CKriTP,CKPTP
Av\b'JH2 (75)
AI.PHA9,Ci
-------�
IF (JK ,F(J. 8)
TF (JK .tiJ. 9) PSFOrtEd) = ALbAE (iOrt) * ALPHAIJ (I )
IF (J,< .EU.tO) PSTUHEd) = COLI(IOK)
IF (JK .EO.ll) PSTOKEd)=CI)NS(IUR)
IF (JK .EQ.12)
IF UK .EU.i:$.)
IF (JK .Eij.14) PvSTOKEd) = /.dOR)
100 CONTINUE
615 DO 111 1=1,51
00 111 J=1,1U1
111 IliRAPhd,J) = ]
DJ .112 1=2,50
112 IliRAPrid, 101)=IVE8
00 113 1=2,100
loK'APrK 1,1) =lHOit
113 I5RAPH(51,I)=1HOR
DO 114 1 = 1,101,5
IliKAPrid, i)=IPLUS
114 IiilUPHKSl ,I)=IPLUS
IliRAPK(I,l)=IPLUS
US IliHAPrid,101)=IPLUS
K'd)
AMAX=PSFORE(l)
AMI J = PSFfiKEd)
Ou 115 I = l,.-iREACH
IF (IFLAtid,!) -EU. 1 .AND. I .GT. 1) GO TO 116
IF (PSTOKEd) .r,T. AMAX) AMA XrPSTuRE d)
IF (PSTuKEd) .LT. AM1W) AMlN = PSTOI'AX) CM AX
IF (OAT-|(JK,I) .LF. CMI'M) C^I'M
IF («;•!'•]( JK, I) .GT.. DMAX) DM A X=RMM ( JK , I )
IF (W«-)M(JK, 1) .LT. DMIM) OMIM = RMM(JK,I)
177
620 IF (OlAX ,G1. A-IAX) AMAX=CMAX
IF (OiIM .LT. AY.I-4) AMlM=CMtN
[F (OiiAX .GT. R-iAX) «MAX=OMAX
If (O'-iliM .LF. H-fl.J) B.viIN=D(-iIN
DEL.-?=(HMAX-riMj;jj /l 00.
IFdFLAG(I,l) .EQ. 1 .AMD. 1 .GT. 1) GO TO 711
11 = 1
IF (P3TOI?E(I) .iiE. AMAX) GO TO 118
1=AMAX
119 IF (PSTOWEd) .LT. XNUH1 .AND. PSTHRFd) ,GE . XNIIM2) GO TO lltt
IF (II .EQ. 51) GiJ TO llfl
RU ni 119
D-2-49
-------�
I Itt JJ=l
XigUi-ll =8 MAX
FF (RMTrlOK(I) .GE. rtMAX) GO TO "
IF"cRMT
JJ=JJ+1
120 IF"cRMTriOrt(I) .LT. XMLH1 .AND. Rr'THlJKCI) .GE. XMUM2) GO TO 117
IF (JJ .EJ. 101). GO TU 117
Gu TO 120
117 IGKAPHUI, JJ) = IASi<
711 CONTINUE
IF CIXYZ2CJK) .EQ. 0 ) GO TO 121
OU 130 1 = 1,IO/J
11 = 1
IF (UAT-UJK, I) .GE. AMAX) GO TO 131
11 = 2
XiJl) -11 =A 1AX
132 IF (i)ATM(Ji<,I) .LT. X'JUMl .AMD. DATM(JK,I) .GE.. XNUii2) GU TO 131
11=11+1
X^i.ri2 = X -HIMl-CJELU
IF (II .Eli. 51) GO TO 131
GU TO 1:52
JJ=1
Xn.U ^2 = X \IUMl -
If- (RMi'KJK, I) .GE. rtMAX) GO TO 135
JJ = 2
133 IF («,Miv,(.IK, I) .LT. XMUM1 .A->Jf). RM-KJK, I) .GE. XMUM2) GO'TO 135
JJ=JJ+1
XMl'-ll =Xi'jU:-12
IF (JJ .EU. lulj GO TO 135
GU TO 133
135 IF (IGK>AHH(II,JJ) .EQ. 12 .JR. IG* APH ( I I , J J ) .EQ. IASK) GO TO
K LI r i j i 3 o
136 iGK'APHdl, JJ)=I2
121 DELOO=n£LO*5.
WHITE (i-JJ,6U09)
fa 009 Flirt -iAT ( ' 1 ' )
XNiJ .11= AM AX
ou iao 1=1, si, 5
If- (I .En. 26) GO TU 144
wiklTE (r-iJ,l'4r) XN'!.i.'«l, (.IGRAPHd, J) , J = l , 101)
141 FU1^ -I AT (J 3X/F7.3, 101A1)
IF (I ,£U. 51) GO TO MO
Mv;=I + l
145 ''i = T + 4
Du 142 LI=M:-1,M
142 /- h I ! E ( M J , 1 4 3 ) ( I G K1 A P H ( I I , J ) , J = 1 , 1 0 1 )
143 FORMAT (20X,101A1)
XM.ril=X:'ll'Ml-DELDO
G LI TO 1 4 u
144 RL! 10 (150, 151, 152, 153, 154, 155, 156, 157, 150, 159, 160, 161, 162, 163)JK
ISO i"nlTE (.Jj,MlUO Xi-JU.'-il , ( 1GKAPH (I , J) , J= I , 101 )
bOlO FuRMAT (7X, 'Tti-P. ' , 1 X, F7 . 5, 1 01 Al )
MM =1+1
^•KITE (viJ,6011) (IG^AFH(H»I, J) , J = l , 101 J
bOll FUFvlAT (hX,1 (F) ',9X,101A1)
G U TO 148
Ibl '"KlIE ( ;J ,f.l;22) Xi-in -i 1 , ( IGWAPri ( I , J ) , J=l , 1 01 )
D-2-50
-------�
6022 FuRMAf C7X, M).0. ' , 2X ,K7 .3, 1 0 1 Al)
WHITE (:NiJ,6u23) UGRAPMCM"l,JKJ = r, 101)
t>023 FOR'-IAT (6X , ' (Mfi/L ) ' , ft X , 1 0 1 A 1 )
GU ro 148
152 WRITE (A|J,60?/O XNiUMl, ([GRAPh(I,J),J=i,ion
6024 FORMAT (6X , ' B'.O .0 . ' , 1 X , F 7 . 3 , 1 0 1 A 1 )
GU TO 149
153 I/'.FVITE (rtJ,602b) XNU.*l , ( IGRAPH ( I , J ) , J = l , 1 0 1 )
faOc?5 FQR-IAT (3X, '0-iGAMOK'1 ,1X,F7.:5, 101AU
MM=I+1
rtKlTE (r,'J,60P6) (16RAPHCMM, J) , Jrl , 101)
6026 FORMAT C4X , ' ( MG/L ) ' , 1 0 X , 1 0 I A 1 )
GU TO 148
154 WRITE (fJJ,6027) XMUM1 ,( IGRAPH (I , J ), J = l , 1 o 1 )
6027 FURi-UF (7X, 'MH3' ,3X,F7.2, 101A1)
GU TO 149
155 WHITE HJ, 602(3) XNIM 1 , ( IG«APH (I , J) , J=l , LOU
6028 FURMAT (7X,-»!-IOa' ,3X,F7.3, 101A1)
GO TO 149
156 -.'JRETE (i'Jj,6029) X.'JUrtl , (IGiiAPH ( I , J )., Jr 1 , l 0 1)
6029 FiiRMAf C7 X , ' N03 ' , 3X , F7 . 3, 1 U 1 A 1 )
GU 10 149
157 irfhiUE (iJ,!,6030) X^UM 1 , (I GR APH ( I , J J , J= 1 , 1 0 1 )
6030 FUKMAF C7x, »PHOS. ' , ix,F7.3, IOIAU
GO TO 149
158 MITE (-.|J,6031) X •JllMl, (IG«APH(I,J) ,J = 1,101)
6031 FUK.1AT (6X, 'ALUAE1 ,2X,F7.3,101A1)
Gu TO 149
159 WKire (;\.f,6032) XIMU^I, (IGI?APH(I, j) , j=i. 101)
b032 FUR. -I AT (3X, 'CuLIFUR,-tS', I X , F7 . 3, 1 0 1 A U
ft'kirif. lwJ,6033) (IGWAPHCMw, J) , J=l , 101)
b033 FORMAT CSX, ' (MPN) ' flOX, 101A1)
GO 70 14»
160 WRITE UJ,60TJRE(1)=BMAX
PblUREU 1 )=6MIN
PtLR = l)tLR*10.
J = 2
LIU 6052 1 = 1,9
D-2-51
-------�
P 6 TH K1 E ( J ) = P S r (>R E ( I) -0 E L K
AKlfE (NJ,605-1) (PSrHK'E(J) r J = l , 1 t )
6053 FURMAT It3X,11(4X,Fb . 2) , / )
WHITE (MJ, 605-4)
faOb'J FQR-iAT (57X, 'RIVER MILE TU HEAD OF REACH',//)
6055 FURiAT (U9X,'(*) = CALCULATED DATA,
600 C U i-J T I !\l U f
110 HE TURN
END
pous
(X) = MEASURED DATA')
C
C
C
1200.
CUMMON A(500),8(500),C(500),X(500),3(500),Z(500),W(500),G(500)
CuM'iON /RLK1/ ICLUMO(75,20) , CUEFQ V ( 7 5 ) ,EXFOUV(75) ,CdEFNH(75),
A EXPCH-H (75),£^1-1*2(75) ,R CHID (75, 5) , 1^'THUR ( 75) , KMT EOS (75) ,
b C:'lA,MN(7b),CM(7b),CK3(75),K2f"IPT(7b),CK2(75),CL"iEt!K2(75),
C TARi;i><")(75),IAlJGi)R(7b',fe),nCELRH(7S),lFLAi;(75,?0),ALPHAil(75),
0 Ci<'l(7ci),CK5(75),CKi-lH3(75) , CKN02(75) , CMii'iii (75) ,SroH3(75) ,
£ CuLIR(75),ALGI(75),PHUSI(75),CM*3 I(75),CNU2I(75),6 I(75),TI(75),
P HO I (75) , BOO [(75) ,CO.\SI (75) ,ALGSET(75) ,3PHuS(75) ,CK6(75) ,
G EXCOEF(75),«AON 1(75),CNJ3I(75),CKPHL1(75),CKPHL2(75),CKHCN1(75),
H CKHCNd(75),HCwI(75),PHLI(75)
2886.
2887.
2888.
2889.
2890.
2891.
2392.
CUMVU'IN
,WSBUO(90) , WSCGMS ( 90 ) ,
, V-'SCULI (90) , rtSAL'J (90 ) , wSHHOS(90) ,
vMSTIii (90 , 5) , 1 KFACT (90) , i\bFLO>M (90) , .-/SrtAON (90) , v«5PHL (90)-
COM^iO.j /RLK 3/ JL*MC ( 1 5 , 3) , HATR ID ( 1 ^, 5) , H»;FLiin\i ( l 5j , HWTEMP (1 5) ,
A h«00( 15) , HViPHuS I I'j) ,H'-.,MI-I 3 U 5) , H,-.MU2( 1 5) ,H*fvG3( 15) , HwRADf>- (15) ,
D QATUTU5) ,H,'jF(Linu^) , H'/;COMS(15) , VH/i (1 5) , OEPHic ( 1 5) , DLMW ( 1 5) ,
C JiJMCILM 15,5J , i\'H-\iWAiUl5) / H.-JCDL I f 1 5 ) , m\ ALG ( 1 5 ) ,HWHCM15) , HlfJPHL ( 1 5)
CUMMO'V /^LK4/ FLO;-, (50 u) , DEP T u (500 ) , VEL (500 ) , 0 TOVCL ( 500 ) , K 2 (500 ) ,
A Kl (500) ,l)u('.500) ,,SJO(500) ,C 0^3(500) , hSiviE 1 ( 50 0 ) , Dl. (500 ) , T ( 50 0 ) ,
d ALGAE (500) , PHU5 (500) ,CNH3 (500) , CM02 (500) ,CMf.')3 (51)0) , KNH3 (500) ,
C K J02 (bOO) , K'cSPS'tV (500 ) , COL I (500) ,GKliftTH (500) , RAliN (500) ,
u K. X2 , DT2UUX ,
b ArMPK,:-v[uij,CLJUiJ,Sll."
-------�
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
IFU8S.G1.U S(iriK)=6.0
PRINCE = FACT*SHH:JS(I)/11EPTH(IUR)
RtACT = ALPHAS* (RtSPRR ( LllK ) -GWf.lrt TH ( IGrt ) ) *D1LT
IFC PHDSIJ .r;r. o.o ) GO TO 90
B(IOR) = 3(Il)>O - PHf)SIJ*OT'JVCL(IOR)
GO TO 95
SO SUOR) = SUOR) + PHOSIJ*PHOSI(I)*OTGVCL(IOR)
95 SUOR) = SUdR) + REACT*ALGAE(I.UR)+PSORCE
IFL=IFLAGU, J)
MODIFY DIAGONAL ANO/OR' KivlOV'iN TERMS
GO TO (101,100,100,100,100,103,104), IFL
101
103
104
100
?937.
S(IOR) = SUOR) - A(IOH)*riWHHOS(Nriw')
GU TO 100
SllUR) = SUOR)
GO TO 100
rtSFLU'rt(i>JWS)*rtSPHOS(NI«S)*DTDVCL(IOft)
BUUR) = B(IOR) - *J3FLOW(NI','S) *DTOVCL(IOR)
CONTINUE
RETURN
E.MD
PROGRAM QUAL-2
MlUL-2 IS A SET OF I MT LRREL A TED STKF.AM
QUALITY ROUTING MODELS. II HAS THE
CAPABILITY TO ROUTE TEMP ., BUD/00,
NITWOGE*! SEMES, PHOSPHATE, ALAGE,
CULIFORMS, RAuIO ivOCLIDE, AND
UP TO THREE CONSERVATIVE MItvF.RAl.sS
THR.OUGH A FULLY-MIXED STREAK SYSTEM.
THESE PARAMETERS CA<>J BE KOHTEO ON AM
[^DIVIDUAL BASIS OR SIMULTANEOUSLY IN
SUCH A COMBINATION AS THE USER MAY
UtSIRE. UUAL-1 ALSO HAS THE CAPABILITY
TO COMPUTE THE FLOH AURp-ENTATIDN REREO
TD MEET PRESELECTED MIMlMt'M 0(i LEVELS.
HYDRAULICS ARt COMSIDERED ST EwOY -STATE
A( 50 0), B(50 0 ),C(500),X(500), 3(500), ZC500J ,l, (50 u),G (500)
A
b
A
LI
C
COMMON /PLK1/ ICLORD.(75,20) , COEFQ V ( 75) ,EXPOUV175) , CfJEFQH ( 75) ,
EXPOMHC75) ,EXPU!\2(7'5) , RCHID C75 , 5) , RMT HOK (75) , KMTEORC75) ,
CuA.Jfs. (75) ,CK1(75),CK3(7S) , K^l JP T ( 75) , CK2 ( 7 5) , C(.iE»K2 I 75) ,
TARGDu(75J , IAUi;OT>(75,t>) , f-!CELRn(.75),JFLAb(75,? H3I (75),CW02I ( 7 ? ) , 10 II 75 ) , TI ( 75) ,
Dul (75) , B.JI)I(Vb) iSI ( 1 5 ) , ALGSET ( 7b) , SPHUS I 7 5 ) , CK6 (75) ,
EXCOF-F(/5) ,RAl)iMI'C7S) ,Cfl03I (75) ,CKPHL1 (75) , CKPHL2 (7 5 ) ,CXHCM (75) ,
CKHCM2C75) , riC.J I ( 75) , PrtL I ( 7 5)
2915.
2916.
29^7.
2948.
2949.
2950.
2951.
2952.
2953.
2954.
2955.
2956-.
2957.
2958.
2959.
2960.
2961.
2962.
2963.
29M.
2965.
2966.
2967-
2968.
2969.
2971).
2971.
2972.
2973.
2974.
2975.
2976.
2977.
2978.
2979.
2980.
2961.
2982.
29P3.
298 a.
29«5.
2986.
2987-
298'fl.
2989.
(90) ,ix.jf!02(9u) ,i»SNG3l(90,5) ,TRFACT(90) ,'.vSFLU>» ( 90) , ftSKAON (90) ,t';SPHL(90)
/8LK3/ JUWU(15,3) , Hi". TRID U 5, 5) , HftFLOw ( 1 5) ,HwTEl-iP(15) ,
IJATOTU5) ,H,%'HUO(1S) , H.-,CONSU5) , VH,-, ( I 5) , DEPH., ( 1 5) ,I;LH/I(15) ,
JUNG rO(l 5, 5) ,f!H.-.'MR.(15) ,H.iCULKl5J ,Hl^ALG(15) / MV- hCr. (1 5) ,HlA.HHL(15)
2992.
2994.
2996.
2997.
299H.
D-2-53
-------�
c
c
c
c
c
c
CGM-'O.-j /HLK4/ FLOA'(500) ,DF.PTH(5lMl) , VEL (500) ,0 fOVCL (boo) ,K2(500) ,
M M ( SOU) ,Du(5oo) , huO(500 ) , COWS (500) , HbniE 1 (500) , OH 500 ) , T (500) ,
b ALGAE (5dO ), PHuS 1500) ,CNH3 (500) ,Cr--)U2 1500) ,CP 03 I 500) , KNH3 (500) ,
C KJ(>2(500) ,WESPRR(500) ,CULI (500) , GK'U'A T H ( bO 0 ) , K AOivi ( 50 0 ) ,
U KK1 (500) , KK2(-DOO)',HCN(500) ,PHL(bOO)
CUMMUi^ ZfiLKbZ MUOLiPT ( 1 2) ,0 (b) , ALPHA 1 , ALPHA?, ALPHA 3, ALPHAS , CKN,CKP,
b A ri«PK',Kl'.iU,CLOUU , SOi-vET ,nl , !VJ , TRLCU , H-'FOA Y , Ul , NC , Tl,Mh , ivCS, L A I ,
C L3M,LLf',ELEy ,I'A1 , At,Hi£,DAYllFY,nRYflLy , iv£ I 9Ln , DEKPT > PI I>b, T PRINT ,
\j OtLX,lS5,ALPH45,ALPHA6,GKUN!AX,f-i H 2 ( b 0 o ) , K K H 2 ( 5.0 0 )•
C OMMOM / B L K 7 / D A T -I (1 5 , 1 0 0 ) , R MM ( 1 5 , 1 0 0 ) , I X Y Z 1 ( 1 5 ) , I X Y Z 2 (1 5 ) , X THE S ,
*XCKT
CUMMO.M/ dLK8/ ALPHA?, ALPHAS
REAL Kl ,K2,LAT,LLM,LSM, JU'MCID
D i M £ N S IUPJ 0 R U F (5 0 0 , 3 ) , I > C T ( 5 0 0 ) , P. X ( 5 0 0 )
EQUIVALENCE (OKiirU , 1) ,Z(1) ) , (DCTU ) , IFLG(l) )
DATA >MsSIT,IMPACT,TI^C,EPS/I0,0.7,2.ofo.i
3001.
3002.
3004.
3006.
3008.
3009.
3010.
301.1.
3013.
STEP 1-0
INITIALIZE CERTAIN PARAMETERS
01 MEW SI ON ZZZO('40oO),Z7Zl(7575),ZZZ2(lftOO),ZZZ3('<«0),ZZZ/U125i:0).
A ZZZ5(&7),ZZZ6(lilb)
EUUIVAl.EfiCE (ZZZO(l) ,A(1)) , (ZZZ1 (1) , ICLOROd ,])),(ZZZ2 ( 1 ), WSTEMP (
A )) , (ZZZ3(1) , JUf-'CU,!)) , (Z/_Z<4(1) ,FLd.''(l)) , (ZZZ5C1) , MiJDOPT (1) ) ,
B (ZZZfell), ALPHA9)
nj
10 ZZZ
no
i 1 ZZZ
1-U
1
•,)
1
1
1
1? ZZZ2
ML)
13 ZZZ
Du
1 'I ZZZ
no
1
5
I
a
1
15 ZZZ5
Ou
1
16 Z Z Z .->
130
I)
.1
=
(J) =
1
fj
2
(J
3
(J
/I
(J
5
(J
6
(J
J =
)
J
)
J
)
J
)
J
)
J
)
1)5 =
I I' E R =
C
CALL i\'
IF(
I3S
I F ( T S S
c
c
c
=
=
• :
-
-
-
—
-
-
-\,
= 0.
0
0
1 ,
0.
1,
0.
1 F
0.
1,
0.
IF
0.
1,
0.
13
0
4000
0
6825
0
1
0
800
480
0
1
0
2500
67
0
Ib
OATA
.EiO.
.G
r.
0
0
) CALL
) CALL
INDYN(1)
STEP 5-0
ESTABLISH REQUIRED COrgSTAMTS,
900
9o 1
.0
IF (ItiS) 901, 901,
KILT = 1.0/2 -1.0
021. r = i.o
DhLf = if.00.0
GO TO
DILI =
i)E"LT/2-4.0
DbL l=OELT*3bO J .0
3014.
3015.
3016.
3017.
30 IB.
3019.
3020.
3021.
3022,
3023.
13024.
3025.
3026.
3027.
302H.
3029.
3030.
3031.
3032.
3033.
3034.
3035.
3036.
3037.
3033.
30^9.
3040.
3041.
3042.
304.5.
3044.
3045.
3046.
3047.
3048.
3049.
3050.
3051.
3052.
305:5.
3054.
3055.
D-2-54
-------�
C
C
C
C
90? CONTINUE
UlUDX2 = OtLT/ (i)F.LX*DELX)
OT2UDX=2.0*OELT/DELX
TF( MOOUI3T(2). + MOOCJPTU) .£Q. 0
CKL = 221.23*CKL
SONET = 3.6fi72*SO^JET
IF( ISS .EH. 0 ) GO TO 110
IF( SONET .GT. 0.1 ) GO TO 47
STEP 6-0
SET INITIAL CONDITIONS.
) GO TO 110
3057,
3058,
3059,
3060,
3061 ,
3062,
3063,
5064,
3065,
3066,
3067,
C-
C-,
C-
.CfMPUTE AVERAGE SHORTWAVE RADIATION
C-
C-,
c-
XA = 0.0
DO '15 I = I, 25
TOFllAY = 1-1
CALL HEATEX(l)
XA = XA + SONET
CONTINUE
SONET = XA
IF( HOOUPTC4) .EM. 0 ) GO TO 53
..INTEGRATE FOR AVERAGE GROWTH..,
47
NULH = 12
OLH = NOLH
FUNCT = 0.0
vSUAVE=SuNET/OLH
Ou 50 M=1,NOLH
50
51
53
110
r = SUAJ = CKL*FU'MC T/ ( 1 . -FUNCT)
SuAVE = SONET / 24.0
CUMriHUE
c
C
c
c
c
c
99ft
999
997
TF( ISS .EQ. 0 ) GO TO 999
CALL HYDRAO
CALL TRIMAT
GO TO 701
CALL IUOYMC2)
CALL HYURAU
CALL TRIMAT
IFC TIME .GE. D2LT
IF (IXPLT2 .EU. I)
CALL WRPT2
TIME = TIME + D2Lf
T f K I N T =
) GO TO 997
GO TO 997
02LT
C
C
C
C
C
C
C
C
3069.
3070.
3071 .
3072.
3073.
3074.
3075.
3076.
3077.
3078.
3079.
3080.
3081.
3082.
3083.
3084.
3085.
3086.
3087.
3088.
3 0 8 9 .
3090.
3091.
3092.
3093.
3094.
3095.
3096.
STEP 7-1 3097.
CALL SUSPOUTIiSES TO PERFORM HYOR3098.
BALANCE DM SYSTEM AMD ESTABLISH 3099.
•COF.FFICIEfMT MATRIX. 3100.
3101.
3102.
3103.
3104.
3105.
3103.
310*}.
3109.
3107.
3110.
3111 .
3112.
3113.
STEP 7-2 311'l.
ROUTE SELECTED QUALITY PARAMETEH3115 .
3116.
MUIUiPT(l) CONSERVATIVE 3117.
MUDOPT(2) TEMPERATURE 3118.
MUDUPI(3) BUD 3119.
(4) CHLOROPHYLL A 3120.
D-2-55
-------�
c
c
c
c
c
c
c
c
MUOOPTC5)
M'lHiPT (6)
I*-'! >ni IP r (?)
MubLPTU.)
MOOUPT(9)
MOUOPF CIO)
ni)
PHOSPHOROUS
NH3,N02,M03
I) XV GEN
RADIOACTIVE
HYDROGEN CYAMOE
PhEtMOL
701 IF (MUDOPTCl) .E«. 0) GO TO 702
CALL CO."JSVT
CALL 3UVMAT
Du S06 I=l,rtCELLS
CUNSCI)=ZCI)
8U8 CU!\'TlPai£
702 IF CMOOOPTC2) .Eu'.O) GO TO 703
IF( 1SS .E.O. 0 J GO TO 399
C-
C-
C-
C-
C-
C-
.PERFORM STEADY-STATE TEMPERATURE CALCULATION,
00 310 1 = 1, iMCELLS
TCIJ = mJTEMP(l)
OUT (i) = o.o
310 CONTINUE
.BEGIN ITERATION FOR STEADY TEMPERATURE,
SONET = SOAVE
NUM = NCELLS - 1
DO 395 "I = 1 , i'JSSI T
IFC M .GT. 1 ) CALL THIMAT
CALL HEATEXC2)
CALL TF>IPS
CALL SUVMAT
DO .355 1 = 1, IMCELLS
CONTINUE
C-
C- COMPUTE CURRENT RESIDUALS....
C-
CALL HEATEXC2)
CALL TEMPS
DO 360 1=2, NUM
R X(I) = A( I)* T C 1 -1) + B(I)*T(I)
360 CONTINUE
R * C1) = fl C1)* T(1 ) > C(1)* F(2) - SCI)
RxCvlCELLS) = A(MCELLS) * f (NCELLS-l )
1 - S(NCF.LLS)
C-
C- COMPUTE THE DERIVATIVES
C-
A Cl) = 0.0
CCNCELLS) = 0.0
DO :JKO 1 = 1, NCELLS
XA = i.o
IFC OCTII) .LT. 0.0 ) XA = -1.0
DCT(I) = XA * TIMC
DO 370 J = 1, 3
K = I + J - 2
IFC K .LF.. 0 ) GO TO 370
TCK) = TCK) + DCTCK)
R = ACI)*T(I-1) > BCT)*TCI) -t- C(I)*TtI + l) - SCI)
DKUT(I,J) = ( R - RX(I) ) / DCTCK)
TCK)=T(K)-DCT(K)
370 CONTINUE
3bO CONTINUE
C(I)*T(I+1) - SCI)
B C.'JCELLS ) * T (N'CELLS)
3121.
3123.'
3125.'
3126.
3129.
3130.
3131.
3133.
3135.
3136.
3137.
3133.
3139.
3140.
3141.
3142.
3143.
3144.
3145.
3146.
3147.
3148,
3149.
3150.
3151.
3152.
3153.
3154.
3155.
3156.
3157..
315».
3159.
3160.
3161.
3162.
3163.
3164.
3165.
3166.
3167.
3168.
3169.
3170.
3171.
3172.
3173.
317 '-I.
3175.
3176.
3177.
3178.
3179.
3180.
3181.
3182.
3163.
3184.
3185.
3186.
D-2-56
-------�
c-
c..
c-
VALUES PITO SOLUTION VFCTMKS,
355
00 385 1=1, NCELLS
All) = IJROT(I,l)
eil) = ORDT(I,2J
cm = oRDTu-,3)
SU) •= -RX(I)
CONTINUE
AID = o.o
ClflCELLS) = 0.0
CALL SUVMAT
C-
\f <
c-
.MAKE CORRECTIONS AND CHECK CONVERGENCE.
NUX = o
00 390 1=1, MCELLS
DCTCT) = Z(I)
Til) = HI) + DCTU) *
IF( ABS( DCT(I) ) .GT.
3VO
395
6067
397
399
703
802
710
809
711
810
RFACT
EPS )
NUX = NUX
300
IF( NUX .ED. o ) en TO 397
CONTINUE
WRITt. UvJ,6067)
FuRHATC IH1 // 10X, 1 1 H***6RROR*** //10X, 71H***STtAOY STATE
EHArUKfl NOT CUNVEKGtO... CHECK INPUTS AND RESULTS*** )
CALL TkiMAT
GO TO 703
COi'JTIi\!UE
CALL rtEATEXdJ
CALL' THMPS -
CALL snvMAT
nu 800 I = l,i>JCELLS
. 0 ) GO TO 710
IF( MUDUPTC3) .EfJ
CALL doos
CALL SUVMAT
DLJ (JO? 1 = 1, MCELLS
BuDlI)=Z(I)
CUNTIMUE
IF (HuOuPT(lO) .EQ. 0) GO TO 711
CALL HCNS
CALL SOVHAT
l)U rt«9 1 = 1, NCEI.LS
HL!\itI)=Z(I)
CONTINUE
IF (MOOOPT(ll) .EQ. 0) GO TO 705
CALL PHLS
CALL SOVMAT
UO 810 1 = 1,I'4CELLS
PhL(I)=Z(I)
3188.
3190.
3191.
3192.
3193.
3194.
3195.
3196.
3197.
3198.
3199;
3200.
3201.
3202.
3203.
3204.
3205.
3206.
3207.
3208.
3209.
32-10.
TEMP32H.
3212.
3213.
3214.
3215.
3216.
3217.
3218.
3219.
3220.
3221.
3222.
3224.
3225.
3226.
3227.
3223.
IF (MUDUP1 (5) .EJ.O) GO TO 706
CALL PO'lS
CALL SI1VMAT
DO 805 I = l,i\CELLS
PtiflSd) = Z(I)
705
«05
706 IF (MOUiJPMfa) .E.J.p). GfJ TO 827
3229.
3230.
3231.
3232.
3233.
3234.
3235.
3236.
3237.
3238.
D-2-57
-------�
1806
606
CALL i>jn2s
CALL SOVMAT
DO Ibufi, I=1,NCELLS
c.\H2(i) = zcn
CU'MTIMUt
CALL N'H3S
CALL SOVMAT
DO 3 ft 6 1 = 1, iMCELLS
826
«27
80 a
7u7
H03
7U8
807
799
815
C
C
C
C
C
CLiK fliMUE
CALL
CALL
DO H16 l = l,AlCELLS
c,M02Ci) = zm
CL'iMri.MUE
CALL i\<03S
CALL sov 1-1 AT
Du 426 I = l,,'vCELLS
C;«03CD = ZCI)
CONTINUE
Cu^TI'^UE
IFC MOL>UPT C4) .EQ. 0 J GO TO 707
IFC ISS .GT. 0 ) "SUNET = SOMNEN
IFC SONET .LT. O.y ) SOi\ET = 0.0
CALL ALGAES
CALL SOVMAT
DU i)04 1 = 1, 'MCELLS
ALGAECI) = ZC1)
CONTINUE
IF CMUDUPTC7.) .E'0.0) GO TO 708
CALL rthAFRC
CALL DOS
CALL SOVMAT
DO 60.3 1 = 1,.MCELLS
DOC l)=ZCI)
CUN riNUE
IF CMLiDuPTC*}) .EiJ.O) GO TO 799
CALL COLIS
CALL suv^'AT
Ou 307 1 = 1,.\CELLS
CUL1 CD = ZCI)
CONTINUE
IFC MODOPTC9) .EQ. 0 ) GO TO 315
CALL KAUIOS
CALL SOVMAT
Du 413 I = 1, IMC ELLS
RAU'-ICI) = ZCI)
CON I
STEP 7-3-
IF STEADY-STATE ClirJOITION
KEACHcD, COMK4UE KUUflNG
IFC I S3 .EU. 0 ) GO TO
IFC MODuPFU) .EQ. 0 )
NUN' = 0
I IE* = ITbR + 1
DU 999/1 JJ = 1, BREACH
9996
GO TO
1001
Oil
I = ICLUWIJ(J.J,KK)
595.
596.
597,
596.
3239.
3240.
3213.
32^15.
3246.
3247.
3248.
3249.
3250.
3251.
3252.
3253.
3254.
3255.
3256.
3257.
3253.
3259.
3260.
3261.
3262.
3263.
3264,
3265.
3266.
3267.
3268.
3269.
3270.
3271.
3272.
3273.
3274.
3275.
3276.
3277.
3278.
3279.
3280.
•3211.
3282.
32*3.
32H4.
= EXP(-EXCOEK(JJ)*|)EPTH(I))
+ SlJUNF:-J*tXPT)
HAS N03286.
32B7.
3289,
3289.
3290.
3291..
3292.
3293.
3294.
3295.
3296.
3297.
3298.
3299.
D-2-58
-------�
LUG/ (EXCOEF(JJ)*i»EFltU [))
XUkOsvsXGRUtt* l.O'47**TC
Tt = i)ELX/(VEL(n*«6400.)
TGRUW = XGROW
IF (MOOOPT(5) .E.i.3.0) GO TO 9ti20
DbDP = -1.0/(ALPHrt2*ALGAE(I)*rT)
XA = UGOP
Xt> = 'GROWTH (I ) + CCKP + PHOS(l) )*OGUP-XGROW
XC = GRUWlH(IJ*(CKPtPHOS(I)J-XGROw*PHOS(I)
RUOF = 3URT lXd*X6-4 ,0*XA*XC)
OPHDS = -0.5*XH/XA •»• 0.5*ROOT/A8S(XA)
PhOSCI) = PrlUS(I)+l3P.HUS
IF (PHOS(I).LT.O.U) PHOSU) = 0.0
9820 IF (MUDQPT(b).EU.U) GO TO 9.S40
PGDN = -1.0/ULPHA1*ALGAE(.1)*.TT)
XA = DGON
XC = GRUKTHH) * lCrt.N-t-Ci\i03(I) ) -XGKOrt*CNl>3 ( I )
ROOT = SnRT(XB*XB-4.0*XA*XC)
5 = -0.5*XB/XA > 0.5*HOOT/A3S(-XA)
) = C:4ll.5(I) + DCN03
IF CCN03CI) .LT.0.0) ClM03(l) = 0.0
TGRUW = TGROvJ*CNU3(I)/(CKNi-CN03(r))
9840 CONTINUE
Db = TGROiN - GROWTH(I)
"6994
9994
450
9995
7760
9996
451
99V7
1001
452
[F (AdS(UG).Lf
MUM = NUM + i
G*0*TH(I) = GR
CU-^'f IN ME
TF( ITER .LE.
CALL •*> R P T 2
WRITE C^J / 7700)
STOP
CONTINUE
.0.05) GO TO 8994
O.'vTHC
I) + 0.7*OG
15 )GO TO 9995
I'JOM
FORMAT (30H GROWTH
IF( MUNi ,GT. 0
GO TO 1001
If-C TPRIP1T .LT
TF (IXPLT2 .EfJ
CALL A'RPT2
IFC IRPT1 .ED.
TPRI^T = 0.0
IFC TIME .LT.
CALL INOYNOt)
Gu fU 9999
CUfx TIN HE
TF CIXPLT2 .EQ
CALL t\'F
-------�
A(bOO),LU500),C(500),X(5oOj,S(!300),Z(500),w(500),G(5(iO)
3363.
CUM-KJN /HLK1/ ICL-J^O ( 7 b , 20 ) , CUfc'.F fJ V ( 7 5 ) , EXPDIJ V ( 7 5 ) , CutKCJH (75 j ,
$36.5.
3366.
c
c
c
c
c
c
336a.
3370.
EXPU021 (75), UI(7b), 71(75),
f OOI(75),bODi(7?)),COr;81(7'5),ALGSET(75),.SPHOSl75),CKfbl75),
G EXCOF.F (75) ,*AuM (75) /CNU31 C/b) ,CKHHL1 (75.) ,C*PhL2(75) ,CKHCN1 (75) ,
H CKMCr-i2(75) ,HC,'JI(75),PHLI (75)
3373.
CUMMOiM /BLK2/ VvS7EMP(90) , A-SOO(90) ,wSBUO(90) ,hSCUNS(90) ,WSHCN(90) ,
A WSNH3(90) ,/*SM02(90) ,WSW03(90) , WSCOL I ( 90 ) , VJS A L G ( 9 0 ) ,,vSPHOS(9o) , 3375.
b WASTIU(yO,5) , lf(lb') , HWCUNS(15) , VHA ( 1 5 ) , U.fc PHw ( 1 5) , OLH'rtCtS) ,
C JUMCID(15,5),wH'..rtAR(15) , H/.COL I (1 5 ) ,HhALG(15) ,HwhCK-(15) , HhhHL ( 1 5)
3382.
CUMMUN /HLKa/ FLni(bO()),OEPTH(500),VEL(50u),D70VCL(500),K2(500),
A M (bOo) ,0(1(500) , BOD (500) , CONS (500) , HSiviE I (50u) ,OL (500) ,7(500) ,
b ALGAE (500) , PH(..iS(5uO) , CMH3 ( 500 ) , CN02 ( 500 ) , CNU3 (500 ) , KWH3 I 500 ) ,
C KN02(}00) ,RESPRw(500),CCiLI(500),GRO«7ri(500),RADN(500),
0 KK1 (500) ,KK2(t)Ou) ,HCN (500) , PHL (500)
3383.
3385.
IMNilji1-! /HLK5/ ''ilOuPT ( 12) ,0(5) , ALPHA1 , ALPHA2, ALPHA3, ALPHA4, CKM,CKP,
CKL,f!Hi'.iTRS,NWtACH,rJrtAS7E,^JUNC,OEL7,l)lL7,L'2L7,OU')PX2,07200X,
A 7^;PR, nl NO, CLOUD, SOME 7 , NI , h J., 7PLCO , 7 GFO A Y , I'J 7 , NC , 7 I ME , i\iCS , L A 7 ,
LSM,LLM,F.LEv,ijA f , A K, HE, DA YOFY , Oi^YBLB, ^fc'THLb ,OE^P7 ,P7It-',E , 7PRIN7,
OELX, ISS.ALPHA5, ALPH A6 , GRUiv A X , kESPK 7 ,HCELLS, ILIS7, IRP71 , IAUGOP,
7MAX,1HOD5,JSUM,IXPL72,CKH7P,CKP7P
INITIALIZE COUNTERS
LUUP 7HROUGH REACHES AND COMP. ELEMF.NTS
3367.
3389.
3390.
3391.
3392.
3394.
3395.
3396.
3397.
339H.
3399.
3400.
DU 100 1=1, BREACH
IJ = «I(n/CN'CELR
00 100 J = l,NCELt<
= ICL()RO(I, J)
RtACT=01LT*CK6(I)
IWillALIZF DIAGONAL AtgO KNOwN TERMS
S( IOR)=xAONC
If- (ISS.fc.T.0) S(IOf<)=0.0
[F( KAiinU .GF. 0.0 ) GO 70 90
81IOR) = H(IOR) - KAONIJ*070VCL(IOfl)
GU 70 95
S-0 S(IOR) = S(10R) + «A[>NIJ*KA[)t-JI(T)*D7UVCL(10K)
95 IFL = IFLAG(T,JJ
ilUOIFY OIAGU.MAL ANO/OK KNOWN 7ERMS
GO TO (101,100,10^,100,100,10.3,104), IFL
S UilR) =3 ( IOK) -A ( IUR) *rt'/vRAON (MHU)
3402.
3403.
3404.
3405.
3406.
3407.
3408.
3409.
3410.
3411.
3412.
3413.
3414.
3415.
341 h,
3417.
3418.
3419.
3420.
3421.
3422.
3423.
34?4.
3425.
3426.
D-2-60
-------�
c
c
c
c
c
c
c
c
c
C
C
C
C
C
C
103
GO Til loO
SUOtf )=3(IOR)+WSFLOs';(NHS) *»SRADN
GO ru iuo
*0 FLWCL ( 10k)
101
fUrjK-)=ri(If)R)-fcSFLO»(75,5) ,KS• I ( 75) , TI (75) ,
F n:jl (75) ,dUDI (75) ,Cf.lNSl (7S) , ALGStT (.75) ,SPhl.)S(75) ,f:Kh(75) ,
G EXCUFF(75),RADNI(75),CNU31(75),CKPHL1(7b),CKPhL^(75),CKhCN1(7b),
H CKHCrJ2(75) ,HC;JI (75) ,PHLI (75)
3130.
3131 .
3432.
3133.
3131.
3135.
313f>.
3137.
3136.
3139..
3110.
3111.
3112.
3113.
3111.
3115.
3116.
3117-
3118.
3119.
3150.
3151.
3152.
3153.
3151.
3155.
(90) , t\StiCK (90 )
«Si'iH3('JO) , KSMJ2190) ,v^SMU3(90) ,'/vSCuLI (90) , *SALG (90 ) , I'.SPHOS (90 ) ,
rtASI IiH90,5) ,TRF«C l'(90) , rtSFLUA (90 ) , -ASK ADr« ( 90 ) , hSPhL ( 90 )
A
b
COMMON /6LK3/ JO:\'C( 15,3) ,HWTK10(15,5) , HsvFLIn': ( 1 5 ) , Hi'.-TEMP (J 5) ,
A H»vf)0(15) , nrtPHOS(15) , HWNH3( 15) , HrtMI)2( 15) ,hwM03(15) , H-.'vfVAON (1 5) ,
D I.JATOT (15) ,HrtHuri( ]'j) , Hl\CO(iS(15) , VHw( 15) , DEPHi" (1 5) ,DLhW(. 15) ,
L JIJMCIL»(15,5) , .yH»vw/\!<(1 5) .H.vCOLI ( 1 5) , HftALG ( 1 5) , Hl-.HCiJ ( 1 5) ,HWPHL(15)
COM.-10M /IM.K1/ FLO.V (500 ), DEPTH (500) ,VEL(50U) ,OTOVCL( 500) ,K2 (500) ,
M Kl (•DOO) ,1)0(500) ,900(500) ,CO>\'S(500) ,HS,-iET (500) ,UL (SOO) ,T(500) ,
b ALGAE (500 ) ,PHUS (500) ,CI\:h3 (500) , CM',? (500) ,CWd3(500) , KNH3 (500) ,
C K-j()2(tii>(» , RESPRIv(500) , COLT (500),GHO«TH(500)»RADN(500)/
D KK1 (500) ,KK2 f.bOl)) , HCN (500) ,PHL (500)
3158.
3160.
3162.
3163.
3161.
3167.
3168.
3170.
A
B
C
L)
t
jMHOtvl /HLK5/ l'.uDuPT(12),0(5) ,ALPHA1 , ALPHA 2 , ALPh A 3 , ALPHA1, CKN , CK P ,
C , NT , fJC , T 1 ME , [.-C S , L A T ,
L3i-i,LLf, ELEv , OA 1 , <\E , 1>E, MA Ynf: V , Oh YtiLb , V'ETBLb ,Df»';PT, PT ] i"fc , TPR J.MT,
DELX,1SS,ALPHA5, ALPHAS,GWjW AX, RESHKT,KCtLLS,ILlbT,I(xPT U1AOGOP,
T-iAX, lhOI)5, JSU'1, T XPLT2,CKHTP,CKPTP
3172.
3171.
3175.
3176.
3177.
3179.
RtAL K2
STEP 1-0
LOOP IHH11UGH SYSTEM OF BREACH
ANiO NCELR Ct'MPUTAl IOMAL ELEMEi
REACH.
00 lOtt 1=1,BREACH
31flO.
3181.
31H,?.
R£31«3.
TS3l81 .
31«5.
3186.
31K7.
31H8.
D-2-61
-------�
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
KUPr=K2uPT(I)
PCTR - 1.00
IK KOPT .GT. 1 .AND. CK2(I) .GT. l.OE-6 ) PCTR = CK2U)
OU 103 J=1,NC£LR
IUR=ICLORO(I, J)
T h L = I F L A G ( I , J )
STEP 1-1
SELECT K2'S FOR Ai\Y OPTION AS
6Y REACH.
KOPT •= 1 K2 IS READ I M .
KOPf = 2 CHURCHILL (1965)
KOPT = 3 O'CONIvER - OOtiBINS
3409.
"^UQil
•J ™ 7 \J •
3491.
3492 ,
3493.
3494.
3495.
3496.
UE3497.
3498.
3499.
3500.
3501.
3502.
(193503.
KUPT = 4 LIKENS, tin'sAKDS, - GlBb3504.
KOP1 = 5 THACKSTC.N - KREi\KEL
KOPT = b LANGBlEh - DUKOM (1
KUHT = 7 K2=A*Q**B
GO TO (101,102,103,104,105,106,107), KOPT
101 K2(1GK)=CK2(I)
GO TO 100
U2 K2(IOK)=5.026*VtL(lOR)**0.9b9/OEPrH(lOR)**1.673*2.31
GO f!) 100
103 DM=2.25t-o8
K^(iUK)=J)U«r(uri*VtLllOR))/l)ti-lIH(10K)**1.5*fc.64E+-04
Gu TO 100
1 04 K2(IOR)=9.4*veL(I:jR)**0.67/DEPTn(IOR)**l.e5*2.3l
GO ro 100
105 F = 0.176*VELUOR)/SURT(DEPTH(IOR) )
SliRVtL = 5.b75*Vi:L ( I OR) *Cr'Ai\w ( I ) / ( 1 ,49*()EPTH ( IOR) ** 1 . 1 67)
K d ( 1 0 K ) = 1 0 . H * (1 ,0 + SUR T (1- ) ) *SHRVEL*2.31
GU TO 100
Ub K2 ( IOR) =3. 3* VELUi.iR) /DEPTH (IOR)** 1.333*2.31
GO ro 100
1 07 K2(IftW)=COEaK2f 11 *FLO'/; ( I OR ) * *EXFQK2 ( 1 )
U" Ke!(If)K) = K2(IOR) * PCTR
CON F IiviUt
IFIALPHAR .£(J. 0 ) GO TO 108
IF (i)F.HTH(IOR) .L! .5.0) GO TO 108
A 2M I i-i = 2 .(i/ DEPTH ( TOR)
IF U2( TOW) .GT.A2NIi\l) GO TO 108
K2 ( IOR) =A2MIM
IdM CGNTIMJE
RETURN
EivU
SuRRfujT IhE SOVMAT
SOVMAT SOLVES A SYSTEM OF S 1'MUH AlvitDUS
LIMEAK t!.iiJATIf.^S '/"HOSE COEFFICIENT
MATRIX IS OF TR1DI AGONAL FORM USIi^G
A '•/|L)OIFIEU UAOSSIAN EL I Hi N A T 1 UN TYPE OF
ALGORITHM.
C iM --itJ.vi A ( 5 0 0 ) , !H 5 (i 0 ) , C ( b 0 0 ) , X ( 5 0 0 ) , S ( 5 0 0 ) , 2 ( 5 0 0 ) , In ( 5 0 0 ) , G ( 5 0 0 )
COM UJi\i /KLK1/ ICLuRO(75,20) , -COEKlJ V ( 7 5 ) , E XPOU V ( 75 ) , CUEF QH ( 7 5 ) ,
A En.l3(7b) ,SKH3 (75) ,
b CiJLlR(75) , ALG 1 (75) ,PHUS1 (75) ,Cr.'M3J ( /S) ,Cf"021 (75) ,CJI (75) ,T1 (75
(13505.
9673506.
3507,
3508.
3509.
3510.
3511.
3512.
3513.
3514.
3515.
35)6.
3517.
3518.
3519.
3520.
3521.
3522.
3523.
3524.
3525.
3526.
3527.
3528.
3529.
3530.
3531.
3532.
3533.
3534.
3535.
3536.
3537.
3530.
3539.
3540.
3541.
3542.
3543.
3544.
3545.
3546.
), .3547.
D-2-62
-------�
c
c
c
c
c
c
.c
c
c
c
c
c
c
c
c
c
c
c
c
c
F
K
H
EXCUF.F(75)
(.75)
,CMU31 (75) ,CKHHL1 (7b) , Ch PiiL2 (75) , CKHCfJ 1 ( 7b) ,
PHLH75)
CUM.-10.M /HLK2/ KSTtMP (90),.rt 300(90) , rtSiH.ib (90 ) , .nS.CliNS I SO) , v^bhCN (90 )
A WSNH3(9U) ,W5M02(90) , wSNiJ3 ( 90 ) ,fc'SCOl.I (90) ,v'iSALG (90) ,'.'.SPHOS (90 ) ,
'& rtASTIO(90,5-) , PRFACT(90) , rtSFLOA ( 90) , ftSRADN (90 ) ,wSPHL(90)
CUMMOw /BLK5/ JUNG (1 5 , 3) , hwT R I I) (1 5 , 5) , H'.',FLOv: ( 15) , hV;T EMP ( 1 5) ,
A H-viHH 15) ,rirtPHOS(-15) , H',vMH3(15) ,HKMQ2U5) , HwiMt.i3( 1 5) , H.\RAOM (15) ,
H UATI3T (15) ,H.','BUO(15) , HhCOwS ( 1 5) , VHi'.' ( 1 5) , UF.PHU-. (1 5 ) ,l>LhW(15) ,
C JUUCIL)(15,5) ,fMHf,WAlU15) ,H;,COLI (15) ,Hl".ALG(15) ,HKhCN(15) ,HhPHL(15)
3550.
3552.
3554.
3555.
3556.
3559.
CufMON /BLK4/ FLO,N(500) ,OEPrH(50d) , VEL(500) ,010VCL(500) ,K2.(500)
A Kl(500),0ij(50o) ,BulH500) , CONS (500 ), HS.'^ET ( 500 ), DL ( 50u ), T (500) ,
B ALGAE(500),PHUS(500),CNH3(500),CN02(500),CN03(500),KMH3(500) ,
C KfJ02( 500) , Ht-SPWR (500) ,COL1 (500) , GKIMTH (500) , WADN (500) ,
U KKl(5uO),KK2(500),HCH(5oO)
3562.
3564
COMMON /RLK5/ NH.IOOPT (12),0(5),ALPhAl,ALPHA2,ALPHAS,ALPHAS,CK1M,CKP,
A CKL,Mri^i fRS, .\ikfc ACH,Nv*ASTc,NJ U(-JC,L'ELT, OIL \ , 021. T , D TI1UX2 , DT200X ,
b ATMPR ,,-.- i !MO , CLOL1U , -Si I.ME T , •'•! I , W,J, f KLC 0 , 10F U A Y , fc T , NC , T I ME , iMCS , L A T ,
C Lb^,t.Li-1,FLf V,UA r , At,Ht ,I)AYOF Y,nKYijLH, wE fHLP,nr^PT,P TIMF, TPRJMT ,
U OELX,ISS,ALPHA5,ALPHAb,GWOMA X,KESPM,NCELLS, (LIST,IRPI1,IAUGOP,
t TMAX,IB005,JSuM,lXPLT2,CKHTP,CKPrH
CrMh2lT(75),CfMH2i(75) ,HwNU2(15),
3567.
3568.
3569.
3571.
/BLK6/ ALPHA9,CKWH2(75),
AWSNH2(75),CMH2(bOO),KNH2(500)
DIMENSION IFLCH500)
1JUNC=0
STEP 1-0
IfMlTIALIZE
COUNTER FOR STREAM
STEP
LUOP
WITH iMCELR
REACH.
2-0
THROURH SYSTEM OF MREACH
COMPUTATIONAL
DO 100 1=1,BREACH
NCELl<=ivCELI»H( i)
DO 100 .1 = 1
FFL=IFLAG(I,J)
If-LG(IOK)=IFL
Go TO (101,102,102,103,102,102,102),
IFL
STEP 2-1
OPERATE ON
TYPE 1.
EQUATTUN FOR
101
G(10N)=iJ(ICR)/8(IOR)
GU TO 100
STEP 2-2
OPF.KATE C
2,3,5,6,
I to EUUA'flGfJ
OK 7.
FOR
102
OLNOM = P ( IOK) -A (If IK) *>M ( IOtf-1 )
W(lL)R)=C(IDK)/OtNi3M
G 11 OR ) = ( S ( I OR ) - A (IOK1) *G (I OR- 1 ) ) /DEfJUM
GO FO 100
3572.
3573.
3574.
JU3575.
3576.
3577-
3578.
3579.
RE35HO.
ELEMENT3581.
3582.
3583.
3584.
3585.
3566.
3587.
3588.
3569.
3590.
3591.
3592.
AN ELEME3593.
359U.
3595.
3596.
3597.
3598.
3599.
3600.
ELF.MEr:Tb3601.
36.02.
3603.
3604.
3605.
3606.
3607.
3600.
D-2-63
-------�
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
U>7
STEP 2-3
OPERATE ON
T7PE 4.
= IJH;MCtl
NS=1
MN = JIJMC (I JUMC, NS)
SlU HO = SHOW) - IK T JONG) * G(HN)
n£NQM=H (Il)f<) -A ( I OK) */UIOK-l ) -U (1 JUNG)
IOrO*G(IOR-l) )/DENUM
(NN)
100 CONTINUE
STEP 3-0
SOLVE SYSTEM OF BREACH
EQUATIONS USING HACK
Z(IHK)=G(IOR)
109 IUR=IOR-1
IFL=IFLG(IOR)
GO TO (106,106,107,106,106,106,106), IFL
STEP 3-1
SOLVE THE EQUATION
1,2,4,5,6, OR 7.
1 06
GU CO 108
STEP 3-2
SOLVE THE
TYPE 3.
3609.
fcHUATIUN FOR AK E.l.tMt3610.
361 1 .
3612.
3614.
3614.
3615.
3616.
3617.
3618.
3619.
3620.
3621.
3622.
NCELR 3623.
103624.
3625.
3626.
3627.
3628.
3629.
3630.
3631.
3632.
3633.
3634.
3635.
3636.
3637.
3638.
BY
FOR ELEMENTS
EQUATION FOR
AN ELEMEN3639.
3641.
NS=1
DO 9
IF
9 a IJ = 1 , 'JJUNC
ClHR.E'.J.'Jll,vClIJ,.MS))
r
r (ijU'\c , IMS)
cow r
IF (IOW.NE
l) GU TO 109
STEP 4-0
IF DESIRED,
fllUTTE
WlTHt.vl THE SYSTEM
3643.
3644.
3645.
3646.
3647-
364H.
3649.
3650.
3651.
3652.
KEPURI'2 WHICH 3653.
OF CUM) I 3654.
AT ANY GIVEN T3655.
3656.
365/.
3650.
3659.
3660.
3661.
3662.
3663.
/(ILK I/ ICLijRO(75,20) ,CGEFQV(75) , EXPOOV(75) , COEFCOH ( 75 ) , 3664.
(75),KMi£Uk(75), 3665.
C1A Jl,'(75). ,CM (75) ,CKl3(75) , K2.UPT (75),CK2(75) , CUEGK2 (75) ,
1 A K GOu (75) , IAUC,UR(75,6) , NCELKH ( 7 5) , I FL AG ( 7 5 , 20 ) , AL.PH AO ( 7 5 ) ,
COLIR(75) ,ALT,i (75) , PHOSI ( 7 5 ) , CM:13 I (7 5) , CN02 I ( 7 5 ) , U I ( 75 ) , T 1 (7 5 ) ,
001 (75) ,'10DI(75) ,COMSI (75) ,ALGStT(7b) ,SPHuS(75) ,CKb(75) ,
EXCOKK( 7'5) , KAu.NI (75) , CH031 (75) ,CKPHL1 (7b) ,CKPHL2( 75) , CKhCNl (75)
C*hC'-;2(75) , HC Jl (75) , PHLI (75)
CONTINUE
RE TOWN
END
SiJHRUUTIHE
COH:-il).N A
TE.-IHS
,H(500) ,C(500) , X (500) ,S(500) ,Z C500) ,ir. 1500) ,GC5.00)
3666.
3667.
3668.
3669.
CUf-HUM /KLK2/ nb TtMH (90) , /:S'Hlf go) , WSHIJO (<*0) ,
3672.
(^0) ,
s(SO) ,
D-2-64
-------�
C
C
C
C
C
C
C
C
C
A H.'ji>lrl.U90) ,WSif02(90) , wSMf.)3 (90) ,'/,SCUI.l ( 90 )., \iS ALG ( 90) ,
l> WAST ID (SO, 5) ,TK(= ACT (9U) , KSFLH.v ( 90) , '/.SkAOw ( 90 ) , IvSPhL 190)
(90)
COMMON /ULK3/ JU\'CC15, 3) ,HftTRIl)U5,5) ,llwFLUir.-( 15) ,HmTEKPC15) ,
A H il)(j (15) , nv.PHi.jSU5) , H.M'I1H3( 15) , HM'MJ2 ( 1 5 ) , H',vrv03( 1 5) , H'\K A[)N ( 1 5) ,
b fUTUI (15) , Hrt!!.JO(15) , HrtCONS ( 1 5) , VHw ( 1 5) , OEPHv. ( 1 5) , bLH*. ( 1 5) ,
C JUf.'ClU(15,5) , >MH«.N4K(15) ,HwCOLI(15) ,Hl?iALG(15) ,HhHCN(15) , HwPHl. (15)
3fa7(S.
3677.
3b7d.
COMMON /RLK4/ FLOvv (SOU ) , DF.P f H (500 ) , VEL ( SOU ) , DTOVCL ( bOO ) , K 2 (500) ,
A' Kl (50u) ,00(500) , BUh ( 500 J , CUl'iS (5uO ) , hSME T (500) , DL (500 ) , T (500) ,
ti ALGAE(500) ,HHuS(500) ,CfiM3(500) ,CMU2(500) ,Cf-jU3l500) ,KNM3(500) ,
C K ^02 (500) ,f?ESPKt<(50o) ,COLt (500) , GRUw TH ( 500) , RADK' (500 ) ,
0 KK1(500),KK2(50(I),HCN(500) ,PHL(500)
3661.
3682.
3664.
CDI-NUN /HLK5/ HODUPT ( 12) »0(5) ,ALPHA1, 4LPHA2 , ALPHA 3 , ALPHA/I, CKN , CK P ,
A CKL,l-iHi'.TRS,hJKtACH,rirtASTt.,:gJ.UNC,UELr,DlLT,02LT,D1(JDX2/DT200X,
\!> A f MPfv , I'j 1NU , CLUUU , Sf)(V;F. T , NI, N J , T RLCU , THFD A Y , NT / MC , T I ML , NCS , LA f ,
C LSKi,LLM,ELEV,UA f , AE , i3E , U A YOF Y , OK YULB , V.E T BLb , l)£ftP T , P T IN£ , T PRINT ,
L) OELX, I S.S, ALPHAS, ALPHAfa,GROM'AX,RESPRT,NCELLS,ILISTr IkPT I , I AIJUOP ,
t TMAX,IHUOS,JSUM,[XPLT2,CKHTP,CKPTP
103
INITIALIZE COUNTERS
NHW=0
IJUiMC = 0
ftrtOCP=62.l, 102,
••Uj!)(FY DIAGONAL AND/OR Kf;Of.N TERMS
,2, 104, 102, 103,105), "1FL
GO TO 100
GO ro 100
3686.
3688.
3689.
3690.
3691.
3693.
3694.
3695.
3696.
3697.
3698.
3699.
3700.
3701.
3702.
3703.
3704.
3705.
3706.
3707.
3708.
3709.
3710.
3711.
3712.
3713.
3714.
3715.
3716.
3717.
3718.
3719.
3720.
3/21.
37?2.
3723.
3724.
3725.
3726.
3727.
3728.
3729.
3730.
3.731.
3732.
3733.
3734.
3735.
3736.
3737.
3738.
D-2-55
-------�
3739,
c
c
c
c
c
c
c
c
S(IOK) = 3
GO ro 100
TJU
REACT + WSFLIJ^(|MWS)*WS7E-KP(NA'S)*UTIWCL(IUIO
3741.
3742.
3743.
i = 0.25*(i)FPTH(IOK-l)+OEPTH(NN)+2.0*DEPTH(jrjR))
N'ET (IGR) / l'?HUCP*AOEPTH)
'S(IOR) = S(IUrt) + REACT
GU ro 100
= 0.5*(l>£PTH(IOR-l )+OEPTH(IOR) )
Rt ACTsHSuET (HJR) / (KHIJCP* AOEPTH)
S(IUR) = S(IOR) + REACT
FJ(IijR)=d(IOiO-rt3FLO/Ki;EKSiriMA|_ (AUVECTIONt +
OISPEKSIOM) 1KAMSPUKT EQUATION.
CUM-iLiN A (500) , b C500) , C (500) , X(5UO) ,5(500) ,Z (500) , /-• (^00) ,6(500)
COM'iUN /BLM/ ICLURO(75,20) ,COEFOV(75J ,EXPOOV(75),COEF(JH(75J,
H:i(75) ,CNi)3I (/5) ,CKPHL1 (75 ) , CKPhL? (7 5 ) , CKHCN U 75 ) ,
3745.
3746.
3747.
3748.
3749.
3750.
3751.
3752.
3753.
3754.
3755.
3756.
3757.
3758.
3759.
3760.
3761.
3762.
3763.
3764.
3765.
3766.
3767.
3768.
3769.
3770.
3771.
3772.
3773.
3774.
3775.
CLM'iLH /HLK2/ ".STENV (S»0) , mSUG (90) , A1 SB00 (90 ) , wSCUKiS ( 90 ) , l^SHCN ( 90 ) ,
A «3nn3(9iJ) ,^5rM)2 (90) , WS.-!U3(9D) , WSCULI (90) , tvSALii (v>0) , rtSPHUS (90) ,
b WASTlL) (90 , 5) , TRF.ACT (90) , ASFLHw(90) , ASRAON (lMy) .WSPhL (90)
CUMMOij /F.LK3/ JJ.'.'C(15,:<) , ;-lft TRIO (15, 5) , H.vFLL.M (1 5) , H/JTF.MP (I 5) .
A H,-j3(15) , VHft (15) , DEHH/ (15) , OLrirt(lS) ,
C JUIjCID(15,5) , :\'ll'vKAR(15) ,HACOLI ( 1 5 ) , HW ALG, (1 5) , HWHCN ( I 5 ) , HWPHL (1 5)
Cu'li^lM /i!LK4/ FLO,. (500) , f)EPrH(500)/VEL(500),OTfiVCL(500),K2(500),
A K 1 (500) , Ou(5i'u) , rtul) (500) , CU'MS (500) ,"HS;ASTE,iJjur.; C.OELT , HILT ,02 LT , OTOI;X2,UT20I>X,
a A TMHk, i, I>ML),CluO<>, 5i Kit f ,,j f , l\ij , TRLCu,,TOFOA Y , WT ,i\C, T 1 Mt, i'JCb , L A T ,
C L jM,LLM,ELEv,!M r, /\E,ttE,L)AY(;FY,l)lvY.JLiJ,wET6Lrtf OE>PT,PT 1ME, TPRJ^I ,
Li DtLX, ISS, ALPHA5,ALPH A6,GRUM AX, REbPKT, iviCELLS, ILISTrIKPTl,IAUbCJP,
t T:-1AX, IKOOb, JSUM, IXPLT2,CK,1TP,CKPTP
CuN''1UN /HLK6/ ALP:iA9,CKNH2(75) , CNH2 II ( 7 5 ) , CNH2I ( 7 5) , Hi'INH2 (1 5 ) ,
M75) i C:iH2 15'iu) ,
3792.
3794.
3795.
3796.
3797.
3799.
D-2-66
-------�
c
C
C
C
C
C
C
C
C
C
C
C
C
C
c
C
C
C
C
C
C
N»\iS = 0
IJU.-JG =
STKP i-o naoo.
INITIALIZE COUNTERS FljF< HE ADWA TE3HO 1 .
WA51E LOADS UK ;-j 'I T Hurt Af-L S , AMU S3802.
JUMCHOMS. 3303.
3804.
3805.
3&06.
3307.
380».
STEP 2-0 3809.
LOOP THROUGH SYSTEM OH r.'REACH RE3810.
WITH NCELft COMPUTATIONAL ELEMENT3811.
RtACH.
OU 100 1=1, BREACH
NCELR=NCELRH(1)
DU 100 J = l,iMCELii
3812-.
3813.
3814.
3815.
3816.
XC1UH) = 1.0
IF (ISS.GT.O) XCI(JR) = 0.0
IFL=IFLAG(I,J) .
GO TCI (lul.toa, 1-02, 103,.10«, 102, 102), JFL
3818.
3819.
3820.
3821.
3322.
STEP 2-1 3323.
COMPUTE COEFFICIENTS b AND C FDR3824.
ELEMENT OF TYPE u
101
3825.
3»26.
3827.
AlIiJK)=-l)TOOX2*DLHrt(NHvO-HKFLU!»i(NHW)*IJTiJVCL(IOR)
XlI'.)(V)=X(10R)+f>100X2*(DLH:'v(,L(NN)+2.W*OLCiaR))+FLO^(IOlO* 3351,
* DTUVCL(IUR) 3852.
C(lUR)=-l)TOuX2*ul. (IOR) 3853.
GO TfJ 100 3854.
C 3855.
c STEP 2-4 3856.
c COMPUTE COEFFICIENTS A ANO B FOR3857.
c ELEMENT OF TYPE 5. 3858.
C 3859.
C 3860.
104 A(IOlO=-OT()UX2*(OL(IUrt-l)+iX(IOR))-FLOw(IUK-l)*DTOVCl. (IOR) 3861 .
«-l)fUL(10K))*FLOlA'(IOR)*uTOVCL(IOR) 3862.
3863.
3864.
3365.
D-2-67
100 CONTINUE
RETUWiJ
-------�
IT I ME .-JKPT2
3866.
3'.(67.
'ARPT2 wrtlTES AN IN TERMED I ATE SUMMARY
OF THE SELECTED DUALITY CONb T 1 TuEI;TS.
Thfc'SE CONSTITUENTS ARfc wKIITEN dY REACH
AIM!) 6Y ELEMENT. THTS SuNiMAKY CAN RE
GIVEM AT A TIME INTERVAL UF DELT OK
SOME MULTIPLE &F DELI.
3rt71.
3672.
COMMON A(500) ,0(500) ,C(500) ,X(500) ,S(500) ,Z(500) ,'A'(SOu) ,G(500)
/hLKl/ ICLGi<0(75,20) ,COEFUV(75) ,EXPQuV(7'j) ,CUEFQh(75) ,
EXPOf-H(/5),£XPiM2(75) , RCHJfJ(75,5) ,KMlHU'<(75) ,KMTEURC73) ,
C.''IA\.N(75),Cim75),Cl<.3(75),K2i)PT(75),CK2(75),CDE6K2(75),
TAKGDij(75),IAUiJiJK(75,6),rJCELRn-(75),£FLAii(75,?0),ALPHAO(75),
CK4(75),C«5(75),CKfviri3(75),Cl1P (90 ) , A'SDO ( 90 ) , A SB 00 ( 90 ) , VMSCUiMS ( 90)
A K"SlVrt3(90) , A'S")J?(90) , ,'.'SU03(90) , '.'.SCUL I ( 90 ) , AS ALG ( 90 ) , MiSPhUS ( 90 ) ,
B WAS1Iu190,5). fRFUCT (9u) , WSFLOW(90) , A'SKAUM(90) , l«SPI-iL (90)
(15,3) , Hf. f P. 1-0(1 5, 5) , hHvFLQ,\ (1 5 ) ,HnTEwP(15) ,
15) , H1.\,Mh3( 15) ,H'A,!\ia2(15
15) , Hv.COwS (15) , VH« ( 15)
•MA!< ( 1 5) , HA-COL I (15) t MI/\ ALG (15) , H'/'HCf': (15) , HWPHL (15)
3880.
3381.
3882.
3883.
3984.
3885.
3886.
38fl8.
3890.
3892.
3«93.
A H.vDUl 15) , MOiHH;
b N A TOT ( 1 5) , H»\M-ii
L JUNCIO(15,5),,
COM-HJ.vl /HLK4/ FLO.-. (500) , DEPTH (500) ,VEL (500) ,OTOVCL (500) ,K2 (500) ,
A Kt (5»U) ,00(500) ,L'0!J (500) ,CUflS (500) , HSnE r (500) , OL (50(J) , 1 (5UO) ,
b ALGrtE (500 ), PHijS (500) ,CNH3 (500) ,CNIJ2 1500)
C K MQ2 (500) , tfESr1** (-500) ,CULI (500 ) ,GHQ
U KM (500) ,KK2(500) ,HCrt(500) ,PHL(50o)
( 500) ,Ki\iH3 (500) ,
(500) ,R ADM (500) ,
3897.
3898.
3900.
j:\j /BLK5/ f-M.iDUh'T(12),L»(5),ALP HA1,ALPHA2,ALPHAS,ALPHA il,CrtN,CKP,
A CKL,K'riwTRS, IM^E *> CH , i\|h A 5 TE , M JUiVC , UEL T , 0 1 L 1 , D2L T , D TOD Xc!, UT 200 X ,
6 A FHPH , A ll\iO,CL(iUJ , SOi'.ET , ,'J I , rJJ , TKLCU , TOP DA Y , M T , UC , T I ME, MCS , LA7 ,
C LStf ,LLf-',ELE\/,DAT , AF , HE , i) A Y OF Y , OK Yh) Lb , :'JETBLL3., OEV'-iPT , PI INF!, TPK 1 NT ,
U DhLX, ISS, ALPHAS,iLPHAb,GKOi^AX,kESPRI , !vC ELL S , I LI ST , I HP I 1 , IAUGOP,
c. T.-1AX, ItHjIJ'j, JSU".', I XPL f2,CKHTP,CKPTP -
PEAL K i, K 2, K ivj in 3,
OATA
CUM,--1Uiv| /BLKfa/
Alc.SUH2(75) ,C:-jH<
ALPlA9,CK(-gH2 (75)
(50o-) , K VH2 (500)
(75) ,C!vH2i (75) ,HHNH2( 15)
3902.
3904.
3905.
3906.
3907.
3909.
3910.
3911.
IviH'M = 0
f-U'S = 0
LP = 0
DELM = DELX / 52SO.O
IF( fiT .Gf. 0 ) DtLM
DJ (LP,50) .'J£. 1 ) GO 10
3912.
3913.
3914.
3915.
3916.
3917.
3913.
3919.
3920.
3921.
3922.
3923.
39?4.
D-2-68
-------�
MPAGF = r-:PA.;E
'\'imtUJj,600h HME
ISS .£0. 0 )
ISS .Gf. 0 )
NT .EQ. 0 ) 'fi.il FECNJ,6010)
TF. C'JJ,6011)
290
292
296
IK(
IFC
IFC
IF C HT .fit. 0 )
IUR = ICLUHuKifJ)
HHrtl.) •= 0.0
0/vSI = 0.0
IFL = IFLAG(I,.J)
GU ID (290,296,29b,296,296,292,29')), IFL
NhW = MHri •»• 1
GiirtU = HWFLUW(MHW)
Gu TO
Mr. 5 =
Q.-.SI .=
GU TO 296
Nn-S = M/iS + 1
(Ji-vSI = - WSFL
X;.;H = R-ITHOKU) - FLOAT C J - 1 ) * OELM
CALC-AE =
* ALPHAUCI)
0
c-
o
X«E = Xi«H - DELM
UXXX = FLOW C I OH)
TxXX = 1 CIU*)
DXXX = UEPTHCIUK
VXXX = VKLCillK)
TF( UT .KU. 0 )
Dy.SI = Uf'SI / 3b
OXXX = JXXX / 3b
TXXX = ( TXXX -'
VXXX s VXXX / 3.
DXXX = OXXX / 3.
297 CUMTIiVillE
V.KlTt. 16,601S)LH,
2 CULI(IUk) ,RA[)ii
300 CONTINUE
)
GU TO
.3133
. il 33
32.0 )
?808
2808
T,J,XM
T 1 1 iV 'i r*
i. U 1* / t \*
CIOR)
OUTPUT SECONDARY ll\jF
297
/ 1.8
,CMJ3(IUR) ,PhOStIl.)R) ,CALGAE,
350
352
IF I ISS .EQ. 0 .A'MO. PTIf-'E .LT. 0.0 ) RETURN
LP = 0
IJUNC = 0
DU aOO 1 = 1, fJREACH
I^CF.Lf? = i'JCELRH(I)
f)G '400 J = 1, NCELR
tF (JSLIM .EQ. 1 .AND,
LP = LP + 1
IFC Ml.lDll.Pf 50)
NPAGt = MPAGE + 1
f 6005) NPAGE
.£«.. o ) .'i\lTE(.'«lJ,&007)
.!\'F. . 0 ) Ah(ITECiMj,600S)
.E'-l. (I ) iM
-------�
= (i).25* U«>Ui."<-l )+K2('Mi>U + 2.0*-K2(1GK) ))*! ,0159**TC 39Bb.
370 X;-iH = P-lTHOiUl) - FLOAT(J-t)*DFLM 34H7.
X'vic. = X ill - HELM 39H(J.
375 CUNT [,;Ut 399').
«KITF.(MJ,002-3) UP, I./ J, XMH, XME, XK2,K1(IOR), 39'H2(IOiO , CuNS(IOK) ,hCN(IUR),PHLUOR)
'400 CONTINUE 3997.
RtTUKN 3990.
6005 FORMATC 1H1 / 3999.
* 10X, 25HSTKEAM fJUALlTY SIMULATIO'^f 35X, 19HOUTPUT PAGE NUMBFR ,15^000.
* / 10X, JbnQUAL II STREA'i DUALITY KCUTING I^UDSt. ) 4001.
6007 FtiR.-iAT( / 1UX, 19HSYSTEM STATUS AFThK, F8.3, 2.7» HDURS OK DYNAI1IC 4003.
lOftSArinw ) ^ooa.
6008 FuK.iAn / 10X, 35H***** STEADY STATE SIMULATION ***** ) ^005.
bOH) FuR'iAT C/,'4/X, 13HSTKEAH STREA'M,/,
1'tA, ISfaHriCn El. F FWUM TU STREAM WASTE 1NCR VI-'L DEPTH
2TEMP 00 RL10 r.(n3-M '\l02-i'J NU3-^ PU4-P CHL A CULI RAO
}w, / , 4X, l?bH.Mir.i ,gu.-vi MILE MILE FLCHv FLLIW FLUrt (FPS) (FT
4) OfeG (MG/L) l^G/L) (MG/L) (MG/L) (MG/L) (NG/L) CUG/L) CMPM) (
bPC/L) )
bOii FORMAT i/,a?x,iSHSTREAM STREAM,/,
iax,126hriCH ELf FROM TO STPEANi WASTE INCR VEL DEPTH
2TEMP IH'1 fJOO MH3-N iMOd-W r)D3-Ni POa-P CHL A CULI RAO
IV, /, ax, 12bH!-JiUl Mi-1 KILO KILO FLCU' FLOW FLOrt Cf-'PS) IM
a) DEJi (rib/L) (MG/L) (MG/L) (MG/L) (MG/L) (^G/L) (UG/L) (MPN) (
SPC/L) )
6015 FUR 1 AT (IarIU, I3,2F7.1,F8.0,F7.1,F6.0,IOF7.2,F7.0 , F?.2)
'-T (/,26X, uyhOXrGbN BUU i\H3 M02 CDLI ALGAt ALGAE,
19X, bHUK'G-;;, /, ax, 1 ubnRCH F. L T FKOM TO REA1W DECAY DECAY OE
2CAY LiECAY GRO'/.TH h'ESPK ORG-N DECAY CO^-I HCfJ PhElVOL,/,
3'4X, 106HrjilM 'MU.-! f-iILF. MILE (1/DY) (^/DY) (1/DY) (1/DY) (1/DY) (1
*)/:jYJ ll/OY) (-'G/LJ (MG/L) ('-iG/D (MG/L) IMG/L) )
1 Fuk 'AT (/,26X,ii'iHOXYGti'J BUI) fjH3' M02 COLI ALGAE ALGAE,
1Q.\, Shuki:,-',,./ , ax , li;(SnRCH El.T FROM ff) REA1K LtbCAY DECAY DE
cCAf OECAt1 GRu/rTH ^ESPW I'!RG-N DECAY CON-I hCI\J PHFwOL,/,
jj^U, l()bh\H,i i\iu,.; MLO . KILU U/I.)Y) (1/uY) (1/DY) (1/DY) (l/DY) (1
4/DY) (1/DY) (. '(-,/{.'} (:--..-;/L) (''.G/l.) (MG/L) (MG/L) )
KuR"!AT(ia,l4ri3,2F7.1,9F7.2,2F7.3,Frt.3)
E"1"* 4032.
D-2-70
-------�
APPENDIX D-3
MOD EL CALIBRATION
-------�
APPENDIX D-3.1
MODEL CALIBRATION
OWENS-GIBBS REAERATION COEFFICIENTS
-------�
**»* INPUT OAIA LlSriNG FUR THE WIAL 11 STREAM QUALITY HUUI1NG MODEL ****
,«S$ (PROHLEM TITLES) $$S
(JUAL II PKOGRAM TITLES
AwARF IJOAL-1I AllH HCN AND PHENOL
NAME OF dASIiM = VALL1Y-OPOSSUM CKEtK
CONSERVATIVE MINERAL IN MG/L
HYDROGEN CYAfllOE IN MG/L
PHENOL IN MG/L
IEMPEKATUWE IN DEGREES FARtNHElT
BIOCHEMICAL OXYGEN DEMAM) IN
ALGAE AS CHI. A IN MG/L
PHOSPHOROUS AS P 1 IM MG/L
ORGANIC IIITROGFN IN MG/L
AMMONIA NI IMOGEN IN
MTRITE NITROGEN IN
NIIRA1E ^IIRUGEN IN
01 SOLVED OXYGEN IN MG/L
COLIFORMS AS KPN
RADIUMUCLIDE
CARD TYPE
T1TLF01
T1TLFO?
11TLE03
T11LF01
TITLE05
T 1 T L 1: 0 h
1 ITLtO?
TITLD.OH
II TLE09
TITLF 10
TITLE11
TULE'12
TITLE 13
TITLEH
TITLElb
T1TLE16
FNOTI TLE
1 ES
YES
YES
110
YES
NO
YES
YES
fES
YES
YES
CES
NO
hil
MG/L
MG/L
MG/L
$SS OA1A TYPE 1 (ClIMIKUL DATA)
CARD TYPE
LIST OATA INPUT
PLUIS Prtl^TtH
Nl) FLOW AUGMENTATION
S1EADY STATE
NUMHtK LlF REACHES =
NIJN L)F HEAll.^AlERS =
TIMt STEP CHOURS) =
MAXIMUM ROUTE TIME (HHS)=
ENI.)A1 A I
.00000
. 0 (1 0 0 0
.00000
.00000
. ooooo
. 0 0 0 0 0
.00000
3 0 . 0 0 0 U 0
.00000
I
CAKD lYPt
CDMPLF1E HEPURT
METRIC
NUMiER (IF JIIMCIILiNS :
NUMJER UF HASTE LOADS :
LMTH. LUMP. ELEMENT (MI):
TIME IMC. FUR KP12 (HRS):
.00000
.00000
.00000
.00000
.00000
1.00000
.20000
.00000
.00000
:SS$UAIA IYPF; IA (ALGAL PRI.IUUCT ION AND NIIHOGEN OXIDATION CONSTANTS) s.i>$
CARIJ IYHF.
U OHTAKE oY iJUfi-N (MG II/MI", N) =
IJ UPTAKE HY NH3 OX 10 (Ml, U/MG IM ) =
O Pi<(iU. l)Y ALGAt (Mli U/MI, A) =
N CONTENT OF ALGAE (MG fJ/MIi A) =
ALG MAX SPFC iJRUwTll RA 11 ( 1/DA Y ) =
M HALF SAlUWAflUN CONS I. (MG/L) =
LIGHT HALF bAT CONS I (LNGLY/MIN) =
MCN ItMP CHEF =
tNDAIAl H
CARD TYPE
.0000 MINIMUM REAERATION CIMSIANT OPT= .0000
.24UO II UPTAKE tl Y NO? llXIDtMU IJ/MU W)= 1.1100
.(IOOO 0 UPTAKE HY ALG4E (Mi; U/MG A) = l.SOOO
.08t>U P CONIEN1 OF M.GAE (HG P/MG A) : .0130
.OOOU ALGAF PtSPIRATIUN RATE (1/UAY) = .1000
.3000 P HALF SATURATION CONST. (MG/L)= .OUOO
.1HOU TOIAL DAILY KAD I A F I DM (L ANGLE Y S ) = 500.0(100
.0000 PHENOL IKMP COF.F = 1.0000
.0000 .0000
-------�
IS* DATA TYPE d (REACH I UF.NT IF 1 C A T HIM ) Vt.4
O
I
CO
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CARD 1 »
SIRE'AM
S1REAM
SIRtAH
S 1 R E A M
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S 1 R E A M
STKt AM
S 1 R E A M
S T R E A 1-1
STREAM
STREAM
STREAM
S 1 R t A M
STREAM
STREAM
STREAM
END AT A 2
PE
RF ACH
REivCH
REACH
RE ACH
REACH
R F A C 1 1
REACH
RF ACH
.-(F ATM
-, 1 -U. • 1
•)
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TU
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1 J
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TU
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111
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TU
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57.4
5S. 7
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31 .4
50.1
a? .3
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aa.i
21.5
9.7
H.5-
Ib. I
5.7
I . 7
10.7
B.3
6.9
3.5
.7
.0
-------�
DATA TYPt
CfAKGEI LEVEL 00 AMD FL'Jl" AUGMEM1 A T IIJN SOURCES) $$$
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FIELD
>}EACH AVAIL HOWS IARGET
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0. 0. 0. 0. 0. 0,
(CIJHPIJTATIOML IVEACH FLAG FIELD) $5>$
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1 .0
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19.0
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21. (i
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US* UAIA TYPt 5 (HYDRAULIC CiJE> Fl C I E M I b F Ok Ut 1t:.KM IM1 Ml- VtLUtlTY AMD Otl'lH) J>$Si
CD
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CAUiJ IYPE
MYDHAUL1CS
HYOKAUL ICU
HYDRAULICS
HYUWAill ICS
HYDRAULICS
HYUHAULICS
HYDIVAlJL ICS
HYDkAULICd
H r 1>IMUL 11. J
HYDKAIJL Kb
HYItWAUL ICS
HYDrtAUl. ICS
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HYDWAUUCS
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HYIHAUL ICS
HYDRAULICS
HrORAuLlCS
HYDRAULICS
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hNDATA5
K E A C H
1 .0
0
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0 1 H 5 0 (1 0
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0359600
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DMA TYPE 6 (REACTUIN CUEFF 1C I ENT f> FllR DEUX YGEWA T I UN AH.D REAERA 1 KJN) $$$
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REACT
REACT
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HtACT
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REACT
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REAC T
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REAC I
REAC1
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REAC i
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TYPE
CUEF
CJEF
CUEF
COF.F
CLlEF
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CUFF
CUEF
CUEF
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CUtF
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CUEF
CUEF
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CJEF
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CUEF
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1.0
2.0
3.0
4.0
5.0
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12.0
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4.00
4.00
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.•),$$ DATA TYPt oA (ALGAE, N I I KUGt. u, ANli PHUSHHUkUUS CUNSlAtllS) S>!5$
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ALGAt, ,4 AND P CUtF 4.11
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ALGAE, iM AND P CUEF 7.0
ALGAF, N AMU P CUtF 8.0
ALGAh, i>l AND P CUEF 9.0
ALGAt, n( AND P CUtF 20.0
ALGAE, M AND P CUEF ai.o
ALGAE, >M ANU P COEF za.o
ALGAE, i'l AND P CUEF 2:5.0
ALGAE, H AND P CUEF zu.o
ALGAt, .M AND P CUEF 25.0
ALGAt, N AND P CUtF ?b.O
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20.0
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20.0
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JU.6 DATA TYPE fall (OTHEtf CUtFF 1C I Efo TS) J>J*
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II1MEW COEFFICIENTS
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CITHER CUKFF ICIEiMfS
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3.0 90.0
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5.0 75.0
6.0 75.0
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4.0 75.0
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3.0 75.0
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7.0 75.0
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.00
.00
.00
.00
.00
.00
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SIHtAM illlAUIIr SIMI1LOIUN
DUAL II 3IHEAH UUALllr HIIUIING MIIUEL
• •••• SIKAUT STATt SIMULATION •••••
CAGE NIIHIIEH
HCH tLI
NUM NUM
51 9 |
b2 9 2
SI 9 i
54 44
55 IU 1
sb iu 2
57 IU 3
58 10 4
51 JU 5
60 IU f>
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62 II |
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66 II •>
67' II 6
68 11 7
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71 tt f
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27.9 b.14
27.7 h.19
27. S fr.19
27.3 b.19
27.1 10.99
26.9 IS. BO
2b.7 lb.80
26.5 15.79
26.3 11.24
26.1 h.64
25.9 b.6'1
25.7 6.66
BOD MM; mn
DtCAY UfCA* UtCAT
(I/DY) (1/I1Y) (I/DV)
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.16
.4H
.48
.48
.48
.48
.48
.48
.48
.48
.48
.48
.48
.48
.48
.48
.48
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.48
.48
.48
.48
.48
.48
.48
.48
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.36
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.43 .85
.43 .05
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.43 .85
.43 .85
.43 .as
.41 .05
.43 .65
.41 .65
.43 .85
.41 .»5
.43 .85
.43 .ttb
.43 .05
.43 .85
.43 .05
.43 .85
.43 .US
.43 .85
.43 ,t»b
.41 .85
.43 .85
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.41 .85
.43 .85
.43 ,N5
.43 .85
.43 .85
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.36 .96 .Hb
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.017
.017
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.012
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(MG/L)
.008
.008
.008
.008
.008
.008
.008
.008
.008
.008
.008
.008
.008
.008
.008
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.008
.008
.008
.007
.007
.007
.007
.007
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.007
.007
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3IKEAM 'JUALItf SIMIILAIIUN
UllAL II SIHtAM UUALIK HOUIIN1, Mill) EL
• •••• Slt»l)» STATE SIMULA I KIN ••«••
IllltPUl PAUf. NUMIItH
O
CO
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O
101
lOd
101
1 04
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lOb
107
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111
1 12
111
1 14
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117
118
1 19
120
121
122
1 ^ J
124
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126
127
128
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1 30
111
132
133
1 *4
135
I3b
137
1 38
1 31
140
141
142
141
144
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NUN HUM
Ib b
Ib 6
Ib 7
Ib 8
Ib 1
Ib 10
Ib 11
15 12
Ib 1
Ib 2
Ib 3
Ib 4
Ib 5
Ib b
Ib 7
Ib 8
Ib 1
Ib 10
16 1 1
Ib 12
Ib 11
17 1
17 2
17 3
1 7 4
1 7 5
17 b
17 7
17 8
17 1
Ib 1
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18 3
In 4
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18 b
11 1
11 2
11 3
11 4
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11 7
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145 11 9
116
147
1 48
141
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11 12
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20 2
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25.7
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24.1
24.7
24.5
24.1
24.1
21.1
21.7
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21.3
21.1
22.1
22.7
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22.1
22.1
21 .1
21.7
21. b
21.3
21.1
20.1
20.7
20.5
20.3
20.1
11.1
11.7
11.5
11.1
11.1
18.1
18.7
18.5
18.3
18.1
17.1
17.7
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17.1
17.1
16.9
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111
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25.5
25.3
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24.1
24.7
24.5
24.3
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23.1
23.7
23.5
23.3
23. 1
22.1
22.7
22.5
22.1
22.1
21.1
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20.9
20.7
20.5
20.1
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11.3
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16.7
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16.1
16.1
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(I/I)*)
6.61
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6.61
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6.62
6.62
6.62
6.62
5.21
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1.76
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1.16
1.76
1. 76
1.76
1. 76
1.75
5.11
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2.06
2.05
2.04
2.04
2.25
2.47
2.47
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2.4b
2.46
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2.4b
2.4b
2.45
2.45
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.16
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.85
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.85
.85
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( I/UY)
.00
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.00
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(I/OY)
.00
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.00
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SIKtAH UIIAinV MMIILAIIlIN
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SIKtAII UUALIK SIMIIIAIIUN
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.00
.Oil
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.on
.85
. B5
.H5
.85
.«5
.B5
.85
.85
.65
.05
.B5
.85
.85
.65
.85
.85
.85
.85
.05
.85
.85
.B5
.B5
.05
.85
.115
.05
.65
.85
.8b
.85
.85
.85
.85
.85
.Bb
,H5
.8b
.lib
.65
.B5
.as
.ab
.85
.85
.as
.Bb
.flb
.Hb
."b
CliLI
OK.Ar
(I/OV)
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
. 0(1
.00
.00
.00
.(Mi
At GAP
bllUWIH
(I/U!)
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
. 00
.00
. 00
ALbAt
wespit
( | /[) y )
.00
.110
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.01)
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.1)0
.00
.00
.1)0
.00
.00
.00
.00
.00
.00
.110
UHK-N
(HG/U
.15
. 15
.15
. 15
.35
.35
.15
.15
. 15
.35
. 15
.34
. 14
. 14
.34
.14
.14
.34
.14
.34
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.34
.34
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.11
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. 10
.30
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.19
. 18
.17
.lb
.15
.15
.14
. 1 1
IJUfi-N
UkCAV
(MG/LI
.00
.00
.00
.00
.00
.00
.00
.00
.0(1
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.36
.36
-3b
.3b
.lb
.16
.3b
.36
.36
.36
.36
. 36
.36
.16
.ib
.3b
. lb
.3h
.3b
.3b
.36
.36
.36
. 16
. In
CUN-I
(HG/L)
.oai
.021
.oai
.021
.021
.021
.020
.020
.oao
.oao
.oao
.oao
.oao
.oao
.oao
.ban
.oao
.oao
.019
.019
.019
.019
.0)9
.019
.019
.019
.019
.019
.019
.019
.019
-.019
.019
.019
.019
.019
.017
.017
.017
.017
.017
.017
.017
.III/
.017
.017
.017
.017
.017
.017
IICN
(m; /i )
.ooa
.004
.004
.004
.004
.004
.ooa
.004
.003
.003
.003
.003
.003
.003
.003
.003
.003
.003
.003
.003
.001
.003
.003
.oda
.002
.002
.002
.002
.002
.ooa
.002
.ooa
.002
.ooa
.002
.00)
.001
.001
.001
.001
.001
.1101
.001
.001
.001
.001
.000
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.1)00
.000
PIIF.NIIL
(Mb/L)
.007
.007
.007
.007
.007
.007
.007
.007
.007
.007
.out,
.OOb
.OOb
.OOb
.OOb
.OOb
.OOb
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.006
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.OOb
.006
.006
.OOb
.006
.006
.006
.006
.006
.OOb
.OOb
. 0 0 6
-------�
APPENDIX D-3.2
MODEL CALIBRATION
TSIVOGLOU REAERATION COEFFICIENTS
-------�
O
I
CO
ro
**** INPUT UATA LISITNG HOW THE (JUAL II SIREAM UUALITY ROUTING MODEL ****
3S-S (PROBLEM TITLES) 54$
CARD TYPt
TITLE 01
TITLE02
TITLEU4
1 ITLEO'I
TITLMS
TITLEOb
TITLED/
TITLEOH
TITLE09
TITLE1U
TITLE 11
T I ILK 12
TITLE13
TITLE11
TIT LEI 5
UTLElfe
ENDTITLE
YES
YES
YFS
NO
YES
NO
YES
YFS
YES
YES
YES
YFS
MO
NO
IJIJAL II PMIGKAN'. TITLES
AWARE IJUAL-IT rtllM HtN AND PHENOL
NAME UF tfASlN = VALLEY-OPOSSUM CHEEK
CONSERVAT1 VE MINtHAL IN MG/L
HYUUIJliEN CYANlDF IN MG/L
PHENUL I'M Mb/L
ffcMPtHATUKE IN OEGKtES FAHENHEIT
tHUCHEMICAL OXYGEN DEMAND IN MG/L
ALGAE AS CI1L A IN MG/L
I'HuSPHOHUUS AS P liv MG/L
OMGANIC NITROGEN IN MG/L
AMMONIA W1TWOGEM IN MG/L
NITK1TE NITKOGEN IN MG/L
NIIKATE N1THOGEU IN MG/L
DISOLVED OXYGEN IN MG/L
COLIFOKMS AS MPN
HAUIONUCLIDE
»S» UATA TYPE 1 (CONTROL DATA) $$$
CARD TYPE
LIS1 DATA INPUT
PLOTS PriliMTEH
NO FLOW AUGMENTATION
SIEAI'Y STATE
NUMUER UF KtACHES =
iJUM OF HEADrtATEHS =
TIME STEP (HOUKS) =
MAXIMUM ROUTE TIME (IIRS) =
ENDATA1
.00000
.00000
.00000
.00000
26.00000
.00000
.00000
1
CARD TYPE
COMPLETE HEPORT
METRIC
NUMBER OF JUNCTIONS :
NUMBER OF WASTfc LOADS :
LMIH. COMP. ELEMENT (MI):
IIMF INC.. FOR kPTa (MRS):
.00000
.00000
.00000
.00000
.00000
.00000
in.ooooo
.aoooo
.00000
.00000
iSSOATA IYPE 1A (ALGAE PRODUC1ION AMD NllKOGEN OXIDATION CONST ANTS)$$S
CARD JYPE
0 UPTAKE OY OrtG-N (MG 0/MG N) = .0000
0 OPTAKE HY NH3 UX1D(MG 0/MG N)= J5.2500
0 P^OD. BY ALGAE (MG 0/MG A) = a.0000
N CONTEiMl OF ALGAE (Mii N/MG «) = .0050
ALG MAX SPEC GROWTH RATE ( 1/DAY)= a.0000
0 HALF SATURAIIUN CONST. (Mi;/L)= .3000
LIGHT MALI- -SAT CONST (LNGL Y /MI IM )= .UMIO
HCN TEMP COEF = 1.0000
ENDATAtA .OOOC
CAKD TYPt
MINIMUM REAERAT1DM COMSIAIH OPT:
0 UPTAKE BY NIJ? OXIO(MG 0/MG N) =
(I UPTAKE BY ALGAE (MG 0/MG A) :
P CON1EMT OF ALGAE (MG P/MG A) :
ALGAE RESPIRATION RATE (I/DAY) :
P HALF SATURATION CONST. (MG/L):
TOTAL I'AILY PAD 1 A f ION (L ANGLE YS) =
PHENOL TEMP COEF :
500
1
.0000
1 .1100
1 .5000
.0130
.1000
.0100
0000
0000
.0000
-------�
DA1A TYF'E 2 (KtALH I UKN I I F I C A II (.IN) $**
CO
ro
i
ro
CARD 1YPF
STREAM
STREAM
S1REAM
SI REAM
S (REAh
S T H E A M
S I R t A M
STREAM
S T H r A M
S 1 Rt AM
STHEAM
SlKtAM
STREAM
STHtAM
STREAM
STREAM
STREAM
STREAM
STREAM
SI RE AM
STREAM
SIHEAi-t
STREAM
STREAM
S 1 R E rt M
STREAM
ENI'A TA2
HE ACM
HEnCH
REACH
Kt ACM
REACH
HF ACH
Ht ACH
HE AC II
>H- ACM
Mt ACM
HE *CH
HEATH
REACH
REACH
REACH
HEATH
REACH
RF. ACH
HtACH
REACH
HEACH
HtACH
HbACH
HE ft CM
REACH
Hk ACH
REACH
1 .0
2.0
3.0
1.0
b.O
h.O
7.0
B.(l
9 . 1)
1 I) .11
11.0
12 .(>
15.0
11. U
lb.0
16.0
17.0
1».0
19.0
20.0
21.0
22.0
23.0
2 >\ , 0
25.0
2fa.O
.0
RCH:
RCH
hCH
RCH
RCH
RCH
IUFNT
FPUM
FROM
F HUM
FROM
FROM
F RUM
F RUM
FHUM
F HUM
FKI.'II
F RUM
FRuM
F RUM
F RUM
FRUM
FRUM
F HUM
FROM
FRUM
FRUM
FROM
FKUH
FKOM
FROM
FRUM
FRUM
1b
'11
13
'12
'12
1?
'10
3 7
3'i
31
33
31
?0
27
?b
?.5
21'. 1
21 .b
9.7
fl.b
b. 1
3.7
1 .7
0.7
H.3
h.9
3.b
.7
.0
-------�
SSS DATA TYPt i (fAHbEI LEVEL !>(> AND FLOW AUGMENTATION SOURCES) SJi
CAKU TYPE
F.IMOATA3
UEACH AVAIL HUWS TAKGET
0. 0. .0
DkDfcR (IF AVAIL SUUKCES
0. 0. 0. 0 . 0 . 0.
$$* UAfA TYPE M (CUMPIJTAI UINAL REACH FLAG FIELU) ***
O
CO
•
ro
i
CO
CAKD TYPE
FLA.; FIELD
FLAG FItLO
FLAG F (ELD
FLAG FIELD
FLAG FItLD
FLAG FItLD
FLAG FIELO
FLAG FIELD
FLAG FIELU
FLAG FIELD
FLAG FIELU
FLAG FIELD
FLAG FIELU
FLAG FIELD
FLAG FIELD
FLAG FIELD
FLAG FItLD
FLAG F (tLD
FLAG FIELD
FLAG FIELD
FLAG FIELU
FLAG FIELD
FLAG FIELD
FLAG FIELD
FLAG FIELD
PI A 1 ' P 1 £ 1 \\
r l_l\\3 riCLU
END A I A1
KEACH ELEMENTS/REACH CO"PU ( AT KINAL FLAGS
1.0
2.0
3.0
1.0
b.O
6.0
7.0
8.0
9.0
0.0
1.0
2.0
3.0
1.0
'j.O
16.0
17.0
10.0
19.0
20.lt
21 .0
22.0
23.0
21.0
2S.O
'•) f. (l
tl O • U
.0
6.
3.
5.
2.
2.
10.
11.
1 1 .
1.
7.
H.
q.
11.
1 .
12.
1 1.
q.
6.
12.
12.
10.
5.
12.
7.
17.
0.
1 . 6 . 2 . 2 . 2 . 2 . (' . 0 . 0 . 0 . 0 . 0 . 0 . 0 . 0 . 0 . 0 . 0 . 0 . 0
2.2.2.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0
6.2.6.2.2.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0
2.6.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0
6.6.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0
2.2.2.6.2.2.2.2.6.2.0.0.0.0.0.0.0.0.0,.0
2.2.2.2.2.6.2.2.2.2.2.0.0.0.0.0.0.0.0.0
6.2.2.2.2.2.2.2.2.2.2.0.0.0.0.0.0.0.0.0
2.2.2.6.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0
2.2.2.2.2.2.2.0.0.0.0.0.0.0.0.0.0.0.0.0
2.2.2.2.2.2.2.2.0.0.0.0.0.0.0.0.0.0.0.0
2.2.2.2.2.2.2.2.2.0.0.0.0.0.0.0.0.0.0.0
2.2.2.2.2.2.2.2.2.2.2.2.2.2.0.0.0.0.0.0
2.2.2.2.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0
2.2.2.6.2.2.2.2.2.2.2.2.0.0.0.0.0.0.0.0
2.2.2.2.2.2.2.2.2.2.2.2.2.0.0.0.0.0.0.0
2.2.2.2.2.2.2.2.2.0.0.0.0.0.0.0.0.0.0.0
2.2.2.6.2.2.0.0.0.0.0.0.0.0.0.0.0.0.0.0
2.2.2.2.2.2.2.2.2.2.2.2.0.0.0.0.0.0.0.0
2.2.2.2.2.2.2.2.2.2.2.2.0.0.0.0.0.0.0.0
2.2.2.2.2.2.2.2.2.2.0.0.0.0.0.0.0.0.0.0
2.2.2.2.2.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0
2.2.2.2.2.2.2.2.2.2.2.6.0.0.0.0.0.0.0.0
2.2.2.2.2.2.2.0.0.0.0.0.0.0.0.0.0.0.0.0
2.2.2.2.2.2.2.2.2.2.2.2.2.2.2.2.2.0.0.0
0 . 0 . 0 . 0 . 0 . 0 . 0 . 0 . 0 . 0 . 0 . 0 . 0 . 0 . 0 . 0 . 0 . 0 . 0 . 0
-------�
S$$ UA1A TYPt 'j (HYDKAUL1C CUF>f- I C 1 El\! TS H UH DM EKMIN IMb Vf.LMCITY ANI1 UtPTH)
O
CO
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HYDKAULILS
HYDRAULICS
HYDRAULICS
HYDRAULICS
HYDHAUL ics
HYDRAULICS
HYDWAUL ICb
MYOKAIIL ICS
HYOKAUI. IC.i
HYDRAULICS
HYORAUL IC.S
HYDKAULICo
HYDRAULICS
HYLMAUL ICh
HYUKAULICS
HYDKAIIL f CS
HYOKAULIC 3
HYUKAULICS
HYDKAIIL 1LS
HYORAUL ICS
HYURAUL1CS
HYDRAULICS
HYUKMILICS
HYURAuLICb
HYDRAULICS
riYOKAULICS
ENOATA5
REACH
1 .0
t? . 0
3.0
1.0
b.o
6.0
7 .0
rt .0
4. II
1 II. 0
1 1 .11
1 d .0
13.0
14.0
15.0
16.0
17.0
10. 0
14.0
dO .0
d\ .0
??. .0
r?3.0
dl .0
2^.0
?6 . 0
.0
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0 9 '1 0 0 0 0
O9'l OOOd
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o inbioo
031^400
ObPObOO
0 1 .< 4 3 0 0
0 t' 6 1 b 0 (1
0 _i54hOO
0 tf a h 5 0 0
0^09/00
0 1 1 0 c? 0 ()
0^ 5t?«00
0165200
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0 0 0 6 d \ 0
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0 U 0 0 0 0 0
t XHUUW
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.6700
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.6700
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.6700
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.6700
.6700
.6700
.6700
.6700
.6700
.6700
1 .0000
1 .0000
1.0000
1 . 0 0 0 0
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.1700
.1700
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.9191
.1114
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.6712
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. d 1 1 '1
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-------�
DATA TYPE 6 (KtACTION COEFF 1C IEIJ \ S FUK UtdXYGbNAl 1IJN AMD KEAEKATIOlM) $SS
O
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CAHL) TYHK
KEACT CUEF
HtACT CJEF
RtACT CUEF
KEAC1 CUEF
HEACT CUtF
HEALT CUtF
HtACT CUEF
REACT CuEF
KEACT CUEF
HtACT CUtF
HEACT CUEF
HEACT CUEF
HtACT CUtF
KtACT CUtF
HtACT CUtF
UtACT CUtF
HtACT CUF.F
KtACT CUtF
HtACT CUtF
HtACT CUEF
HtACT CUhF
HEACT CdEF
KtACT CUfcF
KtACT CUEF
KtACT CUEF
KtACT CuEF
EwUATAfa
HtACH
1 .0
2.0
3.0
4.0
5.0
b.O
7.0
d.O
9.0
10.0
1 1 .0
12.0
15.0
14.0
1S.O
I b.O
17.0
tb.O
19.0
20.0
21.0
22.0
25.0
2't.O
2S".0
2b.O
.0
Kl
.40
.40
.(10
.40
.40
.40
.40
.40
.40
.40
.40
.40
.30
.30
.30
.30
.20
.20
.20
.20
.20
.OS
.Ob
.OS
.OS
.OS
.00
K3 K«
.00
.00
.00
.0(1
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.uu
!UPT
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
?.0o
5.00
4.00
3.00
3.00
.00
K2
3.24
3.29
3.29
3.29
3.29
b.72
5.63
2.92
1.94
1 .94
1 .94
S. 9fl
2.3c!
4.77
'1.77
1.37
.77
.77
.77
.77
1.91
.00
.00
.00
.00
.00
.00
CUtOK2
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
tXf'UK2
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
-------�
S OAIA TVPt bA (ALGAE, NITKUbtN, AM) PhlJSPhUKUlKS CllN&l AN I S)
O
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(V)
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CAHU IYPE
ALGAt,
ALGAE,
ALGAE,
ALGAt,
ALGAE,
ALGAt ,
ALGAE,
ALGAt ,
ALGAt,
ALGAt,
ALGAt ,
Al ..•M- ,
ALGAt ,
ALGAt ,
ALGAt,
ALGAE,
ALGAt,
ALGAt,
ALGAE,
ALGAE,
ALGAE,
ALGAE,
ALGAt,
ALGAE,
ALGAE,
ALGAE,
ENUATAb
'VI
i\l
N
.M
iM
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N
N
•M
•M
iM
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J
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N
N
N
N
N
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ANU P
ANU P
ANU P
ANU P
ANU P
AND P
KtACH ChL/ALG
CUtF
CUtF
CHEF
CUtF
CUtF
CUtF
CUtF
CUtF
CUtF
CUtF
CUt-F
l.HI- I7
U.ltt
CUFF
CUtF
CUtF
CUtF
CUtF
CUtF I
CUEF i
1.0 20
2.0 20
3.0 20
4.0 20
b.O 20
6.0 20
7.0 20
« . 0 20
4.0 20
il. u 20
J.H 20
r'... 2.1
I.'' 20
4.1- 20
b.O 20
h . 0 20
7.11 20
U.O 20
9.1. 20
0.0 20
CUtF 21.0 20
CUtF a
2.0 20
CUtF 23.0 20
CUtF 24.0 20
CUtF r
CUtF c
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.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
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.00
.00
.00
.00
.00
.00
.00
.00
.00
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.00
.00
.00
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b-PU
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
KUHG-N
.00
.00
.00
.00
.84
.84
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.42
.42
.42
.42
.00
.00
.00
.00
.00
.00
.00
.00
.00
.30
.30
.30
.00
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SSS DATA TYPE 6B (OTHER COEFFICIENTS) $$$
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OTHER COEFFICIENTS
OTHER COEFFICIENTS
COEFFICIENTS
COEFFICIENTS
COEFFICIENTS
COEFF ICIEMTS
COEFFICIENTS
COEFFICIENTS
COEFFICIENTS
COEFFICIENTS
COEFFICIENTS
COEFFICIENTS
COEFFICIENTS
COEFFICIENTS
COEFFICIENTS
COEFFICIENTS
COEFFICIENTS
CllEFF IC1ENTS
COEFFICIENTS
COEFFICIENTS
COEFFICIENTS
COEFFICIENTS
COEFFICIENTS
COEFFICIENTS
COEFFICIENTS
COEFFICIENTS
ENUATA66
OTHER
OIHER
OTHER
OTHER
OTHER
OTHER
OTHER
OIHEK
OIHEW
OTHER
OTHEk
OTHER
OTHEK
OTMtK
OTHER
OTHEK
OTHER
OTHER
UIHER
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OTHER
OTHER
EACH
1.0
2.0
3.0
4.0
5.0
6.0
7.0
H.O
9.0
10.0
1 1 .0
12.0
13.0
14.0
Ib.U
16.0
17.0
18.0
19.0
20.0
ai .0
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2.5.0
24.0
25.0
26.0
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H-OXY
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
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.00
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.00
.00
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KCOLI LITE EX
.00
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.00
.00
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.00
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.00
.00
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KRADIO KHCNt
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.00 26.70
.00 26.70
.00
.00
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.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
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.00
.00
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KHCN2
.00
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.00
.00
.00
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.00
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.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
KPHL1
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
KPHL2
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
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.00
.00
.00
.00
.00
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S«» DATA TYPt 7 (S[RtA4 JUNCTIONS) $t$
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CARD TYPF JUNCHIJN ORDbR AN
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CARD IYPE
HIJNUFF CONDITIONS
RUNOFF CONDITIONS
RUNOFF CONDITIONS
RUNOFF CONDITIONS
RUNOFF CUNDITIOMH
RUNOFF CONDITIONS
RUNOFF CONIHT IONS
RUNOFF CONUl 1 IONS
RUNOFF CONDITIONS
KUhOFF C 1 T IM'MS
KUIvHjFF CONDITIONS
i\UiiijF 1- LI'i-l11 1 1 lll.-lS
RUNOFF CONDI 1 IONS
RUNOFF CONDITIONS
RHNUFF CONDITIONS
RUNOFF CONDITIONS
RUNOFF CONDITIONS
RONOFF COI<||) IT IONS
RUNOFF CONDITIONS
RUNOFF CONDITIONS
KUNJFF CONDITIONS
RUNOFF CONDITIONS
RUNOFF CONDITIONS
RUNOFF CONDITIONS
RONOFF CONDITIONS
RUNOFF COJOITJUNS
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R F A C H 1
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3.0
4 .0
5.0
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r .'1
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4.0
5.0
16.0
17.0
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20.0
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26.0
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75.0
75.0
75.0
75.0
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75.0
75.0
75.0
75.0
75.0
75.0
75.0
75.0
75.0
75.0
75.0
75.0
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7.0
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7 .0
7 .0
7 .0
7 .0
7.0
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7.0
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.000
.000
.000
.000
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.000
.000
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4S4 DATA TYPt »A (INCREMENTAL FLOW CONOI1IUNS FOR NITROGEN,PHOSPHOROUS,
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CARD TYPE
RUfJUFF CIMO-?
WUI'-UF'F CUuU-2
RUNOFF CUNO-?
RUNUFF CHND-?
RUNIIFF COiMO-2
RUNUFF CUND-2
RUNUFF CH.MU-2
RUNOFF ciMD-2
HUMOfF CUnU-?
RIJMUFF CO'JH-2
RUNUFF Cll:tll>-2
RUNUFF CUNIJ-2
RUNOFF CIMD-2
RUNUFF cowo-2
RUNOFF COiJO-2
HUNUFF COND-2
RUNOFF CUNO-?
RUNOFF CO^O-2
RUNUFF CI)'JO-2
RUNUFF CU"JO-2
RUNOFF cu.^D-2
MUNUFF CMUU-2
RUNUFF CUMU-2
RUNOFF COND-2
RUNOFF COMD-2
RUNUFF CONO-2
EIJftATAHA
REACH
i .
2.
3.
1.
5.
6.
7.
H.
9.
10.
11.
12.
13.
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15.
16.
17.
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19.
20.
21 .
22.
23.
21.
25.
26.
0.
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.17
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. 17
.17
. 17
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NU2
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.00
.00
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.00
.00
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.00
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.19
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.19
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.19
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.19
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.19
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.19
.19
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P01
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.00
.00
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.00
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.00
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COL I
.0
.0
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ORI5-N
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.20
.20
.20
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.20
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.20
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.20
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.20
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.20
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.20
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DATA lYPt 9 (INITIAL CONDITIONS) $«
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CARD TYPE
INI T IAL
INITIAL
INITIAL
I'MlT IAL
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INI T IAL
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TNI T IAL
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.Ml UAL
Ml TIAL
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INITIAL
INI TIAL
INITIAL
INITIAL
INITIAL
INITIAL
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h .\il>ATA9
CONDI
CUNDI
CUUUI
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CONDI
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COMD I
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CONDI
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IONS
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IONS
IONS
KINS
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1 1 IN ;-)
1.0 90
2.0 90
3.0 90
U.O 90
5.0 75
h.O 75
7.0 75
H.O 75
9.0 75
0.0 75
1.0 75
?.0 75
5.0 75
'1.0 / 5
'i . U / >
IUNS ih.o 7 ••>
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7.0 75
IONS IH.O 75
TIONS 19.0 75
IONS ?0.0 75
IUNS ?1.0 75
IUNS 22.0 75
IONS 23.0 75
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.0
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NITROGEN, PHOSPHOROUS,
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INITIAL CUNU-a
INITIAL CUNU-a
INITIAL CUflO-a
INI flAL CUNU-2
IiMll IAL COMD-a
INITIAL coNi>-a
INI 1 IAL CUNI)-a
INITIAL cuNu-a
INITIAL CUND-a
INITIAL CUNU-a
INITIAL CUNU-a
INI I IAL CONU-a
INI TIAL CUNU-a
INITIAL CUNU-a
INITIAL cuwo-a
INITIAL CUND-a
INI 1 IAL CUND-a
INITIAL CUNU-a
INITIAL coND-a
INITIAL CUNU-a
INITIAL CUND-a
INITIAL COND-a
INITIAL CUND-a
INITIAL COND-a
INITIAL curiD-a
INITIAL COlMO-2
ENOATA9A
SS* DATA 1YPE
CARD TYPE
HEADWATER
ENDATA10
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CARD TYPE
HEADWATF.W-a
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6.
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9.
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MOD CONS I
4.4 .000
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PHENOL
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1SS UA[A lYPt 11 (WASTE LI.UniMUS) j. J $
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WASIFLUAD 4
WASTE LOAD 1
rtASIEL'JAL' j
WASIFI.iJAl) r>
lUAStELOAD 7
WAIIF-LOAD tt
WASTELOAD 9
WAbFELOAD 10
WASIELOAl) 11
WASFEIOAD 12
WASl'tLUAD M
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ENDATA11 0
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WASTELOAD-2
WASTELOAU-2
WASIF.LOAD-2
WAS 1 ELUAD-2
WASTfc'LOAI)-2
VMASTELilAD-2
WAS [ELIHD-2
WAS fELOAD-2
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188.
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IBS.
166.
18".
168.
IflH.
188.
188.
168.
189.
119.
217.
217.
217.
21 7.
?l 7.
217.
218.
218.
216.
218.
218.
218.
218.
il8.
SIIIF*M SIHtAH
WASIt INCH VlL DtPIH IEMI'
FLflx FLtlrt (FPS) (Fll DEC,
.0 . .SO .59 (5.00
.0 . .50 .60 75.00
.0 . .51 .6U 75.00
.0 . .51 .61 75.00
.0 . .51 .M 75.DO
.0 . .51 .62 75.00
.0 . .51 .62 75.110
.0 . .51 .65 75.00
.0 . .52 3.63 75.00
.0 . .52 3.61 75.00
.0 . .75 2.63 75.00
.0 . .76 2.83 75.00
.0 . .76 2.81 75.00
.11 . .76 S.B1 75.00
.0 . .76 2.85 75.00
.0 . .77 2.85 75.00
.0 . .77 2.85 75.00
.0 . .11 2.86 75.00
.0 . .77 2.86 75.00
.0 . .77 i. 87 75.00
.0 0. .55 3.01 75.00
.0 0. .55 3.01 75.00
.0 0. .55 J.OI 75.00
.0 0. .55 3.01 75.00
.0 0. .55 3.01 75.00
.0 0. .21 7.50 75.00
.0 0. .21 7.50 75. UO
.0 0. .21 7.50 75.00
.0 0. .21 7.50 75.00
.0 0. .21 7.50 75.00
.0 0. .21 7.50 75.00
.0 0. .21 7.50 75.00
.0 0. .28 .50 75.00
.0 0. .25 .50 75.00
.0 fl. .25 .50 75.00
.0 0. .25 .50 75.00
2».0 0. ,2« .50 75.00
.0 0. .11 1 .60 75.00
.0 0. .11 1 .60 75.UO
.0 0. .11 1 .60 75.00
.0 0. .11 1 .60 75.00
.0 0. .11 1 .60 75.00
.0 0 . .11 11.60 75.00
.0 0. .11 11.60 75.00
.0 0. .07 13.10 7 5. "('
.0 0. .07 13.1" 75.00
.0 0. .07 13.10 75.00
.0 0. .07 13.10 75.00
.0 0. .07 13.10 75.00
.0 I. .11 7 1 1.1
ND2-II
(Mr,/L)
.1 1
.1 1
.1 1
.1 1
.10
.10
.10
.10
.09
.09
.09
.09
.09
.09
.08
.08
.08
.06
.08
.08
.08
.00
.07
.07
.07
.07
.06
.06
.05
.05
.01
.01
.01
.03
.03
.03
.02
.02
.02
.01
.01
.01
.01
.01
.00
.00
.00
.00
.00
.00
ND1-N
(nr,/L)
1.21
1.20
1.19
1.18
1.1 7
1.15
1.11
1.13
1.12
1.11
1.09
1.06
1.07
1.05
1.01
1.03
1.01
1.00
J.99
3.96
3.97
3.97
1.97
3.97
3.97
3.97
3.9B
3.98
3.99
3.99
3.99
3.99
1.00
1.00
1.00
1.00
3.51
1.51
1.51
3.51
1.51
3.51
3.51
3.51
3.51
3.51
3.51
3.51
3.51
1.51
PII1-P
( Mli / L )
.62
.62
.61
.61
.61
.60
. l>0
.60
.60
.59
.59
.59
.59
.56
.58
.58
.58
.57
.57
.57
.57
.57
.57
.57
.57
.56
.56
.56
.56
.56
.56
.56
.56
.56
.56
.56
.67
.87
.87
.87
.87
.67
.U7
.67
.07
.87
.87
.87
.87
.07
cm A
(IIC./L)
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
CULI «A
(MCNl (PC/
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
-------�
a
i
CO
no
I
iJIIAI.ITT SIMULATION
UUAL II SIHEAM DUALITY KOIIl IMC, MIIUEL
»•• 3ir»llt SlAtE SIHULAIIUN ••••»
OUTPUT PAGE NUMMEII
HIH tLI
NUM NIIM
201
202
203
201
205
20b
20/
20H
209
210
21 1
212
213
214
215
216
217
2IB
219
22U
221
222
223
224
225
25
25
2b
25
25
25
25
25
25
25
25
26
2b
2b
2b
2b
2h
2b
20
2n
2b
2b
2b
2b
2b
I
8
1
10
1 1
12
13
11
IS
16
1 1
1
2
1
'1
5
h
7
a
»j
lu
1 1
12
11
la
FHIJM
MILK
5.7
5.5
5. I
5.1
1.9
1.7
1.5
1.S
1.1
3.9
3.7
3.5
J.3
3.1
2.1
2.7
2.5
2. J
2.1
.V
.1
.^1
.i
.1
.9
III
MILt
5. 5
5.3
5.1
1.9
i.r
1.5
1.3
1.1
3.9
3.7
1.5
3.3
3. 1
2.9
2.7
2.5
2.3
2.1
.9
.7
.5
.3
.1
.9
.7
STHfAM ««31E
FLUfl
2IH.
218.
2IH.
210.
2IH.
2IB.
219.
219.
219.
219.
219.
219.
219.
219.
219.
219.
219.
219.
219.
219.
219.
220.
220.
220.
220.
STREAM
INCW VIL
FLMft FLUn
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.11
.(1
. 0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
0.
0.
0.
0.
0.
0.
0.
0.
1).
(1.
0.
0.
0.
0.
0.
0.
0.
(1.
0.
0.
0.
0.
0.
0.
0.
(Mti/l) (MC/L) (HG/U) (MC/L) (MG/L) UJG/l) (MI'N) (PC/
75.00
75.00
75.00
75.00
75.00
75.00
75.00
75.00
75.00
75.00
75.00
75.00
75.00
75.00
75.00
75.00
75.00
75.00
75.00
75.00
75.00
75.00
75.00
75.00
75.00
7.28
7.2/
7.26
7.21
7.21
7.?2
7.21
7.19
7.10
7.17
7.lb
7.15
7.12
7.10
7. OB
7. Ob
7.05
7.03
7.01
7.00
b.9rt
b.97
6.96
6.91
6.8B
2.73
2.71
2.6A
2.65
2.62
2.60
2.57
2.51
2.5?
2.49
2.17
2.1 J
2.39
2.»5
2.32
2.2H
2.21
2.20
2.17
2.13
2.09
2.06
2.0J
1 .99
1 .95
.27
.28
.28
.29
.30
.30
.31
.31
.32
.32
.32
.35
.34
.34
.35
.35
.35
.36
.36
.36
.37
.37
.37
.37
.37
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
3.54
3.51
3.54
3.51
3.53
3.53
3.53
3.53
3.53
3.53
5.53
3.53
3.53
3.53
3.5?
.53
.52
.52
.52
.52
.52
3.52
3.52
3.52
1.49
.87
.87
.87
.87
.87
.87
.67
.87
.67
.87
.67
.(16.
.66
.86
.66
.86
.86
.116
.B6
.B6
.1)6
.06
.86
.86
.85
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
,
.
,
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
-------�
•JIUtAM DUALITY SIMULAIIUN
UUAL II SINf.AM IJUAHlr HUH I I fU, rtllDEL
• »... SIEAI1Y SIAIE SIMllLAtlllN •••«•
Illllflll PH,f. NUMIIEH
I
GO
INJ
I
CO
HLH ELI
HUM MUM
1 1
2 2
I 3
4 4
5 5
b b
7 i \
B t I
10 3 t
II 32
12 13
U J 4
14 55
15 4 1
1642
II 51
1852
19 b 1
20 b 2
2163
?d b 4
21 t "i
25 b 7
26 6 8
2769
2B fa 10
29 7 1
30 7 J
11 7 3
32 7 4
11 7 5
34 7 6
35 7 7
36 7 8
3/ 7 9
III 1 ID
39 711
40 81
41 82
4t » 1
43 8 4
40 85
4586
46 a 7
VI 88
He a 9
39 dill
so oil
HIOM Ifl
MILE MILE
45.7 45. S
45.5 45.3
45.3 45.1
43. 1 44.9
44.9 44.7
44.7 44.5
44.5 44.3
44.3 44.1
43.9 43.7
43.7 41.5
45.5 43.3
43.3 43.1
43.1 42.9
42.9 42.7
42.7 42.5
42.5 42.3
42.3 42.1
42.1 41 .9
41 .9 41.7
41.7 41.5
41 .5 41.1
41.3 41.1
40.9 40.7
40.7 40.5
40.5 40. 1
40.3 40.1
40.1 39.9
39.9 39.7
39.7 39.5
39.5 19.1
39.1 19.1
39.1 16.9
38.9 38.7
3ti.7 38.5
38.5 18.3
58.3 18.1
38.1 37.9
37.9 '17.7
37.7 37.5
37.5 37.3
17.3 37.1
37.1 16.9
36.9 36.7
36. / 16.5
16.5 Jb.3
36.3 36. 1
36.1 15.9
35.9 35.7
IIXVGtf
HEA1H
(1/UY)
4.11
4.08
4.05
4.02
3.99
3.96
1.96
4.00
4.00
4 . 00
4.00
4.00
4.00
4.00
4.00
3.50
1.50
4.79
h.08
6. Ob
b.oa
6.08
6. OH
6.06
6.08
6.08
fc.03
5.99
5.99
5.99
5.99
5.99
5.99
5.99
5.99
5.99
5.99
4.55
5.1 1
3.11
3.11
3.11
1.1 1
3.11
1.1 1
1. 11
l.ll
3.1 1
Illlll
DECAY
( 1 /U Y )
.80
.78
.76
.75
.73
.72
.70
.70
.70
.70
.70
.70
.70
.70
.70
.48
.4ft
.48
.43
.48
.411
.48
.48
.48
.46
.48
.48
.48
.46
.48
.48
.48
.48
.48
.48
.'IX
.18
.'16
.'IB
.48
.48
.46
.48
.48
.48
.40
.40
. 4 H
NH1 NII2
IILCAY UtCAY
(I/UY) 11/1,1)
.00 3.09
.00 3.02
.00 2.96
.00 2.90
.00 2.84
.00 2.78
.00 2.72
.00 2.72
• 0 0 £,72
.00 2.72
.00 2.72
.00 2.72
.00 2.72
.00 2.72
.00 2.72
.00 2.72
.00 .85
.00 .U5
.00 .85
.00 .85
.00 .85
.00 .85
.00 .65
0 1) 85
.00 .85
.00 ,«5
.00 .85
.00 .85
.00 .85
.00 .85
.00 .85
.00 .85
.00 .85
.00 .05
.00 .85
.00 .85
.00 .85
.00 .85
.00 .85
.43 .85
.41 .85
.43 .85
.43 .85
.43 .85
.41 .85
.43 .85
.43 .85
.43 .1)5
.43 1.85
.15 1 .65
U.LI
DECAY
(1/UY)
.00
.00
.00
.00
.00
.00
.00
.00
An
t U V
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.0(1
.00
0 0
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
ALGAE
fcHUMM
(I/UY)
.00
.00
.00
.110
.00
.00
.00
.00
U 0
!oo
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
U 0
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.0(1
.00
.00
.00
.00
.00
.00
ALGAE
HE SHU
(I/UY)
.00
.00
.00
.110
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
0 0
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
UHb-N
LWG-N UtCAY
(MG/L) (MG/L)
.33 .00
.89 .00
.88 .00
.86 .00
.88 .00
.87 .00
.87 .00
.86 .00
85 00
.81 .00
.60 .00
.75 .00
.75 .00
.74 .00
.74 .00
.49 .00
.49 .00
.48 .00
.47 .00
.47 .00
.46 .00
.45 .00
.45 .00
44 00
.44 .00
.43 .00
.42 .00
.42 .00
.41 .00
.40 .00
.40 .00
.19 .00
.38 .00
.49 .00
.48 .00
.48 .00
.47 .00
.46 .00
.46 .00
.74 .50
.72 .50
.71 .50
.70 .50
.68 .50
.67 .50
.66 .50
.65 .50
.63 .50
.62 .50
.61 .50
CDN-1
(MG/L)
.931
.100
.099
.096
.098
.097
.096
.095
.OBa
.087
.080
.080
.079
.079
.04.5
.042
.041
.041
.041
.041
.040
.040
0 1 0
.040
.040
.040
.040
.040
.040
.010
.040
.040
.031
.031
.031
.031
.031
.031
.028
.020
.028
.028
.028
.028
.028
.028
.028
.028
.028
HCN
(MG/L)
.004
.021
.020
.020
.019
.019
.019
.018
nit
. U I »
.674
.519
.378
.295
.231
.182
.086
.084
.081
.080
.079
.078
.076
.075'
071
.073
.072
.071
.070
.069
.067
.066
.065
.064
.051
.050
.049
.048
.048
.047
.045
.043
.042
.040
.019
.0)6
.016
.035
.034
.032
.031
PlItHUL
(MG/L)
.019
.023
.023
.023
.023
.023
.022
.022
.021
.020
.019
.019
.019
.019
.01 1
.01 1
.010
.010
.010
.010
.010
.010
0 1 U
.010
.010
.010
.010
.010
.010
.010
.010
.010
.008
.008
.008
.008
.008
.008
.008
.006
.008
.008
.008
.0011
.0118
.008
.008
.008
.008
-------�
SIHtAM DUALITY SIMULA!IOU
UUAL II SINEAM DUALITY KUUIIM6 MtlUEL
• •»• sir»nt SIATE SIMULATION ••••«
(IUIPUT PAGE NllMitEM
a
i
CO
ro
to
BLH ELT
MUM NUM
51 ^ I
a t 2
53 1 3
5'1 9 0
55 III 1
56 10 2
s; lu 3
5h lu 1
59 10 S
bU 106
hi 107
62 1 1 1
(•ill 2
ha || 3
65 1 1 1
66 II 5
67 II 6
bb 1 1 7
69 II 8
JO 12 1
M 122
12 12 3
75 12 a
74 I,!S
75 Id 6
7b 12 7
77 12 R
7b 12 9
7 '1 1 i 1
flli 132
01 133
fl2 I3o
B3 1 J 5
84 13 b
65 137
B6 1 3 (I
8( 131
Bf 13 10
"9 Mil
10 13 12
91 1313
92 13 11
13 10 1
10 10 2
95 In 5
91, la 4
97 15 1
9H 15 2
9'l 15 5
100 IS 1
FHfM
MII.E
J5.7
15.5
35.3
35.1
30.9
30.7
30.5
JO. 3
51.1
33.9
33.7
33.5
55.5
3S.I
52.9
32.7
32.5
32.1
.52.1
31.9
31.7
31.5
31.3
31.1
30. 9
30. 7
30. i
30. *
10.1
29.9
29.7
29.5
2 .03 .BS
•OB .13 .85
.01) .03 .B5
.'IP .03 .B5
.18 .03 .05
.OB .13 .85
.OB .13 .85
.08 .03 .65
.08 .03 .85
.08 .03 .85
.08 .03 .«5
.06 .03 .85
.00 .03 .65
.IB .03 .05
.18 .03 .85
.08 .03 .85
.08 .03 .85
.OB .«3 .85
.OH .«3 .B5
.IB .13 .H5
.48 .43 .85
.36 .43 .05
.36 .03 .85
.36 .13 ,HS
.36 .03 .115
.56 .13 .85
.36 .03 .B5
.36 .03 .15
.36 .45 .85
.36 .03 .«5
.36 .03 ,H5
.36 .03 .H5
.56 .03 .115
.36 .45 .(15
.16 .05 .(15
.36 .96 .85
.56 .'16 .05
.56 .V6 .15
.16 .9h .115
.56 .9h .fl5
.56 .9b .H5
.36 .16 1.H5
.56 .9b 1 .65
ClILI
DECAY
(1/HY)
.00
.00
.00
.00
.00
.(10
.(III
.Oil
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
,110
.00
.00
.0(1
.110
.00
.00
.0(1
.ou
.00
.00
.00
.00
ALGAE
bHIIKlH
(I/DY)
.00
.00
,00
.00
.00
.00
.00
.00
.00
.on
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.110
.00
.00
.00
.00
.1)0
.IIU
.00
.00
.00
.00
.00
.1)0
.00
.00
.00
.110
.00
.110
AlGAe
HISPH
(I/DY)
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.ou
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.no
.00
.ou
.00
.00
.00
.00
.00
.00
.00
.00
.00
.ou
.110
.ou
.00
.00
.00
(1RB-N
(MK/L)
.60
.60
.59
.59
.59
.58
.->7
.S7
.56
.55
.55
.54
.53
.53
.52
.51
.51
.50
.50
.09
.OH
.08
.07
.07
.06
.45
.15
.04
.44
.43
.45
.15
.42
.'12
.12
.41
.'II
.01
.on
.40
.'HI
. 59
. 59
.19
.19
.59
.59
.39
. 59
.18
(IRfi-N
(If CAY
(MG/L)
.50
.50
.50
.50
.50
.50
.50
.50
.50
.50
.50
.50
.50
.50
.50
.50
.50
.50
.50
.50
.50
.50
.50
.50
.50
.50
.50
.50
.50
.50
.50
.50
.50
.SO
.50
.50
.50
.50
.50
.SO
.50
.50
.00
.110
.00
.00
.00
.00
.00
.00
CUN-I
(MG/L)
.028
.028
.028
.028
.028
.n2»
.02B
.028
.028
.028
.028-
.028
.028
.028
.028
.028
.020
.028
.028
.028
.028
.028
.027
.027
.027
.027
.027
.027
.027
.027
.027
.027
.027
.027
.027
.027
.027
.027
.027
.027
.027
.027
.027
.027
.027
.027
.027
.027
.027
.0?5
HCN
(HG/I.)
.050
.030
.050
.029
.029
.028
.027
.027
.026
.026
.025
.025
.020
.023
.023
.022
.022
.021
.0?!
.020
.020
.019
' .019
.'018
.018
.017
.017
.017
.016
.016
.016
.013
.015
.015
.015
.015
.010
.010
.010
.010
.015
.01 i
.015
.013
.01 3
.013
.011
.012
.012
.0(1
PHENOL
(Mli/L)
.008
.OOB
.008
.008
.008
.008
.006
.008
.008
.008
.008
.008
.OOH
.008
.008
.008
.008
.000
.008
.008
.008
.007
.007
.007
.007
.007
.007
.007
.007
.007
.007
.007
.007
.007
.007
.007
.007
.007
.007
.007
.007
.007
.007
.007
.007
.007
.007
.007
.007
.008
-------�
SlWtAM gllALIK S1MULAIIUN
QUAL II SIHtAH IJUALIIr HllUlllgl, MllllEL
***** SIEAItV STATE SIMULAIluN *****
OUTPUT PAKE UIIMIltH
O
CO
INi
ro
O
KCH ELI
NUM NlIM
101 1 b S
i o a is h
103 1 b 7
104 Ib 8
lOb Ib 9
lOb Ib 10
107 Ib 1 1
IOB ib ia
109 Ib 1
i 10 ib a
III Ib 3
1 la Ib 4
113 Ib 5
111 Ib b
lib Ib 7
lib Ib B
llf Ib 9
110 Ib 10
119 Ib 11
iao ib ia
lai Ib 13
l?a 17 1
123 if a
lai if i
tab if i
136 I/ 5
iaf if b
iaa i/ 7
ia9 ii e
110 17 9
m i
i M a
133 3
1 11 4
I3b S
1 ib b
1 3) 1
1 ib 19 2
139 19 3
140 19 4
141 19 5
|4a 19 b
143 19 7
144 19 8
145 19 9
lib 1910
1 4 f 19 II
1 1 ii 19 i a
119 a» i
iso ao a
FKIIM
MILE
as.f
2b.b
ab.3
ab.i
24.9
a4.7
ai.s
ai.3
ai . i
ai.9
ft. i
ai.s
ai.3
ai.i
aa.9
aa.7
aa.b
aa. i
aa.i
ai .9
a i . 7
ai.s
PI.3
ai.i
ao.9
ao.7
ao.b
ao.3
ao. i
19.9
19.7
19. b
19.3
19.1
18.9
la. 7
la.s
lb.3
IB.I
1 f .9
If .7
17.5
1 f .i
17. 1
lb.9
16.7
lh.5
Ib.i
Ib.l
lb.9
III
MlLE
as.s
as. 3
as.i
a4.9
a4.f
a4.s
ai.3
ai.i
a3.9
<:3.7
i J.5
aJ.3
a3.l
aa.9
22.7
aa.b
aa.3
aa.i
ai.9
ai.7
ai.b
ai.i
ai .1
ao.9
ao.7
ao.s
ao.3
ao.i
19.9
19.7
19. b
19.3
19.1
1H.9
18.7
18. S
18.3
IB.I
17.9
17.7
17.5
17.3
1 f .1
16.9
Ib.f
lb.5
Ib.J
Ib.l
lb.9
15. f
OXYGEN
KEAlIt
(!/!)»)
S.Of
b.07
5.07
5.07
5.07
5.07
5.07
5.07
.26
.45
.15
.45
.45
.15
.IS
. 4b
.15
.15
.15
.45
.45
.14
.aa
.8a
.aa
,aa
,aa
.8?
.sa
.aa
.aa
.aa
. aa
.aa
.sa
. aa
. aa
.aa
,82
.aa
.Ba
.aa
.aa
.ua
,oa
.Ba
,na
,'»a
. 82
.aa
llllU
UlCAV
n/nr)
.3b
.36
.lh
.16
. 16
.ih
. 36
.Ib
. ih
.lh
. Hi
.36
.16
. Ib
. ib
. Sh
.3b
. 36
.36
.3b
.36
.ai
.24
.ai
.24
.ai
.ai
.ai
.ai
.ai
.ai
.ai
.ai
.ai
.ai
.21
.ai
.ai
.a4
.24
.a4
.24
.a4
.24
.a4
.a4
.ai
.a4
.24
.a4
MIS l>
IlLLAT Lit
( | /u y ) (|
.9b
. 9b
.9b
.9fa
.9b
.96
.96
.9b
.9b
-9b
.9fa
.96
.9b
.9b
-9b
.96
.96
.9b
.96
. 96
.96
.96
.96
.96
. 96
.96
.9b
.96
.9ft
.96
.96
.96
.96
.96
.96
.96
.96
.9h
.96
.96
.9b
.9b
.96
.96
.96
.9b
.96
.96
.9b
.96
(ia
CAT
UK)
.(IS
.as
.as
.as
.as
.as
.d5
.as
.(IS
.as
.as
.85
.as
.85
.as
.05
.85
.85
.as
./'S
.85
.85
-ai
.85
.85
.as
.as
.as
.as
.as
.as
.as
.as
.85
.as
.as
.65
.ts
.85
.65
.85
.85
.85
.85
.as
.bS
.as
.85
.BS
.as
CUL1
UECAI
( 1 /bY )
.00
.00
.00
.00
.00
.00
.00
.00
.(III
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.0(1
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
ALGAE.
GkunlH
u/im
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.no
.00
.00
.00
.00
.00
Air.AE
kf SI'H
(I/IIV)
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.no
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.CO
.00
.00
.00
.00
.00
.00
(MU-N
(hG/L )
.38
.38
.38
. 3a
. 38
.18
.18
. IN
. 18
. 18
. IB
.18
.18
.18
.18
.38
.38
. 18
. 18
.la
.38
. ia
.31
.in
.16
.38
.38
. 18
. , 18
.ifl
. 18
. 18
.ia
. 16
.ib
.Ib
.36
.16
.36
. 16
.16
. 16
.16
. 16
. 16
. 16
. IS
.15
.15
. 15
UHU-N
DECAY
(MC/L)
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
CUN-I
(MG/L) (
.oas
.oas
.oas
.oas
.oas
.oas
.oas
.oas
.oas
.oas
.oas
.oas
.oas
.oas
.oas
.oas
.025
.oas
.oas
.oas
.oas
.025
.025
.025
.oas
.025
.oas
.oas
.oas
.oas
.oai
.oai
.(liH
.oai
.oai
.oa3
.oaa
.oaa
.oaa
.oaa
.oaa
.oaa
.oaa
.oaa
.oaa
.oaa
.oai
.oai
.oai
.oai
MCIJ
M(i/L )
.01 1
.Oil
.01 1
.01 1
.Oil
.Oil
.010
.010
.010
.010
.010
.010
.009
.009
.009
.009
.009
.009
.008
.OOR
.008
.008
.008
.006
.008
.008
.008
.007
.007
.007
.007
.007
.007
.006
.006
.006
.006
.006
.006
.006
.005
.005
.005
.005
.005
.005
.005
.005
.005
.004
PHENOL
(MG/L)
.008
.008
.008
.008
.008
.008
.008
.ooa
.008
.008
.008
.008
.008
.008
.000
.007
.007
.007
.007
.007
.007
.007
.007
.007
.007
.007
.007
.007
.007
.007
.007
.007
.007
.007
.007
.007
.007
.007
.007
.007
.007
.007
.007
.OOf
.007
.007
.007
.007
.007
.007
-------�
SfllEAN DUALITY 3IMIILA11UN
'JUAL II SrHfcAil UUALItY HMljTIhG MIIUE.L
• «••• RIEADY SIA1E SIMIILAI1UN •••••
IIIITPUr PAGE IJUMIIEM
o
I
CO
IND
ro
RCH ELT
NUH NUM
151 50 5
ISb 21 b
167 21 7
Ifctt 21 6
169 21 9
170 21 10
IM 22 1
172 22 2
17} 22
1714 22
1 75 22
176 23
177 23
ITb 23
179 21 1
180 2J 5
|B| 23 h
lie? 21 7
183 23 B
inn 23 9
185 23 10
Iflb 23 II
117 23 12
I «M ?4 1
in-* 21 1
190 24 3
|9| 21 4
192 24 5
193 24 b
194 24 7
195 25 1
rib 25 a
|9( 25 J
|9» ?i a
199 2b 5
200 25 h
FHfH
MILE
15.7
15.5
15.3
15.1
14.9
14.7
14.5
14. I
14.1
13.9
13.7
13.5
1 5.3
13.1
12.9
12.7
12.5
12.3
12.1
11.9
11. 1
11.5
11.3
II. 1
10.9
10. 7
10.5
10.3
10.)
9.9
9.7
9.5
9. J
9. 1
fl.9
0.7
H.5
8.3
B.I
».9
1.1
I .5
7.5
7.1
h.9
h.l
b.5
6.3
(. . 1
5.9
IU
MILE
15.5
15.3
15.1
11.9
14.7
l«.5
14.3
14.1
•13.9
13.7
13.5
13.3
13.1
12.9
12.7
12.5
12.3
12.1
11.9
11.7
II .5
11.3
11.1
10.9
10.7
10.5
10.3
10.1
9.9
9.7
9.5
9.1
9.1
8.9
B.7
fl.5
U.3
0. 1
7.9
7.7
7.5
7.3
7 . 1
b.9
6.7
6.5
b. 5
6.1
5.9
5.7
IIXVbEM
HEAIR
(l/lltl
.112
.Hi
.02
.82
.82
.82
.82
.82
.82
.82
1.43
2.03
2.03
2.03
2.03
2.03
2.03
2.03
2.03
2.03
.99
.96
.9b
.96
.96
.14
.33
.])
.33
. 53
.33
.35
.35
.33
.33
.33
.34
.21
.1 1
.1 1
.11
.11
.1 1
. 1 1
.09
.07
.til
.01
.07
.01
IM.IU
DECAY
U/DY)
.24
.24
.24
.24
.24
.21
.24
.21
.24
.24
.24
.24
.24
.24
.24
.24
.24
.24
.24
.28
.06
.06
.Ob
.Ob
.Oh
.Ob
.06
.Oh
.Oh
.Oh
.Ob
.06
.06
.lib
.(It.
.Ob
.Uh
.Ob
.Ob
.lib
.Ob
.Ob
.Ob
.Oh
.Ob
.lib
.Ob
.Ob
.(J(,
.Ob
Nil 3 WII2
DECAY lifCAY
CI/OV) (1/DV)
.96
.9b
.9b
.96
.96
.96
.96
.9o
.96
.9b
.96
.9b
.9b
.9b
.9fa
.9fa
.9b
.96
.96
.96
.9b
.96
.9b
.9b
.96
.00
.00
.00
.0(1
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.HS
.B5
.85
.US
.85
.05
.85
.65
.85
.85
.05
.85
.85
.85
.«5
.05
.85
.85
.85
.85
.85
.85
.85
.85
.85
.85
.85
.85
.85
-H5
.85
.85
.b5
.f>5
.H5
-MS
.Ii5
.05
.115
.05
.«5
.'15
.«5
.H5
.P5
.85
.85
.US
.('5
.85
rOLI
utCAr
(1/UY)
.00
.00
.00
.00
.00
.00
.00
.00
.0(1
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.on
.00
.00
.00
.0(1
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.on
.Ou
ALFAt
GI1UWIH
(I/OY)
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.no
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.on
.110
.00
.no
.00
.00
.00
.00
.00
.00
.110
ALGAE
RtSI'H
II/IH)
.00
.00
.00
.00
.01)
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
. 10
. 10
. 10
.00
. Ml
. to
. 10
.00
.nu
.no
.00
.O'l
.no
DRG-N
(MG /L)
.35
. J5
. J5
.55
.35
.35
.35
.35
. 55
.35
.55
. 54
.34
.34
.54
. 54
.54
.34
.54
.34
.54
.34
. 54
.34
.34
. 53
.33
.52
.52
. (1
.51
.30
.30
.29
.26
.dli
.24
.23
.22
.22
.21
.20
.19
.1"
.1'
. |b
.15
.15
.14
. 1 J
l)R(i-M
UECAf
(MB/L)
.01)
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.no
.no
.00
.00
.00
.00
.00
.00
.no
.3*.
.36
.3b
.3b
.3d
.3b
.3i)
.3b
.3b
.16
.36
.3h
.36
. 56
..
-------�
3fHE»M DUALITY SIMULATION
(111HI. II SIREAH 'JIIALIIY HIMIIING MIIIIfL
»••• 3IHRY S1ATE SIMIILMIIIN • ••••
flUTPIM PAGt rillMKEI)
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MUM NUH
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UXVUEN BUO NHJ N(I2 CUL1 »lG»f
IO KE»IH DEC»Y UEC»> OtC»» DEC*» GKUHIH
*LGAE UKG-N
DESPII ORG-N OECAY
LON-I
HCN PHENOL
MILE (I/OO (1/0») ll/UY) ll/DV) (l/n») 11/OH (l/(ir) (Mli/L) (HG/L) (MG/L) (HG/L)
b.5
5.3
5.1
1.9
1.7
1.S
1.3
1.1
3.9
3.7
3.5
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13.500
10.SOU
9.000
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(MG/L)
J.OUU
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X • • * •
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(•) = LtlCUI.nTHl tlATA, (X) = .-lfcASUIII.il IIA1A
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IS. 0(1 10.00 5S.IIO
JO. 00 i"S.OO Jo. 00
ivm MIL! Ill IIFAI) {if IIF.ICM
IS.00 1(1.0(1 S.OO .00
= C»(CII(.Attn li/ll«, («) r
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(MC./L)
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50.00
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h'lVtk' Mill III HF«!) PF «K«CH
til. 00 5.00 .00
(•I - CAICIILAUH I»1A. (X) : Ht«SUHHI DATA
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4.000
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(MG/L)
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50.DO 'IS.HO 140.00 3S.OO 10.011 PS.OO ^0.00 15.00
Mil t Til HMD (IF HI »CH
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5.00 .00
(•I : C*l CtlLAlH) DATA, («) : Ht»3lll'tU DAT*
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CO
i.600*-
5.0
1.130
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5.00 111.00 Zb.OO ?0.(lli IS.00 10.00 5.01)
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(•) = OLCULtlhll I)AI»,
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(•) = C«LCIH«IK> P«l», (X) = ;•'!;
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50.00 'IS. 00 00.00
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... — x» < ( » , > « * . < » »—
(s.oo lo.oo ;>5.
-------�
APPENDIX D-3.3
MODEL CALIBRATION
TSIVOGLOU REAERATION COEFFICIENTS
NO NITRIFICATION
-------�
co
co
i
**** INPUT DATA LISTING FOR THE OUAL II STREAM QUALITY ROUTING MODEL ****
$$S (PROBLEM TITLES) SSS
CARD TYPE
TITLE 01
TITLE02
TITLE03
TITLE01
TITLE05
TITLF06
TITLF07
TITLE08
TITLE09
TITLE10
TITLE11
TITLEia
TITLE13
TITLE1'4
TITLE15
TITLE16
ENOTITLE
YES
YES
YES
NIJ
YES
NIJ
YES
YES
YES
YES
YES
YES
NO
NO
OUAL II PROGRAM TITLES
AWARE (JHAL-IT WI1H HCN AND PHENOL
NAME OF BASIN = VALLEY-OPOSSUM CRHhK
coNStRVAiivE MINERAL IN MG/L
HYDROGEN CYANIDE IN MG/L
PHENOL IN MG/L
TEMPERATURE IN DEGREES FARfcNHEIT
BIOCHEMICAL OXYGEN DEMAND IN MG/L
ALGAE AS CHL A IN MG/L
PHOSPHOROUS AS P IN MG/L
ORGANIC NITROGEN IN MG/L
AMMONIA NITROGEN IN MG/l
NITRITE NITROGEN IN MG/L
NITRATE NITROGEN IN MG/L
DISOLVEO OXYGEN IN MG/L
COLIFORMS AS MPN
RADIONUCLIOE
$$$ DATA TYPE 1 (CONTROL DATA) $SS
CARD TYPE
LIST DATA INPUT
PLOTS PRINTER
NO FLOW AUGMENTATION
STEADY STATE
NUMBER OF REACHES =
NUM f)F HEADWATERS =
TIME STEP (HOURS) =
MAXIMUM ROUTE TIME (HRS)=
ENOATA1
.00000
.00000
.00000
.00000
26.00000
1.00000
.00000
30.00000
.00000
CARD TYPE
COMPLETE REPORT
METRIC
NUMBER OF JUNCTIONS :
NUMBER OF WASTE LOADS :
LN1H. COMP. ELEMENT (MI):
TIME IMC. FOR RPT? (MRS):
. 0 0 0 0 0
.00000
.00000
.00000
.00000
11.00000
.aoooo
.00000
.00000
SSSDATA TYPE 1A (ALGAE PRODUCTION AND NITROGEN OXIDATION CONST ANTS)«$$
CARD TYPE
0 UPTAKE BY ORG-N (MG 0/MG N) = .0000
0 UPTAKE dY NH3 OXIIMMG 0/MG N)= 3.2300
0 PROD. BY ALGAE (MG 0/MG A) = 3.0000
N CONTENT OF ALGAE (MG N/MG A) = .08-50
ALG MAX SPEC GROWTH RATE(1/DAY)= 3.0000
N HALF SATURATION CONST. (MG/L)= .3000
LIGHT HALF SAT CONST(LNGLY/MIN)= .1800
HCN TEMP COEF = 1.0000
ENDATA1A .0000
CAKD TYPE
MINIMtIN REAERATION CONSTANT HPT:
0 UPTAKL BY MO? OXID(MG 0/MG W)=
0 UPTAKE BY ALGAE (MG 0/MP, A) :
P CONTENT OF ALGAE (MG P/MG A) :
ALGAE RESPIRATION RATE (I/DAY) :
P HALF SATURATION CONST. (MG/L):
TOTAL DAILY RAD I ATION(LANGlEYS) =
PHENOL TEMP COEF :
.000 0
1.1100
1 .5000
.01 <0
.1000
.000 0
SOO.OOOU
.000 o
.0000
1
-------�
$$$ DATA TYPE 2 (REACH IDENTIFICATION) S$$
O
I
CO
CO
ro
CARD TYPE
STREAM
STREAM
S1REAM
STREAM
STREAM
STREAM
STREAM
STREAM
S 1 H C. A ..1
STREAM
STREAM
STREAM
S1REAM
STREAM
STREAM
STREAM
S I RE A 11
S ) R E A M
STREAM
STREAM
STREAM
STREAM
STREAM
STREAM
STREAM
STREAM
ENOATA2.
REACH
REACH
REACH
REACH
REACH
REACH
REACH
REACH
iv' b A L. 1 1
REACH
REACH
REACH
REACH
REACH
REACH
REACH
R E A C H
REACH
REACH
REACH
REACH
REACH
REACH
REACH
REACH
REACH
REACH
1 .0
2.0
3.0
«.o
b.O
6.0
7.0
c.n
1 . l'
10.0
11.0
12.0
13.0
in. a
15.0
16.0
17.0
1 H.O
19.0
20.0
21.0
22.0
23.0
2'l.0
25.0
26.0
.0
RCH
RCH
RCH
RCH
RCH
RCH
RCH
RCH
HL'I
RCH
RCH
RCH
RCH
RCH
RCH
RCH
RCH
RCH
RCH
RCH
RCH
RCH
RCH
RCH
RCH:
RCH:
REACH UKOER AMD FOENT
FRUM
FRUM
FRUM
FRUM
FRUM
FRI.iM
FRUM
T- RUM
1 l.'ln-i
FRUM
FRCIM
FRUM
FRUM
FRUM
FROM
FRUM
FRUM
FRUM
FRUM
FRUM
FRUM
FROM
FRCIM
FRUM
FRUM
FRUM
4b
4,
1
(l
(t
6
3
.7
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.9
.9
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. 1
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. /
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.1
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.S
.1
.7
.7
.7
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.9
.5
.0
TU
TU
TU
TU
TU
TU
TU
TU
1 • i
TO
TU
TU
TU
TU
TO
TU
TU
TU
TU
TU
TU
TU
TU
Ul
TU
TU
'4 '4 . S
'11.9
'12.4
'12.5
'12. I
'in . 1
W .9
31.9
30. 1
?7. 5
?6.S
P«. 1
?1 .b
19.7
1 8.S
16.1
15.7
11.7
10.7
H. ?
6.9
3.1!
.7
-------�
$$$ DATA TYPE 3 (TARGET LEVEL 0(J AND FLOw AUGMENT A TTOM StIIIRCE-S) $S$
O
I
CO
OJ
CO
CARD TYPE
ENOATA3
$$S DATA TYPE 4 (COMPIJ1
CARD
FLAG
FLAG
FLAG
FLAG
FLAG
FLAG
FLAG
FLAG
FLAG
FLAG
FLAG
FLAG
FLAG
FLAG
FLAG
FLAG
FLAG
FLAG
FLAG
FLAG
FLAG
FLAG
FLAG
FLAG
FLAG
FLAG
TYPE
FIELO
FIELD
FIELO
FIELD
FIELD
FIELD
FIELO
FIELD
FIELD
FIELD
FIELO
FIELO
FIELO
FIELO
FIELD
FIELO
FIELO
FIELO
FIELO
FIELD
FIELO
FIELD
FIELO
FIELO
FIELO
FIELO
KEACH AVAIL HOWS TARGET ORDER OF AVAIL
0. 0. .0 0. 0. 0. 0.
AFIONAL REACH FLAG FIELD) StS
WF.ACH ELEMENTS/REACH
1
2
3
it
5
6
7
fl
9
10
11
12
13
14
15
1 6
17
IB
19
20
21
22
23
24
25
26
ENOATA4
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
6.
3.
5.
2.
2.
10.
1 1 .
1 1 .
4.
7,
P.
9.
1 4 .
4.
12.
13.
q.
6.
12.
12.
10.
5.
12.
7.
17.
14 .
0.
t
2
6
2
6
2
2
6
2
2
2
2
2
2
2
2
2
?
2
2
2
2
?
2
2
2
0
SMI.IRCES
0. 0
COMPUTATIONAL FLAGS
.6.2.2.2.2.0.0.0.0.0.0.0.0
.2.2.0.0.0.0.0.0.0.0.0.0.0
.2.6.2.2.0.0.0.0.0.0.0.0.0
.6.0.0.0.0.0.0.0.0.0.0.0.0
.6.0.0.0.0.0.0.0.0.0.0.0.0
.2.2.6.2.2.2.2.6.2.0.0.0.0
.2.2.2.2.6.2.2.2.2.2.0.0.0
.2.2.2.2.2.2.2.2.2.2.0.0.0
.2.2.6.0.0.0.0.0.0.0.0.0.0
.2.2.2.2.2.2.0.0.0.0.0.0.0
.2.2.2.2.2.2.2.0.0.0.0.0.0
.2.2.2.2.2.2.2.2.0.0.0.0.0
.2.2.2.2.2.2.2.2.2.2.2.2.2
.2.2.2.0.0.0.0.0.0.0.0.0.0
.2.2.6.2.2.2.2.2.2.2.2.0.0
.2.2.2.2.2.2.2.2.2.2.2.2.0
.2.2.2.2.2.2.2.2.0.0.0.0.0
.2.2.6.2.2.0.0.0.0.0.0.0.0
.2.2. 2. 2. 2.?. 2. 2. 2. 2.. 2. 0.0
.2. 2. 2. 2. 2. 2. 2. 2. 2. 2.?. 0.0
.2.2.2.2.2.2.2.2.2.0.0.0.0
.2.2.2.2.0.0.0.0.0.0.0.0.0
.2.2.2.2.2.2.2.2.2.2.6.0.0
.2.2.2.2.2.2.0.0.0.0.0.0.0
.2. 2. 2. 2. 2. 2. 2. 2. 2.?. 2. 2. 2
. 2. 2. 2. 2. 2. 2. 2. 2. 2. 2. 2. 2. r
.0.0.0.0.0.0.0.0.0.0.0.0.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
0
.0
.0
.0
.0
.0
.0
.0
.0
.2
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
0
.0
.0
.0
.0
.0
.0
.0
.0
.2
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
0
.0
.0
.0
.0
.0
.0
.0
.0
.2
.0
,0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0.0
.0.0
.0.0
.0.0
.0.0
.0.0
.0.0
.0.0
.0.0
.0.0
.0.0
.0.0
.0.0
.0.0
.0.0
0 (I
.0.0
.0.0
.0.0
.0.0
.0.0
.0.0
.0.0
.0.0
.0.0
.0.0
.0.0
-------�
SS4 DATA TYPE 5 (HYDRAULIC COEFFICIENTS FOR I>F 1 F.lvM] Ml Nf; VFLDUTTY AMI) DEPTH)
O
CO
CO
CARD TYPE
HYDRAULICS
HYDRAULICS
HYDRAULICS
HYDRAULICS
HYDRAULICS
HYDRAULICS
HYDRAULICS
II YIIKAUl. K..1
HYDRAULICS
HYDRAULICS
HYDRAULICS
HYDRAULICS
HYDRAULICS
HYDRAULICS
HYDRAULICS
HYDRAULICS
HYDRAULICS
HYDRAULICS
HYDRAULICS
HYORAUL ICS
HYDRAULICS
HYDRAULICS
HYDRAULICS
HYDRAULICS
HYDRAULICS
HYDRAULICS
ENDATA5
REACH
1 .0
2.0
3.0
1.0
5.0
6.0
7 .0
'>. i)
9.0
10.0
11.0
12.0
13.0
11.0
15.0
16.0
U.O
18.0
19.0
20.0
21 .0
22.0
23.0
21.0
25.0
26.0
.0
CHEFOV
091001)0
09100(10
0910000
0910000
0179900
0179900
0331700
ill MJ r' IM)
U 3 7 0 « (1 0
0 2 1 5 »M> 0
0206200
0185100
O3i29oo
0520600
0339300
0862500
0359800
0216500
0209700
0160200
0232000
0165200
001 3000
0001926
0003210
0001950
0000000
EXPUUV
.6700
.6700
.6700
.6700
.6700
.6700
.6700
. h / ijn
.6700
.6700
.6700
.6700
.6700
.6700
.6700
.6700
.6700
.6700
.6700
.6700
.6700
.6700
1 .0000
1 .0000
I .0000
1 .0000
.0000
Cllt'FUH
.1700
.1700
.1700
,1700
.31 M
.3171
.SI <2
. 91 l"i
.11 1^
.5792
.5S9J
.671?
.378H
.2711
.3737
.1195
.3090
.6211
.5299
.6571
.5102
.6266
/ .5000
1 1 .6000
13.1000
11.0000
.0000
FXPIIUH
. 5300
.3300
.3100
. 3 5 0 0
. 3 ; U o
. 53UO
. 5300
. 5 .M'll
.3300
. 5300
.3300
.3300
.3300
.3300
.3300
,3300
. 5300
.3300
. 5300
.3300
. 3300
. 5000
.0000
.0000
.0000
.0000
.0000
CMAiJ'J
. 0 U 0 0
.010 0
.O'lOO
. 0 1 0 0
. U '1 0 0
. 0 1 0 'I
. Oil)"
. 1! '4 11 II
.O'lOO
.0100
.0100
.0100
.0100
.0100
. 0 1 0 0
. 0 'I I) 0
. 0 '1 0 0
.0100
.0100
.0100
.0100
.0100
.010 0
.0100
= I) 1 0 0
.0100
.0000
-------�
$$$ DATA TYPE 6 (REACTION COEFFICIENTS FOR OEOXYGENATHIN AND REAERATION) $$$
O
GO
CO
I
cn
CARD TYPE
REACT CUEF
REACT COEF
REACT COEF
REACT COEF
REACT COEF
REACT COEF
REACT COEF
REACT COEF
REACT COEF
REACT COEF
RtACT COEF
REACT COEF
REACT COEF
REACT COEF
REACT COEF
REACT COEF
REACT COEF
REACT COEF
REACT COEF
REACT COEF
REACT COEF
REACT COEF
REACT COEF
REACT COEF
REACT COEF
REACT COEF
ENDATA6
REACH
1.0
2.0
3.0
4.0
5.0
6.0
7.0
fl.O
9.0
10.0
1 1 .0
12.0
13.0
14.0
15.0
16.0
17.0
18.0
19.0
20.0
21.0
22.0
23.0
24.0
25.0
26.0
.0
Kl
.40
.40
.40
.40
.40
.40
.40
.40
.40
.40
.40
.40
.30
.30
.30
.30
.20
.20
.20
.20
.20
.05
.05
.05
.05
.05
.00
K3 K20PT
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00 3.00
.00 3.00
.00 3.00
.00 3.00
.00 3.00
.00 .00
K2
3.24
3.24
3.29
3.29
3.29
5.72
5.63
2.92
1 .94
1 .94
1 .94
5.9B
2.32
4.77
4.77
1.37
.77
.77
.77
.77
1.91
.00
.00
.00
.00
.00
.00
COEQK2
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
EXHIJK2
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
-------�
$$i DATA TYPE 6A (ALGAE, NI TRUCEN, AND PHOSPHOROUS CONSTANTS) $$$
O
CO
CO
cn
CARO TYPE
ALGAE,
ALGAE,
ALGAE,
ALGAE,
ALGAE,
ALGAE,
ALGAE,
ALGAE,
ALOAE,
ALOAE*
ALGAE,
ALi»«l-. ,
ALGAE,
ALGAE,
ALGAE,
ALGAE,
ALGAE,
ALGAE,
ALGAE,
ALGAE,
ALGAE,
ALGAE,
ALGAE,
ALGAE,
ALGAE,
ALGAE,
ENOATA6
N
N
N
N
N
N
M
N
N
I)
N
.1
M
PJ
N
M
N
N
N
N
N
N
N
N
N
N
ANO P
AND P
AND P
ANO P
ANO P
ANU P
ANO P
ANO P
ANO P
ANU P
A HO P
AHO t'
ANO P
ANO ('
ANO P
AND P
AND P
AND P
ANO P
AND P
AND P
ANO P
ANO P
ANO P
AND P
ANO P
CHEF
COEF
COEF
COEF
COEF
COEF
COEF
COtF
COEF
COtF
COEF
Ciu.r
COtF
COEF
COEF
COEF
COEF
COEF
COEF
COEF
COEF
COEF
COEF
COEF
COEF
COEF
HEATH CHL/ALG
1 .
2.
3.
4.
5.
f>.
7.
8.
9.
Ok
1 .
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1.
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1b.
17.
10.
1 9.
20.
21.
22.
23.
24.
25.
26.
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0
0
0
0
0
0
0
0
0
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()
0
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0
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0
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.0
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ALGSE1
.0
.0
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. 1'
.11
.0
.0
.0
.0
.0
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KMH3
.110
.00
.00
.00
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.00
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.00
.00
.00
.00
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.00
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KKJO2
.00
.00
.00
.00
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. 00
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.00
.00
.00
.00
.00
.00
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.00
.00
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.00
.00
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.00
.00
.00
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.00
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H-PO
.00
.00
.00
.00
.00
.00
.00
.00
.00
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. 00
.00
.00
.00
.00
.00
.00
.00
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.00
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.00
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.00
.00
.00
.00
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. 00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
-------�
$$$ DATA TYPE 6B (OTHER COEFFICIENTS) $$$
O
CO
CO
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CARD TYPE
OTHER COEFFICIENTS
OTHER COEFFICIENTS
OTHER COEFFICIENTS
OTHER COEFFICIENTS
OTHER COEFFICIENTS
OTHER COEFFICIENTS
OTHER COEFFICIENTS
OTHER COEFFICIENTS
OTHER COEFFICIENTS
OTHER COEFFICIENTS
OTHER COEFFICIENTS
OTHER COEFFICIENTS
01HER COEFFICIENTS
OTHER COEFFICIENTS
OTHER COEFFICIENTS
OTHER COEFFICIENTS
OTHER COEFFICIENTS
OTHER COEFFICIENTS
OTHER COEFFICIENTS
OTHER COEFFICIENTS
OTHER COEFFICIENTS
OTHER COEFFICIENTS
OTHER COEFFICIENTS
OTHER COEFFICIENTS
OTHER COEFFICIENTS
OTHER COEFFICIENTS
ENOATA6B
$$J DATA TYPE 7 (STREAM JONCTIONS) $$S
REACH
t.O
2.0
3.0
t.O
5.0
6.0
7.0
fl.O
9.0
10.0
11.0
12.0
13.0
11.. 0
15.0
16.0
17.0
18.0
19.0
20.0
21.0
22.0
23.0
21.0
25.0
26.0
.0
8-OXY
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
KCULI LITE EX
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
KRAIHO KHCN1
.00 i.oo
.00 1.00
.00 26.70
.00 26.70
.00 1.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
..00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00 1.00
.00 .00
KHCN2
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
KPHL1
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
KPHL2
.00
.00
.no
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
CARD TYPE
ENOATA7
JUNCTION OKDER AND IDENT
0.
UPSTRM
0.
JUNCTION
0.
-------�
$$$ DATA TYPE 8 (RUNOFF CONDITIONS) $$*
O
I
OJ
CO
00
CARD TYPE
RUNOFF CONDITIO'MS
RUNOFF CONDITIONS
RUNOFF CniMniTIONS
RUNOFF CONDITIONS
RUNOFF CONDITIONS
RUNOFF CONDITIONS
RUNOFF CONDITIONS
RUNOFF CONDITIONS
RUNOFF CONDITIONS
RUNOFF COMDITIONS
RllNOH t Cltnl.' I I I O.jS
RUNOFF CONDITIONS
RUNOFF CONDITIONS
RUNOFF CONDITIONS
RUNOFF CONDITIONS
RUNOFF CONDITIONS
RUNOFF CONDITIONS
RUNOFF CONDITIONS
RUNOFF CONDITIONS
RUNOFF CONDITIONS
RUNOFF CONDITIONS
RUNOFF CONDITIONS
RUNOFF CONDITIONS
RUNOFF CONDITIONS
RUNOFF CONDITIONS
RUNOFF CONDITIONS
ENDATAfl
EACH
1 .0
2.0
3.0
1.0
•5.0
6.0
7 . 0
0.0
9.0
10.0
1 1 .11
12.0
15.0
It .0
15.0
lfa.0
17.0
18.0
19.0
20.0
21.0
22.0
83.0
24.0
25.0
26.0
.0
FLOW
1 .6
1 .2
2.0
.0
.0
1 .2
1 . J
1 .3
.5
. H
1 . 1
.2
.9
.5
.6
.7
.2
3.2
9.5
9.5
8.0
.0
.0
.0
.0
.0
.0
TEMP
75.11
75.0
75.0
75.0
75.0
75.0
75.0
75.0
75.0
75.1)
("i . 0
75.0
75.0
75.0
75.0
75.0
75.0
75.0
75.0
75.0
75.0
75.0
75.0
75.0
75.0
75.0
.0
D.O.
7 .0
7.0
7 .0
7 .(>
7.0
7 .0
7 .0
7 .11
7.0
7.1,
/ .11
7.0
7.0
7.0
7.0
7 .0
7 .0
7 .0
7.0
7.0
7 .0
7.0
7.0
7.0
7.D
7.0
.0
HOI)
1.0
4.0
4.0
4 .0
4.0
4.0
4.0
«.o
4 .0
'1 .0
;l .u
4.0
4.0
4.0
4.0
4 .0
4.0
4.0
4.0
4.0
4.0
4.0
4.0
4.0
4.0
4 .0
.0
CONS I
. 0 0 0
.000
.000
.000
.000
.000
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.000
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. utiii
.000
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.000
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.000
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. 0 0 0
. 0 0 (j
. o o o
.000
.000
.000
.000
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. 1 " 1 0
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.000
.000
.000
. 0 0 0
.000
.000
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.000
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PHENOL
.000
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.000
.000
. 0 0 0
.000
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,ono
.001)
. iM '
-------�
o
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CO
I
IO
SSS DATA TYPE 8A (INCREMENTAL FLOW CONDITIONS FOrt NITROGfcN,PHOSPHOROUS,
COLIFOHM AND RADIONUCLIDE} $$$
CARD TYPE
RUNOFF CONU-2
RUNOFF CUND-2
RUNOFF COND-2
RUNOFF COND-2
RUNOFF COND-a
RUNOFF COND-2
RUNOFF COND-2
RUNOFF COND-2
RUNOFF COND-2
RUNOFF CnND-2
RUNOFF CCIND-2
RUNOFF COND-2
RUNOFF COND-2
RUNOFF COND-2
RUNOFF COND-2
RUNOFF COND-2
RUNOFF COND-2
RUNOFF COND-2
RUNOFF COND-2
RUNOFF CONO-2
RUNOFF COND-2
RUNOFF CONO-2
RUNOFF COND-2
RUNOFF CONO-2
RUNOFF CONO-2
RUNOFF COND-2
ENDATA6A
EACH CIILORA
1.
2.
3.
1.
5.
6.
7.
fl.
9.
10.
11.
12.
13.
11.
15.
16.
17.
18.
19.
20.
21.
22.
23.
21.
25.
26.
0.
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
NH3
1.60
1.60
1.60
.17
.17
.17
.17
.17
.17
.17
.17
.17
.17
.17
.17
.17
.17
.17
.17
.17
.17
.17
.17
.17
.17
.17
.00
NCI2
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
N03
.19
.19
.19
.19
.19
.19
.19
.19
.19
.19
.19
.19
.19
.19
.19
.19
.19
.19
.19
.19
.19
.19
.19
.19
.19
.19
.00
PM4
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
cnui
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
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RADN
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
ORG-N
.33
.35
.33
.20
.20
.20
.20
.20
.20
.20
.20
.20
.20
.20
.20
.20
.20
.20
.20
.20
.20
.20
.20
.20
.20
.20
.00
-------�
$$$ DATA TYPE •> (INITIAL CONDITIONS) $S$
a
CO
CO
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CAHO TYPE
INITIAL CONDITIONS
INITIAL CONUIIIONS
INITIAL CONDITIONS
INITIAL CONDITIONS
INITIAL CONDITIONS
INITIAL CONDITIONS
INITIAL CONDITIONS
INITIAL CONDITIONS
INITIAL CONDITIONS
INITIAL CONDITIONS
INITIAL CONDITIONS
INITIAL CONDITIONS
INITIAL CONDITIONS
INITIAL CONDI I IONS
INITIAL CONDI IIOWS
INITIAL CONDITIONS
INITIAL CONDITIONS
INITIAL CONDITIONS
INITIAL CONDITIONS
INITIAL CONDITIONS
INITIAL CONDITIONS
IMITIAL CONDITIONS
INITIAL CONDITIONS
INITIAL CONDITIONS
INITIAL CONDITIONS
INITIAL CONDITIONS
EiMDATA9
EACH
1 .0
2.0
3.0
1.0
5.0
6.0
7.0
8.0
9.0
0.0
1 .0
2.0
3.0
4.0
5.0
6.0
7.0
18.0
19.0
20.0
21.0
22.0
23.0
21.0
25.0
26.0
.0
TEMP
90.0
90.0
90.0
90.0
75.0
75.0
75.0
75.0
75.0
75.0
75.0
75.0
75.D
7 'j . II
75.0
75.0
75.0
75.0
75.0
75.0
75.0
75.0
75.0
75.0
75.0
75.0
.0
D.O.
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
. 11
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.0
.11
.0
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.0
.0
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HOD
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CONS I
.000
.000
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. 0 0 0
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.000
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.(111,.
.000
. 0 0 0
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.000
.000
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.000
.000
.000
.000
.000
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MCN
.000
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.000
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.0011
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. 0 0 0
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. tj 1 M i
. 0 0 0
.000
. 0 0 0
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
PHENOL
.000
.000
.000
.000
.000
.00(1
.000
.000
.000
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.000
. 0 0 IJ
.000
. 0 0 0
.000
.000
.000
.000
.000
.000
.000
.000
-------�
$$$ DATA TYPE 9A (INITIAL CONDITIONS FOR CHLOROPHYLL A, NITROGEN, PHOSPHOROUS,
COLIFORM AND RAOIONUCLIDE) $S$
I
CO
CO
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CARD TYPE
INITIAL COND-a
INITIAL COND-a
INITIAL CONO-a
INITIAL COND-a
INITIAL CONO-a
INITIAL COND-a
INITIAL COND-a
INITIAL CONO-a
INITIAL COND-a
INITIAL CONO-a
INITIAL COND-a
INITIAL COND-a
INITIAL CONO-a
INITIAL COND-a
INITIAL COND-a
INITIAL CONO-a
INITIAL CONO-a
INITIAL CONO-a
INITIAL CONO-a
INITIAL COND-a
INITIAL COND-a
INITIAL CONO-a
INITIAL CONO-a
INITIAL COND-a
INITIAL COND-a
INITIAL COND-a
ENDATA9A
$$$ DATA TYPE
CARD TYPE
HEADWATER
ENOATA10
$$$ DATA TYPE
REACH CHLORA
1. .0
a. .0
3. .0
4. .0
5. .0
6. .0
7. .0
8. .0
9. .0
10. .0
11. .0
ia. .0
13. .0
14. .0
15. .0
16. .0
17. .0
18. .0
19. .0
ao. .0
ai. .0
aa. .0
a3. .0
24. .0
as. .0
a&. .0
0. .0
10 (HEADWATER SOURCES)
HEADWATER ORDER AND
1 . HDW=OPOSSUM CK
0.
NH3 N(ia
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
sss
IDENI
10A (HEADWATER CONDITIONS FflH
00
00
00
00
00
00
oo
00
00
00
00
00
00
00
00
00
00
00
00
00
00
00
00
00
00
00
00
N03
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
FLOW
3.6
.0
CHLOROPHYLL
PI14 COLI
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
TEMP
9b.O
.0
.NITROGEN,
RAON ORG-N
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
n
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
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-------�
STREAM IUIALITV SIMULATION
IIU»L 11 STREAM IUIALITV RdUTING HIIUFL
• «»< S1EADV STAll SIMULATION ••••*
HID Pill PARF NIIMHFII
UJ
I
Ul
BtH ELI
HUH NlIM
01 15 5
at ib 6
03 15 7
01 15 n
05 15 9
06 Ib 10
07 15 II
OU 15 1?
09 Ib 1
10 Ib 2
II Ib 3
12 Ib 1
\i Ib 5
la ib 6
15 16 7
Ib Ib B
17 169
IB Ib 10
19 1611
2U 16 1?
21 16 13
22 17 1
23 17 2
2 11 5
11 11 b
?t> 17 7
P9 17 fl
30 179
31 IB 1
32 IB 2
33 IB 3
34 IH 1
35 ID 5
36 111 6
37 191
3d 19 2
39 193
10 190
HI 195
02 196
01 19 7
04 19 X
45 19 9
Ob 19 10
47 1911
46 19 If
49 at) 1
511 ?0 ?
FROM 10
MILE MILE
25.7 25.5
25.5 2-1.3
25.3 25.1
25.1 20.9
20.9 20.7
20.7 20.5
24.5 21.3
20.3 20.1
20.1 £3.9
33.9 23.7
23.7 23.5
23.5 23.3
?3.3 23.1
23.1 22.9
22.9 22.7
22.7 22.5
22.5 22.3
22.3 23.1
22.1 21.9
21.9 21.7
21.7 21.5
21.5 21.3
21.3 21.1
21.1 ao.9
20.9 20.7
20.7 20.5
20.5 20.3
20.3 an.)
21). 1 19.9
19.9 |9.7
19.7 19.5
19.5 19.3
19.3 19.1
19.1 l«.9
18.9 18.7
18.7 IB. 5
16.5 IB. 3
1 B . 3 1 II . 1
18.1 17.0
17.9 17.7
17.7 11.5
17.5 17.3
If. 3 17.)
17.1 16.9
16.9 lh.7
16.7 16.5
16.5 16.3
lfc.3 16.1
16.1 15.9
IS. 9 15.7
STREAM
FLOW
10J.
103.
143.
140.
104.
104.
100.
140.
144.
140.
100.
145.
105.
105.
145.
105.
145.
105.
106.
106.
106.
106.
106.
146.
106.
106.
10'.
l«7.
107.
l«7.
107.
108.
109.
159.
159.
l'>0.
161.
161.
162.
163.
164.
165.
165.
166.
P. 7.
168.
169.
169.
I/O.
171 .
HASTE INCH
FLIln FLOW
.11 0.
.0 0.
.0 n.
.0 0.
.0 0.
.0 0.
.0 0.
.0 0.
.0 1).
.0 0.
.0 0.
.0 0.
.11 0.
.0 0.
.0 0.
.0 n.
.0 0.
.0 0.
.1) 0.
.0 0.
.0 0.
.0 0.
.0 0.
.0 0.
.0 0.
.0 n.
.0 0.
.0 0.
.0 0.
.0 0.
.0
.0
.0
9.7
.1)
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.1) .
.0
. II
51HEAM
VFL
(FI'S)
.90
.94
.90
.95
.95
.95
.95
.95
.73
.73
.73
.74
.70
.70
. '4
.70
.70
.70
.74
.70
.70
.01
.01
.01
.02
.02
.oa
.02
.02
.02
.70
.70
.70
.70
.74
.70
.63
.63
.63
.64
.64
.64
.60
.60
.65
.65
.65
.65
.SO
.Ml
SIRt AM
nt.flU 1EM1
(M) DtK
.92 7S.OO
.9? 75.00
.92 75.00
.92 75.00
.92 75.00
.95 75.00
.93 75.00
.93 75.UO
2.32 75.00
a. 32 75.00
?. 32 75.00
2.32 75. UO
a. 32 75.00
?.32 75.00
a.3a 75.00
2.32 75.00
2. 32 75.00
?.32 75.00
2.33 75.00
2.33 7b.OO
a. 33 75.00
.60 7b.0fl
.60 75.00
.60 75.00
.60 75.00
.60 75.00
.60 75. (in
.60 75.00
.60 75.00
.60 75.00
.ao 75.00
.35 75.110
.a5 75.00
.32 75.00
.33 75.00
.53 75.00
a . n 3 75.0(1
2.H4 75.00
a. 84 7S.OO
2.P5 75.00
2.85 75.00
2.B5 75.110
P. Kb 75.110
2.66 75. '0
2.87 7S. 10
2.87 75.10
?.B6 75. 10
2.88 75. Ill
1.SII 7S. Ill
1)11 Kill)
(MR/I.) (MR/LI
7. on n.ii
7. HI 4.09
7.90 O.DA
7. 'II 0.116
7.«2 4.00
7.91 0.02
7.90 0.00
7.94 3.98
7.90 3.96
7.95 3.94
7.91 J.9I
7.90 3.S9
7.K9 3.17
7.88 1.115
7.86 3.82
7. 115 3.81)
7.84 3.71
7.B1 3.76
7.P2 5.71
7.8| 3.71
7.00 J.69
7. HO 1.68
7.79 3.67
7.79 3.66
7.7« 5.65
7.77 J.64
7.77 1.61
7.76 3.62
7.76 3.61
7.75 J.bO
7.75 .1.59
7.70 3.57
7. 75 5.56
7.77 3. SI
7.76 S.O'I
7.75 1.0«
7.74 J.07
7.71 5.16
7.72 5. '11
'.71 5.03
.70 3. '12
.69 5.41
.t-'l ».!•*
.Ml 3.JH
. '• 7 4 . J 1
.66 3.56
.66 5.5'l
.6'"' 5.15
.'>'! 1.
-------�
SIREAM IIIIALITT 3IMIILAIION
QUAL II 31HEH DUALITY RlltlllUi; HllllfL
»••• SIEADV STATE SIMIILAIIUN • •««•
IIUII'MT l'Ai;i-
o
UJ
U)
o\
HLM FLT
NUM NU»
|5|
152
153
1 54
155
156
157
150
159
160
161
162
163
164
165
166
167
166
169
170
1 71
172
173
171
I7b
176
177
178
179
180
181
182
183
184
I8b
186
187
I8U
189
190
111
|92
193
194
I9b
196
197
190
199
200
ao
ao
20
ao
20
20
an
ao
20
20
ai
i*l
21
21
21
ai
ai
21
21
21
aa
aa
aa
aa
aa
23
23
as
as
23
23
23
as
23
23
as
as
21
21
24
24
24
24
ai
2^,
as
25
25
25
a5
3
1
5
6
7
8
9
10
| |
| f
\
2
3
4
5
6
7
8
9
l n
I
a
3
q
5
1
a
3
4
S
6
7
8
9
10
It
ia
i
a
3
i
5
6
7
1
a
3
4
5
f.
FMUH
MILE
15.7
15.5
15.3
15.1
|1.9
14.7
14.5
14.3
14.1
1 3.9
13.7
13.5
13.3
13.1
ia.9
ia.7
12.5
12.3
12.1
11.9
11.7
11. S
11.3
11.1
10.9
10.7
10.5
10. S
10.1
9.9
9.7
9.5
9.3
9. 1
U.9
a.7
8.5
6.5
a.i
7.9
7.7
7.5
7.3
7.1
6.9
6.7
6.5
6. 3
6.1
'i.9
IU
MILE
15.5
15.3
15.1
11.9
11.7
11.5
14.3
14.1
13.9
11.7
13. S
I 3.3
13.1
12.9
12.7
ia.5
ia.3
i a . i
11 .9
11.7
11.5
11.3
11. 1
10.9
10.7
10.5
10.3
10. 1
9.9
9.7
9.5
9.3
9. I
8.9
8.7
8.5
B.3
8.1
7.9
7 .7
7.5
7.3
7.1
6.9
6.7
6.5
6.3
b. 1
5.9
5.7
STREAM
FLOW
i?a.
172.
173.
174.
175.
176.
176.
177.
178.
179.
100.
180.
181.
iaa.
183.
184.
184.
185.
IB6.
187.
187.
187.
187.
iaa.
180.
too.
108.
188.
iaa.
188.
188.
1811.
188.
1811.
189.
189.
217.
217.
an.
217.
ai7.
an.
aia.
ais.
ait>.
218.
218.
218.
218.
218.
STREAM STKT.AM
KASTt INCH Vtl Ijtl'TH
FLIJrt FLI
.0
.0
. l>
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
rt IFP'S)
.50
.50
.51
.51
.51
.51
.51
.51
.5a
,sa
.75
. 76
.76
.76
.76
.77
.77
.77
.77
.0 1 . .77
.0 0. .55
.0 0. .55
.0 0. .55
.0 0. .55
.0 0. .55
.0 0. .24
.0 0. .24
.0 0. .21
.0 0. .24
.0 0. .24
.0 0. .24
.11 fl. .24
.0 0. .24
.0 o. .as
.0 0. .25
.0 o. .as
28.0 0. .28
.11 0 . .11
.n n. .n
.0 0. .11
.0 0. .11
.0 0. .11
.0 0 . .11
.0 II . .11
.0 n. .07
.0 0 . .07
.0 0 . .07
.0 0. .07
.11 fl. .07
.0 0 . .07
(1 1)
3.59
5.60
3.60
3.61
3.61
1.62
3.62
3.65
3.63
3.64
a. 85
2.83
2.84
2.84
2.85
2.05
2.85
2.86
2. 86
a. a;
3.01
3.0|
3.01
3.0|
3.01
7.50
7.50
7.50
7.50
7.50
7.50
7.50
7.50
7.50
7.50
7.50
7.50
11.60
1 1 .60
1 1 .60
II. 60
1 1 .60
II .60
1 1 .61
13.41
13.41
13.4(
13.40
11.41
13.41
1 ( Ml'
Oil
.1 IIM-'U llllr'-N
rjll <.-!•* rill-M CM). A
utii (MG/I ) (MG/L) IMI;/I. ) (MI./L) cir, /i ) . 76
.6h
. hh
. 66
.66
.65
.65
.6b
.65
.65
.6'!
.61
.61
.64
.64
.6 5
.65
.65
.63
.63
.62
.62
.62
.62
.62
.62
.62
.62
.62
.62
.62
.62
.62
.6^
.62
.62
.62
.56
.S6
.56
.56
.56
.56
.56
.56
.56
.56
.Sh
.5S
,5h
.5h
.1 1
.1 1
.1 1
. 1 1
.1 1
.1 1
. ID
.10
.10
. 10
.10
. 10
.10
.10
.10
.10
.10
. 10
.10
.10
.10
. 1 n
. 10
.10
.10
.in
. 1 n
. in
. i n
. 10
.10
.10
.10
.III
. 1 n
. 10
.09
.09
.09
.09
.09
.09
.09
.09
.09
.!)«
.08
.08
.08
. Ill*
3. 55
3.55
5. 52
5.31
3.29
3.28
3.27
3.26
3.24
1.25
3.22
3.21
3.20
3.18
3.17
3.16
3.15
3.14
3.1 5
3.1 1
3.11
3.11
3.11
3. 10
3.10
3.10
3. Ill
3.10
5. Ill
5.10
3.09
1.09
3.09
5.09
3.09
3.09
2.74
2.74
2.74
2.74
2.74
2.73
2.73
2.73
2.75
2.73
2.7 3
2.7 5
2.7 5
2.7 5
.62
.02
.61
.61
.61
.60
.611
.60
.60
.59
.59
.59
.59
.50
.58
.58
.58
.57
.57
.57
.57
.57
.57
.57
.57
.56
.56
.56
.56
.56
.56
.56
.56
.56
.56
.51.
.87
.87
.87
.87
. 8 t
.HI
.07
.87
.H7
.87
.117
.H7
.87
.87
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.on
.no
.00
.00
.00
.(in
.no
.00
.00
.00
.00
.on
.no
.00
.00
.00
.no
.00
.00
.00
.00
.00
.00
.no
.no
.110
.no
.no
.no
.00
.00
.00
1 1 IL 1
H 4
MI'.M) (I'C/
0 ,
0.
0.
0.
0.
0.
0.
0.
0 .
0 .
0.
0.
0.
II.
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0.
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0.
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0.
0.
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0.
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-------�
STREAM tlUALITY SIMULATION
GUAL II STREAM QUALITY ROUTING MOUEL
***** STEADY STATE SIMULATION *****
OUTPUT PARE NUMHEK
RCH ELT
NUM MUM
0
1
CO
CO
1
— •
"^
01
02
03
04
05
06
07
108
109
! 1 0
'11
!I2
.'13
>1 4
J15
*16
217
218
219
220
221
222
223
224
225
25
25
25
25
25
25
25
25
25
25
25
26
26
26
26
26
26
26
26
26
26
26
26
26
26
7
8
9
10
11
12
13
14
15
16
17
1
2
3
4
5
6
7
8
9
10
11
1?
13
14
FROM
MILE
5.7
5.5
5.3
5.1
4.9
4.7
4.5
4.3
4.1
3.9
3.7
3.5
3.3
3.1
2.9
2.7
2.5
2.3
2.1
.9
.7
.5
.3
.1
.9
TO
MILE
5.5
5.3
5.1
1.9
4.7
4.5
4.3
4.1
3.9
3.7
3.5
3.3
3.1
2.9
2.7
2.5
2.3
2.1
1.9
1.7
1 .5
1.3
1.1
.9
.7
STREAM WASTE
FLOW
218.
218.
218.
218.
218.
218.
219.
219.
219.
219.
219.
219.
219.
219.
219.
219.
219.
219.
219.
219.
219.
220.
220.
220.
220.
FLOW
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
STREAM
INCR VEL
FLOW
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
(FPS)
.07
.07
.07
.07
.07
.07
.07
.07
.07
.07
.07
.04
.04
.04
.04
.04
.04
.04
.04
.04
.04
.04
.04
.04
.04
STREAM
DEPTH
(FT)
13.40
13.40
13.40
13.40
13.40
13.40
13.40
13.40
13.40
13.40
13.40
14.00
14.00
14.00
14.00
14.00
14.00
14.00
14.00
14.00
14.00
14.00
14.00
14.00
14.00
TEMP
DO
nno
NH3-N
JIIP-N
NOi-N
P04-P CHL A
COLI RA
DEG (MG/L) (MG/L) (MG/L) (Mii/L) (MG/L) (MG/L) (UG/L) (MPN) (PC/
75.00
75.00
75.00
75.00
75.00
75.00
75.00
75.00
75.00
75.00
75.00
75.00
75.00
75.00
75.00
75.00
75.00
75.00
75.00
75.00
75.00
75.00
75.00
75.00
75.00
7.58
7.56
7.54
7.52
7.51
7.49
7.48
7.16
7.45
7.43
7.42
7.40
7.37
7.35
7.32
7.30
7.28
7.26
7.24
7.?2
7.?0
7.19
7.17
7.15
7.09
2.73
2.71
2.68
2.65
2.62
2.60
2.57
2.54
2.52
2.49
2.47
2.43
2.39
2.35
2.32
2.28
2.24
2.20
2.17
2.13
2.09
2.06
2.03
1 .99
1.95
.56
.56
.56
.56
.56
.56
.56
.56
.56
.56
.56
.56
.56
.56
.56
.56
.56
.56
.56
.56
.56
.56
.56
.56
.55
.08
.08
.08
.08
.08
.08
.08
.08
.00
.08
.08
.08
.08
.08
.08
.08
.08
.08
.08
.08
.08
.08
.08
.08
.08
2.73
2.73
2.73
2.72
2.72
2.72
2.72
2.72
2.72
2.72
2.72
2.72
2.72
2.72
2.72
2.72
2.72
2.72
2.7
2.7
2.7
2.7
2.7
2.7
2.69
.87
.87
.87
.87
.87
.87
.87
.87
.87
.87
.87
.86
.86
.86
.86
.86
.86
.86
.86
.86
.86
.86
.86
.86
.85
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
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SIHEAM UUAI.II> SIMIM A I HIM
DUAL II STRtA'1 UUALllr HIIIIIIMG M(IIJ[(_
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03.9
03.7
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03. 3
03.1
02.9
02.7
02.5
42.3
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41.9
01.7
01.5
01.3
01.1
00.9
00.7
40.5
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19.9
39.7
39.5
39.3
39.1
10.9
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37.9
37.7
37.5
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36.7
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III RFAI't 1)1. C»» OFCAY DECAY ||FC»Y GUdWIH KF SI'H PUT. -N III-CAY
MILS (I/OY) (I/DY) (I/DY) (I/in) (1/llY) (I/Oil (1/llY) (fli/U ('lli/ll (
05.5
05.3
05.1
40.9
00.7
00.5
00.5
45.9
03.7
03.5
41.3
01.1
02.9
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42.5
02.3
02.1
01.9
01.7
01.5
41.3
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00.9
00.7
00.5
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59.9
39.7
39.5
39.3
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58.3
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57.9
37.7
37.5
37.3
37.1
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36.7
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36. 1
35.9
55.7
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4.05
0.02
5.99
3.96
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4.00
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4.00
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5.50
3.50
0.79
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6.00
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b.OB
b.OB
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6.01
5.99
5.99
5.99
5.99
5.99
5.99
5.99
5.99
5.99
5.99
0.55
3.11
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STREAM DUALITY SIMULATION OU1IMII PAf;E NIJMilER
(JUAL II STREAM QUALITY ROUTING MODEL
• ••*• STEADY STATE SIMULATION • • • • •
U>
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RtH ELT
NUM NUM
SI
sa
53
54
55
56
57
50
59
60
hi
62
63
(•4
65
66
6?
68
6V
70
71
12
73
71
75
76
77
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79
80
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82
83
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86
87
Bb
89
9V
91
92
93
94
95
96
97
90
99
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9
9
9
9
10
10
10
10
10
10
10
II
II
II
II
II
II
II
II
12
12
12
12
12
12
12
12
12
13
13
13
13
13
13
13
13
13
13
13
13
13
13
14
14
14
14
15
15
15
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2
3
a
1
2
3
4
5
6
7
1
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3
4
5
6
7
8
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4
5
6
7
8
9
1
2
3
4
5
6
7
A
9
10
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12
13
14
1
2
3
4
1
2
3
4
FROM
MILE
35.7
35.5
35.3
35.1
31.9
34.7
34.5
34.3
34.1
33.9
33.7
33.5
31.3
33.1
32.9
32.7
32.5
32.3
32.1
31.9
31.7
31.5
31.3
11. 1
30.9
3U.7
30.5
30.3
30.1
29.9
29.7
29.5
29.3
29.1
20. 9
20.7
28.5
28.3
28.1
27.9
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27.5
27.3
P7.I
26.9
26.7
26.5
26.3
26.1
25.9
OXYGEN KUO NH3 N02 CIlLI ALKAF ALKAE IIIIG-H
TO KEAIR DECAY DECAY DECAY DECAY GRMWIH flESPH (IRG-N DECAY CON-I MCN I'HKNIIL
MILE (I/DY) (I/OY) (l/Ot) (I/DY) tl/UV) (I/OY) (I/I)Y) (Mfi/L) CMG/LJ IMG/I.) (MR/L)
6.36
6.36
6.36
4.42
2. 47
2.47
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2.47
a. 47
a. 47
a. 47
a. 47
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a. 47
a. 47
a. 47
a. 47
J.77
5.07
5.07
5.07
5.07
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5.07
5.07
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STHE'M QUALITY SIMIILAMMN
(IIIAL II SlltfAM DUALITY HIIUTINi;
>.<. STEADY SIATt SIMULATION «•
IMilHIII I'»C,E IJIIMIII-W
0
co
CO
I
HtH ELT
NUM rillH
101
102
103
101
105
106
107
IOB
109
no
1 1 1
1 12
113
1 10
115
1 16
117
1 1 8
1 19
120
121
122
123
12"
125
126
127
126
129
110
131
112
113
110
135
13b
137
1 18
139
10
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02
13
11
15
16
07
lid
1 19
150
I s
I 5
15
15
15
15
15
15
16
Ib
Ib
16
16
16
16
16
16
16
16
16
16
17
17
1 7
17
17
17
17
17
1 7
in
16
IB
10
Ib
lu
19
19
19
19
19
19
19
19
19
19
19
19
20
20
5
h
7
B
9
10
1 1
12
1
2
3
1
5
6
7
8
q
10
1 1
12
1 3
1
2
3
-------�
SI REAM QIJALIIY SIMIILMIUN
UUAL II STHKAM |JIJ*LIIY HOOTING MODEL
• >*•• STEADY STATE SIMULMIUN «••••
UllTPIir I'AGk NIIMHFH
o
oo
•
CO
I
ro
RCM ELT
NUH NIIM
51
52
53
SO
55
56
5»
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59
60
hi
62
65
64
65
66
67
68
69
70
71
72
73
74
75
76
77
7H
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no
XI
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83
HI
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87
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90
91
92
13
94
95
96
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70
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JO
70
20
70
?0
20
20
20
71
21
21
21
21
21
21
21
21
21
?2
22
22
22
22
23
23
23
23
23
21
23
23
23
23
23
23
24
24
24
24
24
74
24
25
25
2b
25
25
75
3
4
5
*
7
A
9
10
II
12
1
2
3
A
5
6
7
A
9
10
1
2
3
a
5
1
2
J
4
5
h
7
H
9
10
II
12
|
2
3
4
5
6
7
1
2
1
4
5
b
FHII'1
MILE
15.7
15.5
15.3
15.1
14.9
14.7
14.5
14.3
14.1
13.9
13.7
13.5
13.3
13.1
12.9
12.7
12.5
12.3
12.1
11.9
II. 7
1 1 .5
1 1.1
1 1 .1
10.9
10.7
10.5
10.3
10.1
9.9
9.7
9.5
9.3
9.1
H.9
H.7
6.5
8.3
n.i
.•>
.7
.•>
.t
.1
6.1
6.7
6.5
6. S
d.l
5.9
OXYGEN Him NH3 N07 COL 1 ALG»f ALf.AE IIHK-H
TO REMR DECAY I)EC«Y DFC*Y DECAY GIIIIHTII HFSPH PUG-M I1F.CAY
riiN-i
IICN PHFWIL
MILE (1/iiY) (i/nv) (i/uY) (i/ov) (l/iiv) (i/nr) (I/IIYI (MI; /i) 6
.S6
.S6
.56
.56
.Sf.
.110
.00
.00
.00
.00
.00
.00
.00
.00
.no
.00
.00
.00
.on
.00
.00
.00
.00
.00
.no
.no
.on
.00
.00
.00
.00
.00
.00
.00
.00
.no
.00
.00
.00
.00
.00
.no
.00
.00
.00
.00
.00
.00
."0
.00
.00
.00
.on
.00
. "0
.021
.021
.071
.021
.021
.0?|
.020
.020
.020
.020
.020
.020
.020
.020
.020
.020
.020
.020
.019
.ni9
.019
.019
.019
.019
.019
.011
. ii n
.011
.019
.ni9
.019
.019
.019
.019
.0)9
.019
.017
.017
.01 7
-0|7
.017
.017
.017
.017
.017
.017
.01 7
.017
.017
.«! 7
.004
.004
.004
.004
.004
.004
.oni
.004
.on 3
.nnj
.001
.001
.005
.00)
.001
.003
.003
.003
.003
.001
.001
.00 J
.001
.on2
.007
.00?
.002
.no2
.002
.00?
.00?
.on2
.002
.002
.002
.001
.001
.001
.001
.001
.001
.011
.001
.nni
.001
.001
.1)011
,ono
.1100
.into
(MC/L)
.007
.nor
.007
.1107
.007
.007
.007
.00)
.00)
.007
.1)06
.1101.
.006
.006
.006
.006
.006
.006
.006
.006
.006
.006
.006
.001,'
.006
. 006
.1106
.006
.006
.006
.uni,
.006
. 001)
.006
.(Kill
. 00(>
.OOh
.006
. 006
.006
.006
. 0 0 (t
.OOh
.006
.006
.006
.006
.01)11
.001.
.11 Of.
-------�
SIRE*M DUALITY SIMULAMUN
IIUAL II STREAM QUALITY ROUTING MOUFL
• •••• STEADY STATE SIMULATION
OUTPUT PAGE MIINItEK
OJ
I
rvj
ro
RCH ELT
NUM MUM
20 1
202
203
201
205
206
207
20B
J09
2 \ 0
2ii
?I2
3 1 3
7 I 4
3 1 b
>I6
a 1 7
? 1 e
M9
?20
>2i
?22
?23
?24
!25
25
25
25
25
25
25
25
25
25
25
25
26
26
26
26
26
26
26
26
26
?b
26
26
26
26
7
fl
9
10
1 1
12
i ;
1 1
15
16
IT
1
2
3
'1
5
6
7
n
9
|0
| |
12
13
H
FHI1M
MILE
5.7
5.5
5.3
5.1
0.9
0.7
1.5
1.3
1. 1
J.9
3.7
3.5
3. J
3.1
2.9
2.7
2.5
2.3
2.1
.9
.7
.5
.3
. |
.9
(1XTGFN
HI HFAIH
IIOU
DECAY
NH3 Nfi? CIJLI AL<;AE ALG«E iwr,-
-------�
o
I
co
t
co
ro
CO
15.000
M.SflO
12.001)
10.500
••.000
0.0. 7.son
(MG/L)
6.000
3.000
1.500
I
.onox---
so.oo
*** * *** if *
X
XX «•
• X X
a xx
X • X
* xx
X
15.00 HO.00 J5.00
50.00 2S.OO ?0.00
KlVfh flit Til HF»U I'F rfF»CH
1'i.uO 10.00
5.00
(•) = I. AI.CH1 A IF H HATA, (X) = 4f A SIIIVF n OAIA
-------�
JO.OOOX-
I
I
I
in. ooo*
I
I
Ih.OOO*
1
I
I
lo.ooo*
i
I
[
I
ta.ooot
' B.o.n. 10.000*
I (MG/U I
I »
I
8.000* X
I X
b.OOO* «
I
I x *
I » . X
1.000* * * •
1 * *
I ...
1 *
I
J.OOO*
I
I
I
I X
.000* * •* • » * « « + » * * * * *
so.00 15.00 ao.oo ^s.oo 10.uo ps.no po.oo is.mi
KIVEW MIL I" 111 HFAI) HF MFftfH
(•) = CAlCHLAKn titlt, (X) = '•FASIICFII IIAI4
-------�
CO
CO
I
ro
en
5.000*-
1.500
4.000
i.SOO
1.000
ORGHUIC-N 2.500
CMG/U
2.000
1.500
1.000
.ooox—
50.00
• > K
*
1C X
x
•« *
» * * A
* * *
05.00 HO.OO
3b.OO 10.00 ?S.l'0 Pil.DO l-i.od
UlVlk Mil . F. Ill HFAI) IIF aln.lt
TII.OO
.110
!•) = C«ICIM»HIP
HAIA
-------�
5.000
o
i
CO
CO
I
ro
en
UHl
(MG/L)
3.000
2.000
1.500
1 .OHO
.0011
5II.UO
X X
X »
as.oo oo.oo ib.oo in.no p1)."" ?I'.IMI is.on
HtVFH MILf 111 t-FOII (IF IIFIPH
5.00
<«) = CMCIILAlKl OA1A, (X) = "ll
-------�
-•500
O
I
CO
•
co
i
ro
.'100
NOZ
(MR/I)
.300
.aso
.zoo
.tso
.100
.050
.000
50.00
* «
15.00 00.00
50.00 ?S.(PO PO.nO IS.00 10.011 S.OO
H\VfU MILF Tl> HF/kl) OF 4FAOI
(») = fMCllLAII.I) DATA. (XJ r -iF A SIMVI-.H
-------�
o
i
CO
I
ro
CO
s. out
a.quo
N03 2.800
(MG/L)
a.210
1.6RO
1.120
-.ooox—
50.00
X K
• X »2
15.00 00.00 3S.OO
10.00 ?S.on ?«.«n
HIVKH MHf TO MFAfl OF UF *TH
IS.on in.oo
.00
(«) = C»iriJl.MEIl H«TA, (XI z MF4SHHKI1
-------�
a
CO
co
i
ro
PHOS.
(MG/L)
1.000* «-
.9110
.flOO
.TOO
.500
.100
.100
.aoo
.100
X • *
.OOOX * KX-X--K-X-X*
50.00 05.00 00.00
A * ft
* * *
# * *
-* + 4 «-
^0.00 PS. MO ?II.OO Ib.OO
-------�
o
CO
CO
I
CO
o
HCN
(Mfi/L)
.337
.OOOX
Ml.00
• XX
* • X
X
* X
X«X X
15.00 10.00
?5.00 Itf.OO ?5.ljO ?u.OO 15.00
HIVFtv WTL6 TU MF An OF HKACH
(•) = cticiiLtitn HAH, (x) = MEAsnue"
-------�
APPENDIX D-4
MODEL VERIFICATION
-------�
• •** INPUT OATA LISTING FOR THE OUAL II STREAM QUALITY ROUTING Mflor.L ****
S$$ (PROBLEM TITLES) $$S
O
CARD IYPE
TITLF01
TITLEO?
TITLE03
TITLFOil
T1TLE05
TITLE06
TITUE07
TITLE08
TITLE09
TITLE10
TITLE1I
TITLE12
TITLEU
TITLEld
TITLE I 5
TITLE16
FNOTITLE
YES
YES
YES
NO
YES
NO
YES
YES
YES
YES
YES
YES
NO
NO
OUAL II PROGRAM TITLFS
ArtARE (JUAL-IT WITH HCN AND PHENOL
NAME OF BASIN = VALLLY-OPOSSUM CRELK
CONSERVATIVE MINERAL IN MG/L
HYDROGEN CVAiMlOE IN MG/L
PHENOL IN MG/L
TEMPERATURE IN DEGREES FARENHE1T
BIOCHEMICAL OXYGEN DEMAND IN MG/L
ALGAE AS CHL A IN MG/L
PHOSPHOROUS AS P IN MG/L
ORGANIC NITROGEN IN MG/L
AMMONIA NITROGEN IN MG/l.
NITRITE NITROGEN IN MG/L
NITRATE NITROGEN IN MG/L
DISOLVEO OXYGEN IN MG/L
COLIFORMS AS MPN
RADIONUCLIDE
$$$ DATA TYPE I (CONTROL OATA) $$$
CARO TYPE
LIST OATA INPUT
PLOTS PRINTER
NO FLOW AUGMENTATION
STEADY STAT.E
NUMBER OF REACHES =
NOM OF HEAOrtATERS -
TIME STEP (HOURS) =
MAXIMUM ROUTE TIME (HHS)=
ENOATA1
.00000
.00000
.00000
.00000
36.00000
1.00000
.00000
30.00000
.00000
CARD TYPt
COMPLETE REPORT
METRIC
NUMHER OF JUNCTIONS :
NUMBER OF kASTE LOADS :
LNUI. COMP. ELEMENT (MI):
TIME IMC. FOR RPT? (MRS):
.00000
.00000
.00000
.00000
.00000
11.00000
.20000
.00000
.00000
SSSUATA TYPE !A (ALGAF PRODUCTION AND NITROGEN OXIDATION CONST AN IS)$$5
CARD TYPE
0 UPTAKE UY DRG-N (MG 0/MG N) = .0000
0 UPTAKE HY NH3 OXIO(MG 0/MG N)= ?.?30(l
0 PROD. BY ALGAt (M(J 0/MG A) : P.OOOO
N CONTENT OF ALGAE (MG N/MG A) = .OHSO
ALG MAX SPEC IjWOWTO RATE(l/DAY)= 2.0000
U HALF SATUKATIOM CONST. (MG/L)= .3000
LIGHT HALF SAT CONST ILNGLY/MIN)= .1ttOO
MCN TEMP COEF = 1 .0000
tiMDATAlA .0000
CARD TYPE
MINIMUM PtAKRATIO'J COM.STAHjl (1PT= .(HUM)
0 MP1AKI- HY MO? OXIDC1G 0/MG N)= 1.1100
ii UPTAKE UY ALGAF (MG O/MI, A) = i.sooo
P CUNIENT OF 4LGAH. (MG P/MG A) = .0130
AI.GAK RHSPTRATION RATt (I/DAY) = .1(100
I5 HALF SATURATION CONST. (MG/L)= .0100
TI'TAL OAH.Y RAI1IA T THNd.AMGLf YS) = SOO.OOOO
PhENOL TEMP CHEF = 1.0000
.0000
-------�
SSS DATA TYPE 2 (REACH IDENTIFICATION) $?,$
I
ro
CARD TYPF
STREAM REACH
STREAM REACH
STREAM REACH
STREAM REACH
STREAM REACH
STREAM REACH
STREAM REACH
SlREAM REACH
STREAM KEACH
STREAM REACH
STREAM REACH
STREAM REACH
STREAM REACH
STREAM REACH
STREAM REACH
STREAM REACH
SlREAM REACH
STREAM REACH
STREAM REACH
STREAM REACH
STREAM REACH
STREAM REACH
STREAM REACH
STREAM REACH
STREAM REACH
STREAM REACH
ENOATA2
$$$ DATA TYPE
CARD TYPE
ENDATA3
REACH URPiER AMD IDENT
1 .0
2.0
3.0
1 .0
5.0
6.0
7.0
>1.0
9.U
10. 0
1.0
2.0
3.0
0.0
5.0
6.0
17.0
18.0
19.0
20.0
21 .0
22.0
23.0
21.0
25.0
26.0
.0
RCH =
RCH =
RCH =
RCH =
PCH =
RCHr
RCHr
PCH =
WCH =
RCH =
RCII=
RCHr
RCH =
RCH =
RCH =
RCH =
RCH =
RCH =
RCH =
RCH =
RCH =
RCH =
RCH =
RCH =
RCH =
RCH =
3 (TARGET LEVEL DO
REACH
0.
FRUM
FRUM
FRUM
FROM
FRUM
FROM
FROM
HRI.pki
HVliM
FRUM
FRUM
FRUM
FRUM
FRUM
FRUM
FRUM
FROM
FROM
FRUM
FRUM
FRUM
FRUM
FRUM
FRUM
FROM
FROM
AND FLOW AUGMENTATION
AVAIL HOWS TARGET
0. .0 0.
«5 . 7
HU .S
m.»
'12.°
Ur' .S
'42.1
UO . 1
W."
. 1
1 5.7
11.7
I 0.7
ft. 3
6.9
3.5
.7
.0
-------�
$$$ OAIA TYPC U (ClIMHIITA f IONAL KEACH FLAG FULD) SI
O
I
-fi.
I
CO
tAHl)
FLAG
FLAG
FLAG
FLAG
FLAG
FLAT,
FLAG
FLAG
FLAG
FLAG
FLAG
FLAG
FLAG
FLAG
FLAG
FLAG
FLAG
FLAG
FLAG
FLAG
FLAG
FLAG
FLAG
FLAG
FLAG
FLAG
TYPE
FIELO
FIELD
FIELO
F IELO
FIELO
FIELO
FIELO
FIELO
FIELD
FIELO
FIELO
FIELO
FIELO
FIELO
FIELO
FIELO
FIELO
FIELD
FIELO
FIELD
FIELD
FIELD
FIELD
FIELD
FIELD
FIELD
kFACH ElEMENI
1
2
3
n
5
6
7
n
9
10
1 1
12
15
14
15
lh
17
IP
19
20
21
22
23
21
25
2f>
ENOATAO
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
6.
3.
5.
?..
2.
10.
11.
1 I .
1.
7.
fl.
<».
1«.
«.
1?.
M.
9.
6.
t?.
I?.
1 0.
5.
1?.
7.
17 .
I'l.
n.
.8.2,
.2.2.
.2.6,
.6.0.
.6.0,
.2.2,
.2.2,
.2.2,
.2.2,
.2.2,
.2.2,
.2.2,
.2.2,
.2.2,
.2.2,
.2.2,
.2.2,
.2.2,
.?.2,
.2.2
.2.2,
.2.2
.2.2
.2.2
.2.2
.2.2
. 0 . (I
2.2
0.0
2.2
0.0
0.0
6.2
2.2
2.2
6.0
2.2
2.2
2.2
2.2
2.0
2.2
2.2
2.2
6.2
2.2
2.2
2.2
2.2
2.2
2.2
2.2
2.2
0.0
coMt'UTAi HINAL
,2.0.0.0.0.0.0,
,0.0.0.0.0.0.0,
.0.0.0.0.0.0.0,
,0.0.0.0.0.0.0,
,0.0.0.0.0.0.0,
.2.2.2.6.2.0.0
,2.2
.0.0
,2.2
,2.2
,2.2
,2.2
,0.0
.2.2
.2.2
.2.2
.2.0
.2.2
.2.2
.2.2
.0.0
.2.2
.2.2
.2.?
.2.2
.0.0
2.2
0.0
0.0
2.0
2.2
2.2
0.0
2.2
2.2
2.2
0.0
2.2
2.2
2.2
0.0
2.2
0.0
2.?
2.2
0.0
.0.0.0
.0.0.0
.0.0.0
.0.0.0
.2.2.2
.0.0.0
.2.?.2
.2.2.2
.0.0.0
.0.0.0
.2.2.2
.2.2.2
.2.0.0
.0.0.0
.2.2.6
.0.0.0
.2.2.2
.2.2.2
.0.0.0
FLAGS
o.o.o,
o.o.o.
o.o.n.
o.o.n.
o.o.o.
o.o.o.
o.o.o.
o.o.o,
o.o.o.
o.o.o,
0.0.0.
0.0.0.
?.2.0.
0.0.0,
o.o.n,
2.0.0,
o.o.o,
0.0.0,
0.0.0,
0.0.0,
0.0.0,
0.0.0,
,0.0.0
,0.0.0
P.2.2
2.2.0
,0.0.0
0.0
0.0
0.0
0.0
0.0
0.0
o.o
0.0
0.0
0.0
0.0
0.0
0.0
0.0
0.0
0.0
0.0
0.0
0.0
0.0
0.0
0.0
0 .0
0.0
2.2
0.0
0 .0
.0.0.0.
.0.0.0.
.0.0.0.
.0.0.0.
.0.0.0.
.0.0.0.
.0.0.0.
.0.0.0.
.0.0.0.
.0.0.0.
.0.0.0.
.0.0.0.
.0.0. l».
.0.0.0.
.0.0.0.
. 0 . o . n .
.0.0.0.
.0.0.0.
.0.0.0.
.0.0.0.
. 0 . 0 . (I.
.0.0.0.
. 0 . 0 . 0 .
. 0 . II . 0 ,
.0.0.0.
.0.0.0.
.0.0.0.
-------�
DATA TYPE 5 (HYDRAULIC CUEFF 1C 1EN18 FfJK DETERMINING VFU.1CITV »UD llbPTH) '(.*$
O
I
CARD 1YPF.
HYDRAULICS
HYDRAULICS
HYDRAULICS
HYDRAULICS
HYDRAULICS
HYDRAULICS
HYDRAULICS
HYDRAULICS
HYDRAULICS
HYDRAULICS
HYDRAULICS
HYDRAULICS
HYDRAULICS
HYDRAULICS
HYDRAULICS
HYDRAULICS
HYDRAULICS
HYDRAULICS
HYDRAULICS
HYDRAULICS
HYDRAULICS
HYDRAULICS
HYDRAULICS
HYDRAULICS
HYDRAULICS
HYDRAULICS
ENDATA5
REACH
1 .0
2.0
3.0
1.0
5.0
f>.()
7 .0
h . d
9.0
10.0
1 1.0
12.0
1 3.0
I'l.O
15.0
16.0
17.0
1H.O
19.0
20.0
21.0
22.0
?3.0
21.0
25.0
26.0
.0
CUtFUV
0910000
0910000
0910000
0910000
0479900
("179900
0331700
0 1 1 Or' II II
0370800
0215800
0206200
0185100
0312900
0520600
.0339300
.0262500
,0359600
,0216500
.0209700
,0160200
,0232800
,0165200
,001 3000
.0001926
,0003210
,0001950
,0000000
h XHfll.IV
.6700
.670(1
.6700
.670 0
.6700
. t> 7 0 0
» ^ 7 0 0
.(-. /OO
.6700
.6700
.6700
.6700
.6700
.6700
.6700
.6700
.6700
.6700
.6700
.6700
.6700
.6700
1.0000
1.0000
1.0000
1 .0000
.0000
CHLFOH
.170 0
.170 0
. 1 7 0 0
.1700
.5171
. it 7 1
.513?
. •-> i '/ 'i
.1119
.579?
.5591
.671?
.3708
.2711
.3737
.1195
.3090
.6211
.5299
.6571
.510?
.6266
7 .5000
1 1 .6000
13.1000
11.0000
.0000
t Xf'fhJH
.1300
. 1100
. 1300
. 1 300
. 1 1llO
. 3300
« 130(1
. •> '.IMI
.3300
.3300
. 3300
. 5300
.3300
.3300
.3300
.3300
.3300
.3300
. 3300
.3300
. 3300
.3000
.000 0
. 0 0 0 0
.0000
.0000
.0000
l>i A N M
.0100
.0100
. 0 1 0 0
. 0 1 0 0
. d 100
. ii 'ioo
. I1 100
. II '! II 0
.0-100
.0100
.0100
.0100
.0100
.0100
.0100
.0100
.0100
.0100
.0100
.0100
.0100
.0100
.0100
.010 0
. 0 1 0 0
.0100
.0000
-------�
tS$ DATA TYPE 6 (REACTION COEFFICIENTS FUR DEUXYftENAT KIN AMO REAERAIIUN) $SS
O
I
cn
CARD TYPE
REACT
REACT
REACT
REACT
REACT
RHACT
REACT
REACT
REACT
REACT
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CARD TYPE WASTE LOAD ORDER AND TOENT EFF
WASTFLOAO
WASTfcLOAO
WARTFLOAO
f.ASIFLUAD
WASTFLOAO
kVASTFLOAO
WASTFLOAD
WASTELOAD
WASTELOAD
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ro WASTFLOAD-2
WASTELOAD-2
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WASTELOAO-2
WASTELOAO-2
WASTELOAO-2
WASTELOAO-2
WASTELOAO-2
WASTELOAO-2
WASTELOAO-2
ENOATA11 A
WSL= US STEEL .00
WSL= KUPPERS .00
WSL = WOODWARD I RUN .111'
ivSL= VAI.LlY LK. .(M.I
WSL= STORM StwtR .00
WSL= U.S. PIPE .00
WSL= SMALL CK. .00
WSL= HALLS CK. .00
WSL= VALLEY STP .00
WSL= UNNAMED CK. .00
. WSL= 5-MILE CK. .00
WSL= BIRMINGHAM HIDE .00
WSL= ROCK CK. .00
WSL= MUD CK. .00
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11A (WASTE LOAD CHARACTERIST
COLIFORMS AND RA010NUCL
WASTE LOAD ORDER AND IDENT
1. WSL= US STEEL
2. WSL= KOPPFRS
3. WSL= WOODWARD IRON
1. WSL= VALLEY CK.
5. rtSL= STORM SfWER
6. WSL= U.S. PIPE
7. WSL= SMALL CK.
8. WSL= HAI.LS CK.
9. WSL= VALLEY STP
10. WSL= UNNAMEO CK.
11. WSL= 5-MILE CK.
12. WSL= BIRMINGHAM HIDE
13. WSL= ROCK CK.
11. WSL= MUD CK.
0.
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35.0
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SIRIAM HIIALIK SIMIILAIIUN
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FROM
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45.7
45.5
45.3
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44.9
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43.9
44.7
43.5
43.3
43.1
42.9
42.7
42.5
42.3
42.1
41.9
41.7
41.5
41.3
41.1
40.9
40.7
40.5
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39.9
39.7
39.5
39.3
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45.5
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44.9
44.7
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42.9
42.7
42.5
42.4
42.1
41.9
41 .7
41.5
41.3
41.1
40.9
40.7
40.5
40.3
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19.9
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39.5
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4.18
4.34
4.29
2.85
2.85
2.85
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STHEAM UIIALITr 3IMIILAIION
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• «••• STEAD* STATE SIMULATION •••••
IllltPUl I'AGt IJIII-mlM
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HUH NIIM
51 9 1
Sa 9 2
51 9 3
54 9 4
55 10 1
56 102
57 10 3
58 10 4
59 105
60 IU 6
61 IU 7
62 II 1
61 1 1 2
64 II 3
65 1 1 4
66 II 5
67 116
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69 II 8
70 ia 1
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72 ta 3
73 ia 4
74 13 5
75 126
76 127
77 12 B
78 12 9
79 11 1
80 132
81 13 3
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87 119
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91 13 13
92 13 14
93 14 1
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95 14 1
96 14 4
97 15 1
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99 15 3
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35.7
35.5
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31.9
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55.5
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32.9
12.7
12.5
32.3
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31.9
31.7
31.5
31 .3
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30.9
30.7
30.5
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29.9
29.7
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28.7
28.5
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27.7
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STHEAM
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237.
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3 IKE AM SI 1(1 AM
WASTE INCH VI- L OFPTH TFHI' (HI Him
FLOW FLOW (FPS) (FT) DEC, IMC/l) (Mli/L)
.0 0. 1.45 a. 52 75.00 5.11 17.94
.0 0. 1.45 2.52 75.00 5.10 17. (17
.0 0. 1.45 2.52 75.00 5.09 17.80
.0 0. 1.45 2.52 75.00 5.08 17.73
.0 0. .84 1.52 75.00 5.07 17.61
.11 0. .84 1.52 75.00 5.05 17.51
.0 0. .84 5.52 75.00 5.04 17.19
.0 0. .84 3.5a 75.00 S.03 17.27
.0 0. .84 1.52 75.00 5.02 17.15
.0 0. .84 3.52 75.00 5.0a 17.01
.0 0. ,A4 3.52 75.00 5.0| 16.91
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.81 3.4| 75.00 5.02 16.60
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.81 3.4| 75.00 5.04 16.29
.81 3.42 75.00 5.04 16.14
.82 3.42 75.00 5.05 15.99
.8? 3.41 75.00 5.06 15.84
.82 3.43 75.00 S.07 15.70
.74 4.14 75.00 5.24 15.55
.74 4.15 75.00 5.52 15.40
.74 4.15 75.00 5.77 15.24
.74 4.15 75.00 5.99 15.10
.75 4.16 75.00 6.17 14.95
.75 4.16 75.00 6.31 14.80
.15 4.17 75.00 6.47 14.66
.75 4.17 75.00 6.59 14.52
.75 4.18 75.00 6.69 14.18
.27 2.35 75.00 6.71 14.29
.28 2.35 75.00 6.72 14.21
.28 2.35 75.00 6.72 14.13
.28 2.36 75.00 6.71 14.06
.28 2.36 75.00 6.70 13.99
.29 2.36 75.00 6.70 15.91
.29 2.36 75.00 6.69 13.84
.29 2.37 75.00 6.69 11.77
.29 2.17 75.00 6.69 11.70
.10 2.37 75.00 6.68 1 1.63
.10 2.37 75.00 6.68 13. '16
.30 2.38 75.00 6. 68 13.49
.11 2.38 75.00 6.68 J.42
.31 ?. J8 75.00 6.67 1. !5
.18 1.71 75. 10 6.70 1.29
.19 1.73 75. 10 6.74 1.24
.!» 1.73 75.00 6.78 i . 1 9
.20 1.74 7S. lO 6. HI 1.14
.41 2.16 75. lO 6.86 1.H9
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(nr,/L)
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.75
.72
.72
.71
.71
.70
.70
.61
.68
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.67
.66
.66
.65
.65
.64
.63
.65
.62
.61
.61
.60
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.59
.58
.58
.57
.57
.57
.56
.56
.56
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.54
.54
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. 52
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.26
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.10
.10
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.12
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.35
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.36
.36
. 36
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S1HEAM DUALITY SIMIILAflllN
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1 0 | IS 5
102 IS 6
103 IS 7
104 IS 8
105 IS 9
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101 IS 1 1
108 IS 12
109 Ib 1
110 16 2
III Ib 3
112 Ib 4
113 Ib 5
114 Ib 6
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lib Ib 8
117 Ib 9
1 IB Ib 10
114 Ib 1 1
120 16 ia
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122 17 1
123 17 2
124 17 3
125 1) 4
126 17 5
127 17 6
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130 II 9
131 IB 1
132 18 a
113 IB 3
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135 III S
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11) 14 1
138 19 2
139 19 3
140 19 4
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142 19 h
143 14 7
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148 14 1?
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20.1
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20.9
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362.
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S1HEAM SIHt AM
WASTt INCH VfL lit I1 III UMP IMI 1)1111
FLOW FLOW (FPS) (FT) lltG (Mf./l ) (Hr./L)
.0 1. .45 2.37 75.00 7.02 12.85
.0
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.45 7.57 75.00 7.06 12. /4
.45 3. 38 75.00 7.04 12.7)
.as 2.3« 75.00 7.13 12.67
.46 2.58 75.00 7.16 12.61
.46 2.311 75.00 7.18 12.55
.46 2.39 75.00 7.21 12.50
.47 3.39 7S.OO 7.25 12.44
.14 2.88 75.00 7.25 12.38
.14 3.88 75.00 7.19 13.31
.14 2.88 75.00 7. IS 12.35
.14 3.88 75.00 7.13 12.10
.15 2.89 75.00 7. OB 12.12
.15 2.89 75.00 7.05 13.05
.15 2.89 75.00 7.0? 11.99
.15 2.40 75.00 b.44 11.43
.15 2.40 75.00 6.Q6 11.87
.16 3. 40 75.00 6.43 11.40
.16 2.90 75.00 6.40 11.74
.16 a. 41 75.00 b.HB 11.68
.16 2.9| 75.00 6.BS 11.62
.60 2.00 75.00 6.84 11.58
.60 2.00 75.00 6.82 II. ia
.60 2.01 75.00 h.80 11.51
.61 3.01 75.00 6.79 11.47
.61 2.01 75.00 6.77 11.43
.61 2.01 75.00 6.76 11.40
.62 2.01 75.00 b.74 11.36
.62 3.01 75.00 6.73 11.53
.62 2.02 75.00 6.71 11.29
.11 4 . 0 a 75.00 6.70 1 1 . 26
.11 4.08 75.00 6.67 11.21
.12 4.08 75.00 6.65 11.17
.ab 4.34 75.00 6.86 10.94
.37 4.34 75.00 6.8S 10.41
.27 4.15 7S.OII 6.85 10.87
.08 3.64 75.00 6.81 10.83
.08 5.70 75.011 6.74 10.79
.08 5.70 75.00 6.7B 10.75
.09 3.70 75.00 6.76 1 0 .'7 1
.09 5.71 75.00 6.74 10.66
.09 3.71 75.00 6.73 10.6?
.04 3.71 75.00 6.71 10. bH
.09 3.72 75.00 6.70 O.VI
.10 5.72 75.011 6.6H n.SO
.10 3.72 75.00 6.67 n.'!6
.10 3.73 7S.OO 6.66 0.42
.10 3.71 75.00 6.6S U.1B
, fta a.6i 7S.no 6.61 11.14
.115 4.63 7S.UO b.62 II. 2 u
iJIH-N
(Hli/L)
.50
. 44
.44
.411
.48
,4H
.17
.41
.46
.46
.45
.4S
.44
.44
.44
.43
.41
.42
.42
.41
.41
.41
.40
.40
.40
.19
.39
.39
.39
.38
.SB
.18
.37
.31
.30
. 10
.30
.30
.29
.24
.24
.2H
.2H
.?H
.2'!
. 2 1
.? 1
.27
.27
.21-
NI|?-N
(MG/L)
.54
. 34
. 34
.sa
. 55
. 55
. 55
.55
.5?
.32
.32
.32
.31
.31
.31
. 11
. 10
.30
.30
.50
.24
.24
.29
.39
.29
.28
.28
.28
.?8
.28
.27
.27
.22
.22
.2?
.2?
.22
.21
.21
.21
. 2 1
.21
.;-o
. 21
.21
.r>l
.21
.21
. 1'
Ullt-N
(MG/I. I
3.5A
3.57
1.57
3. 57
1.57
5.57
5.57
5.56
3.56
3.56
S.56
5.56
3.56
3.56
3.S6
1.56
1.S6
3.55
3.55
3. 55
3.55
3.55
3.55
3.54
1.54
5.54
3.54
3.51
3.51
1.51
3.51
5.53
3.94
2.44
2.44
?. 4 4
2.44
2.4/1
2.44
3.95
2.91
2.41
2. .1
2 . 1
2. 1
2. 1
p ^
2.4 (
',43
PII4-P
(MU/L)
.68
.68
.bB
.68
.68
.67
.67
.67
.b7
.b7
.66
.66
.66
.66
,bb
.65
.bS
.65
.65
.65
.65
.64
.64
.64
.64
.64
.63
.61
.61
.65
.63
.6?
.52
.5?
.5?
.52
.51
.51
.51
.51
-SI
.51
. bl
.50
.50
.50
.SO
.SO
.SO
CHL A
tllG/l )
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.on
.00
.00
.no
.00
.00
LIU I
(HP-ill
0.
u.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
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0 .
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0.
0.
0.
0.
0.
0.
0.
0.
0.
1) .
0.
0.
0 .
0.
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0.
-------�
SCREAM OIIALIU SIMULATUIN
IIUAL II STREAM UIIALIU RnillING MODEL
• "*•• SIEAOV SIATE SIMULATIIIN ••>•>
(IUIPIII PAGE HIIMIII-H
O
I
CT>
RCH ELI
HUM HUM
51
52
51
54
55
St>
57
58
59
60
61
62
63
64
65
66
67
611
69
70
71
72
71
74
75
76
11
78
79
80
81
Bf?
83
84
Bb
86
87
88
89
90
9t
92
93
94
95
.96
.Q7
.98
|99
?00
20
20
20
20
2U
20
20
20
20
20
21
21
21
21
21
21
21
21
21
21
22
22
22
22
22
23
23
23
23
23
23
23
23
23
23
23
23
24
24
24
24
24
24
24
25
25
25
2b
25
25
3
4
5
6
7
8
9
10
II
12
|
2
3
4
5
6
7
8
9
10
1
2
1
4
5
1
2
3
4
5
6
7
8
9
10
II
12
1
2
3
4
•y
6
7
1
2
3
4
5
6
FHOM
MILE
15.7
15.5
15.3
15.1
14.9
14.7
14.5
14.3
14.1
13.9
II. 7
13.5
13.3
13.1
12.9
12.7
12.5
12.3
12.1
11.9
II.'
11.5
11.3
II. 1
10.9
10.7
10.5
10.3
10. 1
9.9
9.7
9.5
9.3
9. 1
8.9
8.7
8.5
8.3
8.1
.9
.7
.5
.3
.1
.9
.7
6.S
6.3
6.1
5.9
TO
MILE
IS. 5
15.1
IS.I
14.9
14.7
14.5
14.1
|4.|
13.9
13.7
13.5
13.3
13.1
12.9
12.7
12.5
12.3
12.1
II .9
11.7
11.5
11.3
II. 1
10.9
10.7
10. S
10.3
10. 1
9.9
9.7
9.5
9.1
9.1
8.9
8.7
8.5
8.1
6.1
7.9
7.7
7.5
7.3
7. 1
6.9
6.7
6.5
6.3
6.1
5.9
•>. 1
SIREAM STRtAM
STREAM HASIE INCH VtL UEPTH
FLOW FLOW FLOW (FPS)
373. .0
374. .0
1)5. .0
376. .0
377. .0
178. .0
179. .0
1BO. .0
3B|. .0
182. .0
383. .0
384. .0
385. .0
386. .0
3B7. .0
3B8. .0
189. .0
390. .0
.85
.85
.85
.85
.85
.85
.86
.86
.86
.86
.25
.26
.26
.26
.26
.26
.27
.27
391. .0 1. .27
392. .0 1. .27
392. .0 0. .90
192. .0 0. .90
192. .0 0. .90
392. .0 0. .90
392. .0 0. .90
392. .0 0. .51
392. .0 0. .51
192. .0 0. .51
192. .0 0. .51
192. .0 0. .51
392. .0 0. .51
392. .0 0. .51
392. .0 0. .51
192. .0 0. .51
192. .0 0. .51
39J. .0 U. .51
412. 20. U 0. .54
412. .0 0. .20
412. .0 0. .20
412. .0 0. .20
412. .1) 0. .20
412. .0 0. .20
412. .0 0. .20
4IS. .0 0. .20
412. .0 0 . .11
412. .0 0. .11
412. .0 0. .11
412. .0 0 . .11
412. .0 0 . .11
III f . .0 0 . - 1 '
If 1)
4.64
4.64
4.65
4.65
4.66
4.66
4 . 66
4.67
4.67
4.68
1.63
3.64
3.64
3.64
3.65
3.65
3.65
3.66
3.66
3.66
3.76
3.76
3.76
3.76
3.76
7.50
7.50
7.50
7.50
7.50
7.50
7. SO
7.50
7.50
7.50
7.50
7.50
1 1 .60
1 1 .60
II .60
1 1 .60
II .60
1 1.60
1 1 .60
1 1.40
11.40
13.40
13.40
1 1.40
I « . ii ii
IE HP
DO
II tf, (HB/1.)
75.00
75.00
75.00
75.00
75.00
75.0"
75.00
75.00
75.nO
75.00
75.00
75.00
75.00
75.00
75.00
75.00
75.00
75.00
75.00
75.00
75.00
75.00
75.00
75.00
75.00
75.00
75.00
75.00
75.00
75. UO
75.00
75.00
75.00
75.00
75.00
75.00
75.00
7S.OII
75.00
75.00
75.00
75.00
75.00
75.00
75.00
75.00
75.00
7S.OO
7 S . 0 (1
7 S . I'll
6.60
6.S9
6.57
6.56
6.55
6.54
6.52
6.51
6.50
6.50
6. SI
6.54
6. 57
6.60
6.63
6.66
6. 68
6.71
6.74
6.76
6.01
6.92
7.01
7.09
7.16
7.21
7.21
7.20
7.19
7.19
J.I8
7.18
7.17
7.17
7.16
7.16
'.19
7. IB
7.15
7.12
7.09
7.06
7.01
7.«l
6.9H
6.93
6 . "9
6.«5
6.81
*. . 7 «
HOl) rilli'N N02-N
Mlll-N P04-P CHL A
(MG/L) MB/LI (Mli/L) ( 10 /I ) (Ml, XL) (1
10.24
10.20
1 1) . 1 S
10.11
10.06
10.02
9.97
9.91
9. 88
9.84
9.80
9.77
9.74
9.70
9.67
9.64
9.61
9. SB
9.55
9.52
9.51
9.50
9.49
9.49
9.48
9.47
9.45
9.44
9.41
9.41
9.40
9.39
9. 17
9. 16
9.15
9.13
9. 15
9.31
9.30
9.26
9.2 1
9.20
9. 16
9.11
9.09
9.04
8.99
fl.9'1
11.19
•' - * "
.26
.26
.25
.25
.25
.24
.24
.24
.24
.21
.21
.21
.21
.21
.22
.22
.If.
.22
.22
.22
.21
.21
.21
.21
.20
.20
.20
.20
.20
.20
.20
.211
.20
.20
.20
.20
. 1 9
.19
.19
.19
.19
. 9
. 9
. 9
. 9
. 9
. 9
. 9
. 9
- ''
.19
.19
.19
.19
. 18
.18
.in
.18
.18
.17
.17
.1 1
.1 '
.17
.17
.17
.16
.16
.16
.16
.16
.16
.16
.16
.15
-.15
. 14
.14
.11
.1 1
.12
.11
.1 1
.11
.10
.10
.09
.08
.07
.0)
.06
.OS
.05
.04
.O'l
.01
.01
.02
.02
-"'
2.91
2.91
2.91
2.91
2.91
2.91
2.91
2.93
2.91
2.91
2.93
2.91
2.93
2.93
2.93
2.91
2.92
2.92
2. 92
2.92
2.92
2.93
2.93
2.94
2.94
2.94
2.95
2.96
2.96
2.97
2.97
2.98
2.98
2.99
2.99
1.00
2.86
2.86
2.87
2. ill
2.88
2.89
2.90
2.90
2.91
2.9|
2.92
2.92
2.9?,
•'-'"
.50
.49
.49
.49
.49
.49
.49
.49
.49
.48
.48
.48
.48
.40
.48
-IB
.48
.47
.47
.47
.47
.47 .
.47
.47
.47
.47
.47
.47
.4f
.47
.47
.'17
.47
.47
.47
.47
.45
.45
.45
.45
.45
.45
.45
.45
.'15
.45
.45
.45
.45
_ us
COLI
RA
IG/LI (MCW) (PC/
.00
.00
.00
.00
.00
.no
.no
.00
.00
.00
.no
.00
.00
.no
.00
.00
.00
.00
.00
.00
.00
.00
.00
.ou
.00
.00
.110
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
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.110
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0.
0.
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0.
0.
0.
0.
0.
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0.
0.
0.
0.
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0.
0.
0.
0.
0.
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0.
0.
0.
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0.
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-------�
STREAM IIIIALIK SIMIILAHIIN
DUAL II STREAM QIIAL1TV HHUTING MODEL
••••« STEADY STATt 3IMULAIION • «•••
OUTPUT I'«GE NIIMHEH
O
I
I—"
~-J
RCH ELT
NUM NIIM
201
202
201
204
205
206
207
20tt
209
210
21 1
212
213
214
215
216
217
210
219
220
221
222
223
224
225
25
25
25
25
25
25
25
25
25
25
25
26
26
26
26
26
26
26
26
26
26
26
26
26
26
7
8
9
10
II
12
13
14
15
Id
17
|
2
3
a
5
6
7
8
9
10
11
12
13
1 4
FNflM
HILb
5.7
5.5
5.1
5.1
4.9
4.7
4.5
4.1
4. 1
1.9.
3.7
1.5
3.1
3.1
2.9
2.7
2.5
2.1
2.1
1.9
1.7
1.5
1.1
I.I
.9
TO
MILE
5.5
5.3
5.1
4.9
4.7
4.5
4.1
.1
.9
.7
.5
.3
.1
2.9
2.7
2.5
2.3
2.1
.9
.7
.5
.3
.1
.9
.7
SIUEAM WASTE
FLOW
412.
412.
412.
412.
412.
412.
412.
412.
412.
412.
412.
412.
412.
412.
412.
412.
412.
412.
412.
412.
412.
412.
412.
412.
412.
STKEAM SIHtAM
INCH VEL DEPTH
FLOW FLDW
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
(FPS)
.11
.13
.13
.13
.11
.13
.13
.11
.13
.11
.13
.08
.08
.08
.08
.08
.08
.08
.08
.08
.OB
.OB
.08
.08
.08
(M)
13.40
13.40
13.40
13.40
13.40
1 S.40
I3.4H
13.40
13.40
13.40
11. '10
14.00
14.00
14.00
14.00
14.00
14.00
14.00
14.00
14.00
14.00
14.00
14.00
14.00
14.00
TEMP
IK)
HOI) NIH-N NM2-N
NOJ-M PII4-P CHL A
CULI HA
DIG (MK/L) (MK/L) (HC/L) (MG/L) (Mfi/L) IMG/LI (UG/I ) (MPN) (PC/
75.00
75.00
75.00
75.00
75.00
75.00
75.00
75.00
75.00
75.00
75.00
/5.00
75.00
75.00
75.00
75.00
75.00
75.00
75.00
75.00
75.00
75.00
75.00
75.00
75.00
.74
.70
.67
.64
.60
6.57
6.S4
6. SI
6.48
6.45
6.42
6.38
6.33
6.28
6.21
6.18
6. I'l
6.09
6.05
6.00
5.96
5.92
5.88
5.84
5.76
8.79
8.75
8.70
8.65
8.60
8.56
8.51
K.Hh
U.42
».17
8.32
H.26
8.19
8.11
8.04
(.97
7.90
7.81
7.76
7.69
7.62
7.55
7.48
7.41
7.29
.19
.19
. 19
.19
.19
.19
.19
.19
.19
.19
.19
.19
.19
.19
.19
.19
.19
.19
.19
.19
.19
.19
.19
.19
.19
.01
.01
.01
.01
.01
.01
.01
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
2.91
2.9}
2.93
2.93
2.94
2.94
?.94
2.9U
2.94
2.94
2.94
2.94
2.94
2.94
2.94
2.94
2.94
2.94
2.94
2.94
2.94
2.94
2.94
2.94
2.92
.45
.45
.45
.45
.45
.45
.45
.45.
.45
.45
.45
.45
.45
.45
.45
.45
.45
.45
."5
.45
.45
.45
.45
.45
.45
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
1).
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
-------�
SIKEAM UIIALITV SIMULATION
DUAL II a(REAM DUALITY ROUTING MOUEL
OUTPUT PAKE
• •«•• Sit.Kit STATE SIMULATION •>•••
o
I
-F»
I
t—«
00
Rtll ELT
NUM NUM
1 1 1
d 1 2
3 1 3
4 | 4
5 1 5
b 1 6
7 2 1
822
923
10 3 1
11 32
12 33
13 14
1435
IS 41
Ib 4 2
17 51
us;
19 6 1
20 b 2
21 b 3
22 b 4
23 b 5
24 b b
25 b 7
2b b 8
27 6 9
2b b 10
29 7 1
30 7 2
31 7 3
32 7 4
33 7 5
34 7 6
35 7 7
36 7 a
37 7 9
3a 710
39 711
4u a i
4i a 2
42 B 3
43 a 4
4485
45 8 b
16 B 7
47 B 8
46 8 9
49 U 1 0
50 Hll
FHUM
MILE
45.7
45.5
45.1
45.1
44.9
44.7
44.5
44.3
44.1
43.9
43.7
43.5
43.3
43.1
42.9
42.7
42.5
42.3
42.1
41.9
41.7
41.5
41.3
41 .1
40.9
40.7
40.5
40. 3
40.1
39.9
39.7
39.5
39.3
39.1
38.9
38.7
38.5
38.3
38. 1
37.9
37.7
37.5
37.1
37. 1
3b . 9
16.7
36.5
Jh.l
36.1
35.9
f)»YGEN
TO NEAIR
MILE U/DY)
45.5 5.29
45.3 5.29
45.1 5.29
44.9 5.29
44.7 5.29
44.5 5.29
44.1 5.29
44.1 5.29
45.9 5.29
43.7 5.29
43.5 5.29
43.3 5.29
43.1 5.29
42.9 5.29
42.7 5.29
12.5 5.29
42.1 5.29
42.1 5.29
41.9 7.18
41.7 9.07
41 .5 9.07
41.3 9.07
41.1 9.07
40.9 9.07
40.7 9.07
40.5 9.07
40.3 9.07
40.1 9.07
59.9 9.38
39.7 9.69
39.5 9.69
39.3 9.69
39.1 9.69
18.9 9.69
38.7 9.69
18.5 9.69
18.3 9.69
38.1 9.69
17.9 9.69
37.7 6.23
17.5 2. 78
17.3 2.78
37.1 2.78
36.9 2. 78
36.7 2.78
36.5 2.78
16.3 2.78
16.1 2.78
15.9 2.7B
15. 7 2.7fl
DUD
DECAY
(I/OYI
.48
.48
.48
.48
.46
.48
.4(1
.48
.40
.46
.46
.46
.46
.48
.46
.48
.46
.48
.48
.48
.48
.48
Nlll N02
UECAY DECAY
U/IIY) (1/IIY)
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.65
.85
.65
.85
.«S
.85
.as
.85
.85
.65
.85
.85
.85
.85
.85
.85
.00 2.39
.00 2.39
.00 2.39
.00 2.39
.00 2.39
.00 2.39
.46 .00 2.39
.48
.48
.48
.48
.48
.48
.48
.48
.46
.48
.46
.48
.48
.46
.46
.'IB
.48
.48
.48
.48
.46
.48
.46
.48
.46
.46
.40
.00 2.39
.00 2.39
.00 2.39
.00 2.39
.00 2.39
.00 2.39
.00 2.39
.00 2.19
.00 2.39
.00 2.39
.00 2.39
.00 2.19
.00 2.39
.00 2.39
.00 2.39
.00 2.19
.4]
.43
.41
.43
.4]
.4!
.43
.45
.45
.45
.4 1
I.W5
1.65
1 .85
I.H5
I.S5
1.85
1 .85
1.85
1 .US
1 .HS
1 . fS
CHLI Ai r,»E
UECAY UIIIIWHI
(I/DY) tl/flY)
.00 .00
.00 .00
.00 .00
.00 .00
.00 .00
.00 .00
.00 .UO
.00 .00
.00 .00
.00 .00
.00 .UO
.00 .00
.00 .00
.00 .00
.00 .00
.00 .00
.00 .00
.00 .00
.00 .00
.00 .00
.00 .00
.00 .00
.00 .00
.00 .00
.00 .00
.00 .00
.00 .00
.00 .UO
.00 .00
.00 .00
.00 .00
.00 .00
.00 .00
.00 .00
.00 .UO
.00 .00
.00 .00
.00 .UO
.00 .00
.00 .uo
.00 .00
.00 .00
.00 .00
.00 .00
.no .uo
.00 .00
.00 .00
.00 .00
.00 .00
.00 .bo
AIGAE lll(i;-M
BESPH lllir.-N UFCAY
(I/DY) (HfJ/L) (I-K./LI
.00 1.10 .00
.00 i.ll .00
.00 1.06 .00
.00 3.01 .00
.00 2.96 .00
.00 2.92 .00
.00 2.88 .00
.00 2.64 .00
.00 2.80 .00
.00 2.66 .00
.00 2.65 .00
.00 2.12 .00
.00 2.10 .00
.00 2.29 .00
.00 2.27 .00
.00 2.16 .00
.00 2.15 .00
.00 2.05 .00
.00 2.04 .00
.00 2.02 .00
.00 2.00 .00
.00
.00
.00
.00 "
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.Oil
.00
.01)
.00
.00
. no
.97 .00
.95 .00
.94 .00
.92 .00
.90 .00
.79 .00
.77 .00
.75 .00
.73 .00
.71 .00
.69 .00
.67 .00
.56 .00
.54 .00
.53 .00
.SI .00
.50 1.00
.46 1.00
.41 .SO
.12 .SO
.'10 .50
.18 .50
.56 .^U
. »5 .so
.13 .50
.12 .50
. 10 .5(1
.ft .50
.^l .so
CiiN-l
(Mli/L I
.762
.096
.094
.O'M
.088
.086
.084
.082
.060
.071
.071
.058
.057
.056
.055
.010
.010
.028
.028
.028
.028
.026
.028
.02H
.028
.026
.026
.026
.02b
.026
.026
.026
.026
.021
.019
.019
.019
.019
,0|9
.017
.017
.017
.017
.017
.017
.017
.017
.HI 7
.017
.(il /
HCri
(HK/L)
.015
.065
.063
.060
.058
.056
.054
.052
.050
.042
.034
.026
.021
.017
.014
.015
.015
.015
.015
.015
.015
.015
.014
.014
.014
.014
.014
.014
.014
.014
.014
.014
.011
.015
.015
.015
.014
.014
.014
.015
.OM
.014
.014
.011
.013
.01 1
.012
.012
."12
.HI/*
PIIFNHL
(MU/L)
.001
.001
.001
.001
.001
.001
.00)
.00)
.001
.001
.001
.004
.004
.004
.001
.010
.010
.009
.010
.010
.010
.010
.010
.010
.010
.010
.009
.009
.009
.009
.009
.009
.009
.on
.Oil
.011
.Oil
.Oil
.011
.010
.010
.010
.010
.010
.010
.010
.010
.010
.010
.010
-------�
STHEAh JIIALIIY 31MIILAIIIIN
HllAL II S1REAM QUALITY MnilllNG MllllFL
..... STEAD* SHU SIMULA! HIM .....
nilll'lll I'Atf MIMIILH
HUM tLi
MUM NIIM
51 9 1
52 9 2
53 9 3
54 9 4
55 ID 1
56 IU 2
57 10 3
Sb 10 4
59 IU 5
60 10 6
61 10 7
62 II 1
63 II 2
64 || 3
65 II «
66 11 5
67 116
68 II 7
69 11 8
70 12 1
71 122
72 12 3
73 124
74 125
75 12 6
76 12 7
77 12 8
78 12 9
79 M 1
80 M 2
81 Ml
82 1)4
83 1)5
84 136
85 137
86 138
87 134
80 M 10
89 Mil
90 M 12
91 Ml)
92 M |4
93 14 1
94 14 2
95 14 3
96 14 4
97 15 1
98 15 2
99 15 3
I Ob 15 '1
FHUM
MILE
35.7
35.5
35.3
35.1
34.9
34.7
34.5
34.1
34.1
33.9
33.7
33.5
33.)
33.1
32.9
32.7
32.5
32.)
32.1
31.9
31.7
31.5
31 .1
31.1
30.9
30.7
30.5
30.3
30.1
29.9
29.7
29.5
29.3
29.1
28.9
28.7
28.5
28.)
28.1
27.9
27.7
27.5
27.1
27.1
26.9
26.7
26.5
26.!
26.1
25.9
ro
MILE
35.5
35.3
|5. |
34.9
14.7
)4.5
14.)
34.1
13.9
J3.7
33.5
33.3
33.1
12.9
32.7
32.5
32.3
32.1
31.9
31.7
31.5
11.3
31.1
30.9
30.7
30.5
30.3
30.1
29.9
29.7
29.5
29.3
29.1
28.9
28.7
28.5
28.3
28.1
27.9
27.7
27.5
27.3
27.1
26.9
26.7
26.5
26. 1
26.1
25.9
?5.7
OXYGEN
KEAIR
(1/DY)
3.11
3.45
3.45
3.45
3.4i
3.45
3.45
3.45
3.45
3.45
3.45
3.45
3.45
3.45
3.45
3.45
3.45
3.45
3.45
6.69
9.9)
9.9)
9.93
9.9)
9.93
9.93
9.95
9.93
7.23
4.5)
4.53
4.5)
4.5)
4.5)
4.53
4.53
4.5)
4.5)
4.5)
4.5)
4.5)
4.5)
6.49
n . 45
8.45
8.45
8.45
H.45
B.45
8.45
HUD NH3 NII2
DtCAY DECAY DECAY
(I/DY) (I/UY) tl/DY)
.48 .4) .85
.Of .43 .85
.48 .4) .85
.4B .4) .85
.48 .4) .85
.48 .4) .85
.48 .43 .85
.48 .43 .85
.48 .4) .85
.48 .43 .85
.48 .43 .85
.48 .43 .85
.48 .43 .85
.48 ./|) .85
.48 .43 .85
.'18 .43 .H5
.48 .43 .85
.48 .4) .85
.48 .43 .85
.48 .43 .85
.48 .43 .85
.48 .4) .85
.48 .4] .85
.48 .43 .85
.48 .4) .85
.4R .4] .85
.48 .4) .P5
.48 .4) .85
.56 ,4J .H5
.36 .43 .85
.36 .43 ,H5
.36 .43 .85
.36 .43 .85
.36 .43 .85
.36 .43 -K5
.36 .4) .H5
.36 .43 .85
.36 .43 .85
.36 .4) .85
.16 .43 .85
.16 .43 .85
.16 .43 .85
.56 .96 .85
.16 .96 .85
.36 .96 .85
.36 .96 .85
.16 .9fc .05
.36 .96 .85
.16 .96 .85
.16 .96 .l'5
CIILI
DECAY
(I/I'V)
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.no
.00
.00
.00
.00
.00
.00
.no
.no
.00
.00
.00
.00
.00
.00
.00
ALliAF
GMUHlh
(I/DV)
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.on
.00
.on
.00
.on
.no
.00
.00
.00
.00
.00
.00
.0(1
.00
.00
.00
.00
.00
.00
.00
.00
.on
.00
.on
.on
.on
.00
.00
.on
.110
.00
.110
.00
.no
.00
.00
.00
ALGAE
HESPH OIIG-N
(I/DV) (MG/L)
.00 .26
.no .25
.00 .25
.no .24
.00 .24
.00 .2)
.00 .22
.00 .21
.00 .20
.00 .19
.00 .18
.00 .17
.00 .17
.00 .16
.00 .15
.00 .14
.00 .13
.no ,t?
.no .11
.no .10
.no .09
.00 .08
.00 .07
.00 .07
.on .06
.00 .05
.00 .04
.00 .03
.00 .02
.Oil .02
.00 .01
.01) .01
.00 .00
.nn .00
.00 .99
.00 .99
.on .99
.no .98
.on .9n
.no .97
.no .47
.no .96
.no .46
.Oil .96
."'I . *6
.Oil .46
.no .46
.no .46
.nu .46
.110 .46
IIHt-N
DECAY
(.4G/I. )
.50
.50
.50
.50
.511
.5n
.50
.50
.511
.50
.50
.50
.50
.50
.50
.50
.50
.50
.50
.5(1
.50
.50
.50
.50
.50
.50
.50
.50
.50
.50
.50
.511
.5(1
.50
.50
.50
.50
.50
.SO
.511
.50
.5"
.Oil
.00
.no
.00
.1)0
.nu
.1)1)
.00
CIIN-I
(Mf./L)
.01 7
.017
.017
.017
.017
.017
.017
.n|7
.0)7
.017
.017
.017
.017
.017
.017
.017
.017
.016
.016
.016
.016
.1)16
.1)16
.016
.016
.016
.01'.
.016
.016
.016
.016
.016
.016
.016
.016
.n|6
.nis
.015
.ni5
.015
.nis
.nis
.015
.ois
.OIS
.OIS
.015
.015
.OIS
.nis
new
(HC./L)
.oil
.01 1
.nu
.oil
.Oil
.oil
.01 1
.oil
.010
.010
.010
.010
.010
.010
.009
.009
.009
.004
.004
.009
.000
.008
.008
.008
.008
.008
.007
.007
.007
.007
.007
.007
.007
.007
.007
.007
.007
.1)06
.006
.006
. Iflh
. 106
. 1116
. IOI>
. )U6
. )06
. JOb
. I0*i
. 106
. 106
HlltNIIL
(MG/L)
.010
.010
.010
.010
.010
.010
.010
.010
.010
.010
.010
.1110
.010
.010
.010
.OKI
.010
.010
.(Illl
.010
.009
.009
.009
.009
.009
.009
.009
. 0 0 9
.009
.009
.009
.009
.009
.1109
.1109
.009
.009
.009
.009
. 0 II 9
.1104
.1104
.0119
. 009
.009
.009
.004
.009
. II 0 4
.1109
-------�
3IHt»M IIUALIT* SIMULATION
OIIAL II STREAM IIUALITV HUNTING MODEL
• ••>< STEAD* 3TATE SIMULA! KIN «••"•
OUTPUT CAGE NllHIiew
I
ro
O
HCH ELT
HUH NlIM
01 155
02 15 6
03 15 7
04 15 A
05 15 9
Ob 15 10
07 1511
Ott 15 12
04 Ib 1
10 Ib 2
II Ib 3
12 16 4
11 16 5
14 tb b
15 Ib 7
16 Ib A
17 16 9
IB 16 10
19 Ib 11
20 Ib 12
21 Ib 13
22 17 1
21 17 2
24 17 3
25 17 4
26 17 5
27 176
28 17 7
29 If »
30 17 9
31 18 1
J2 18 2
11 IH 1
34 Ib 1
35 185
16 186
37 191
3b 192
39 19 1
40 14 4
41 19 5
42 14 6
43 147
44 19 A
45 19 9
4b 19 10
47 1911
48 19 12
49 20 1
SO ?() 2
f ROM
MILE
25.7
25.5
25.1
25.1
24.9
24.7
24.5
24.1
24.1
2J.9
21.7
21.5
21.1
21.1
22.9
22.7
22.5
22.3
22.1
21.9
21.7
21.5
21 .1
21.1
20.9
20.7
20.5
20.1
20.1
19.9
19.7
19.5
19.1
19.1
18. 4
IS. 7
18. S
18.1
11.1
17.4
11. 1
17.5
17.1
17.1
lb.9
16.7
Iti.'i
16.1
Ib.l
15.4
OXYGEN
Til HEAIH
MILE (1/OY)
25.5 H.45
25.1 A. 45
25.1 A. 45
24.9 fl.45
24.7 A. 45
24.5 A. 45
24.1 8.45
24.1 A. 45
21.9 5.4|
21.7 2.16
23.5 2.3b
23.3 2.36
23.1 2.36
22.9 2.36
22.7 2.36
22.5 2.36
22.3 2.16
22.1 2.16
21.9 2.16
21.7 2.36
21.5 2.36
21 .1 .88
21.1 .40
20.9 .40
20.7 .40
20.5 .40
20.1 .40
20.1 .40
19.9 .40
19.7 .40
19. S .40
19.1 .40
14.1 .40
18.9 .40
|8. 7 .40
18.5 .40
18. 1 .40
la.i .40
17.9 .40
17.7 .40
17.5 .40
17.1 .40
17.1 .40
lb.9 .40
16.7 .40
16.5 .40
16.1 .40
Ib.l .40
15.9 . II 0
IS. 7 .no
Dili)
DECAY
( 1/OY)
.3b
.16
.16
.16
. 16
.16
.36
.16
.16
.16
.16
.36
.16
.16
.16
.16
.16
.16
.16
.16
.16
.24
.20
.24
.24
.24
.24
.24
.24
.24
.24
.24
.24
.24
.24
.24
.24
.24
.24
.24
.24
.24
.24
.24
.24
.24
.24
.24
.21
.?•!
NH3 NII2 CtlLl
DECAY DECAY DECAY
(I/DY) (I/DY) (I/DY)
.96
.96
.96
.96
.96
.96
.96
.96
.96
.96
.96
.96
.96
.96
.9b
.9b
.96
.96
.96
.9b
.9b
.96
.96
.96
.96
.96
.96
.96
.96
.96
.96
.96
.96
.96
. 46
.46
.9b
.96
.96
.96
.96
.96
.91,
.96
.96
.96
.96
.96
.96
.It:
.05 .00
.85 .00
.85 .00
.(15 .00
.85 .On
.85 .00
.85 .00
.85 .00
.»5 .00
.85 .00
.85 .00
.85 .00
.85 .00
.85 .00
.85 .00
.85 .00
.85 .00
.05 .00
.85 .00
.85 .00
.85 .00
.H5 .00
.85 .00
.85 .00
.85 .00
.85 .00
.85 .00
.85 .00
.85 .00
.85 .00
.85 .00
.65 .00
.85 .00
.85 .00
.85 .00
.H5 .00
,«5 .Oil
.K5 .00
.85 .00
.85 .00
,H5 .00
.H5 .00
.85 .00
.85 .00
.H5 .00
.85 .00
.115 .00
.85 .00
. H 5 .00
• " " - " "
ALC.tE ALGAE
GIIOKIH HESPM
(I/IIY) (1/OY)
.00 .00
.00 .00
.00 .00
.00 .00
.00 .00
.00 .00
.00 .00
.00 .00
.00 .00
.00 .00
.00 .00
.00 .00
.00 .00
.00 .00
.00 .00
.00 .00
.00 .00
.00 .00
.00 .00
.00 .00
.00 .00
.00 .00
.00 .00
.00 .00
.00 .00
.00 .00
.00 .00
.00 .00
.00 .00
.00 .00
.00 .00
.00 .00
.00 .00
.00 .00
.00 .00
.00 .00
.00 .00
.00 .00
. 0 0 .00
.00 .00
. I) 0 .00
. I) 0 .00
.00 .00
.1/0 .00
.00 .00
.00 .00
.00 .01)
.no .00
.00 .00
-"" -""
our, -N
(MG/L)
.96
.46
.46
.96
.96
.96
.96
.46
.96
.96
.96
.97
.97
.97
.97
.97
.97
.47
.97
.97
.97
.47
.97
.97
.97
.47
.97
.47
.97
.97
.47
.97
.47
.HO
.80
.81
.81
.81
.H 1
.11
.HI
.81
.HI
.HI
.11
."I
.HI
.11
.11
- H '
uHfi-'<
DECAY
(HI1/L)
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.Oil
.00
. on
.11(1
.00
.00
."0
.00
.'III
.00
.00
.on
. fill
CON- I
(Mi;/L )
.015
.015
.015
.015
.015
.015
.015
.014
.014
.014
.014
.014
.014
.014
.014
.014
.014
.014
.014
.01 4
.014
.014
.014
.014
.014
.014
.014
.014
.014
.014
.014
.014
.014
.01 1
.Oil
.Oil
.Oil
.Oil
.oil
.011
.Oil
.Oil
.oil
.Oil
.01 1
.01 1
.Oil
.01 1
.oil
.nil
MCN
(MG/L)
.006
.006
.005
.005
.001
.005
.005
.005
.005
.005
.005
.005
.005
.005
.005
.005
.005
.004
.004
.004
.004
.004
.004
.004
.004
.004
.004
.004
.004
.004
.004
.004
. 0 (I 4
.001
.001
.001
.003
.00]
.00]
.00 1
.001
.001
.OliJ
.00 i
.00]
.1101
.001
.00 )
.110 4
-""•'
PHENOL
(uc./D
.009
.009
.004
.009
.009
.OOH
.001
.008
.OOH
.008
.008
.OOH
.008
.008
.008
.008
.008
.OOH
.0011
.008
.001)
• .008
.008
.008
.008
.004
.008
.OOH
.0110
.008
.OOH
.008
.OOH
.007
.007
.•006
.006
.OOb
.006
.006
.006
.006
.006
.OOb
.OOb
.006
.Illlh
.006
.0*16
- '""•
-------�
ro
SINEtM DUALITY S|MHL*[I{IN
HIIAL II SIHEAM DIKI.III HOUIINC MODEL
..... SlEAhr SIAIE SIMIILAIION •>•••
OIIIKUI t'AGE NIIMHFR
HCH ELI
NUM NUM
151 20 3
152 20 4
151 20 5
154 20 6
155 20 7
156 20 a
157 20 9
I5a iu in
159 20 ii
160 20 12
161 21 I
162 21 2
163 21 ]
164 21 4
165 21 5
166 21 6
167 21 7
I6B 21 ft
169 21 1
170 21 10
171 22 1
172 22 2
173 22 3
174 22 4
175 22 5
176 23 1
177 23 2
171) 23 3
179 23 4
MID 23 5
I8| 23 6
182 23 7
1 (1 3 23 6
184 23 9
165 23 Id
1B6 23 11
in; 23 12
180 24 1
189 24 2
190 24 3
191 24 4
192 24 5
193 24 6
194 24 7
|9S 25 1
196 25 2
197 25 3
198 25 4
199 25 5
200 25 6
FHOrt
MILE
15.7
15.5
IS. i
15.1
14.9
11.7
14.5
14.)
10. 1
13.9
13.7
13.5
11.3
l).l
12.9
12.7
12.5
12.3
12.1
11.9
11.7
11.5
11.3
1 1. 1
10.9
10.7
10.5
10.3
10. 1
9.9
9.7
9.5
9.3
9.1
8.9
6.7
ft. 5
8. J
8. 1
7.9
7.7
7.5
7. 1
7.1
6.9
6.7
6.5
h.3
6.1
S.9
UXYGEN
ID HEAIH
MILE (l/Dr)
15.5 .40
15.3 .40
15.1 .40
14.9 ..10
14.7 .40
14.5 .40
14.3 .40
14.1 .40
13. •» .40
13.7 .40
13.5 .46
1J.J .52
13.1 .52
12.9 .52
12.7 .52
12.5 .52
12.3 .52
12.1 .52
11.9 .52
II. 1 .52
1 1 .5 4.74
11.3 5.95
11. 1 5.95
10.9 5.95
10.7 5.95
10.5 3.22
10.3 .48
10.1 .48
9.9 .118
9.7 .48
9.5 .48
9.3 .48
9.1 .48
a. 9 .48
A. 7 .48
a. 5 .48
H.3 .49
8.1 .3d
7.9 .16
7.7 .Ifc
7.5 .16
7.3 .16
7.1 .16
6.9 .16
'. . 7 .11
6.5 .10
6.3 .10
6.1 .10
5.9 .10
'i . 7 .10
1100
OECAr
(I/DTI
.24
.24
.24
.24
.24
.24
.24
.24
.24
.24
.24
.24
.24
.24
.24
.24
.24
.24
.24
.24
.06
.06
.06
.06
.06
.06
.06
.06
.06
.06
.06
.06
.Oh
.06
.06
.06
.06
.1)6
.01.
.06
.06
.06
.06
.Of,
.06
.01,
.Oh
.Of.
.06
.06
NII3 NO2 CIILI
OECAr UECAV UECAV
(i/o») (i/ori (i/or)
.96
.96
.96
.96
.96
.96
.96
.96
.96
.9b
.96
.96
.96
.96
.96
.96
.96
.96
.96
.96
.96
.96
.96
.96
.96
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.01)
.on
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.85 .110
.85 .00
.85 .00
.85 .00
.85 .00
.85 .00
.85 .00
.85 .00
.85 .00
.85 .00
.85 .00
.85 .00
.85 .00
.85 .00
.85 .00
.85 .00
.115 .00
,B5 .00
.65 .00
.85 .00
.05 .00
.85 .00
.85 .00
.85 .00
.85 .00
.85 .00
.85 .00
.85 .00
.85 .00
.85 .00
.85 .00
.85 .00
.85 .00
.85 .00
.85 .00
.115 .00
.85 .00
.H5 .00
.»S .00
.H5 .00
. 1) 5 .00
.H5 .00
. « 5 .00
.CS .lid
. « ?> .00
. H'j .00
.HS .00
.85 .00
.85 .00
.8S .00
• lliAF
nHUMlll
d/nr)
.on
.00
.on
.00
.00
.on
.00
.00
.00
.on
.on
.1)0
.on
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.on
.on
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
AlKAE
KE5PK
(i/nr)
.00
.110
.01)
.Oil
.00
.no
.no
.00
.00
.no
.00
.00
.00
.no
.no
.00
.00
.00
.00
.00
.00
.no
.00
.00
.on
.no
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.Oil
.Oil
.00
.on
.00
.no
.00
."U
.00
.00
.Oil
nuc-N
(MG/L)
.81
.81
.81
.HI
.82
.H2
.«2
.«2
.«2
.12
.H2
.112
.•12
.«2
.82
.12
.82
.82
.82
.82
,H2
.82
.82
.02
.82
.H2
.82
.«2
.82
.82
.82
.82
.82
.12
.82
.8?
.If
. '8
.78
.78
.78
. 78
.18
.lit
. 7«
.78
.78
. '»
.IH
. in
IIKK-H
ntCAr
(MG/L)
.0(1
.flu
.00
.00
.00
.00
.00
.Oil
.00
.00
.00
.00
.00
.00
.00
.00
.on
.nn
.00
.00
.00
.00
.00
.00
.00
.00
.00
.no
.00
.00
. no
.00
.00
.1)0
.on
.00
.on
.00
.on
.00
.00
.00
.00
.00
.no
.00
.on
.00
.no
.00
CDN-I
(MG/L)
.Oil
.nil
.01 1
.nil
.nil
.oil
.nil
.nil
.010
.010
.010
.010
.010
.010
.010
.0)0
.010
.010
.010
.010
.010
.010
.010
.010
.010
.010
.nin
.010
.010
.010
.mo
.010
.010
.010
.Oil)
.010
.010
.010
.010
.010
.010
.010
.010
.010
.010
.010
.010
.010
.010
.oin
IICM CIIEtlUL
{rtl./l ) (MG/L)
.On2 .006
.002 .006
.002 .006
.002 .006
.nn2 .006
.002 .0116
.002 .006
.002 .006
.002 .006
.002 .006
.002 .006
.002 .006
.002 .006
.002 .006
.002 .006
.01)2 .006
.002 .006
.002 .006
,002 .not,
.00? ,no6
.002 .006
.002 .006
.002 .006
.002 .OOh
.002 .006
.002 .006
.002 .006
.002 .006
.002 .006
.002 .006
.0112 Io<)6
.001 .006
.001 .006
.001 .006
.00) .006
.001 .006
.001 ,006
.001 .006
.001 .11116
.001 . 1) 0 h
.001 .006
.001 .006
.001 .006
.'ini .006
.001 .OOh
.001 .006
.001 .006
.1101 .006
.001 .006
.00) .006
-------�
STHEAM QIULirr SIMULATION
DUAL II STREAM QUALITY ROUTING HdUfL
«••>• 3IEAOV STATE SIMULATION •••••
OUTPUT PAGE' NIIMHEW
a
-P.
ro
HCH ELT
MUM NIIM
)l
)^
01
04
05
Ob
07
Ob
09
10
11
12
13
ID
15
Ib
17
IB
14
?U
21
12
11
•21
:25
25
25
25
25
25
25
?5
25
25
24
25
26
2b
2b
26
2h
it,
2b
26
2b
?6
26
2b
26
26
7
H
9
10
11
12
13
11
15
Ib
17
1
2
3
a
5
b
7
a
9
in
li
12
13
11
FHIJM
MILE
5.7
S.5
5.3
5.1
1.9
.;
.5
.3
.1
.9
.7
.5
3.J
3.1
2.9
2.7
2.5
2.3
2.1
.9
.7
.">
.3
.1
.9
OXYGEN Him NII] NU2 rui I ALGAE
TO HEAIH DECAY UECAY UECAY DECAY t.UUMIII
ALGAE: IIUG-N
(ESPW (IHG-N UtCM
CIIN-I
"CM PHENIIL
MILE (t/nv) d/nr) (I/OY) (i/nr) (i/i>v) (i/oo (i/in) (MI, /L) IHO/L) IMG/L) (MG/LI
5.5
5. 3
.1
.9
.;
.5
.3
1.1
3.9
3.7
3.S
1.3
1.1
2.9
2.7
2.5
2. I
2.1
.9
.7
.5
.3
. |
.9
.7
.10
.10
.10
.10
.10
.10
.10
.10
.10
.10
.10
.09
.07
.07
.07
.07
.07
.07
.07
.07
.07
.07
.07
.07
.07
.Ob
.Ob
.Ob
.Ob
.Ob
.Ob
.Ob
.Ob
.Ob
.Oh
.Ob
.Ob
.Ob
.Oh
.Ob
.06
.Oh
.Oh
.06
.06
.06
.06
.06
.Ob
.Ob
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.85
.65
.05
.65
.B5
,U5
.65
.65
.65
.65
.65
.65
.65
.65
.85
.65
.65
.65
.65
.85
.05
.B5
.65
.«5
.»5
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.01)
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.78
.78
.78
.78
. 78
.78
.78
.78
.7H
.78
.78
.78
.76
.78
.76
.78
.78
.78
.76
.78
.78
.78
.78
.78
.78
.00
.00
.00
.00
.00
.00
.00
.Oil
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.0(1
.00
.00
.00
.00
.00
.010
.010
.010
.010
.010
.010
.010
.010
.010
.010
.0|0
.010
.010
.010
.010
.010
.010
.010
.010
.0)0
.010
.010
.('10
.010
,0|0
.1100
.000
.000
.000
.noii
.(Hill
.000
.1100
.000
.000
.0110
.000
.000
.0011
.000
.000 .
.1100
.000
.000
.000
.000
.000
.000
.000
.000
(MTi/l.)
.OOb
.uOh
.OOb
.006
.Ulllt
. OOh
.006
.001,
.OOh
.006
.OOb
.OOh
.OOb
.OOb
.0(16
.OOb
.006
.Olio
.006
.006
.006
.OOh
.OOh
.OOb
.006
-------�
15.0001-
I
ro
CO
12.000
10.500
4.000
O.U. 7.500
(MG/L)
6.000
1.500
i.OOU
.000
50.00
ft ft ft
15.00 40.01)
Jo.oo P^.IIO ?
-------�
o
I
•c»
I
ro
-p.
J6.00U
32.1)00
as.ooo
24.000
H.CI.D. 20.000
(MG/L)
16.000
12.000
8.000
.000 --
so. oo
u'j.oo no. on is.oo
30.00 f^.tia ?o.ou
HIVED MRE in HEAD ni- Hfucn
is.oo to. on 5.00 .00
- r»irin«Tei'
-------�
ro
en
5.000K-
4.500
4.000
l.SOO
3.00U
URCANION 2.500
(MU/L)
2.000
1.500
1.000
.000 t « t *
SO.00 '15.00 10.00
S5.00 30. DO ?S.UO 20.00 15.011
MI/EN HUE III Hf«n IIP UK ACM
-»
.110
(•) = C4K.UIAIU) DATA, (X) = MHASlll'tO IIAfl
-------�
5.UOOX-
I
ro
3.000
NH1 i.50
(HG/L)
2.000
I.SCO
I .000
.5011
.000*
50.00
X
'15.00 iio.oo is.oo SD.OII fs.au ?n.ou is.iio
HIVKH MIL! Tl. IlKAO t» HtACII
I 0 .0II 5 . (10
.DO
(•) = LAI mi AI t-ti DATA, (v) = •llA^lll.•[u
-------�
o
ro
.450
.800
.150
1,02
OlG/L>
.100
* *
SO.00 'IS.00 40.00 3S.OO 311.00
IS.ill) 10.00 i.OO .0(1
HlVtl' MILf III HFAI) (IF «F»r.H
(•) = CALCIIIAIFII HATA, (») r MF.ASIIII1.0 HA1A
-------�
IO.OOOK » t-
o
I
ro
00
4.000
a.ooo
l.ooo
6.000
NO! 5.000
(MG/U1
J. 000
2.000
1.000
.000
50.00
***** ** * **
15.00 00. 00 IS. 00
10.00 ?S.OO i>u.on
KIVfH MIE III HtAO IIF
IS.Ol> Hi.oil 5.110
-«
.no
MAT/. . (1) r '^ASIH^D MAM
-------�
t\i
CtcOS.
(HC/L)
I.OOOX-
.400
.800
.roo
.600
.500
.100
.100
.aoo
.100
* • • *
K >< •
•
• X
* • *
.000< • » Xt * « < 1 «--
50.00 15.00 .o<' ?o.uo I1).oo 10.00 b.oo .uo
KIUEK hILK 111 HFAfl tlf [JK<
(•) = CALCIILAltll I'AIA, («) = ..||--A',|
-------�
o
I
-fc.
co
o
HCN
(M6/L)
.130
.117
.101
.000*---
50.UO
15.00 40.00 15.00
311.00 ?'j.dfl ?O.IIO Ih.OO
KIVfH Hllf IU HEAD I1F KtKCH
>
111.01) b.OO
.00
(>) - CALCIIIAUI) DATA, (») = ^r.«Sll»tn DATA
-------�
.050X *-
CO
HMtNUL
IHG/L)
.040
.055
.030
.U25
.020
.010
.000 —
50.00
45.00 40.uo 3*1.00 jo.(10 ^b.no ?U.(MI t^>.on IU.HII s.no
klVFH MILt III lit All III III AC.II
-X
."0
(•) '- L«l Till » II I) |i*l«, (II : -it
n«]A
-------�
APPENDIX D-5.1
MOD EL PROJECT IONS
CONDITION 1
-------�
**** INPUT DATA LISTING FUR IMF. DUAL II S1REAM UIJALITY ROUTING MODEL ****
SSS (PKUULEM TITLES) SSS
O
I
Ol
CARD TYPE
TITLFOt
TITLEO?
TITLE 03
TITLEIM
TITLE05
TITLEuh
TITLF.07
T1TLE08
TITLED1*
TITLE10
TITLE11
TITLE12
TITLE13
TITLE14
TITLE15
TITLE16
ENOTITLE
YES
YES
YES
MO
YES
(Ml)
YES
YtS
YES
YES
YES
YES
MU
NO
OUAL II PROGRAM TITLES
AWARE (JIIAL-II WITH IICN AMD PHENOL
NAME OF BASIN = VALLEY-OPOSSUM CREEK
CONSERVATIVE MINERAL IN MG/L
HYDROGEN CYANIDE IN MG/L
PHkNOL IN MG/L
TEMPERATURE IN DEGREES FARfcNHEIT
BIOCHEMICAL OXYGEN DEMAND IN MG/L
ALGAE AS CHL A IN MG/L
PHOSPHOROUS AS P IN MG/L
ORGANIC NITROGEN IN MG/L
AMMONIA NITROGEN IN MG/L
NITRITE NITROGEN IN MG/L
NITRATE NI1ROGEN in MG/L
DISOLVEU OXYGEN IN MG/L
COLIFORMS AS MPN
RADIUNUCLIDE
$$$ DATA TYPE 1 (CONTROL DATA) SSS
CARD TYPE
LIST DATA INPUT .00000
PLOTS PRINTER .ouooo
NO FLOW AUGMENTATION .00000
STEADY STATE .00000
NUMBER OF REACHES = 36.00000
MUM (IF HEADWATERS = 1.00000
TIME STEP (HOURS) = .00000
MAXIMUM ROUIF TIME (HRS)= 30.00000
EiMOATAl .00000
CARD TYPE
COMPLETE REPORT
METRIC
NUMBER OF JUkCTlONS :
NUMBER OF WASTE LOADS =
LN1H. COMP. ELEMENT (MI):
TIME INC. FOR RPT? (HRS):
.00000
.00000
.00000
.00000
.00000
14.00000
.^0000
.00000
.00000
SSSOATA TYPE 1A (ALGAE PRODUCTION AND NITROGEN OXIDATION CONSTANTS)SSS
CARD TYPE
o UPTAKE HY ORG-N (MG O/MG w) =
0 UPTAKE HY NH1 I)XTU(MG O/MG .M) =
0 PHUD. HY ALGAE (MG O/i-'G A) =
11 CONTENT OF ALGAE (MG N/MG A) =
ALG MAX SPEC GROWTH RATE (1/DAY) =
N HALF SATURATION CONST. (M(4/L) =
LIGHT HALF SAT CUNST(LNGLY/M!M)=
HCN TEMP COEF -
Ei'JDATAl A
CARD TYPE
.0000 MINIMUM REAERATIHIM CONSTANT OPT= .0000
.^300 fl UPTAKE BY NO? OXIO(MG O/MG N)= 1.1100
.oooo (i UPTAKE HY ALGAE (MG O/MG A) = i.sooo
.0850 P CONTENT OF ALGAE (MG P/MG A) = .0130
.OUOO ALGAE RESPIRATION RATE (I/DAY) = .1000
.5000 P HALT SATURATION CONST. (M(,/L)= .(MOO
.1IU10 TOTAL DAILY RAD I ATION(LANGLEYS)= 500.0000
.(li)O(i PHH-JDI TtMP CULF = 1.0000
.0000 .0000
-------�
O
cn
ro
CAIIIJ rvpE
SfMtAH
.SIKtAH
SlhtAH
SIHtAM
SIHtAM
SIHtAM
M lit AH
HI HE AH
HIKEA.H
IllMLH.
s r H F. A .'i
S THE AH
3IHKAM
SIIIEAH
SIHtAM
SIIIEAH
SIRtAM
S 1 Ht AH
SIHtAM
SIHtAM
S 1 It E * M
SIMtAM
SIHEAH
SIHtAM
3THEAM
SIHtAM
HEACll
HtACH
KF. A( ri
KE ACH
KEACH
KEAC.I
i
6.0
1 .U
U.O
v.u
lli.u
1 1.0
U.O
13.0
lu.O
15.0
16.0
17. U
Ifl.u
19.0
ao.o
ai.o
r.z.v
11. 0
an.o
ab.o
Ph.O
.0
*ICH =
HCH =
HCH:
HLH =
HCII =
KCHs
KCM:
HCH =
HLII =
.'UH =
hCH =
HCH =
HCH =
HCH:
HCMs
HCtl =
HCHs
RCH =
HCHs
RCH=
HCH =
RCH=
HCH =
Kt.lt-
HCH:
WCH =
F HI ..'<
FHI.H
FhllH
Fhim
F hliti
FHdFI
FHI.H
FHt.H
FHI.H
F HUH
FHIJH
FHUM
FHtlFI
FHlill
FHl'H
FHI.H
FKOM
FRCiH
FHtiH
FHUM
FHUM
15.7
flu.b
H3.9
1^.9
li'.'j
'Id . 1
'IU.I
il .1
-------�
$SS OATA TYPE 3 (TARGET LEVEL UU ANO FLOW AUGMENTATION SOURCES) $$$
O
cn
i
CO
CARD TYPE REACH AVAIL HDhS TARU
ENOATA3 0. 0.
$$$ DATA TYPE. 1 (COMPUTATIONAL REACH FLAG FIELD)
CARO
FLAG
FLAG
FLAG
FLAG
FLAG
FLAG
FLAG
FLAG
FLAG
FLAG
FLAG
FLAG
FLAG
FLAG
FLAb
FLAG
FLAG
FLAG
FLAG
FLAG
FLAG
FLAG
FLAG
FLAG
FLAG
FLAG
TYPE
FIELD
FIELD
FIELD
FIELD
FIELD
FIELD
FIELD
FIELD
F I ELD
FIELD
FIELD
FIELD
F I ELD
FIELD
FIELD
FIELD
FIELD
FIELD
FIELD
FIELD
FIELD
FIELD
FIELD
FlhLO
FIELD
HtLO
REACH F.LEMENTS/REACH
1
2
3
a
•3
6
7
H
9
10
It
12
u
11
lb
16
17
in
19
20
31
22
23
2«
25
2f>
ENDATA4
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.u
.0
.u
.0
.0
.0
.0
.0
.0
6.
3.
5.
2.
2.
10.
1 1 .
11 .
«.
7.
8.
9.
11.
1.
1?.
13.
9.
n.
12.
12.
10.
s.
12.
7.
17.
M.
0.
1
2
6
2
&
2
2
6
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
0
.6
.2
.2
.6
.6
.2
.?
.2
.2
.2
.2
.2
.2
.2
.2
.2
.2
.2
.2
.2
.2
.2
.2
.2
.2
.2
.0
.2.2
.2.0
.6.2
.0.0
.0.0
.2.6
.2.2
.2.2
.2.6
.2.2
.2.2
.2.2
.2.2
.2.2
..= .6
.2.2
.2.2
.2.6
.2.?
.2.2
.2.2
.2.2
.2.2
.2.2
.2.2
.2.2
.0.0
.2
.0
.2
.0
.0
.2
.2
.2
.0
.2
.2
.2
.2
.0
.2
.?
.2
.0
.2
.2
.2
.2
.2
.2
.2
.2
.0
ET DHOER OF AVAIL SOURCES
0 0. 0. 0. 0. 0. 0.
$$$
COMPU1 ATIONAL FLAGS
.2.0.0.0.0.0.0.0.0.0.0.0.0
.0.0.0.0.0.0.0.0.0.0.0.0.0
.0.0.0.0.0.0.0.0.0.0.0.0.0
.0.0.0.0.0.0.0.0.0.0.0.0.0
.0.0.0.0.0.0.0.0.0.0.0.0.0
.2.2.2.6.2.0.0.0.0.0.0.0.0
.6.2.2.2.2.2.0.0.0.0.0.0.0
.2.2.2.2.2.2.0.0.0.0.0.0.0
.0.0.0.0.0.0.0.0.0.0.0.0.0
.2.2.0.0.0.0.0.0.0.0.0.0.0
.2.2.2.0.0.0.0.0.0.0.0.0.0
.2.2.2.2.0.0.0.0.0.0.0.0.0
.2.2.2.2.2.2.2.2.2.0.0.0.0
.0.0.0.0.0.0.0.0.0.0.0.0.0
.2.2.2.2.2.2.2.0.0.0.0.0.0
.2.2.2.2.2.2.2.2.0.0.0.0.0
.2.2.2.2.0.0.0.0.0.0.0.0.0
.0.0.0.0.0.0.0.0.0.0.0.0.0
.2.2.2.2.2.2.2.0.0.0.0.0.0
.2.2.2.2.2.2.2.0.0.0.0.0.0
.2.2.2.2.2.0.0.0.0.0.0.0.0
.0.0.0.0.0.0.0.0.0.0.0.0.0
.2.2.2.2.2.2.6.0.0.0.0.0.0
.2.2.0.0.0.0.0.0.0.0.0.0.0
.2.2.2.2.2.2.2.2.2.2.2.2.0
.2.2.2.2.2.2.2.2.2.0.0.0.0
.0.0.0.0.0.0.0.0.0.0.0.0.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.-0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0.
.0.
.0.
.0.
.0.
.0.
.0.
.0.
.0.
.0.
.0.
.0.
.0.
.0.
.0.
.0.
.0.
.0.
.0.
.0.
.0.
.0.
.0.
.0.
.0.
.0.
.0.
-------�
fit IIAU TKHt 5 IMVIimilLIC CUFFMCIINIS flm Ut I tHM| N|Nr, vELDCIIV A«0 llECfH) SSI
O
I
cn
CAMII l»Pl
imjinni ica
MIDHIMJL IC3
HVOKAUL IT. 5
HdlHAUL IC3
imi'lAllLIrS
HtUHAIII |Cb
HfllKAIIl ItS
IIVIIHAIIL ics
rUIIHAHLIL >
lirilHAUL IC3
HVIIHAIILICS
HY(>U»I/I. IC.S
HTOHAIILIC!!
HrUHAUL ICS
HVUUAIILICS
HVDHAUL KM
MVUHAUI.IC3
IOOHAULICS
H«IIKAULIC3
HdlHAIJUCS
IUIHHULIC3
IKIINAULICS
HTDKAIII.1CS
h»DH*UL ICS
HtUHAUI. ICS
im>H»ULirs
ENOAIA'J
HI! tCH
1.0
i.U
3.0
4.11
5.11
h.O
1.0
H.O
•<.u
10.0
1 1.0
12.0
1 J.O
14.0
15.0
16.0
17.0
ia.o
19.0
iU.O
21.0
il.U
24.0
24.0
25.0
2b.o
.0
C.lllFOV
0940000
0940000
0440000
0'>4onoo
0479400
017940P
0114700
(M lOr-IIO
t( i /tH nil
02I5HOO
020b200
OIH5400
0112900
0520hOO
0334300
0262500
OJ59SOO
0246500
0209700
0160200
0212100
0165200
0011000
.0004926
0003210
0001950
,0000000
t Kf'UliV
.1.700
.6700
.6700
.6700
.6700
.6700
.(700
. 1. 7 d 0
.(.7uo
,
,0'<00
.11 'Kill
.0400
.0400
.0400
.0400
.0400
.0400
.0400
.0400
.0400
.0400
.0400
.0100
.0400
.0400
.0400
.0400
.0,400
.1.000
-------�
t$S DATA TYPE 6 (REACTION COEFFICIENTS FUR OEOXYtENATION .AND REAEKATION) S$»
CD
CARU TYPE
REACT
HEACT
HEACT
REACT
REACT
REACT
REACT
REACT
HEACT
REACT
REACT
HEACT
REACT
REACT
REACT
REACT
REACT
HEACT
REACT
HEACT
REACT
REACT
REACT
REACT
REACT
REACT
CUEF
COF.F
CLIEF
COEF
COEF
COEF
COEF
COEF
CUEF
CUEF
CUEF
COFF
COtF
COEF
COEF
COEF
C'JEF
COEF
CfJEF
CUEF
COEF
CUEF
CUEF
CUEF
CUEF
COEF
REACH
1
2
3
4
5
6
7
6
9
10
1 1
12
13
in
15
16
17
1H
19
20
?1
22
23
24
25
?6
ENOATA6
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
Kl
.10
.to
.40
.10
.40
.40
.40
.40
.40
.40
.40
.40
.50
.30
.30
.30
.20
.20
.20
.20
.20
.Ob
.05
.Ob
.Ob
.05
.00
K3
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
K20PT
1
3
3
3
3
3
.00
.00
.OU
.00
.00
.00
.00
.00
."00
.00
.00
.Ou
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
2
2
2
2
2
3
3
1
1
1
1
3
1
3
3
1
K2
.73
.73
.73
.73
.73
.1?
.64
.03
.30
.30
.30
.72
.66
.03
.03
.66
.47
.47
.47
.47
.06
.90
.90
.90
.90
.90
.00
COF.QK2
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
EXPOK2
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
,000
.000
.000
.000
.000
.000
.000
.000
-------�
Ill DMA lift ht (ALUM:, NIlHOl.tN. AND PHtlSPHUHUUS CONSTANTS) SIS
o
en
CAHU I»PE
ALI'AF,
ALGAE ,
ALGAE,
ALGAE ,
AL'iAE,
ALIJAE,
ALGAE ,
ALGAE,
ALGAE,
ALGAE,
ALGAF,
ALGAL,
ALI'At ,
ALGAF,
ALGAE,
ALGAE,
ALI'.At,
ALKAC,
ALGAE,
ALGAE,
ALGAF,
ALGAE,
ALGAE,
ALGAt ,
ALHAE,
H AND P
N AND ^
•'< AND f
N AND I1
H AND f
H AND f
N AMU V
II AND 1'
N AND P
N AMU P
il AND H
H AND H
• g ANII 1'
N AUI> H
H AND H
N AND H
H AND H
Bl ANU H
N ANU P
N ANU P
14 AND P
H ANU P
N AND P
N AND P
N AND P
COFF
CUIF
CHEF
CULK
COFF
CI)£F
CIJtF
CDLF
CIJtF
CfllF
CIIIF
CIILF
Clltf
ClltF
CUEF
ClltF
CUtF
ClltF
COO
CHEF
COEF
COtF
COEF
CHEF
CHEF
ENOAlAh
liEACII
1 .U
c!.0
.0
.U
.U
. U
.U
.U
.11
III. II
1 1 .11
I.".!'
1 •!.»
Ib.u
Ih.U
II. U
IH.U
I'l.U
iu.U
21.11
zi.n
f.i.O
a'l.u
25.0
26.0
. I'
LHL/AH.
20
20
?0
?0
20
20
?0
20
20
20
20
fu
SH
20
20
20
20
20
20
20
20
20
20
20
20
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.1'
.(I
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
ALGbt 1
.0
.0
.0
.0
.0
.ll
.11
.0
.0
.0
.11
.0
. 1'
.0
.0
.0
.0
.U
.11
.0
.0
.0
.0
.0
.0
.0
KNHJ KMIM
.00
.Oil
.110
.(III
.00
.00
.00
l.dO
1.20
1.20
l.2li
1.20
. OK
.110
.HO
.HO
.HO
.HO
.00
.HO
.HO
.00
.1111
.00
.lit)
.55
.S-j
.55
.55
.55
.55
.55
.55
.*•>
.55
.55
.51
. ~> j
.51
.55
.55
.55
.55
.55
.55
.55
.55
.55
.55
.55
.00 .00
II-NII1
.00
.00
.00
.no
.00
.00
.00
.1)0
.00
.00
.00
.mi
. " '
. 00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
U-PII
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.1)0
.00
.00 .
.00
.00
.00
.00
.on
.00
.00
.00
.00
.00
.00
KUUG-N
.00
.00
.00
.no
.84
.All
.HI
.12
.12
.12
.12
.12
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
-------�
51$ DATA TYPE 611 (OIHfH ClltK 1C. ihN I S)
O
Ol
CARD TYPE
OTHER COEFFICIENTS
OTHER COEFFICIENTS
OTHER COEFFICIENTS
OTHER COEFFICIENTS
OTHER COEFFICIENTS
OTHER COEFFICIENTS
OTHER COEFFICIENTS
IITHER CIJEFFICIENTS
OTHER CIJEFFICIENTS
OTHER COEFFICIENTS
OTHtR COEFFICIENTS
OTHtR COEFFICIENTS
OTHER COEFFICIENTS
OTHER COEFFICIENTS
OTHER COEFFICIENTS
OTHER COEFFICIENT
OTHER COEFFICIENTS
OJHER COEFFICIENTS
llfHER COEFFICIENTS
01HER COFFFICIF.NTS
OTHER COEFFICIENTS
OTHER COEFFICIENTS
OIHER COEFFICIENTS
OTHER COEFFICIENTS
OftltR COEFFICIENTS
OIHER COEFFICIENTS
ENDATA6H
RF ACH
1.0
2.0
3.0
'1.0
5.0
6.0
7.0
P.O
9.0
10.0
11.0
12.0
J3.0
11.0
15.0
16.0
17.0
18.0
19.0
?0.0
21 .0
22.0
23.0
2«.0
25.0
26.0
.0
tt-OXY
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
KCOLI
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
LI1E EX
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
KHAOIO KHCN1
.00
.00
.00 2f
.00 2(
.00
.00
.00
.00
.00
.00
.00
.00
.00
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SS$ DATA TYPE 7 (STREAM JUNCTIONS) SSS
CARD TYPE
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CARD TYPE
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RUNOFF CflNO-2
RUNOFF COND-2
RUNllFF CCMD-2
RUNOFF COND-2
RUNOFF CUMD-2
RUNOFF CCMO-2
RUNOFF COND-2
RUNOFF COND-2
RUNOFF CONO-?
RUNOFF COUD-2
RUNOFF CONO-2
RUNOFF C()nlD-2
RUNOFF CO.JO-2
RUNOFF CONH-?
RUNOFF COND-2
RUNOFF COND-2
RUNOFF CllND-2
RUNOFF CONO-2
RONOFF COND-2
RUNOFF COND-2
RUNOFF CONO-2
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SSS DATA TYPE 9A (INITIAL CONDITIONS FU« CHLOROPHYLL A, NITROGEN, PHOSPHOROUS,
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O
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CARO TYPt
INITIAL CONO-3
INITIAL CONO-a
INITIAL CONU-2
INITIAL CONO-2
INITIAL CUNU-a
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INITIAL CONO-2
INITIAL CONO-2
INITIAL CONO-2
INITIAL CONU-2
INITIAL CONU-2
INITIAL CONU-2
INITIAL CUNU-2
INITIAL COND-2
INITIAL CUNU-a
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INITIAL CUNU-2
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REACH CHLURA
1. .0
2. .0
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10 (HFADwATER SOURCES)
HEADWATER ORDER ANO
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TEMP
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27.50
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3.58
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.00
.00
.00
.00
.90
.11
.05
.20
.56
.34
.19
.30
.90
4.50
.00
.23
.18
.00
.00
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SIHtiM IJUALIII SIMULA I ILH4
IIIML II SrHtAM IJIIALI11 NIJ1IIING MUUFL
.«••• sitAiiv suit b i MIII > r HIM
IIIITMIII HAlit IIIIMIIfh
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JuM MUM
1 1
1 2
I 3
1 4
1 5
1 6
2 1
2 2
2 3
3 1
i 2
3 3
1 4
3 5
4 1
4 2
5 1
5 2
b 1
b 2
b 3
b 4
b 5
b 6
6 7
6 8
h 9
b 10
1
2
3
4
5
6
7
8
9
10
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0 2
b 3
0 4
B 5
a b
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8 9
B 10
a 1 I
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MJl.t
45. /
45.5
45. 3
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44.9
44.7
44.5
44.3
44.1
43.9
43.7
43.5
43.3
41.1
42.1
42. /
42.5
42.3
42.1
41.9
41.7
41.5
41.3
41.1
411.9
40.7
40.5
40.3
40.1
39.9
39.7
19.5
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39.1
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38.7
38.5
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42.9
42.7
42.5
42.3
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41.7
41.5
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40.9
40.7
40.5
40.3
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39.9
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39.5
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.96 .111 95.00
.96 .48 95.00
.96 .48 95.00
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1.05 .54 95.00
.53 .04 86.00
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.53 .04 86.00
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.54 2.13 86.00
.54 2.13 Bb.OO
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.54 2.13 lib. 00
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.22 3.B4 flb.OO
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.22 3.B4 Bb.OO
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.22 3.B4 Bb.OO
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.22 3.04 116.00
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6.74
5.69
5.68
5.66
5.65
5.64
5.63
5.63
5.62
5.63
5.62
5.65
5.63
5.6|
5.59
5.73
5.76
5.76
5.82
5.B6
5.90
5.94
5.98
6.02
6.05
6.08
6.12
6.15
6.19
6.25
b.3l
b.36
6.40
6.95
6.92
b.89
h.Bb
h.84
b.B2
b.l 3
5.22
4.41
3.70
3 . 0 B
2.54
2.011
1 .b9
1 .37
1 .10
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iiuii NII 1-1
(MG/I ) (Mli/L )
.00 .00
4.97 2.40
4.92 2.40
4.88 2.40
4.83 2.40
4.78 2.40
4.73 2.40
4.68 2.40
4.63 2.40
4.81 2.43
4.77 2.43
6.39 .37
6.33 .37
6.27 .37
6.21 .37
5.92 .10
5.86 .12
5.77 .15
5.69 .17
5.61 .19
5.53 .21
5.45 .23
5.17 .25
5.30 .27
5.22 .29
S.I5 .31
5.07 .33
5.00 .34
4.91 .3b
4.81 .39
4.72 .41
4.62 .43
4.53 .45
5.74 2.B6
5.66 2.88
5.58 2.90
5.50 2.91
5.42 2.93
5.34 2.95
5.29 2.63
5.11 2.41
4.94 2.21
4.77 2.03
4.61 .1)1.
'1.46 .71
4.11 .S7
4.1h .45
4.0? .33
1.B9 .21
J. 76 .11
NU2-N Ntl*-.J 1*1
(Mi;/L 1 I Ml. XL ) I Ml
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-2» .7S
.26 .(b
.25 .77
.24 .77
.23 .78
.22 .79
.21 .80
.20 .81
.11 .Bl
.19 .82
.17 .84
.17 .85
.16 .85
.16 .86
.14 .88
.13 .89
.11 .90
.12 .90
.11 .91
.11 .91
.10 .92
.10 .93
.09 .93
.09 .94
.08 .94
.08 .94
.07 .95
.07 .95
.06 .96
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.05 .97
.05 .98
.01 4.42
.03 4.42
.03 4.42
.03 4.43
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.27 b.2f
.46 6.31
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.72 b.S|
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.09 .00
.09 .00
.09 .00
.09 .00
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.09 .00
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.09 .00
.09 .00
.09 .00
.09 .00
.09 .00
.09 .00
.09 .00
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.09 .00
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.09 .00
.09 .00
.09 .110
.10 .00
.55 .00
.55 .00
.55 .00
.55 .00
.55 .00
.55 .00
.41 .00
.43 .00
.43 .00
.43 .00
.43 .00
.43 .00
.43 .00
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cm i HA
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0.
0.
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0.
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SIHEAH DUALIK SIMULAI1UN
DUAL II 3IHtAM UUALIlt HOtlllNU MIIUtL
• «••• STEAUV STATE SMULAIIUN
OII1PIU I'»I.E NUMHEH
HCII ELI
NUM NUM
51 S 1
52 1 2
53 9 }
SI * 1
55 ID 1
56 III i
57 103
50 10 4
59 10 S
60 111
61 IU
62 1 1
63 1 1
64 1 1
65 I 1
6b 1 1
67 II
6B 1 1
69 II H
70 12 1
71 Id i
Id 12 3
73 12 1
71 125
75 1,; 6
7b 12 7
77 12 «
7b 12 1
79 13 1
80 1 3 2
HI 1 J 3
S2 134
83 13 5
84 136
85 IJ1 7
86 138
87 13 9
Kb IJ 10
b9 11 II
9U |J 12
11 13 13
12 13 14
91 14 1
94 |4 2
95 14 3
9b 14 4
97 15 1
9« 152
99 lb 3
100 Ib 4
f HUH
HILE
3S.7
35.5
35.3
35.1
34.9
34.7
34.5
34.3
34.1
33.9
33.7
33.3
33.1
32.9
32.7
32. b
32.3
32.1
31.9
31.7
31.5
31.3
31.1
30.9
30.7
30.5
30.3
30.1
29.9
29.7
29. S
29.3
29.1
2«.9
2B.7
28. S
2tt. i
2B.I
27.9
27.7
2 7. 'I
27. i
27.1
2b.9
2h.7
26.5
2(i. 3
26.1
PS. 9
HI
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35.5
35.3
35.1
34.9
34.7
34.5
34.3
34.1
33.9
H-7
33.5
33.1
32.9
32.7
12.5
32.3
32.1
31.9
31.7
31.5
11.5
31.1
30.9
30.7
30. S
30.3
30.1
29.9
29.7
21.5
29.3
29.1
28.9
21.7
2H.5
28. S
2B.I
27.9
27.7
27. S
27.3
27.1
26.9
?6.7
26.5
26.3
26.1
25.9
2'i.7
3IHEAM
FLIIH
69.
69.
69.
69.
69.
69.
69.
69.
69.
69.
69.
69.
69.
69.
69.
69.
69.
69.
69.
69.
69.
69.
69.
69.
69.
69.
69.
69.
69.
69.
69.
69.
69.
69.
69.
69.
69.
69.
69.
69.
69.
69.
69.
69.
69.
69.
69.
69.
7S.
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K_(l« FLOW
.0 0.
.0 0.
.0 0.
.0 0.
.(I 0.
.0 0.
.0 0.
.0 0.
.0 0.
.0 n.
.0 0.
.0 0.
.0 0.
.0 0.
.0 0.
.0 0.
.0 0.
.0 0.
.0 0.
.0 0.
.0 0.
.0 0.
.0 0.
.0 0.
.0 0.
.0 0.
.0 0.
.0 0.
.0 0.
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.0 0.
.0 0.
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.0 0.
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3IKEAM SIRtAM
Vtl DFMH IEMP
UPS) (FT) nir,
.63 I.6B 86.0(1
.63 1.6? 86.00
.63 1 .68 H6.00
.6) 1.68 86.00
.37 2.34 86.00
.37 2.3U 86.00
.37 2.34 H6.00
.37 2.34 B6.UO
.37 2.34 86.00
.37 2.34 86.00
.37 2.34 86.00
.35 2 . 2b 77.00
.35 2.26 77.00
.35 S. 26 77.00
.35 2.26 77.00
.35 2.26 77.00
.35 2.26 77.00
.35 2.26 77.00
.35 2.26 77.00
.32 2.73 77.00
.32 2.73 77.00
.32 2.73 77.00
.32 2.73 77.00
.32 2.73 77.00
.32 2.73 77.00
.32 2.73 77.00
.32 2.73 77.00
.32 2.73 77.00
.53 .53 77.00
.53 .53 77.00
.53 .53 77.00
.53 .53 77.00
.53 .53 77.00
.53 .53 77.00
.53 .S3 77.00
.53 .53 77.00
.53 .53 77.00
.53 .S3 77.00
.53 .53 77.00
.53 .53 77.00
.53 .53 77.00
.53 .51 77.00
.69 .11 77.01)
.89 .11 77.00
.69 .11 77.00
.89 .11 77.00
.SB .51 77.00
.SB .51 77.00
.58 .51 77.00
.bl 1 .55 7 / .01'
no nun
(MG/Ll (MG/U
.60 3.67
.77 3.63
.76 3.58
.73 3.67
.71 3.61
.69 3.54
,6B 3.46
.69 3.39
.70 3.32
.73 3.25
.77 3.19
. 8B 3.13
.99 3.08
.1 1 3.03
.22 2.98
.14 2.92
.46 2. 87
.57 2.8?
.69 2.78
.10 2.73
.73 2.67
.29 2.62
.78 2.57
.21 2.52
.5B 2.4K
.91 2.4!
5.20 2.38
5.46 2,i4
5.57 2.31
5.59 2.29
5.61 2.27
5.63 2.25
5.63 2.23
5.67 2.21
5.70 2.19
5.72 2.1H
5.74 2.16
5.76 2.14
5.79 2.12
5.81 2.10
5.84 2.08
5.16 2.07
5.92 2.05
5.9» 2.04
6.05 2.03
6.10 2.02
6 . 1 H 2.01
6.26 1.99
6.14 I.9H
6.Sh 2.115
NH3-N
(MG/ll
.07
.04
.01
.09
.05
.00
.95
.90
.86
.82
.78
.75
.72
.69
.67
.64
.62
.60
.57
.55
.53
.51
.«9
.47
.45
.43
.41
.40
.39
.38
.37
.36
.35
.34
.34
.33
.32
.32
.31
. 10
.30
.29
.211
.28
.28
.27
.27
.26
.26
.2S
NU2-H
(HO/L)
.93
.92
.92
.91
.91
.90
.88
.87
.85
.84
.82
.81
.79
.77
.76
.74
.72
.71
.69
.67
.66
.64
.62
.60
.58
.57
.45
.53
.52
.51
.50
.49
.48
.47
.46
.45
.44
.44
.43
.42
.41
.40
.19
.19
.IB
.38
.37
.36
.15
.32
N03-N PU4-P CHL A
(HK/L) (MG/L) (UG/LI
7.45
7.50
7.54
7.58
.64
.71
.78
.85
.92
.99
.06
.11
.16
.22
.27
.32
.37
8.42
H.4b
8.51
8.56
8.61
8.65
8.70
8.74
8.79
8.83
8. 87
8.90
8.92
8.94
8.96
8.99
9.01
9.03
9.05
9.07
9.09
9.1 1
9.13
9.14
9.16
9.ia
9.19
9.20
9.21
9.22
9.23
9.25
l.bd
.43 .00
.43 .00
.43 .00
.43 .00
.43 .00
.43 .00
.43 .00
.43 .1)0
.43 .00
.43 .00
.43' .00
.43 .00
.43 .00
.43 .00
.43 .00
.43 .00
.43 .00
.43 .00
.43 .00
.43 .00
.43 .00
.43 .01)
.43 ' .00
.43 .00
.43 .00
.43 .00
.43 .00
.43 .00
.43 .00
.43 .00
.43 .00
.43 .00
.43 .00
.43 .00
.43 .00
.43 .00
.43 .00
.43 .00
.43 .00
.43 .00
.43 .00
.43 .00
.41 .00
.43 .00
.43 .00
.43 .00
.43 .00
.43 .00
.43 .00
.32 .00
CCILI RA
(MPNI (PC/
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0 .
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
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SIKtAM dllAI. Il» SIMULA!IUN
IIUAL II SIMLA-* IJUAI.II> HUlMINb MIII)fL
...» SII.AIIV SIAIt SIMULA I ION
OUTHIIf PAGE HIIHHEH
O
cn
•
»—•
i
i—*
cn
HCII ELI
MUM NUM
•1 Ib -i
• 2 IS b
i] 1* 7
11 IS ti
IS Ib 1
tb IS III
i; is it
ib is 12
it it i
IU Id 2
II Ib 3
12 ih 4
.65 .2« 77.00 6.74 .64
.65 .28 77. uO 6.73 .63
.44 2.59 77.00 b.72 .62
.44 2.5V 77. UO 6.71 .61
.44 2.59 77.00 6.7U .60
.46 2.64 77.UO 6.79 .66
.59 2.2b 77. UO 6.78 .65
.39 2.?b 77. OU 6.77 .64
. JV 2.25 77.00 6.76 .62
.39 2.25 77.00 6.76 .0!
.39 2. 25 77. UU 6.75 .60
.19 2.2b 77.011 6.74 .59
.3V 2.2b 77.00 6.71 .57
.39 2.25 77.00 6.73 .56
.19 2.25 77.00 6.71 .Sb
.39 ?.2S 77.00 6.72 .'i«
.19 2.25 77.00 6.72 .51
.39 2.25 77.00 6.71 .b'l
.10 2.7B 77.00 6.71 .'iO
.10 2.7H 77.1)0 6.71 .19
.311 f.TH 77.00 6.71 1.47
.10 2.7H 77.011 h.7l .'16
NHJ-N
(MG/L)
.24
.24
.21
.23
.23
.22
.22
.21
.21
.20
.20
.19
.19
.18
.18
.17
.17
.16
.16
.Ib
.15
.15
.15
.14
.14
.14
.!«
.11
.13
.11
.13
.12
.12
.12
.11
.11
.11
.10
.10
.10
.09
.09
.09
.09
.OH
.OB
.OH
.07
.07
.07
NIJ2-N
(MB/L)
.31
.30
.30
.29
.28
.28
.27
.26
.26
.25
.24
.24
.23
.22
.22
.21
.20
.20
.19
.19
.U
.18
.17
.17
.17
.16
.16
.16
.15
.15
.IS
.14
.14
.13
.12
.12
.1?
.11
.1 1
.1 1
.10
.10
.10
.09
.09
.09
.U9
.OH
.OH
.oil
NU1-N PII4-H CML A
(MG/L) (MG/L) (IIG/L)
8.59
A. 60
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SIHtAM UIIALIU SIHIILAIIIIN
IIUAL II SIHtAM uiltLIM KOUT1NG MODEL
• *»* 3IEAO) SIATE SIHULAI1UN ••
UUIHUI PAGE NUMHEN
O
Ol
I
ro
O
HCH ELI
NUM NUH
1 Ib S
2 ib 6
1 15 J
4 Ib B
5 Ib 4
6 15 10
1 11 II
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3165
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25.7
25.5
25.1
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21.4
21.7
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24.3
24.1
21.4
23.7
23.5
23.1
23.1
22.4
22.7
22.5
22.3
22.1
21.4
21.7
21.5
21.1
21.1
20.4
20.7
20. b
20.1
20.1
14.4
14.7
14.5
14.1
14.1
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IB. 3
IB.I
17.4
17.7
17.5
17.1
17.1
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16.5
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15.4
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10
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25.5
25.3
25.1
24.4
24.7
24.5
24.3
24.1
21.4
21.7
21.5
23.3
21.1
22.4
22.7
22.5
22.3
22.1
21.4
21.7
21.5
21 .3
21.1
20.4
20.7
20.5
20.3
20.1
|4.4
14.7
14.5
19.3
19.1
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lfl.1
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17.4
17.7
17.5
17.1
17.1
I6.4
16.7
16.5
16.3
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15.5
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(I/IIM
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154 20 1
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159 21 1
160 21 2
161 21 1
162 21 4
161 21 5
164 21 6
165 21 1
166 21 •
167 21 9
168 21 10
169 22 1
170 22 2
171 22 1
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174 23 1
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178 23 5
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14.5
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12.4
12. 7
12.5
12.3
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11.4
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11.5
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II. 1
10.4
10.7
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10.1
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9.7
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7.9
7.7
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.20
.20
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.07
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dim NMS Mil
DEC»» UFCAI OECAt
(I/OK) (I/Oft (l/lltl
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.25 .61
.25 .01
.25 .11
.21 .01
.25 .01
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.25 .01
.25 .01
.25 .01
.25 .01
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.25 .01
.25 .01
.25 .01
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.06 .01
.06 .01
.06 .01
.06 .01
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.06 .00
.06 .00
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.29 .00
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.29 .00
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.27 .00
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.27 .00
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CUN-I
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.021
.025
.025
.025
.025
.025
.025
.025
.025
.025
.025
.025
.025
.025
.021
.025
.025
.021
.025
.025
.025
.025
.025
.025
.023
.023
.023
.023
.023
.023
.023
.023
.023
.023
.023
.023
.023
.023
.02}
.(lit
-------�
STHt«M IIUALITY SIMULATION
IIUAL II SIHtAM OIIALMY HOUI1MC, MIlOEL
• *••• .1 IE HOY SIAie SIMULATION •••••
OUTPUT CAGE NUMUtH
O
cn
i
ro
HCH tLT
Ml,H MUM
£01 £S 9
£0£ 25 10
£03 2s II
£04 2S l£
205 25 13
£»b £5 14
£07 as is
£OB £S 16
£09 25 17
tftO 2b 1
£11 26 2
£l£ ab 3
fH(\»
OXYIiEN
111 lltAIH
MILE MILL (I/D»
5.3
1.1 .04
5.1 4.9 .04
.9 4.7 .04
.7
. ^,
. 3
i
3.9
1.7
3.5
3.1
.5 .04
.3 .04
.1 .04
.9 .04
.7 .04
.5 .04
.3 .04
.1 .01
3.1 £. 9 .03
^1] 2b 4 £.9 £.7 .03
£14 £b S
dIS 26 b
216 £b 7
£17 ab 8
aie ab 9
£19 ?b 10
£20 £6 II
££l 26 ia
22£ Jo 13
££3 26 14
a. 7 a. s .03
£.5 2.1 .01
£.1 2.1 .0!
£. 1
.9
.7
.5
. J
.1
.9
.9 .01
.7 .03
.5 .01
.1 .01
.1 .01
.9 .01
.7 .03
IIDl)
DECAY
1 I/UI)
.06
.06
.06
.06
.06
.Of.
.06
.06
.06
.Ub
.Ob
.06
.Ob
.Ob
.06
.06
.06
.06
.06
.06
.06
.06
.06
MHi UU2
OtCAY UtCAY
(I/UY) (I/HI)
.00 1.95
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.95
.95
.95
.95
.95
.95
.95
.95
.95
.95
.95
.95
.95
.95
.95
.95
.95
.95
.95
.95
.95
.95
COLI
OECAT
(I/HI)
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
ALGAE ALGAE
UUOHTH HESI'H
-------�
0
en
•
i— •
i
ro
,7.
6. Ill
S.1IS
4.760
I). II. 4.0(10
(MG/L)
l.lOf
2.711
2. Ob*
1.102
.707
• *
•
* *
•
• * • •
* * *
•
•
* * * •
•
*
3. 70
V.t'CI ?7.70 21.20 la. 70
KlVtH HILt Til lltAI) LIF IIEACII
14.20 9. /(I 5.20 .70
!•] i CALI.ULAIF.il IIAIA, (I) = rff.ASIIHtl) DAT*
-------�
o
i
en
no
5.S67
l.tfi
B.U.I). 3.104
(MG/L)
-,OOU« 1 «
IS.10 11.20
* * *
27.70 ?i.?0 Id./O
HIVtH "lit: Tu hEAU OF Ht»CH
1.10
.70
(•) = LAICULAHU II«T«. (X) =
-------�
o
en
i
ro
en
UHUAntC-N
(HG/LI
.6-10
.540
. JhO
..J70
.IHO
-*----»—--«-
.onu«-—
15.70
it, ao ib.io
2/.7U ?1.JO IB.71)
KlVtH HUE 111 HEAD UK litACH
11.iU 9.70
• ) = CALCIILAIID (>«[», (» = MtASIIktll 0»I»
-------�
o
I
en
i
ro
en
J. I75«-
3.03b
2. JM
Mil
(HG/L)
I .012
.675
.JJ7
41.20
?7.;(l fi.in IH.70 111. 20
klvbh HILL Ttl HFAI) Kf HttCH
9.7 II S.iO
.70
{») = IALCIJ1 A ItO !)«!«, (I) = -lt«bl/HEU U*IA
-------�
o
I
en
I
ro
IMG/LI
.nib
.464
.ill
.IHb
.U9J
.unu« » * —
us. f 0 it .<•()
10./O li.tV it .1(1 it.?0 1(3.70 14.20
KlvlK HHt TO HEAD IIF lltACII
l».7U 5.20
.10
(•) = CAt rul.AHl) DAIS, (X) = rtl 1SI/IIEO
-------�
o
en
i
ro
oo
1.375
S.bJI
N03
(NG/U)
3.687
.ooo«
ns./o
* A * •
o 23. su iit.ro
Milt III IIFAI) df KtiCH
4.70 5.20 .70
(•) = C»LCUL«Ttn 11*1*, (K) = ML»3llHtl> DAI*
-------�
o
I
en
ro
I.430«-
I.2B7
1.144
I.UOI
.H5»
rims. .715
(MG/LI
.•572
.111
• * • » * * *
U •., . 7 IP 1 I . J 0 ( b . I 0
• * • •
?i.i<> fi.iu la. JO i<4.io
I.IUlk Ml t H] Hi Kit III- llttCH
>>.7u 5.20 .70
(•) - L»I-CII| A I til IIAIA,
IIAI»
-------�
0
1
tn
CO
o
.020
.018
.016
.01 }
HLN .Oil
(Mt/U
.00-*
.007
.001
.Ulli
• ooo
*
*
*
*
* *
4
*
*
*
* * *
* ft *
, /U «1 .20 Jb./O U'.^O ^7./(> Pi.^0 IH.70 t4.<>0 9.71) b.^0
.70
HIVFK hlLt III MEAH OF XEACH
(•I = C»ICUI*ltl. DAT*. (HI =
-------�
o
I
en
t'MLNIIL
(Mb/I.)
• OSU
.011
.Oil
* * ** *
.001) • » 1 *
'11.70 q\.tn «»..7u
V.7II
hIVt'U HlLt Til lit All III
(>) = l.HLCIIL A 11 II IIATi, ("P = MUSUKtU IIAlA
-------�
APPENDIX D-5.2
MODEL PROJECTIONS
CONDITION 2
-------�
tn
t\3
**** INPUT DATA LISTING FUR THE GUAL II STREAM UUALITY ROUTING MODEL ****
$$$ (PROULEM TITLES) $$$
CARD TYPE
1ITLE01
TITLE 02
TITLE03
TITLE04
TITLEOb
TITLEOb
TITLE07
TITLEOH
T1TLE09
TITLE10
TITLE11
TITLE12
T1TLE13
TITLE 11
TITLE15
TITLEIb
ENOTITLE
YES
YES
YES
NU
YES
NO
YES
YES
YES
YES
YES
YES
NU
NO
UUAL II PROGRAM TITLES
AWARE UUAL-IT WITH HCN AND PHENOL
NAME OF BASIN = VALLEY-UPOSSUM CREEK
CONSERVATIVE MINERAL IN MG/L
HYDROGEN CYANIDE IN MG/L
PHENOL IN MG/L
TEMPERATURE IN DEGREES FARENHEIT
BIOCHEMICAL OXYGEN DEMAND IN MG/L
ALGAE AS CHL A IN MG/L
PHOSPHOROUS AS P IN MG/L
ORGANIC NITROGEN IN MG/L
AMMONIA NITROGEN IN MG/L
NITRITE NITROGEN IN MG/L
NITRATE NITROGEN IN MG/L
OISOLVED OXYGEN IN MG/L
COLIFORMS AS MPN
KAOIOMUCLIDE
S$S DATA TYPE 1 (CONTROL OATA) SIS
CARD TYPE
LIST DATA INPUT
PLOTS PRINTER
NO FLOW AUGMENTATION
STEADY STATE
NUMJER OF REACHES =
HUH OF HEADWATERS =
TIME STEP (HOURS) =
MAXIMUM ROUTE TIME (HRS)=
ENOATAI
.00000
.00000
.00000
.00000
2ft.00000
i.00000
.0001)0
30.00000
.00000
CARD TYPE
COMPLETE REPORT
METRIC
NUMUER OF JUNCTIONS :
NUMBER OF WASTE LOADS =
LNTH. COMP. ELEMENT (MI):
TIME INC. FOR RPT2 (HRS):
.00000
.00000
.00000
.00000
.00000
14.00000
.20000
.00000
.00000
SSSDATA TYPE 1A (ALGAE PRODUCTION AND NITROGEN OXIDATION CONST ANTS)S$S
CARD TYPE
0 UPTAKE HY ORG-M (MG 0/MG N) =
0 UPTAKE UY NH3 UXID(MG 0/MG N)=
0 PROD. BY ALGAE (MU U/MG A) =
N CONIE.gr OF ALGAE (MG ^/MG A) =
ALG MAX SPEC GROWTH RATE(1/UAY)=
N HALF SATURATION CONST. (MG/L)=
LIGHT HALF SAI CONST(LNGLY/MIN)=
HCN TEMP COEF =
FNDATA1A
.0000
3.2300
2.0000
.OOSO
2.0000
.3000
.0000
.OOOU
CARD TYPE
M1NIMUN RFAERATION CONSTANT OPT= .0000
(I UPTAKE UY Mt)2 UXIIHMG 0/MG N)= 1.1100
0 UPTAKE BY ALGAE (MG 0/MG A) = l.SOOO
P CUNTtMT OF ALGAE (MG P/MG A) = .0130
ALGAE RESPIRATION RATE (1/OAY) = .1000
P HALF SATURATION CONST. (MG/L)= .O'tOO
TOTAL DAILY RAOI A T ION (L ANGLE YS) = 500.0000
PHENOL TEMP COEF = 1.0000
.0000
-------�
SS!b DATA TYPE 2 (REACH IDFN1 IF 1C A1 HIM)
I
cn
ro
ro
CAUI) TYPE
STREAM REACH
SI REAM RFACH
STREAM REACH
STREAM REACH
STREAM REACH
STREAM REACH
S| REAM RbACH
STREAM REACH
STREAM REACH
S | KL i\i-, ui. iu.il
STREAM REACH
STREAM REACH
STREAM REACH
STREAM REACH
STREAM REACH
STREAM REACH
STREAM RFACH
STREAM REACH
STREAM RtACH
STREAM REACH
STREAM REACH
STREAM REACH
STREAM RFACH
STREAM REACH
STREAM REACH
STREAM REACH
ENDATA2
$St DATA TYPE
CARD TYPE
ENTIATA3
REALH OkOtR AftlT; IllFNT
1.0 RCHr FRUM
2.0 RCHr FRIlM
3.0
1 .0
5.0
6.0
7 .0
;i.o
4. I)
U . u
I .0
2.0
3.0
1.0
5.0
6.0
7.0
a.o
19.0
20.0
21.0
22.0
23.0
21.0
25.0
26.0
.0
RCHr
RCHr
RCHr
RCHr
RCHr
R r M =
RLHr
M I. I ' -
R C H =
RCHr
RCHr
RCH:
RCHr
RCHr
RCHr
RCHr
RCHr
RCHr
RCH =
RCHr
RCHr
RCH =
RCH =
RCHr
3 (TARGET LEVEL 00
RFACH
0.
F RliM
FRIlM
F RUM
F RUM
F ROM
F RUM
F M'llM
1 l\l .: I
FRIlM
FRUM
FkllM
FRUM
F ROM
F RUM
FRUM
FRUM
FRUM
FRUM
FRUM
FRUM
FRUM
FRUM
FRUM
FRUM
AMD FLOW AUGMEMTATIUN
AVAIL HUWS 1ARGET
0. .0 0.
15.7
11.5
'M.9
1? .9
Id. 5
Id. 1
'II!. 1
M .S
35. /
:i'i .-7
33.5
31 .9
3d. 1
27.3
26.5
21.1
?l .5
19.7
1 H.5
16.1
li.7
I 1 .7
10.7
fl.3
6.9
3.5
.0
SOURCES)
UKDF.R OF
0. 0.
TO
TO
TO
TU
TU
Hi
111
Hi
TU
1 I.
TO
TU
TU
Hi
TO
HI
TO
TU
TO
TO
TO
1U
TU
TU
TO
TO
1iJ$
AVA
.5
12. 1
'Jn . i
37.9
?•>./
VJ . 9
i > . I
31.9
30.1
27 . i
26.5
21. I
21 .5
19.7
18.5
16.1
13. 7
1 1 ;7
10.7
8.3
6.9
3.5
.7
.0
-------�
SS$ DATA TYPt 4 (CUMPUTAT IUNAL REACH FLAG FltLU) $$S
O
01
ro
CO
CARD
FLAG
FLAG
FLAG
FLAG
FLAG
FLAG
FLAG
FLAG
FLAG
FLAG
FLAG
FLAG
FLAG
FLAG
FLAG
FLAG
FLAG
FLAG
FLAG
FLAG
FLAG
FLAG
FLAG
FLAG
FLAG
FLAG
TYPE
FIELD
FIELD
FIELD
FIELD
FIELD
FItLD
FIELD
FIELD
FIELD
FIELD
F IELD
FIELD
FIELD
FIELD
FIELD
FItLD
FIELD
FIELD
F IELD
FIELD
FIELD
FIELD
FIELD
FIELD
FIELD
FIELD
ENOATA4
REACH ELI
1.0
2.0
J.O
1.0
5.0
b.O
1 .0
B.O
9.0
10.0
11.0
12.0
13.0
11.0
15.0
16.0
1 7.0
lfl.0
19.0
20.0
21.0
22.0
23.0
21. 0
25.0
2fa.O
.0
1MENT
6.
3.
5.
2.
?.
in.
11.
11 .
-------�
UAIA TYPt 5 (HYDRAULIC CUEFF JC I EN I S FUR DEIFKMIMING VFLUCITY AM) IJtPlH) t$4
O
cn
ro
i
CAHO TYPl-
HYOUAUL1CS
H YOU A UL1CS
HYDRAULICS
HYUUAUL ICS
HYDRAULICS
HYDKAUL ICS
HYDRAULICS
HYDRAULICS
M 1 D.OUIL 1 L .•>
HYDRAULICS
HYDRAULICS
HYDRAULICS
HYDRAULICS
HYDRAULICS
HYDRAULICS
HYDRAULICS
HYDRAULICS
HYDRAULICS
HYDRAULICS
HYDRAULICS
HYDRAULICS
HYDRAULICS
HYDRAULICS
HYDRAULICS
HYDRAULICS
HYDRAULICS
EMDATA5
RLACH
1 .0
2.0
3.0
4.0
5.0
6.0
7.0
H.O
• . u
10.0
11.0
12.0
13.0
M.O
15.0
16.0
17.0
10.0
19.0
20.0
21.0
22.0
23.0
24.0
25.0
26.0
.0
CIIF.FuV
0 ° 4 0 (1 II 0
094 00 (Ml
09(10001)
(I 9 1 0 0 0 0
047990 0
0 '1 7 9 9 0 l>
033470 (I
013U21MI
u _•> / ii f u u
0215UOO
0206200
0185100
0312900
0520600
,0339iOO
0^62500
0359^00
0 ?. H b S 0 0
0809700
. 0 1 b 0 a 0 0
0232KOU
,0165200
001 3000
0004926
0003210
0001950
0000000
fc XPIJUV
. 6 7 (1 0
.h?un
.6700
.6700
.(,70 ()
. h 7 0 0
,h700
.5700
. t- / 0 i>
.6700
.6700
.6700
.6700
.6700
.6700
.6700
.6700
.6700
.6700
.6700
.6700
.6700
1 .0000
1.0000
1 .0000
1 .0000
.0000
LIILFOH
.47UO
.'1700
.'1700
.4700
.3171
.31/1
.513?
. 4 '1 9 '1
. 4 1 '-i 4
.579?
.5591
.674?
.3768
.274'!
.3737
.4495
.3090
.6241
.5299
.657 1
.5102
.6266
7.5000
11.6000
13.4000
14.0000
.000 0
tXPHiJM
.3300
. i 3 0 0
.3300
.3300
.3300
.3500
.3300
. 3 <00
. 1 300
.3300
.3300
. 3300
.3300
.3300
.3300
.3300
.3300
.3300
.3300
.3300
.3300
.3000
.0000
.0000
.0000
.0000
.0000
CMANto
.040 (I
.040 0
.0400
. 1) '1 0 0
.040 0
. 0 '1 1) 0
.0400
.0400
. U'l HI)
.0400
.0400
.0400
.0400
.0400
.0400
.0400
. 0 '1 0 0
.0400
.0400
.0400
.0400
.0400
.0400
.0400
.0400
.0400
.0000
-------�
$$$ DATA TYPE 6 (REACTION COEFFICIENTS FOR DEUX YGENATIUN AND REAERAT I0i\l) $$$
O
I
tn
ro
•
en
CARO
REACT
REACT
REACT
REACT
REACT
REACT
REACT
REACT
REACT
REACT
REACT
REACT
RtACT
REACT
HtACT
REACT
REACT
REACT
RtACT
REACT
REACT
REACT
REACT
REACT
REAC1
REACT
END AT
TYPE
COEF
CUtF
CUtF
CHEF
CUEF
CUtF
CUEF
CJEF
CUEF
CUEF
CUEF
CUEF
CUEF
CUtF
CUEF
CUEF
CUEF
C'JEF
CUEF
COEF
COEF
COEF
CUtF
CUEF
CUtF
CUFF
A6
REACH
1
2
1
4
5
b
7
a
9
10
1 1
12
I 3
10
15
16
11
IS
19
20
21
22
?3
21
25
2f.
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.u
.0
.0
.0
Kl
.10
.10
.10
.10
.10
.10
.10
.10
.10
.10
.10
.10
.30
.30
.30
.30
.20
.20
.20
.20
.20
.05
.OS
.05
.05
.OS
.00
K3 KPUPT
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.Ou
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00 1.00
.00 1.00
.00 3.00
.00 3.00
.00 3.00
.00 3.00
.00 3.00
.00 .00
2
2
2
2
2
3
3
1
1
1
I
3
1
3
3
1
K2
.73
.73
.73
.73
.73
. 12
.61
.03
.30
.30
.30
.72
.fab
.03
.03
.86
.17
.17
.17
.17
.06
.90
.90
.90
.90
.90
.00
CUEOK2
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
EXPOK2
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000-
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
-------�
$$$ UAIA TfPE 6A (ALGAL, NITHOfifc'N, ANU PHOSPHOROUS CONSTANTS) $$S
i
en
ro
i
cr>
CARD TYPt
ALGAE,
ALl-AE,
ALGAE,
ALGAE,
ALGAt,
ALGAE,
ALGAh,
ALGAE,
ALGAE,
ALGAE,
ALGAt,
ALGAE ,
\I.H,,I ,
ALGAt ,
ALGAh ,
ALGAE,
ALGAE,
ALGAE,
ALGAE ' ,
ALGAK,
ALGAE,
ALGAF,
A L G « K ,
ALGAE,
ALGAE,
ALGAE,
ENOATAh
N ANO P
"i AND F
N, AND P
iM ANU F
l\l AND P
N AND l-
N AND P
M AND ft
^ AND P
!M AND P
N AMI) P
N AIM!) P
i n . >i '
>! AMD P
N * M 0 P
J AMD P
N AND P
•M AND F
M AND P
N ANO P
N AND P
N AND P
i J AND P
M AND P
N AND P
ig AlMU P
COHF
COEF
CLIEF
COEF
COEF
COEF
COEF
COEF
COEF
COEF
COEF
COtF
i- 1 'i
COLh
CUtF
COEF
COEf-
COtF
COEF
COEF
COEF
COEF
COEF
COEF
COKF
COFF
WE ACM
1
2
5
a
5
h
7
H
4
10
1 1
12
1 1
I/I
IS
Ib
1 7
1H
14
20
21
22
2:«
2'J
25
^6
.0
.0
.0
.0
.0
.0
.0
.u
.0
.0
.0
.11
. I/
.u
. ll
. 0
.11
.0
.0
.0
.0
.0
.0
.0
.u
.0
.0
CHL/ALG
2U
20
2U
20
2U
?0
?0
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*S4 DATA TYPE 6tl (OTHER COEFFICIENTS) S$$
i
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CARIJ TYPE
OTHER COEFFICIENTS
OTOER CUfcFFlCIEiJTS
OTHEK COEFFICIENTS
OTHER COEFFICIENTS
OTHER CUFFFICIEiMTS
OTHEK COEFFICIENTS
OTHER COEFFICIENTS
OTHER COEFFICIENTS
OIHEK COEFFICIENTS
OTHER COEFFICIENTS
OTHER COEFFICIENTS
OTHER COEFFICIENTS
OTHER COEFFICIENTS
OTHER COEFFICIENTS
OTHEK COEFFICIENTS
OTHER COEFFICIENTS
OTHER COEFFICIENTS
OTHER COEFFICIENTS
OTHER COFFFICIENTS
OTHER COEFFICIENTS
OTHER COEFFICIENTS
OTHER COEFFICIENTS
OTHER COEFFICIENTS
OTHER COEFFICIENTS
OTHER COEFFICIENTS
OTHER COEFFICIENTS
ENI)ATA6d
Rt ACH
1.0
5.0
1.0
5.0
6.0
7.0
0.0
<».o
10. U
11.0
12.0
13. U
1 '1.0
15.0
16.0
17.0
18.0
19.0
20.0
21.0
22.0
23.0
21. U
25.0
26.0
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KRA010 KHCN1
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.00 1.00
.00 26.70
.00 26.70
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.00
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.00
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.00
.00
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$S$ DATA TYPE 7 (STREAM .III IMC TI UfoS) $$J
CAPO TYPE
ENOATA7
JUNCTION ORDER AND IDENT
0.
UHS1RM
0.
JUNCTION
0.
TRIO
0.
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$»$ DATA TYPE fl (HUNUFF CONDI I IONS)
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PHENOL
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.000
.000
.000
.000
.000
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$$$ DATA TYPE. 8A (INCREMENTAL FLCIW CONDITIONS FOR NI TRUGEN, PHOSPHOROUS,
COLIFOKM AMD RADIONUCL IDt ) J.SS
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CARD TYPt
RUNOFF COND-2
RUNOFF COND-2
RUNOFF ClMO-2
RUNOFF CUi\IO-2
RUNOFF COND-2
RUNOFF COND-2
RUNOFF CONU-a
RUNOFF COND-2
RUNOFF COND-2
RUNOFF COND-2
RUNOFF CHND-2
RUNOFF COND-2
RUNOFF CONO-2
RUNOFF cUNO-2
RUNOFF CO«iD-2
RUNOFF CUNO-2
RUNOFF COiVD-2
RUNOFF COUO-2
RUNOFF COND-2
RUNOFF CUMO-2
RUNOFF CO.MD-2
RUNOFF COIJD-2
RUNOFF CDNO-2
RUNOFF CUnll)-?
RUNOFF CHND-2
RUNOFF CCNO-2
ENDATAHA
REACH CHLURA
1.
2.
3.
5.
7.
fl.
9.
10.
11 .
12.
13.
1<4.
16.
17.
18.
21.
22.
23.
21.
RA
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
NH3
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.1)0
N02
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
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.00
.00
.00
.00
.00
.00
.00
N03
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
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.00
.00
.00
.00
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.00
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.00
.00
P0«
.00
.00
.00
.00
.00
.00
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.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
COLI
.0
.0
.0
.0
.0
.0
.0
.0
.0
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.0
.0
.0
.0
.0
.0
.0
.0
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.0
.0
.0
R4DN
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
ORG-N
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
-------�
SSS DATA TYHt 4 (INI HAL CUh'U 11 I IJIIb) 3>S$
I
Ul
I
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CARD TYPE
INITIAL CONDITIONS
INITIAL CONDITIONS
INI I IAL CONDITIONS
INI F IAL ClINuI IIONS
INITIAL CONDITIONS
INI I IAL CONDITIONS
INITIAL CONDITIONS
INIIIAL CONDI I IUIJS
INI I IAL CONDI I IONS
INITIAL CGNU 11 H.INS
INITIAL CUNOIUONS
INITIAL CONDITIONS
INITIAL CONDITIONS
INITIAL CONDI HOWS
1 ^1 I 1AL Lui'i'i I I iO'i;>
INITIAL CONDIiIUNS
INITIAL CONDITIONS
INITIAL CONDITIONS
INITIAL CUNDI1IUNS
INITIAL CONDIfIONS
INITIAL CONDI HOWS
INITIAL CUNDITIUMa
INI UAL CONDITIONS
IMIIIAL CONDI I IONS
1NUIAL CONDIIIONS
INITIAL CONDITIONS
tNDATA9
HE ACH
1 .0
2.U
3.0
H.U
5). 0
h.O
7 .0
M.O
9.0
0.0
1 .0
£?.0
3.1.
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lf>.0
11 . (1
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19.0
20.0
21.0
22.0
23.0
21.0
2b.O
?6.0
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TEMP
9b.O
95.0
9b.O
9 '3 . 0
Hh.O
P.h.O
PH .0
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ttb.O
Hb . 0
11 .0
77.0
7 / .(I
77.0
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77.0
77.0
77.0
77.0
77 .0
77.0
77.0
77.0
77.0
77.0
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.000
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. 0 0 0
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.000
.000
.000
.000
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.000 -
.000
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PHENOL
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.000
.000
.000
.000
.000
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.000
.000
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.000
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. 11 ll'i
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
-------�
SSS DATA TYPE 9A
(INI1IAL CliriDIUUNS KLW CHLURUPHYLL A,
COLIFOK'M AND R ADIONUCL IDE) 5>$$
NIIROGEN, PHOSPHOROUS,
O
I
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CARU TYPE
INITIAL CUNO-2
INITIAL CUNO-2
INITIAL CUNU-2
INITIAL CiJNU-2
INITIAL CUNO-2
INITIAL CUNU-2
INITIAL cuNu-2
INITIAL CUNU-2
INITIAL coNu-2
INI UAL CONU-2
INITIAL COND-2
INITIAL CUNU-2
INITIAL CONO-2
INITIAL CONO-2
INITIAL CONO-2
INITIAL CONO-2
INITIAL CUNU-2
INITIAL COIJU-2
INITIAL CHNU-2
INITIAL CUNU-2
INITIAL CUNO-2
INITIAL CONU-2
INITIAL CONU-2
INITIAL CONU-2
INITIAL CUNU-2
INITIAL CONU-2
ENOATA9A
$SJ UAIA TYPE
CARD TYPE
HEAUMTEH
E. \IOATA 10
$$$ OATA TYPE
REACH CHLUWA
1. .0
2. .0
3. .0
1. .0
5. .0
6. .0
7. .0
8. .0
9. .0
10. .0
11. .0
12. .0
13. .0
1 « . .0
15. .0
16. .0
17. .0
18. .0
19. .0
20. .0
21. .0
22. .0
23. .0
21. .0
2S. .0
26. .0
0. .0
10' (HEAI)iNAIEK SUURCES)
HEADWATER UROER ANO
1. HUW=OPOSSUM CK
0.
NH3 NU2
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
*$*
IOENT
10A (HEADWATER CUNUITIUNS FUR
00
00
00
00
00
00
00
00
00
00
00
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00
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00
00
00
00
00
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CHI
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.00
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.00
.00
.00
.00
.00
FLUW
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.0
04UPHYLL
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
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.00
.00
.00
.00
.00
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.00
.00
.00
.00
TEMP
95.0
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,NI I RUG
.0
.0
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6.7
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.00
.00
.00
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HUU CONS I
1.3 .000
.0 .000
t
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CARO TYPE
HEAUMIATER-?
ENUATAl OA
HUWATER CHLURA
1 . .0
0. .U
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NU2
01
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NU3
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COL I
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.00 .00
HCN
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.000
PHENOL
.020
.000
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SSS DA[A TYPE 11 (WASTE LOADINGS) *$$
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CARD TYPE
WAS(ELOAl>
WAS ItLOAD
WAS FELOAD
'A'ASTELOAD
WAS! ELOAH
WASIELOAD
WASTELOAD
hASIELOAD
WASTELOAD
fjASri-LOAO
WASTELHAn
WASTELOAD
WASTELOAD
WASTELOAD
ENDATA1 I
WASTE
1 .
2.
5.
'4 .
5.
6 .
7.
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9.
10.
11.
12.
13.
14.
0.
LOAD OK'DEK AND IUENT
WSL=US SIEEL
= KIIPPtKS
I/»,SC = VALLEY CK
A .S L = t> I U ft '• ;> e •;• t h
WSL = II.S. PIPE
WSL=SMALL CREEK
WSL=HALL3 CHEEK
WSL=VALLEY STP
5-MILE CHEEK
BIKMINHAM HIDE
LICK CKEEK
ROCK CREEK
MUD CREEK
S$S DATA TYPE 11A (WASTE LOAD CH AH AC I E R I ST I C S -
COLIFLlRMS AND RAD I ONUCL 1 DE S)
CARD TYPE WASIE LOAD ORDER AND IDENT
hASTELIJAD-2 1. nSL = US SIEEL
WASTELOAD-? 2. WSL=KOPPERS
WASTELOAD-2 3. WSL=wOODwARD IRON
WASTELOAD-? 4. rtSC=VALLEY CK
WASTELOAD-2 5. WSL=STORM SEwER
WASTELOAD-2 6. WSL = II.S. PIPE
WASTELOAD-2 7. wSL=SMALL CREEK
WASTELOAD-2 8. WSL=HALLS CREEK
WASTFLOAD-2 9. /JSL = VALLEY STP
WASTFLOAD-2 10. 5-MILE CREEK
WASrELCUO-S 11. BIRMINHAM HIDE
WASTELOAD-? 12. LICK CREEK
WASTELOAD-2 13. ROCK CREEK
WASTELOAO-2 14. MUD CREEK
ENDATAHA 0.
EFF
.00
.00
.00
.00
.III'
.III)
.00
.00
.00
.00
.00
.00
.00
.00
.00
FL 0"»
31 .6
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1 .3
3.U
. I'
.0
.0
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26.3
6.3
.0
5.8
4.6
6.0
.0
ThMP
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SIREAM DUALITY SIHIILAHUN
DUAL II STREAM UtlALITr HOIKING HlllltL
• ••«• STEAOr STATE SIMULATION .«.«•
OUTPUT PARE
o
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ro
co
RtH ELI
NUM NUN
1 1 1
2 1 2
3 1 3
4 1 1
5 1 -3
b \ h
7 i 1
B «! 2
4 d 3
10 3 1
II 32
1233
13 34
14 35
15 4 1
Ib 4 f
II b 1
Ib S 2
14 b 1
i>0 6 2
21 b 3
22 li 4
23 ti b
24 b fc
25 fc 7
2(> h U
27 b 4
2H b ID
2V 7 1
3D 7 2
31 7 3
12 « 4
33 7 5
34 7 h
35 7 7
3b 7 It
37 7 4
]li 7 1 (1
31 711
411 II 1
4| H 2
42 B J
43 a 4
44 U S
Ib d h
46 H 7
47 B d
db U 1
49 b 10
SI/ till
FROM 10
MILE MILE
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45.1 44.4
44.4 44.7
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44.3 44. 1
44.1 43.4
43.4 43.7
43.7 43. i
43.5 43.3
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43.1 42.4
42.4 42.7
42.7 42.5
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42.3 42.1
42.1 41.4
41.4 41.7
41.7 41.5
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41.3 41.1
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40.4 40.7
40.7 40.5
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40.1 34.4
34.4 34.7
34.7 34.5
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34.1 34.1
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38.7 38.5
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37.3 37.1
37.1 36.4
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.47 45.00 5.64
.47 45.00 5.63
.47 45. UO 5.63
.47 45.00 5.62
.47 45.00 5.63
.47 45.00 5.62
.44 45.00 5.65
.44 45.00 5.63
.44 45.00 5.61
.44 45.00 5.54
.53 45.00 5.73
.04 06.00 5.76
.04 86.00 5.74
.04 86.00 5.82
.04 tit. 1)0 5.86
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.04 86. UO 5.45
.04 86.00 5.44
.04 86.00 6.02
.04 86. UO 6.05
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.04 86.00 6.15
.77 86.00 6.14
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.12 bb.OO 6.42
.12 86.00 6.84
.12 86.00 6.87
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4.47 10.40
4.42 10.40
4.67 10.40
4.62 10.40
4.78 10.40
4.73 10.41)
4.68 10.40
4.63 10.40
4.81 10.37
4.77 10.38
6.41 11.03
6.35 11.03
6.24 11.03
6.22 11.03
5.44 10.12
5.d7 10.20
5.74 10.30
5.70 10.34
5.62 10.44
5.54 10.58
5.46 10.67
5.30 10.75
5.30 10. HO
5.23 10.42
5.15 II. 00
5.08 11.07
S.OI 11.14
.42 11.23
.82 11.33
.72 11.42
.62 11.51
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5.75 7.54
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5.58 7.6d
5.50 7.72
5.42 7.7b
5.15 7.80
5.10 6.76
5. 12 6.17
4.44 5.61
4. /It 5.14
4.h2 4.64
4.46 4.24
4.11 3.42
4.16 3.54
4.02 3.24
1.44 3.01
3.76 ^ .In
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1.74
1.47
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2.24
2.30
2.33
2.31
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3IHt»M IJUALIK 3 I Mill* II ON
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70 12 1
71 122
72 12 3
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76 12 9
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81 111
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86 11 H
87 119
BU 13 10
119 1311
90 11 12
91 1113
92 11 14
91 14 1
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99 Ib 3
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FHIIM
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35.7
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.12 2.72 77.00 -3.95
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.32 2.72 77.00 1.76
.32 2.72 77.00 2.35
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.53 .53 77.00 3.10
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.53 .51 77.00 3.18
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(MG/L) (Mfi/L) (MG/L) (MG/L)
3.67 2.60 2.28 9.22
l.bl 2.52 2.27 9.31
1.58 2.45 2.25 9.44
1.67 2.48 2.24 9.54
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1.54 2.26 2.18 9.86
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1.19
3.13
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2.92
2.87
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2.67
2.62
2.57
2.52
2.47
2.42
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2.27
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2.21
2.19
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.67 .91 10.81
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.47 .78 11.20
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.15 .51 11.66
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1.44
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1 .44
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.00
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.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.no
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
0 0
.00
.00
'.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
5.90
3.90
3.90
3.90
3.90
3.90
3.90
3.90
3.87
3.87
3.73
3.73
3. (3
3.73
3.43
1.36
3.2b
3.16
I. til
2.98
2.89
2. to
2.72
aL (I
. C*1*
2.48
2.32
2.22
2.11
2.04
1 .95
1.47
1.43
1.38
1 .54
1 .30
l.2b
1 .52
1.47
1.41
1 . 16
1 .52
1.27
1 .22
l .in
1.14
1.10
1.06
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
1.33
1.33
1.35
1.33
1.15
1.33
1.31
1.33
Ia 1
» j J
1.33
1.33
US5
1 .31
1 .33
1.13
1 .33
1.33
1.35
1.11
1 .55
1.11
1.31
1.15
.67
.67
.hi
.67
.67
.61
.67
.67
.c/
.67
.b7
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.298
.294
.291
.287
.285
.280
.?7b
.275
.209
.156 '
.112
.084
.061
.047
.031
.031
.032
.031
.031
.030
.029
.029
.028
0? 7
.027
.026
.02b
.025
.024
.023
.023
.022
.017
.016
.016
.015
.015
.015
.016
.015
.015
.014
.01 3
.012
.012
.011
.011
.010
.009
.000
.210
.210
.210
.210
.210
.210
.210
.210
.217
.217
.252
.232
.232
.232
.215
.213
.211
.215
.21)
.213
.213
' .213
.213
P 1 J
.213
.213
.215
.213
.21 3
.213
.213
.21)
.123
.123
.123
.12)
.123
.123
.113
.113
.113
.113
.113
.115
.113
.113
.113
.113
.111
-------�
SIHEAM IJII»LIIr S1MULAIIUM
UUAL II SIREAM DUALITY KUllUNG HlllltL
*•>•• SIEAOV STATE SIMULA! IIJN •••••
nilTI'UI PAGE NUMBER
in
ro
i
HCH ELT FKtIM IU
NUH NUM MILE MILE
51 9 1 35.7 35.5
52 92 35. i 15.3
53 9 3 35. i 35.1
54 9 4 35.1 14. <>
55 IU 1 34.9 14.;
56 IU I 34.7 14.5
51 IU 3 34. i 14.3
58 |U 4 34. S 14.1
59 IU 5 34.1 31.9
60 10 •> 33.9 33.7
61 IU 7 33.7 33. S
62 II 1 33. S 13.3
63 II 2 33.1 33.1
64 II 3 33.1 32.9
65 II 4 32.9 12.7
66 II 5 32.7 32.5
67 II 6 32.5 32.3
bb II 7 32.1 32.1
69 II 8 32.1 31.9
7u 12 1 31.9 31.7
71 12 2 31.7 31.5
72 12 3 31.5 31.3
73 12 4 31.3 31.1
74 12 5 31.1 30.9
7b 12 6 3U.9 30.7
76 12 7 3U.7 30.5
77 12 H 30.5 in, 3
78 12 9 3U.1 1U.I
79 13 1 3U.I 29.9
00 13 2 ?9.9 29.7
HI 13 3 29.7 29.5
a2 13 4 29.5 29.3
HI 13 S 29.3 29.1
H4 13 6 29.1 26.9
U5 13 7 2H.9 2D.I
8b 11 U in.l 2H.5
87 11 9 28. •> 28. 3
8b IS 10 28.1 2b.l
«9 11 II 2U.I 27.9
9u 11 12 27.9 27.7
91 11 11 27.7 27.5
92 1} 14 27.5 27. J
93 14 1 27.1 27.1
94 14 2 27.1
97 15 1 26. * 26.3
9B 15 2 26.3 26.1
99 15 3 26.1 2S. 9
IOU 15 4 25.9 25.7
riXYUEM
HEAIK
ll/IIY)
1.36
1.52
1.52
1.52
1.52
1.52
1 .52
1 .52
1.52
1.52
1.52
1.40
1.40
I.4U
1.40
I.4U
I.4U
1.40
1 .40
2.71
4.02
4.02
4.02
4.02
4.02
4.02
4.02
4.02
2.9|
1 .79
1.79
1.79
1.79
1 .79
1.79
1.79
1.79
1.79
1.79
1 .7>)
1.79
1.79
2.54
1.29
i.2d
3.2(t
).2B
5.2(>
(1RG-N
DECAY
(MG/L)
.67
.67
.67
.6?
.67
.67
.<>»
.67
.67
.67
.67
.S3
.53
.53
.53
.53
.53
.53
.53
.53
.53
.53
.53
.53
.53
.53
.53
.53
.53
.51
.53
.53
.51
.51
.53
.53
.53
.53
.53
.53
.53
.51
.00
.00
.00
.00
.00
.00
.00
.no
CON-1
(MG/L)
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
IICN
(MB/L)
.009
.009
.009
.009
.008
.008
.008
.ODD
.007,
.007
.007
.007
.006
.006
.006
.006
.006
.OU5
.005
.005
.005
.005
.005
.004
.004
.004
.OU4
.004
.004
.004
.003
.003
.003
.003
.001
.001
.001
.003
.00 J
.003
.00!
.003
.003
.001
.001
.001
.001
.002
.002
.00?
PHENOL
(MG/L)
.113
.113
.113
.112
.112
.112
.112
.112
.112
.112
.112
.112
.112
.112
.112
.112
.112
.112
.112
.112
- .112
.112
.112
.112
.112
.112
.112
.112
.112
.112
.112
.112
.112
.112
.112
.112
.112
.112
.112
.112
.112
.112
.112
.112
.112
.112
.112
.112
.112
.105
-------�
SI H£ AH UIIAL1I* SIMULA I I UN
IJIJAL [I SIUEAM OUALI1V HUlIIINb MIJIIEL
••«• SIEAbt SI A It SIMULA I ItIN •••
IIUTHU1 HAliE NIIMIlEU
O
I
CJ1
i
ro
o
HLH ELI
MUM NUM
01 IS 5
02 IS fa
03 IS 7
04 IS b
05 IS 9
Ob IS 10
07 IS 11
OH IS 12
04 Ib 1
10 Ik 1
II Ib 1
12 Ib 4
13 Ib S
14 Ib h
IS 1 b 7
Ib Ib a
17 1 b 4
.III Ib 10
.14 Ib 1 1
120 Ib 12
121 Ib 13
122 11 1
123 17 2
124 II 3
125 II 4
I2b II 5
121 II 6
128 II 7
124 II a
10 II 4
11 IU 1
32 18 2
31 III 3
14 Ib 4
IS 19 1
Ib 192
1 3 / 14 3
138 19 4
134 14 5
140 19 <>
141 19 7
142 19 H
143 19 9
144 19 10
I4S 14 II
|4b 14 12
147 20 1
loll 20 2
144 2 II 3
ISO 20 4
HUM
MILE
25.1
25.5
25.3
25. 1
24.9
24.1
24.5
24.1
24.1
21.9
21.1
23.5
21.3
23.1
22.9
22.1
22.5
22.3
22.1
21 .9
21 .1
21 .5
21.3
21.1
20.4
20.7
20.5
20.1
20.1
14.4
19.7
14.5
14.3
14.1
18.5
IB. 3
Ib.l
17.4
17.7
17.5
17.3
1 I. 1
16.9
Ib.l
16.5
Ib.!
Ib.l
15.9
IS. I
15. i
IU
MILE
25.5
25.1
25.1
24.9
24.7
24.5
24.3
24.1
23.9
23.7
23.5
23.3
23.1
22.9
22.7
22.5
22.3
22.1
21 .9
21.7
21.5
21.3
21.1
20.9
20.7
20.5
20.3
21). 1
14.9
19.7
19.5
19.1
14.1
18.9
111.1
18. 1
17.9
17.7
17.5
17.3
17.1
16.9
Ib.l
It.. 5
|h.3
Ib. 1
15.4
15.7
15.5
15. 1
lIXYGbN
REAIH
( 1 /U Y J
3.28
3.28
1.28
1.2b
3.28
3.28
3.28
3.28
2.11
.93
.93
.43
.93
.91
.93
.91
.91
.91
.93
.91
.91
.72
.51
.51
.51
.51
.51
.51
.51
.51
.51
.51
.51
.51
.51
.51
.51
.51
.51
.51
.51
.51
.51
.51
.51
.SI
.51
.51
.51
.SI
UIMI NH5 N(I2
DECAY DECAY UtCAY
(I/Of) II/UV) (I/OY)
.18 1.01 .45
.38
.38
.38
.3H
. 18
.38
.38
.38
.18
.38
. 18
.18
.38
.18
.38
.38
.38
.38
.38
.38
.25
.25
.25
.25
.25
.25
.25
.25
.25
.25
.25
.25
.25
.25
.25
.25
.25
.25
.25
.25
.25
.25
.25
.2r>
.25
.25
.25
.25
.2S
.01 .95
.01 .95
.01 .95
.01 .95
.01 .95
.01 .95
.01 .95
.01 .45
.01 .45
.01 .45
.01 .45
.01 .45
.01 .45
.01 .45
.01 .45
.01 .95
.01 .95
.01 .95
.01 .95
.01 .95
.01 .45
.01 .95
.01 .95
.01 .95
.01 .45
.01 .45
.01 .95
.01 .95
.01 .95
.01 .95
.01 .95
.01 .95
.01 .95
.01 .45
.01 .95
.01 .95
.01 .95
.01 .95
.01 .95
.01 .45
.01 .95
.01 .95
.01 .95
.01 .95
.01 .45
.01 .45
.01 ,')5
.01 .45
.01 .95
CIILI
DECAY
(I/OY)
.00
.00
.00
.Od
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.ou
.00
.00
.(IU
.00
.00
.00
.00
.00
.ou
ALGAF
GRdrtlll
(I/IIY)
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.60
.00
.00
.00
.00
.00
.00
.0(1
.00
.00
.00
.01)
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
ALGAE
HESPH
d/nt)
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.ou
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.uo
.Oil
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
RUG-N
IMG/L)
.50
.50
.50
.50
.50
.50
.50
.50
.50
.50
.50
.50
.50
.50
.50
.SO
.50
.50
.50
.50
.so
.50
.50
.50
.50
.50
.50
.50
.50
.50
.50
.50
.50
.48
.48
.48
.48
.48
.48
.48
.48
.'18
.48
.48
.48
.48
.4b
.48
.48
.'HI
UfU. -N
DECAI CUN-1
IMG/L) (MI./L)
.00 .000
.00 .000
.00 .000
.00 .000
.00 .000
.00 .000
.00 .000
.00 .000
.00 .000
.00 .000
.00 .000
.00 .000
.00 .0011
.00 .000
.00 .000
.00 .000
.00 .000
.00 .000
.00 .000
.00 .000
.00 .000
.00 .000
.00 .000
.00 .000
.00 .000
.00 .000
.00 .000
.00 .000
.00 .000
.00 .000
.00 .000
.00 .000
.no .000
.00 .000
.00 .000
.00 .000
.00 .000
.00 .000
.00 .000
.00 .000
.00 .000
.00 .000
.00 .000
. 0 ll .000
.00 .000
.00 . o u o
.00 .000
.00 .000
.00 .000
.00 .000
HUN PIIENUL
(MG/L) (MK/L)
.002 .105
.002 .105
.002 .105
.002 .105
.002 .105
.002 .105
.002 .105
.002 .105
.002 .105
.002 .105
.002- .105
.002 .105
.002 .105
.002 .105
.002 .105
.002 .105
.002 .105
.002 .105
.001 .105
.001 .105
.001 .105
.001 .105
.001 .105
.001 .105
.001 .105
.001 .105
.001 .105
.001 .105
.001 .105
.001 .105
.001 .105
.001 .105
.001 .105
.001 .099
.001 .094
.001 .099
.001 .099
,.001 .099
.001 .099
.001 .099
.001 .099
.001 .099
.001 .099
.001 .094
.001 .049
.00) .099
.001 .099
.001 .094
.001 .049
.001 .1)99
-------�
UUAI.II> SMULAIluN
IIIUL II ,Slht»"l KHALI IV llUIIIINi;
• •••• Sit AIM .llAlt SII-.IILA I llll« «•••
HAlit NUMlltM
o
C71
•
PO
I
r\>
HLH ti.I
NUH MIM
|5I 20 b
ISc 20 l>
151 20 /
IS4 20 B
ISb 20 4
ISb f.u 10
IS/ 20 II
150 2u 1?
154 21 1
Iho 21 2
Ihl 21 1
Ib2 21 4
Ibl 21 5
Ib4 21 b
Ih5 21 7
161, 2| U
IbV 21 4
Ibo 2| 10
Ih4 22 1
170 22 2
171 22 3
172 22 4
171 22 5
174 21 1
175 21 2
176 23 i
177 21 4
Do 21 b
174 21 h
100 21 7
Hll 21 B
|i)2 21 9
lltl 21 111
lt>4 21 II
1Mb 21 12
IHb 24 1
IH7 24 2
|A(t 24 3
1B9 24 4
140 24 b
I4| 24 b
19,; 24 7
141 25 1
194 25 2
145 ?b 3
|9h 25 4
14) 25 S
I4B 25 b
149 25 7
fin. 25 H
FHI-M III
flLt MILE
15.1 15.1
Ib.l Ifl. 4
14.4 14.7
14.7 14.5
14. b 14.3
14.1 |4. |
14.1 11.4
11.4 11. 1
13.7 13.5
13.5 11.3
11.1 1 t.l
13.1 12.9
12.4 12.7
12. / 12.5
12.5 12.1
12.3 12.1
12.1 11.4
11.4 11.7
11.7 11.5
1 l.b II. 1
II . 1 It .1
II. 1 10.9
10.9 10.7
10.7 |0.5
10.5 10.3
10. 1 10. 1
10. 1 9.4
4.9 4./
4.J 4.b
9.b 4.3
4.1 9.1
9.1 8.9
(1.4 6.7
B./ B.b
b.i a. 4
H. i H.I
B.I 7.4
/.4 7.7
7.7 7.5
7.b 7.J
7.1 7.1
7.1 h . 9
b.9 b.7
b./ h.b
b.b b . 1
h. i b.l
h.l S.9
b.4 S.7
b.7 b.b
b . 'i b.l
(ixri.Kn
.it AIM
(1/uVI
.SI
.bl
.SI
.51
.51
.51
.51
.SI
.ni
.15
.15
.Ib
.15
.15
.15
.15
.15
.15
.Sb
.9b
.9d
.la
.9H
.04
.20
.20
.20
.20
.20
.20
.20
.20
.20
.20
.20
.11
.O/
.0;
.07
.01
.0)
.O/
.Ob
.04
.04
.04
.U4
.04
.04
. I' •'!
.till) hill M'2
UtCAV UtLAt lltCAV
ll/Pf) (i/iiv) (I/or)
.25 .III .45
.25 .01 .45
.25 .01 .15
.25 .01 .45
.25 .01 .45
.25 .01 .45
.25 .01 .45
.25 .01 .45
.25 .01 .45
.25 .01 .45
.25 .01 .95
.25 .01 .45
.25 .01 .95
.25 .01 .45
.25 .01 .45
.25 .01 .45
.25 .01 .45
.25 .04 .9*
.Ob .01 .95
.Ob .01 .95
.Oh .01 .95
.Oh .01 .95
.Ob .01 .95
.Ob .00 .95
.Ob .00 .95
.Ob .00 .95
.Ob .00 .95
.Ob .00 .45
.Oh .00 .45
.Ob .00 .45
.oh .00 .95
.Oh .00 .9b
.Oh .00 .95
.Oh .110 .95
.Oh .00 .45
.Oh .0.0 .45
.uh .00 .45
.lib .00 .45
.Ob .00 .45
.Oh .00 .45
.Oh .00 .45
.uh .Ob .45
.110 .00 .15
.Oh .00 .45
.Oh .00 .95
.Oh .00 .95
.Oh .00 .45
.Oh .00 .15
.lib .110 .45
.Oh .00 .45
CUL 1
(JtlAr
ll/I.Y)
.0(1
.00
.Oil
.00
.00
.00
.00
,00
.00
.00
.00
.00
.00
.00
.00
.00
.«0
.00-
.00
.00
.110
.00
.00
.00
.00
.00
.00
.00
.wo
.00
.00
.00
.00
.00
.00
.Oil
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.0(1
. 00
ALGAE
UKUhlM
(I/UVI
.00
.0(1
.00
.00
.00
.00
.00
.00
.04
.00
.00
.00
.00
.00
.08
.00
.00
.04
.on
.00
.00
.to
.00
.60
.00
.00
.01)
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.Oil
.00
.00
.60
.00
.00
.00
.00
.00
.00
.0(1
.00
.(id
ALUAt
KtSPK
(I/IK)
.00
.00
.00
.00
.00
.00
.110
.-00
.00
, .00
.04
.00
.00
.00.
' • .00
. .00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.no
.00
.00
.00
.00
.00
.00
.00
.00
OUIi-N
(Htt/Ll
.4(1
.40
.44
.40
.40
.48
.4H
- .40
.40
.40
.48
.411
.4(1
' .10
.40
.40
.40
.40
.40
.48
-.40
.48
.46
.40
.48
. 40
.48
. 4
-------�
3 I lit AH UUALIIV SIMULA I IUII
UIIAL II STREAM DUALITY UUIIIING MIID6L
UU1IMII PAGt NUMBER
• ••• STEADY STATE SIMULATION •••••
O
I
cn
I
ro
ro
HLH ELT
HUH NUH
201
202
203
204
205
20b
207
20U
<;09
210
21 i
212
213
^H
215
cMb
217
2IB
219
220
tT2i
222
223
25
2b
25
2i
25
25
25
25
25
?t>
2b
2b
2b
2b
2b
ih
2b
2b
2b
2b
26
2b
2b
9
in
1 1
12
|]
14
15
Ib
17
1
I
1
'1
S
b
7
It
"*
10
II
12
1)
10
FkUM
MILE
5.J
5.1
1.9
1. 7
1.5
1.1
1. 1
i.Y
J.7
1.5
3.)
3.1
2.9
2.7
2.5
2. I
2.1
.9
.7
.5
.3
.1
.9
UXVGtN Him
10 NtAlrf DtCAV
Nil] NU2 lUI-1 ALGAE ALGAE UHG-N
UtCAt UtCAY DtCAI GHIIMIH htSfH OIIG-N ULCAY
r.uN-i
HCN.
MILE (I/UY) (1/DY) tl/UY) II/UY) (l/pr) (I/DT) (I/Ur) (MC/L) (M(,/L) (MG/L) (MG/L)
5.1
1.9
1.7
1.5
a. 3
1. 1
3.9
1. 7
<.5
3.3
3.1
2.9
2.7
2.5
2. i
2.1
.9
. 7
.5
. J
.1
.9
.7
.04
.01
.04
.04
.01
. ll'l
.04
.04
.04
.04
.03
.03
.03
.1)3
.03
.03
.03
.01
.03
.03
.03
.OS
.03
.Oh
.Oh
.Oh
.Ob
.Oh
.Ob
.Ob
.Oh
.Uh
.IK,
.Ob
.lib
.06
.Uh
.Oh
.Oh
.Ob
.Oh
.Oh
.Uh
.Ob
.Ob
.06
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
. 00
.00
,ou
.00
.00
.95
.95
.95
.95
.95
.95
.95
.95
.95
.95
.95
.95
.95
.95
.95
.95
.95
.95
.95
.95
.95
.95
.00 1.95
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.1/0
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.Oil
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.15
.45
.45
.45
.45
.45
.45
.45
.45
.15
.45
.45
.15
.45
.45
.45
.45
.45
.45
.45
.45
.45
.44
.ou
.00
.00
.00
.00
.00
.00
.00
.0(1
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
MIENflL
(MG/L)
.092
.092
.092
.092
.092
.092
.092
.092
.092
.092
- .092
.092
.092
.092
.092
.092
.092
.092
.092
.092
.092
.092
.092
-------�
o
I
en
IN3
i
IV)
co
I.nib
5.661
11.11. -.001
-1.11*
-2.H32
-S.fchi
-7,07«t-
il.ltt >\.tn lrt.70 14.20 4.70 5.20
klVth ».1l.t Tli HEAD IIF KkACH
.70
DATA, (» =
UAIA
-------�
o
en
ro
i
H.O.I,.
(MU/U
1.M5
2.440
15.70 41. 20 lh.10 3a.
-------�
a
en
ro
ro
5.900
J.ilO
J.UO
1.1 id
UNUANIOII 1.1
(MG/L)
I.S6U
1.170
./HO
* * » * * * * «**
-.00l)< ---- * ---- » ---- » ---- *
15. /O Ul.
-------�
0
I
tn
i
ro
en
1 .Ubi
NHl 5.hi
(MG/LI
J.J69
.000 - - -
-------�
o
I
en
•
ro
ro
2.2
1.370
NUj 1.142
IMG/U
.••II
.157
-.oou«-
Ul.AIA, (X) = MEASIINEU OAIA
-------�
O
I
cn
ro
i
ro
00
13. JM
8.024
nlli o.bAT
(HG/L)
.JJ7
<6.7U
a;.70 ii.du in.70
mvth Mice it. nt»o i^ nt«cn
9.711
.70
(•) = L»irui»itn U«TA,
= •it»s»Hti) OAT*
-------�
en
ro
i
ro
UD
i.ii;«-
1.211
I.I SO
1 .006
KHIJS. .714
(HG/L)
.oil
.an;
.!«'
* * * * *
-.000*
15.70
Jb.7ll V.cTO
ai.ltl ,M.20 IB.70
KlVtU MILt Til HtAI) IIF HtACH
H.iU •)./()
.70
(•) = CALi:uLAIhll DATA, («) =
-------�
I
en
ro
i
oo
O
.[Ik
HLW
IHU/L)
.05<>
36.70
9./0
N1VCK MILE 10 HUD OF HftCll
(•) = CAlLULAItll U»[A, («) = ULASUULI) IIA1A
-------�
o
en
ro
i
co
PMtHUL
(Mk/L)
. Ittb
.162
.116
.ooo* » «-
13.70 11.c
* * *
* * * i *
Jb.70 32.20
27.70 Jl.?0 18.70
HIVFI- HUE III HEAD IIP HtACM
11.20 9.7(1 5.20 .70
(>) = CAltllLAItll (lir«, (HI = HIASIIIIth UAIA
-------�
APPENDIX D-5.3
MODEL PROJECTIONS
CONDITION 3
-------�
en
**** INPUT 0*TA LISTING FUR 1HE (JtlAL 11 SIRtAM UIJALllY ROUTING MflDFL •***
$SS (PHUliLtM IITLES) S.Vf
CARO IYPF
TITLE01
IITLE02
1 ITLE03
ri ILF.O'I
TITLE05
TITLFOh
TITLE07
TIILEOfl
T1TLF.09
TITLF. 10
TMLtll
TITLE12
TITLE 13
UTLE14
TITLE15
TITLhlf.
ENOfITLE
res
YES
YES
uu
YES
NO
YES
YhS
YES
YES
YES
YES
NO
NO
OUAL II PROGRAM TITl.tS
ArtARF. UtlAL-1 I nlTH HCN AND CHKniUL
NAME OH HASIN = VALLEY-OPOSSUM CRELK
CONSERVATIVE MINERAL IN MG/L
HYOKUGLN CYANIDE IN Mi/L
PHEN'JL IN MG/L
lEMPEHATURe IN DEGKEtS FAHENHEir
BlUCHEMICAL UXYGFN OEMANO IN Mli/L
ALGAE AS ChL A IN Mli/L
HHUSPHIJROUS AS P JN MB/L
OKUANIL iMIIHIJGEN Ifo MG/L
AMMUNIA NIIKUGEtJ IN MG/L
NITHlTb NI1KIJGEN IN MG/L
NITRATE NITROGEN IN MG/L
DISDLVEO UXYGEN IN MG/L
COLIFIJHMS AS MPN
rtAOHINUCLIUE
$S$ DATA TYPE 1 (CUNWIL OATA) J.B1-
CAIU) TYHK
LIST OATA INPUT
HLU1S PNINIEW
NU FLUrt AUGMENTAT1UN
SIEAOY STATE
NIJMUEK OF REACHES =
NUM UF HEADrtAlEHS =
TIMt STEP (HOURS) =
MAXIMUM RUUfE TIMh (HRS)=
ENDATAI
.00000
.00000
.00000
.00000
26.00000
1 .00000
.00000
30.00000
.00000
HARD TYPt
CUMPLMF REPORT
METRIC
NUMUtK UF JUNCTIONS :
NUMbER OF iffASTE LOADS :
LNTM. COMP. ELEMENT (Ml):
TIME INC. FOR RPT2 (MRS):
.00000
.00000
.00000
.00000
.00000
11.00000
.20000
.00000
.00000
*$iOATA IYPE 1A (ALGAE PRODUCTION AND NllROGEN OXIDATION CONST ANTS)SSJ
CAI
-------�
DATA TYPt 2 (REACH IDENTIFICATION) s»S>
en
oo
ro
CARD TYPE
STREAM REACH
STREAM HtACH
SIRtAM REACH
SIREAM HtACH
STREAM HEACH
STREAM REACH
STREAM REACH
SIRtAM REACH
STREAM I? F A C H
it 1 Kt Art i
-------�
S$$ DATA TYPE H (COMPUTATIONAL REACH FLAli FIELD) $*S
I
(Ji
CO
CO
CARO TYPE
FLAG FIELD
FLAG FIELD
FLAG HELD
FLAG FIEL')
FLAG FIELD
FLAG FIELD
FLAG FIELD
FLAG FIELD
FLAG FIELD
FLAG FIELD
FLAG FIELD
FLAG FIELD
FLAG FIELD
FLAG FIELO
FLAG FIELD
FLAG MELD
FLAG FIELD
FLAG FIELD
FLAG FIELO
FLAG FIELD
FLAG FIELD
FLAG FIELD
FLAG FIELO
FLAG FIELD
FLAG FIELD
FLAG FIELD
ENUATAU
REACH ELEMENTS/REACH
1.0
3.0
3.0
1.0
b.O
6.0
7.0
«.u
9.0
10.0
11 .0
18.0
13.0
11.0
15. 0
16.0
17.0
ltt.0
1S.O
30.0
31.0
83.o
83.0
81. 0
85.0
86.0
.0
6.
3.
5.
8.
3.
10.
11.
11.
1.
7.
8.
9.
ia.
i.
18.
1 ?.
<>.
1.
18.
18.
10.
5.
18.
7.
17.
1«.
0.
1.6.8.3
8.8.8.0
6.8.6.8
8.6.0.0
6.6.0.0
8.8.8.6
8.8.8.8
6.8.8.8
8.8.8.6
8.8.8.8
8.8.8.8
8.8.8.8
8.8.8.8
8.8.8.8
8.8.8.6
8.8.8.8
8.8.8.8
8.8.8.6
8.8.8.8
8.8.8.8
8.8.8.8
8.8.8.8
8.8.8.8
8.8.8.8
8.8.8.8
8.8.8.8
0.0.0.0
CUMPUTATIUNAL FLAGS
8.8.0.0.0.0.0.0.0.0.0.0.0.0.0.0.
o.o.o.o.o.o.o.o.o.o.o.o.o.o.o.o.
8.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.
0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.
0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.
8.8.8.8.6.8.0.0.0.0.0.0.0.0.0..0.
8.6.8.8.8.8.8.0.0.0.0.0.0.0.0.0.
8.3.8.8.8.8.8.0.0.0.0.0.0.0.0.0.
0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.
8.8.8.0.0.0.0.0.0.0.0.0.0.0.0.0.
8.8.8.8.0.0.0.0.0.0.0.0.0.0.0.0.
8.8.8.8.8.0.0.0.0.0.0.0.0.0.0.0.
,8.?.8.8.8.8.8.8.8.8.0.0.0.0.0.0.
,0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.
,8.8.8.8.8.3.8.8.0.0.0.0.0.0.0.0.
,8.8.8.3.8.8.8.8.8.0.0.0.0.0.0.0.
,3.3.8.3.3.0.0.0.0.0.0.0.0.0.0.0.
,0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.
.3.3.3.3.3.8.3.3.0.0.0.0.0.0.0.0.
,8.3.8.3.3.3.3.3.0.0.0.0.0.0.0.0.
.8.8.3.3.8.3.0.0.0.0.0.0.0.0.0.0.
,3.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.
,8.8.3.3.8.8.8.6.0.0.0.0.0.0.0.0.
.8.8.8.0.0.0.0.0.0.0.0.0.0.0.0.0.
.3.8.3.3.8.3.8.8.8.3.8.8.8.0.0.0.
.3.3.8.3.3.3.3.8.3.8.0.0.0.0.0.0.
,0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.
-------�
DATA TYPt 5 (HYDRAULIC COEFFICIENTS FUR DETERMINING VbLOCITY AIMl) UtPTH)
I
Ol
GO
-P.
CARD TYHK
HYDRAULICS
HYDHAUL1CS
HYDRAUL 1CS
HYDKAUL [US
HYDRAULICS
HYDRAULICS
HYDRAULICS
HYDRAULICS
HYURAULIC;>
HYDRAULICS
HYDRAULICS
HYDRAUL tCS
HYDRAULICS
HYDRAULICS
HYDRAULICS
HYDRAULICS
HYDRAULICS
HYDRAULICS
HYDHAULIC3
HYDRAULICS
HYDRAULICS
HYDRAULICS
HYDRAULICS
HYDRAULICS
HYDRAULICS
HYDRAULICS
ENDATA5
RtACH
1 .0
2.0
4.0
4.0
b.O
b.O
7.0
H.O
V . U
10.0
11.0
u.o
u.o
11.0
15.0
16.0
17.0
18.0
19.0
20.0
21 .0
22.0
23.0
2'l.0
25.0
26.0
.0
CUtFiJV
0910000
0910000
0910000
0910000
0179900
0179900
0331700
0 1 30? 11(1
IO / U t "I"
021 51100
0206200
0185100
0312900
0520600
0339300
0262500
0359600
0216500
0209700
0160200
0232800
0165200
0013000
0001926
0003210
0001950
0000000
tXKUUV
.6700
.6700
.6700
.6700
.6700
.6700
.6700
.6700
. t< / u <)
.6700
.6700
.6700
.6700
.6700
.6700
.6700
.6700
.6700
.6700
.6700
.6700
.6700
1.0000
1 .0000
1 .0000
1 .0000
.0000
CUtFUH
.1700
.1700
.1700
.1700
.31/1
.3171
.51.52
.9191
. '4 1 -1 •
.5792
.5591
.6712
.37(58
.2711
.3737
.1195
.3090
.6211
.5299
.6571
.5102
.6266
7 .5000
1 1 .6000
13.1000
11.0000
.0000
EXPUOH
.3300
.3300
.3300
.3500
.3300
.3300
.3300
.3300
. '.' * • M '
.1300
.3300
.3300
.3300
.3300
.3300
.3300
.3300
.3300
.3300
.3300
.3300
. 3000
.0000
.0000
.0000
.0000
.0000
CMANN
.0100
.0100
.0100
.0100
. 0 « 0 0
.0100
.0100
.0100
-.0100
.0100
.0100
.0100
.0100
.0100
.0100
.0100
.0100
.0100
.0100
.0100
.0100
.0100
.0100
.0100
.0100
.0000
-------�
$$$ UAIA TYPt 6 (REACTION COEFFICIENTS FUR OEOX YliENA T IUN AND REAERATIOH) $$$
I
cn
to
en
CARD TYPE
REACT
REACT
REACT
REACT
REACT
REACT
REACT
REACT
REACT
REACT
REACT
REACT
REACT
REACT
REACT
REACT
REACT
REACT
REACT
REACT
REACT
REACT
REACT
REACT
REACT
REACT
CUEF
COEF
CUEF
CUEF
CUEF
CUEF
COEF
COEF
COEF
CUFF
COEF
CUEF
COEF
COEF
COEF
COEF
COEF
COEF
CObF
CUEF
CUEF
COEF
CUf-F
CUEF
CUEF
CHEF
REACH
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
»
•
•
,
•
•
•
m
m
•
„
•
*
•
•
•
.
.
.
•
.
.
•
.
.
•
ENDATA6
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Kl
.40
.40
.40
.40
.40
.40
.40
.40
.40
.40
.40
.40
.30
.30
.30
.30
.20
.20
.20
.20
.20
.05
.05
.05
.05
.05
.00
K3 K21JPT
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00 3.00
.00 3.00
.00 3.00
.00 3.00
.00 3.00
.00 .00
2
2
2
2
2
3
4
1
1
1
1
4
2
3
3
1
1
Kd
.73
.73
.73
.73
.73
.12
.26
.33
.66
.66
.66
.67
.10
.08
.88
.08
.50
.58
.58
.50
.35
.90
.90
.90
.90
.90
.00
CHEDK2
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
EXPUK2
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
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SS$ DATA TYPE faA (ALGAE, NITHOUElM, AMU PHOSPHOROUS CONSTANTS) I$S
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CAKD 1YPE
ALGAE, N
ALGAE, N
ALGAt, .M
ALGAE, N
ALGAE, i\i
ALGAt, "1
ALG«f, ,M
ALGAE, >\i
ALGAE, iM
ALGAE, N
ALGAE, IM
ALGAt, M
ALGAE, N
ALGAF, N
ALGAE, N
ALGAt, N
ALGAE, N
ALGAE, i\l
ALGAt, N
FNOATA6
AND
AND
AND
AND
AND
AND
AND
ANU
ANU
AND
ANU
AhU
ANU
AND
ANU
ANU
AND
ANU
ANU
AND
ANU
AND
AND
AMD
ANU
AND
P
P
P
P
F
P
F
P
P
P
P
P
P
P
P
P
P
P
P
P
P
P
P
P
P
P
CUtF
CUEF
COEF
COtF
CUEF
COtF
CUtF
COtF
CUtF
COEF
CUfcF
COtF
CUtF
CUEF
CUtF
COtF
COEF
COEF
COtF
CUtF
CUEF
COEF
CUEF
COEF
COtF
COtF
REACH
1 .0
.
20.0
20.0
20.0
20.0
20.0
20.0
20.0
20.0
20.0
20.0
20.0
20.0
20.0
20.0
20.0
20.0
20.0
20.0
20.0
20.0
.0
ALGSE i
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
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.0
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.0
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.0
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KIMH3 h
.00
.00
.00
.00
. 00
.00
.0(1
.20
.20
.20
.20
.21)
1 .20
.80
.80
.80
.80
.80
.80
.80
.80
.80
.OU
.00
.00
.00
.00
(N02
.55
.55
. 55
.55
.55
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.55
.55
.55
. 5b
.55
.S>3
.55
.55
.55
.55
.55
.55
.55
.55
.55
.55
.55
.55
.55
.55
.00
H-NHi
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
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.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
D-PO
.00
.00
.110
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.'00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
KCIRG-N
.00
.00
.00
.00
.81
.81
.81
.12
.12
.12
.12
.12
.M2
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
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$5$ DATA TYPt 6U (OTHER COCFF 1C I EN f S )
o
i
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co
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CARD lYPt
OTHER COEFFICIENT
OTHER COEFFICIENTS
OTHER COEFFICIENTS
OTHER COEFFICIENTS
OTHER COEFFICIENTS
UTHEH COEFFICIENTS
OTHER COEFFICIENTS
01HEH COEFFICIENTS
OTHER COEFFICIENTS
OTHER COEFFICIENTS
OTHER COEFFICIENTS
OTHER COEFFICIENTS
OTHER COEFFICIENTS
OTHER COEFFICIENTS
OTHER COEFFICIENTS
rmiEK COEFFICIENTS
OTHER COEFFICIENTS
OTHER COEFFICIENTS
OTHER COEFFICIENTS
OTHER COEFFICIENTS
OTHER COEFFICIENTS
OIHEU COEFFICIENTS
OTHER COEFFICIENTS
OTHER COEFFICIENTS
OTHER COEFFICIENTS
OTHER COEFFICIENTS
ENDATA63
EACH
l.U
2.0
J.U
1.0
5.0
6.0
7.0
8.0
1.0
10.0
11.0
12.0
i.O
<4.0
5.0
b.O
l.U
1H.O
1'J.O
30.0
21.0
22.0
?3.0
2
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S$S DATA TYPt H (RUNOFF CONO1TIONS)
O
cn
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CARD TYPF
klJIJOFh CONDITIONS
RUNOFF CONDITIONS
RUNOFF COND1T IONS
RUNOFF CONDI f IiJNS
RUNOFF CUrjDIT IONS
RUNOFF CONDI 1 IONS
RUNOFF CONDI f IONS
WUIJUr-F CONDITIONS
RUNOFF CONDI I IONS
RUNOFF CONDITIONS
RU|JU> r LUivii I I I 'M.>
KUNUFF CONDITIONS
HIJNOFF CONDITIONS
RUNOFF CONDITIONS
RUNOFF CONDITIONS
RUNOFF CONDITIONS
RONOFF CONDITIONS
RUNOFF CONDITIONS
RUNOFF CONDITIONS
RUNOFF CONDITIONS
RUNOFF CONDITIONS
RUNOFF CONDITIONS
RUNJFF CONDITIONS
RUNOFF CONDITIONS
RUNOFF CONDITIONS
ENDATAB
Rt ACH
1 .0
2.0
3.0
'1.0
'J.O
b .0
1 .0
b.O
'^.0
1 (1 . U
It:.*.'
1 5.0
I '1.0
15.0
tb.O
17.0
10.0
19.0
20.0
?1 .0
?a.o
23.0
2<).0
25.0
26.0
.0
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.0
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DATA TYPE 8A (INCREMENTAL F-LLW CONDITIONS FOK Nil HUGEN , PHOSPHOROUS ,
COLIFORM AND RAD 1UNUCL 1 Ob ) $J$
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CAHI) TYPE
RUNUFF CUNO-a
RUNUFF COHO-a
RUNUFF CONO-a
RUNUFF CONO-a
HUNUFF CONO-a
RUHUFF CUND-a
RUHUFF COMU-a
HUNUFF COND-2
HtJHUFF CUNU-a
RUNUFF CONO-a
KUNUFF CtlNl)-a
RUNU^F CUNO-?
HUNUFF CONI)-a
HUNUFF CUND-2
HUNUFF CUNO-?
RUNOFF COiXD-a
RUNUFF COMU-a
HUNUFF CUND-2
RUNOFF CONO-a
HUMOFF COUD-2
RUNUFF CONO-a
HUNUFF CONO-a
RUNUFF COiMD-2
RUNOFF
RUNUFF COiMO-2
RUNUFF COiMU-2
ENDATA8A
REACH CHLURA
i.
a.
3.
7.
8.
9.
10.
11.
13.
11.
15.
16.
17.
18.
19.
20.
22.
23.
cJI.
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S$3> DATA TKPh 9 (INITIAL CUNDI1IUNS) $$$
cn
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CAHO TYPE
INI HAL CUN01 TIUUS
INI f IAL CONOI TIONS
INI IIAL CONDITIUNS
IiMI HAL CUNOI flUIMb
INITIAL CONDITIONS
INII1AL CONDITIONS
INI T IAL CONDI TIONS
INIIIAL CONDITIONS
INITIAL CONDITIONS
IiMI TIAL C'INJI HUNS
INITIAL CUNOII IONS
INI I IAL CIJNOI [ IONS
I4ITIAL CONDI IIUW5
Ml I J. AL Ull'iul I lUHS
INI I IAL CONDI I IUNS
INITIAL CONOItIONS
IiMI HAL CONDI TIONS
INITIAL CONDITIONS
INITIAL CONDITIONS
INI I IAL CONOI HUNS
INITIAL CONOIIIONS
INITIAL CONDITIONS
INITIAL CONDITIONS
INI IIAL CUNOITIONS
INI HAL CUNOI T IONS
ENOATA9
IACH
1 .0
2.0
3.0
4.0
5.0
6.0
/ .0
rt.O
4.0
1 0 . 0
1 .0
l^.U
14.0
'D.
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$S$ DA[A TYPE 9A (INITIAL CONDITIONS FOR CHLOROPHYLL A, NITROGEN, PHOSPHOROUS,
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CARO TYPE
INITIAL COND-a
INITIAL CONO-a
INITIAL COND-a
I JITIAL COND-a
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INITIAL CONO-a
INI HAL CONO-a
INITIAL COND-a
INITIAL COND-a
INITIAL COND-a
INITIAL COND-a
INITIAL CUND-a
INITIAL CONO-d
INITIAL COND-a
INITIAL COND-a
INITIAL coNo-a
INITIAL coNo-a
INITIAL COND-a
INITIAL CONO-a
INITIAL COND-a
INITIAL COND-a
INITIAL COND-a
INITIAL CONO-a
INITIAL coND-a
INITIAL COND-a
ENOATA9A
$SS DATA TYPE
CARO TYPE
HEADWATER
ENDATA10
$$$ DATA TYPE
REACH CHLORA
1 . .0
a. .0
3. .0
<4. .0
5. .0
6. .0
7. .0
8. .0
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10. . 0
11 . .0
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13. .0
11. .0
15. .0
16. .0
17. .0
18. .0
19. .0
ao. .0
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10 (HEADWATER SOURCES)
HEADWATER ORDER AMD
1. HOW=UPOSSUM CK
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.00
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.00
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.00
.00
.00
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.00
.00
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.00
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SdS
IDEM
10A (HEADWATER CONDITIONS FOR
00
00
00
00
00
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oo
00
00
00
00
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00
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00
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.00
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.00
.00
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.00
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EIMDAT A10A
HDWA1EH CHLORA
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3.SS DATA TYPE II (rtASTE LOADINGS) $Si
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WASIELOAD
WASIELOAD
wAIiTELOAD
WASrhLOAIi
t« A S 1 1 I uAll
WAS TELOAD
WASTELOAD
WASTELOAD
WASTELOAD
WASTELOAD
WASILLOAD
WASItLOAD
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WASTtLUAO
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42.7
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40.9
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(t-Hb) (Fl) HtG (MG/L) (MG/L) (HG/U
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,9b .47 95.00 b.hB 4.92 .69
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1.04 .51 95.00 5.7b 5.27 ,9B
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.51 .04 86. OU 5.92 4.99 .00
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.53 .04 (16.00 b.OI 4.85 .02
.53 .04 66.00 b.DS 4.78 .02
.53 .04 Ch.OO b.<19 4.71 .01
,b3 .04 Ab.OO b.12 4.64 .04
,'ji .04 Hb.uO b.lb 4.57 .04
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.17 .77 Bb.UO 6.2U 4.3h .06
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.17 .77 1.6.00 6. '11 4.19 .07
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.t.9 2.41 M6.00 7.?J 10. D6 .65
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45.5
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44.9
44. 7
44.5
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41.9
43.7
43.5
49.1
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42.9
42.7
42.5
42.1
42.1
41.4
41 .7
41.5
41 .1
41.1
40.9
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36.5
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IIXYI.EU Dill) Nil! NU2 CKLI ALGAE ALGAE OKG-N
IU HEAIR DECAY DECAY DECAY DELAY CHOhlh HESPR IIUG-N DECAY CON-I HCN PHENOL
MILE II/DY) (I/DY) (I/DV) (1/1)1) (I/Or) (I/DY) (I/DY) (MG/L) (HG/L) (Mti/L) (MG/L) (HG/l)
45.5
45.3
45.1
44.9
44.7
44.5
44.3
44.1
43.7
43.5
43.3
43.1
42.9
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42.5
42.3
42.1
41 .9
41 .7
41 .5
41 .3
41.1
40.9
40.7
40.5
40.3
40.1
39.9
39.7
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19.3
39.1
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18.7
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18.3
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17.9
17.7
37.1
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36.5
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3.4b
3.4b
3.46
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3.46
3.46
3.46
3.46
3.46
3.46
3.46
3.46
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3.19
3.19
3.41
3.66
3.66
3.66
3.66
3.66
3.66
3.66
3.66
3.66
4.34
5.02
5.02
5.02
5.02
5.02
5.02
5.02
5.02
5.02
5.02
3.29
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2.45
2.45
2.45
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HIWtAH IIHALIM SIMULA IIDN
UU*L II SIHE*M UIIAlirr HOOFING MUlltL
»**> SIF.ADV SHIt SIHIIIATIUN >••••
Ul/IPIir I'»GE NUHHER
O
tn
co
I
Ktll ELT
NUH MUM
51 V I
52 9 2
53 9 3
54 9 'I
55 IU 1
56 IU i>
5) IU 3
5b 10 «
59 IU 5
60 IU 6
61 IU 7
62 II 1
Mil a
64 II 1
65 II 4
66 II 5
67 116
6(1 11 7
69 II a
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72 12 3
71 12 4
74 12 5
75 12 6
76 12 7
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79 11 1
80 13 2
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92 11 |4
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04 14 2
95 14 B
9to 11 4
97 IS 1
9B 111 2
99 15 .1
100 I'j 4
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MILE
35.7
35.5
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55.1
34.9
34.1
34.5
34.1
14.1
)i,9
3J.7
11.5
31.1
33.1
32.9
32.7
32. 5
32.1
12.1
31.9
31. 1
31.5
31.1
31.1
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30.5
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29.9
29.7
29.5
29.1
29.1
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20.1
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27.9
27.7
27.5
27.1
27.1
2h.9
26.7
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26. 1
26.1
25.9
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III HE A ID
MILE (!/!>»)
15.5 .11
15.3 .94
15.1 .94
14.9 .94
14.7 .94
14.5 .94
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14. 1 .94
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11.5 .94
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11.1 .79
12.9 .79
12.7 .79
12.5 .79
12. J .79
12.1 .79
11.9 .79
31.7 .42
11.5 5.05
11.3 5.05
11. 1 5.05
30.9 5.05
10.7 5.05
10.5 5.05
10.1 5.05
10. 1 5.05
29.9 3. (.6
29.7 2.2)
29.5 2.27
29.1 2.27
29.1 2.27
28.9 2.27
28.7 2.27
2S.5 2.27
2A.1 2.27
28.1 2.2(
27. 9 2.27
27.7 2.27
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27.1 2.27
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26.9 4.20
26.7 4.?0
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26.1 4.20
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(i/im d/uf) ll /or>
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(MG/L) (HG/L)
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SllltAH UIIAL1TY SIMULATION
(JUAL II STREAM iJIIALllr HUUTING MIIDEL
..... STEADY STATE SIHIILATIIIN
OUTPUT PACJE NUIItlEH
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NUH NllH
101 Ib 5
102 15 6
103 ii r
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105 15 9
106 IS ID
107 IS II
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104 Ib 1
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112 Ib 4
113 Ib 5
111 Ih b
111 Ib 7
lib Ih 8
II' lt> 9
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114 Ib 1 1
120 Ib 12
121 16 13
122 U 1
123 17 2
121 I? 3
I2S 17 4
I2b 17 5
I2/ 17 b
I2B 17 7
124 17 b
130 17 4
lit IB 1
132 10 2
133 IB 3
134 IH 4
135 14 1
llo 14 2
137 14 3
lib 14 4
134 14 5
140 14 b
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143 14 9
144 14 10
145 1411
116 14 12
|47 20 1
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I'I9 20 5
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MILt MILE
25.7 25.5
25.5 25.3
2S.3 25.1
25.1 24.9
24.9 24.7
24.7 24.5
24.5 24.3
24.3 24.1
24.1 23.9
23.4 23.7
21.7 23.5
23.5 23.3
23.1 23.1
23.1 22.9
22.4 22.7
22.7 22.5
22.5 22.1
2c!.l 22.1
22.1 21.9
21.9 21.7
21.7 21.5
21.5 21 .3
21.) 21.1
21.1 20.9
20.9 20.7
20.7 20.5
20.5 20.3
20.1 20.1
20. 1 19.9
19.9 19.7
14.7 19.5
19.5 19.3
19.3 19.1
19.) IB. 9
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IB. 3 IH.I
Ifl.l 17.9
17.4 17.7
17.7 17.5
17.5 17.3
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17.1 16.9
lb.9 16.7
lh.7 16.5
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lb.| 15.9
15.4 15.7
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1 S . i 1 S . i
IJXYGEN
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(I/UY)
4.20
4.20
4.20
4.20
4.20
4.20
4.20
4.20
2.69
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.1 7
.17
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.17
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.00
.00
.00
.(ID
.00
.00
.00
.00
.00
.00
.(Ml
.Ob
.00
. IH'
ALGAE
GHIIWUI
U/OY)
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.Oil
.00
.00
,ou
.00
.00
.00
.00
.Oil
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.110
.00
.00
.00
.00
.00
.00
.00
.on
. Ml'
AIGAE
HESI'R
(1/DY)
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.no
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.no
.00
.00
.110
.00
.110
.I'll
(IHG-N
(MG/L)
.12
.12
.12
.32
.12
.32
.32
.12
.12
.32
.12
.12
.12
.32
.12
.32
.12
.32
.32
. 12
.32
.32
.32
.32
.32
.32
.32
.32
.12
.32
.3?
.32
.32
.11
.31
.31
.31
.31
.31
.11
.31
.31
. II
. 11
.11
.31
.11
. 11
. U
. II
ORG-N
DECAY
(HG/L)
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.Oil
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.01)
.00
.00
.10
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
. 00
CIJN-I
(MG/L)
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
MCN PHENOL
(Mli/L) (MG/L)
.002 .022
.002 .022
.002 .022
.002 .022
.002 .022
.002 .022
.002 .022
.002 .022
.002 .022
.001 .022
.001 • .022
.001 .022
.001 .022
.001 .022
.001 .022
.001 .022
.001 .022
.001 .022
.001 .022
.001 .022
.001 .022
.001 .022
.001 -.022
.001 .022
.001 .022
.001 .022
.001 .022
.001 .022
.001 .022
.00) .022
.001 .022
.001 .022
.001 .022
.001 .022
.001 .022
.001 .022
.001 .022
.001 .022
.001 .022
.001 .022
.001 .022
.001 .022
.001 .022
.001 .022
.001 .022
.001 .022
.001 .022
.001 .022
-OfOI .022
.001 .022
-------�
SIHtAH .JIUlilr &IMIII.AI I III;
DUAL II SIKtAM IIUALIU HIIUIIUG MdUKL
..... SltAIIV UIAFE SIMULATION
UUIPIir HAGl NllHhtH
o
I
en
co
I
ro
(Itlt.Cn Him Nil) «U<>
HIM FL!
NUM NIIM
151 20 b
152 20 6
153 20 T
154 20 8
I5i 20 9
ISb 20 10
IS/ 20 II
ISH 20 12
159 21 1
160 21 2
161 21 ]
162 21 4
163 ?1 5
164 21 6
165 21 7
tbb 21 8
167 21 1
IhU 2| 10
169 22 1
170 22 2
171 22 3
172 22 4
173 22 5
174 21 1
175 23 2
176 23 3
17? 23 4
I7« 23 b
17V 23 b
|AO 23 7
181 23 B
l»2 23 9
163 23 10
184 23 II
1Kb 23 12
lib 24 1
IH7 24 2
inn 24 3
189 24 4
I'lO 24 5
191 24 6
llrf 24 7
193 2b 1
194 ?5 2
I9b 2b 3
ISb 2b 4
197 2b 5
I9H 25 b
199 25 7
iltli 2b H
FNllM
MILfc
li.3
IS.I
14.1
14.7
11. i
14.3
14.1
13. 9
13.7
11. 5
13.3
li.l
12.9
12.7
12.5
12.3
12.1
11.9
11.7
II. 5
11.3
II. 1
10.1
10. 1
10.5
10. 1
10. 1
9.9
9.7
9.5
9.3
9. 1
8.9
8.7
n.-i
U.I
H.I
7.9
7.7
7.b
7.1
7.1
6.9
b.7
h.b
h. 1
b. 1
5.9
b. /
b.b
flj HEAIH DECAY lltLAI DtCAl
MILE (I/U») (l/lir) (I/UVI (I/U»)
IS.I
14.9
14.7
14.5
14.3
14.1
1 3.9
13.)
11.5
13.3
13.1
12.9
12.7
12. S
12.3
12.1
11.9
11.7
II. 5
11.1
II .1
10.9
10.7
10. 5
10.1
Ib.l
9.9
1.7
9.5
9.1
9.1
8.9
6.7
8.S
8.1
8.1
.9
.7
.5
.3
.1
A. 9
b.7
b.3
b.l
•).9
b.7
•i.S
S. 1
.bj .2-i .01 .95
.61 .2b .01 .9%
.61 .25 .01 .9%
.61 .25 .01 .95
.b3 .25 .01 .95
.61 .25 .01 .95
.61 .25 .01 .95
.61 .25 .01 .95
.Ob .25 .01 .95
.4b .25 .01 .95
.4b .25 .01 .95
.16 .25 .01 .95
.4b .25 .01 .95
.16 .25 .01 .95
.16 .25 .01 .95
.16 .25 .01 .95
.46 .25 .01 .95
.46 .25 .01 .95
.66 ,06 .01 .95
.91 .06 .01 .95
.91 .06 .01 .95
.9) .06 .01 .95
.91 .Oh .01 .95
.07 .06 .00 .95
.23 .06 .00 .95
.23 .06 .00 ,9S
.?J .06 .00 .95
.?! .06 .00 .95
.21 .Ob .00 ,9b
.23 .06 .00 .95
,2S .Oh .00 .95
.21 .Oh .00 .95
.21 .06 .00 .9b
.21 .Ob .00 . 4S
.23 .06 .00 .95
.16 .06 .00 .9b
.00 .06 .00 .95
.08 .06 .00 .95
.OH .Oh .00 .95
.08 .Ob .00 ,'lb
.08 .06 .00 ,')b
.OH .06 .00 .95
.06 .06 .00 .95
.Oa .06 .00 .95
.05 -Oh .1)0 .'15
.05 .06 .00 .95
.Ob .06 .00 .95
.Ob .06 .00 .9b
.Ob ,06 .00 .'1^
.Ob .06 .00 . S b
CULI
DECAY
(I/in)
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.0(1
.00
.00
.00
.00
.00
.00
.00
.00
.no
-On
»Ll,At
bkllNIH
U/u»
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.110
AlGAt
ktSHU
(1/UV)
.00
.00
.00
.00
.00
.(10
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.1111
OHC-14
(HG/L)
.31
.31
.31
.11
.11
.11
. 11
. tl
.11
.11
.11
.11
.11
.31
.11
.11
.31
.11
.31
.31
.31
.11
.11
.11
.11
.11
.11
.11
.11
.11
.11
.11
.11
.31
.30
.10
. 10
.10
. 10
. 10
.10
. 10
. 10
.30
.10
.30
. 10
. 10
. iO
. JO
UHG-N
OECAV
(MG/1.)
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
CON- I
(MG/U
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.OllO
MCN
(MG/U
.001
.001
.001
.001
.001
.001
.001
,000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.001)
PlltNUL
(MI./L)
.022
.022
.022
.022
.022
.022
.022
.022
.022
.022
.022
.022
.022
.022
.022
.022
.022
.022
.022
.022
.b22
.022
.022
.022
.022
.022
.022
.022
.022
.022
.022
.022
.022
.022
.021
.021
.021
.021
.021
.0?!
.0?!
.021
.021
.021
.021
.021
.021
.021
.021
.0?!
-------�
SIKtMl IIUALIIV bIMULAIION
DUAL II 3IHE»M DUALITY H1IUT1NU HUUEL
..... SIKAOY 3UIt SIMULAHUN •••<•
OUIHUr CXit NIIMHEK
cn
CO
I
ro
ro
KCH EH
NIIH NUM
201
tot
201
204
201,
iOb
dVI
20B
209
tlo
211
212
213
ail
215
216
an
aiti
219
220
221
222
221
2S
25
25
25
25
25
25
24
25
26
26
26
26
26
26
.26
26
26
26
26
?h
26
26
9
III
II
12
13
14
15
16
17
|
2
1
4
5
6
7
n
9
Hi
1 1
12
13
14
FiiiiM
MILt
5.3
5.1
'1.9
H.l
l.i
4.1
1. 1
-!.»
1.7
J.5
J.I
3.1
2.9
2.7
J.b
2.1
2.1
.9
.7
.S
. J
.1
.9
IIXVGFM
111 HE»IH
HUD
DECAY
NH) Nil? CULI tLHAt
UECAY UECAY IJtCAI GHOhlH
AlKAt UKli-N
HISPH OHG-U OLCAl
CON-I
MCN I'MENUL
MILt (I/IIY) (I/OY) (I/U») (I/HI) (l/(l») (I/Of) (|/D») (ht/L) (MG/LI (HG/L) (MG/U
S.I
'1.9
1.7
a. 5
1.1
4.1
J.9
3./
3.5
J. J
3.1
2.9
2.7
2.5
2.3
2.1
1 .9
1.7
1.5
1.3
1 .1
.9
.7
.05
.Oi
.05
.Ob
.05
.OS
.05
.05
.05
.04
.U4
.04
.04
.04
.04
.04
.04
.04
.04
.04
.04
.04
.04
• Oh
.06
.U6
.Oh
.Oh
.06
.06
.Of.
.Oh
.06
.06
.06
.06
.Oh
.06
.06
.06
.Oh
.06
.06
.06
.06
.06
.00
.00
.00
.00
.00
.Ou
.00
.00
.00
.00
.00
.00
.00
.00
.OU
.00
.00
.00
.00
.00
.00
.00
.95
.95
.95
.95
.95
.95
.95
.95
.95
.95
.95
.95
.95
.95
.95
.95
.95
.95
.95
.95
.95
.95
.00 I.9S
.00
.00
.00
.00
.00
.00
.00
.OU
.00
.00
.00
.00
.00
.ou
.00
.OU
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.on
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.Oil
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.10
.30
.30
.30
.10
.10
.10
.30
.30
.30
.JO
.30
.30
.30
.10
..10
.30
.30
.10
.30
.30
.10
.10
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000 •
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
(HG/L)
.021
.021
.021
.021
.021
.021
.021
.021
.021
.021
.021
.021
.021
.021
.021
.021
.021
.021
.021
.021
.021
.021
.021
-------�
O
I
cn
*
CO
ro
CO
1.113
I).II. I.HflH
(HG/L)
3.17H
i.bli
3. in 'II .. (>) = MLAS(IHtl)
-------�
0
01
CO
ro
6.621
s.bao
n.O.D. 4.II4
(HG/L)
I. nil
-.000* ---- *----* ---- t ---- + •
1S.70 1|.<;0 3h.70
?7.70 fl.itt IH.MI 14.20
K1VEH Milt ril HFAfl OF RttCM
9.7(1 S.20
.70
(*) - CALTdLAltU DATA, (XI = -iKiSlillCO (H I A
-------�
cn
CO
i
ro
tn
UHb»NIC-N
(HG/L)
.S3«
.181
.10'
.15
.OT
'II .t>0 56. Ml
«*7 ,7(1 ? i.(?0 10. lit I 1.2
• I VF H f-lll ID IH AO lit- i^LALH
i.;o s.ao
.70
(•) = CAIMll.AU.il IMIA, (I) = UlASlJKtll IIAlA
-------�
I
en
CO
(V)
cr>
I .45 5
will
MG/L)
1.1 JU
.thO
.81
.646
.161
m.iu
fi.io ei.fo ii.ru
l-IVEk Hilt lu Ht»l) OF Rb«CM
I*) = CAlCUlAlhl' DAT*. (X) = Ht»SUktl)
-------�
o
I
en
CO
i
ro
IMG/LI
.241
.IHO
11.20 U t*.i« 18.70 14.211
kltfEh MILh III MHI1 UF HtACII
(>) = CAlClltAltD HAIA, (>) = HtA.S4IHtl) DAI*
-------�
o
I
en
GO
00
1 .H
/.Old
b.!5b
NUJ 0.1U1
(MU/L)
1.506
i.bJO
.H77
3b.fO H.dO
cfj.70 ?3.20 18.70 I'l.iO
HIVtH MILE ru HEAD OF HK»CH
1.10 S.iO
.70
(*> = tAUCULtllU HAI», (X) = MtASIJKtO DATA
-------�
o
I
en
co
i
ro
l.OJ'l
I.HIill
I.65-*
fHUb. 1.037
CMG/U
****
I
I
.uou«-
* « At
Hl.
-------�
CO
I
CO
o
HCN
(MG/L)
.uir
.111%
.011
.Oil
.00,!
.IIOU*
IS.70
HI. ill Ah. II)
ii. id 27. 70 <>j.iO 18.70
I'lVtH Mitt fu HHI> (IF WEACII
./O
(•) = CALClll.*nU |J»1», («) = MEASUUtO DAI*
-------�
O
I
01
•
CO
co
I'MtNUL
IMG/L)
.ObS
.USB
.036
-UI-)
.01 1
. 00<)« * • » ^ 1 *-
U5./H 'l|.dU Jo. II) il.t
i is.fa ia.;o it.in 1.1*1 s.io ,;o
HILl Til III Al) OF lit Al.ll
I11H-* 0
(•) = l.»LCUL«ltl) DAT*, Ik) = '-itAStlHtll II« I «
-------�
APPENDIX D-5.4
MODEL PROJECTIONS
CONDITION 4
-------�
D
O1
•
-F*
I
**** INPUT DATA LISIINI, FOR HIE (JUAL II SIKEAH DUALITY ROUTING MODEL ****
$S$ (PROBLEM TITLES) SS$
CAHO TYPE
1 ITLEOl
TITLE02
TITLE03
TITLEU4
TITLE05
TlTLf 08
TITLhO/
HlLEOft
I ITLE09
TITLtlf)
T1TLF. 11
TITLE I 3
TITLE 13
TITLE It
TITLE15
TITLE16
END TITLE
YES
YES
YES
NO
YES
NO
YES
YES
YES
YES
YES
YES
NU
NU
UUAL II PKIIGkAM T1TLIS
AWAKE OUAL-II Wl(H HCM AND PHFNOL
IJAMF OF bASIN = VALLEY-OPOSSUM CPFl-K
CONSERVATIVE MINERAL IN MG/L
HYDROGEN CYANIOE IN MG/L
I'lltNllL IN MG/L
IF.MPERATURE IN DEGKEHS t-AkENMfcll
rtlllCHEMICAL IJXYUEN OKMANI) 1IJ MG/L
ALGAE AS CHL A IN MG/L
PHI.ISHHIJKUUS AS P IN MG/L
ORGANIC NITKIIGtN IN MG/L
AMMIINIA NIIRIIGEN IN MG/L
NITWIIE NITKOGEN IN MG/L
NITRATE NIIKOGEN IN MG/L
UISULVEO OXYGEN IN MG/L
COL1FORMS AS MPN
KADIONUCL1DE
S$S DATA IYPE 1 CCONTROL DATA) S$S
CAHD TYPE
LIST DATA INPUT
PLOTS PRINTER
NO FLUW AUGMENTATION
STEADY STATE
NUMHtW JF REACHES =
NUM OF HEADrtAfEHS =
TIME STEP (HOURS) =
MAXIMUM ROUTE TIME (IIHS) =
ENDA(Al
.00000
.00000
.00000
.00000
28.00000
1.00000
.00000
30.00000
.00000
CARD TYPE
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NUMBER OF JUNCTIONS :
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LNTH. COMP. ELtMENT (MI):
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.00000
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.00000
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0 UPTAKE llY NH3 IIXIDfMG 0/MG N) =
I) PROD. BY ALGAe (MG O/MG A) =
N CONTENT OF ALGAE (MG N/MG A) =
ALG MAX SPEC GROW1H RATE(1/DAY)=
N HALF SATORATIUN CONST. (Mt;/L) =
LIGHT HALF SAT CONST(LNGLY/M1N)=
HCM TEMP COEF =
ENDATA1A
CAKO TYI't
.0000 MINIMUM REAEKATIOiM CONSTANT OPT= .0000
.S.^iOO 0 UPTAKE BY M()2 OXIIMMG 0/MG N)= 1.1100
2.0000 O UPTAKE BY ALGAE (MG 0/MG A) = 1.5000
.oiibo P cuNiEHi OF ALGAE (MG P/MG A) = .0130
2.0000 ALGAE RtSPIRATIOM RATE (I/DAY) = .1000
.3000 P HALF SATURATION CONST. (MG/L)= .0«00
.iboo TUTAL DAILY RADIAnow(LANGi EYS)= 500.0000
1.1)000 PHEMOL TEMP COFF = 1.0000
.0000 .0000
-------�
$S4 DATA TrPt 2 (REACH IDENTIFICATION) SJS
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STREAM REACH
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$S$ DATA TYPE
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1 .0
2.0
3.0
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5.0
6.0
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12.0
13.0
11.0
15.0
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19.0
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21 .0
22.0
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25.0
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15.7
11.5
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HYURAUL ICS
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1 .0
2.0
3.0
'1.0
5.0
b.O
7.0
H .0
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10.0
1 1 .0
12.0
1 3.0
11.0
15.0
16.0
17.0
18.0
14.0
20.0
21.0
22.0
23.0
21.0
25.0
26.0
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CdEFljV
0410000
0410000
0410000
0 9 ll/ 0 0 ('
0 '1 7 4 4 0 0
017441)0
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0 2 1 5 1 0 0
0206200
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0312900
0520600
0334300
0262500
0354600
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0160200
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1 .0000
1 .0000
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CUEFUH
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.1700
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.1700
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REACT
REACT
REACT
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REACT
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REACT
REACT
REACT
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S7EACT
REACT
REACT
REACT
REACT
REACT
REACT
REACT
REACT
REACT
REACT
REACT
REACT
REACT
ENDA1
TYPE
COEF
COEF
CQF.F
COEF
COEF
COEF
COEF
COEF
COEF
COEF
COEF
COEF
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COEF
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COEF
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2
3
4
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7
8
9
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1 1
12
13
14
15
16
17
18
19
20
21
22
23
24
25
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OTHER COEFFICIENTS
OTHER COEFFICIENTS
OTHER COEFFICIENTS
OTHER COEFFICIENTS
OTHER COEFFICIENTS
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$S$ DATA TYPE 7 (STREAM JUNCTIONS) $$$
EACH
1.0
2.0
3.0
'1.0
5.0
6.0
7.0
n.o
9.0
10.0
11.0
12.0
13.0
14.0
15.0
16.0
17.0
1(1.0
19.0
20.0
21.0
22.0
23.0
21.0
25.0
26.0
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HUIIOFF CONDITIONS
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.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
-------�
:6SS DATA TYPE OA ( INCREMf N I AL FLUkv CIIN01TIUNS F Ilk N I 1 HliGt iJ , PH(tSHlltlU(Jli:> ,
COL1FOHH AND R AD lONUCLIOF. ) SSS
I
en
CARD TYPE
RUNOFF CHND-2
RUNOFF COMO-2
MUNUFF CUNO-2
RUNOFF CflNO-2
RUNOFF CONO-2
RUNOFF CONO-2
RUNOFF COND-?
RUNOFF COND-2
RUNOFF CONO-2
RUNOFF CUiMO-2
RUNOFF COND-2
RUNOFF CONO-2
RUNOFF COM)-2
RUNOFF CUNU-2
RUNOFF CONO-2
RUNOFF CONO-2
RUNOFF CONO-2
RUNOFF CONO-2
RUNOFF CUNO-2
RUNOFF COMO-2
RUNOFF CONO-2
RUNOFF CUNO-2
RUNOFF CONO-2
RUNOFF COiMO-2
HUNOFF CONO-2
RUNOFF Cdi\IO-2
HNOATA84
RtACH CHLORA
1 .
«>.
3.
4.
5.
6.
7.
10.
11.
12.
13.
15.
16.
17.
Ifl.
19.
20.
21.
21.
25.
26.
0.
RA
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.u
.0
.0
.0
.0
.0
.0
.0
NH3
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
N02
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.OU
.00
.00
.00
.00
.00
.00
NO 3
.00
.0(1
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
Put
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
CHL1
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
RAON
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
OHG-N
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
-------�
$S$ DATA TVPt
(INITIAL CONDITIONS)
O
cn
-P.
i
CAHD TYPt
INI HAL
INITIAL
I NIT IAL
INI HAL
INITIAL
INITIAL
INI HAL
INITIAL
INITIAL
INITIAL
INITIAL
INITIAL
T N I H A L
INI HAL
INI HAL
INI HAL
INITIAL
INITIAL
INI HAL
INITIAL
INITIAL
INITIAL
INITIAL
INITIAL
INI f IAL
INITIAL
ENOATA9
CONDIT IONS
CONDI IONS
CONDI IONS
CONDI I DNS
CONDI IONS
CONDI IONS
CONDI IONS
CONDI T IONS
CONDITIONS
CONDI THINS
CONDITIONS
CONDH IONS
CONDI 1 IUNS
CONDI F 1 ilNS
CONDI 1 IONS
CONDI1 IONS
CONDITIONS
CONDITIONS
CONDITIONS
CONDITIONS
CONDITIONS
CONDITIONS
CONDITIONS
CONDITIONS
CONDI 1 1 ON 3
CONDI HONS
KEACH rEMP
1
2
i
'1
•5
6
7
b
9
HI
1 1
1 S.
\ 4
M
1 S
Ifa
17
Ifl
19
20
8i
22
83
21
25
?.h
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
. 0
.0
.0
.0
.0
.0
.0
.0
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.0
.0
.0
.0
.0
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n c.
()5
•JS
06
H6
H6
Hb
Kb
Ub
77
7 I
7 1
7 /
7 /
77
77
77
77
77
7 7
77
77
77
7 !
7 7
.0
.0
.0
.0
.0
.0
.0
. 0
.0
.0
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.0
.0
.0
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.0
.0
.0
.0
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.0
.0
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.0
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.0
D . 0 .
. u
.0
. 0
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.0
.0
.0
.0
.0
.0
.0
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.0
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.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
bOD
.0
.0
.0
.0
.0
.0
.0
. u
.0
.0
.0
. I.
.0
,11
.u
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
CONS I
.000
.000
.000
.000
.000
.000
.000
. 0 0 (1
.000
. 0 0 1)
.000
.000
. IKIO
.000
. tiou
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
HCN
.
.
.
.
.
.
.
.
.
.
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.
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.
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.
.
.
.
.
.
.
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.
.
.
.
000
000
000
000
000
000
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0 0 0
000
000
000
000'
(1 0 0
noo
(Mill
000
000
000
000
000
000
ooo
000
000
000
000
000
PHENOL
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.(If (I
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
-------�
$$3 OATA TYPF 9A (INITIAL CONDITIONS FUR CHLOROPHYLL A, NI1ROGEN, PHOSPHOROUS,
COLIFOKM AND HAD ICINUCL IDt ) $i$
O
I
tn
CARD TYPE
INI ! IAL CUND-a
INITIAL CONO-a
INITIAL CUNO-a
INITIAL CUNO-a
INITIAL CUNO-2
INI 1 IAL CUNO-a
INITIAL CUNO-a
INITIAL CUNO-2
INITIAL CONU-a
INITIAL CUND-a
INITIAL CUND-2
INITIAL COND-a
INITIAL COND-a
INITIAL CUND-a
INITIAL CONO-a
INITIAL CUNO-a
INITIAL CUNO-a
INITIAL CONO-a
INITIAL CUND-2
INITIAL COND-2
INITIAL CONO-2
INITIAL CUUO-a
INITIAL CUNO-a
INITIAL CONO-a
INITIAL COND-a
INITIAL CONO-a
ENIIATA9A
tS* DATA TYPt
CAK'D TYPE
HtAOWATEK
tNOATAlO
JSi OATA TYPt
REACH CHLURA
I. .0
a. .0
3. .0
1. .0
S. .0
6. .0
7. .0
B. .0
9. .0
10. .0
11. .0
ia. .0
13. .0
it. .6
15. .0
16. .0
17. .0
18. .0
19. .0
ao. .0
ai . .0
aa. .0
a3. .0
ai. .0
25. .0
ah. .0
0. .0
10 (HEAD.VATER SOURCES)
HEAOrtAIEH UROFR AND
1 . HDW = niJUSSUM CK
0.
NH3
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
sis
IOENI
10A (HEADWATER CONOIIIUNS FOR
NO?
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
. 00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
NO 3
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
FLOW
.0
.0
CHLOHOPIIYLL
PU<4 COL I
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
TtMH
95.0
.0
,NI TRUGEN,
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
.0
0
HAON
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.0.
f>.7
.0
ORG-N
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
0(10 CONS I
'1.3 .000
.0 .000
PHOSPHOROUS,
CULIFURM AND HAOIUNUCLIUE) $$t
CARD TYPE
HEAOWATER-a
tNOATAlOA
HDWATtK CIILORA
1. .0
0. .0
NH3
1 .60
.00
NO?
.01
.00
NU3 P01
•J7 .OS
00 .00
COL I
.0
.0
WAUN UHG-N
.00 .34
.00 .00
IICN
.001
.000
PHENOL
.oao
.000
-------�
$$S DATA TYPE 11 (WASTE LOAOINI.S) $]>.•(
CARD TYPE
WASTELOAD
WASIELLUD
WASfbLOAD
WAS1ELIHI)
WAS fhLUAD
ftAS 1 KLllAI)
WAS lELIIAfl
W AS Tt LOAD
wASTELOAD
WASTELOAD
WASTELOAD
WASTELOAD
WASTfcLOAD
ENDATA 1 1
WASTE
1.
f_.
4.
/I .
u .
/ .
rt .
s.
10.
1 1 .
12.
13.
14.
0.
LOAD ORDER AND IOENT
WSL=US STEEL
hSL=KOPP£PS
CK
I. :•. HIPt
«SL=3MALL CREEK
wSL=HALLS CHEEK
wSI. = VALLtY SIP
S-MJLE CREtK
HlRliINHAM HIDE
LICK CHEEK
HOCK CHbEK
MOD CHtEK
EFF
.00
.00
.00
.00
. 01'
.00
.00
.00
.00
.00
.00
.ou
.00
.00
FLdlft
33.2
.?
1 .3
Ji.O
, \
.0
. 0
.0
55. 3
6 . 3
. 0
5.8
4.6
6.0
.0
TtMP
95.0
9S.O
95.0
l» b . 0
1 • . l»
Hf- .u
H6.0
86.0
H6 .0
Hti .(.
1*6.0
77.0
77.0
77.0
.0
0.0.
5. /
7.7
7.0
7.6
f , .
.0
6 . 1
9.5
7.8
6.2
.0
8.5
rt.5
7 .9
.0
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5.0
3/ .9
29.b
3.1
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2 .5
? .9
5.3
15.0
4.7
240.0
3. 1
2.9
3.U
.0
CONS I
.000
.000
.000
.000
. U >l \l
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
HCN
.024
1 .349
.001
.003
, >' ' /
.000
.015
.002
.010
.038
.000
.002
.002
.002
. 0 0 0
PHENOL
.019
1 .261)
.600
.001
. u ' *
.000
.004
.006
.001
.OO'I
.000
.013
.008
.001
.000
tSS DATA TYPE 11A
0
cn
^
i
ro
CARD TYPE
WASIELOAD-2
WASTELOAD-2
WASIELOAD-2
WASIELOAD-2
WASTELOAD-?
WASTELOAD-2
WASfELOAO-2
WASTtLOAD-2
WASTELOAD-2
WASrELOAO-2
WASTELCIAD-2
rtASTELflAD-2
WASTELOAD-2
WASIELOAD-2
EMDATA1 1A
WAS IE
1.
2.
3.
4.
5.
6.
7.
8.
V.
10.
1 1 .
12.
13.
11.
0.
(WASTE LOAD CHARACTERISTICS -
COLIFUHMS AND HAD IONOCLIDES)
ALGAE,MITHOGEN,PHOSPHOROUS,
WAS IE LOAD URDEH AND IDEfjT
rtSL=US SIEEL
=KOPPE«S
rwOOOrtAKI) IRON
WSC=VALLEY CK
WSL = STOR"I SbWbR
IMSL = U.S. PIPE
WSL=SMALL CHEFK
WSL=HALLS CREEK
WSL=VALLEY STP
5-MILE CREEK
U1RMINHAM HIDE
LICK CHEEK
ROCK CREEK
MUD CREEK
CHL. A
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
IMH3
.95
6.75
9.28
. 10
. 10
.96
.19
.10
2.00
1 .34
56.30
.22
.13
.18
.00
N02
.?!
.01
.00
.02
.03
.06
.02
.01
.01
.88
.00
.01
.03
.00
.00
N03
.74
.35
1.20
1 .08
.53
3.57
1 .08
1 .20
9.20
24.50
.00
.15
.62
.41
.00
P01
.10
.00
.00
. 13
.13
.27
.01
.03
3.58
. 18
.00
.02
.05
2.97
.00
con
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.on
.00
RADN ORG-N
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00 4
.00
.00
.00
.00
.00
.36
.11
.05
.20
.56
.31
.19
.30
.90
.50
.00
.23
.18
.00
.00
ENOATA12
-------�
O
I
I
CO
SilHtAM tJIIAI I I r
IIDAL II SIIUA'I
• •••• siiAiit
jl'IIILA I Ill'l
UIIAI Ell Wllnnnti Mllnf L
nilllMII I'Ai.t NMMIItli
Hill ELI
MUM NUM
1 1
2 f.
3 1
4 4
i 5
b 6
7 21
b 2 2
(j ^3
10 31
II 12
1233
1331
1435
15 4 1
Ib 4 2
17 b 1
IB 5 ?
11 61
20 0 2
2165
22 (i 1
23 0 5
?4 (, 6
25 b 7
26 b 8
27 b 9
2 a bio
21 7 1
lo / 2
u ; 3
32 ( 1
33 7 5
54 76
35 7 /
5b 7 ft
3/ 7 1
IB / III
31 711
4U b 1
4| 82
42 B 3
13 B 1
1 6
16 h 7
17 8 b
48 U 1
49 BIO
50 811
t new
Hilt
45.7
45.5
li. 1
1 li . 1
11.9
11.7
44.5
41. 3
41.1
43.9
4J.7
43.5
43.3
43. 1
12.9
42.7
42.5
42.3
42. 1
41.1
41.7
41 .5
11,1
41.1
10.1
1 1I . /
10.5
10.1
10.1
39.1
11.7
11.5
31. 5
31.1
30.1
30.7
38.5
311. 1
3B. 1
3 7.1
57.7
37.5
37. 5
37.1
36.1
36. /
it, .5
3h.5
36 . I
35.9
II)
MILt
45.5
45.3
45. I
41.9
11. /
11.5
11.1
11.1
11.1
11. /
43.5
43.1
43.1
42.9
42. /
42.5
42.3
42.1
41.9
41 .7
41.5
41.1
41.1
40.9
10. /
10.5
10. 5
40.1
19.9
59.7
39.5
19.3
39. 1
18.1
18. /
38.5
58.3
38.1
37.1
I/. 7
1/.5
37.3
3/.I
16.9
16.7
36.5
16.3
16.1
15.1
15.7
STHl AM
FLlin
0.
31.
31.
15.
33.
31.
13.
35.
31.
33.
31.
15.
15.
15.
35.
58.
30.
38.
38.
38.
SO.
38.
38.
38.
18.
38.
38.
38.
18.
38 ,
38.
5) (M> iiir. (nii/L) (Mi;/i. ) (MC/L)
.00 .00 1'J.UO 6.74 .00 .00
.18 .41 95.110 5.69 4.98 .15
.98 .11 95.00 5.68 1.93 .15
.98 .41 15.00 5.67 4.88 .95
.18 .41 15.00 5.65 4.U3 .95
.IB .41 95.00 5.64 4.78 .95
.98 .19 15.00 5.61 4.74 .95
.98 .11 Ib.OO 5.61 4.69 .95
.Ifl .49 95.00 5.62 4.na .95
.19 ,5o 95.00 5.63 4.81 .99
.19 .50 95.00 5.62 4.77 .99
1.01 .51 95.00 5.65 5.62 .21
1.01 .51 95.00 5.64 5.56 .29
1.01 .51 9S.OO 5.1,3 5.51 .29
1.01 .51 9b.OO 5.61 5.16 .29
1.07 .56 95.110 5.76 5.25 .19
.55 .05 86.00 5.79 5.19 .20
.55 .05 86.HO 5.82 5.12 .21
.55 .05 86.00 5.86 5.05 .22
.55 .05 86.00 5.9| 1.18 .23
.55 .05 B6.00 5.95 4.11 .24
.55 .05 flb.OO 6.00 4.84 .25
.55 .05 86.00 6.04 4.77 .26
.55 .05 86.00 6.08 4.70 .26
.55 .05 86.00 6.11 4.64 .21
.55 .05 86.00 6.15 4.57 .28
.S5 .05 86.00 6.18 4.51 .29
.55 .05 B6.0P 6.21 4.45 .21
.38 .UO 86.00 6.27 1.17 .10
.58 .80 B6.00 6.35 4.28 .31
.58 .80 Bb.OO 6.42 4.20 .32
.18 .80 86.00 6.11 4.11 .35
.18 .80 C6.00 6.5'l 4.04 .31
.10 ?.42 86.00 7.21 10.45 .74
.70 2.42 86.uO 7.12 10.14 .76
.10 2.12 86.00 7.04 10.23 .77
.70 2.12 81,. 00 6.97 10.11 .78
.70 2.12 80. 00 6.90 10.00 .80
./O 2.12 86.00 6.81 9.89 .81
.28 1.31 06.nO 6.10 1.19 .70
.28 4.31 U6.no 5.01 9.14 .51
.28 1.31 116.00 5.28 8.40 .11
.28 4.11 86.00 1.AO 11.66 .51
.28 4.35 Bb.llO 4.37 8.13 .51
.28 4.31 i)6.00 3.11 8.20 .23
.28 4.11 H6.00 5.66 7.11 .15
.28 4.33 81,. HO 1.37 7.7/ .08
,f» 4.33 116.00 3.11 /.'i7 l.(ll
.28 4.31 86.00 2.81 /.!/ .15
.20 4.15 86.00 2.70 / . 1 7 .111
IJ02-N
(MU/L)
.00
.27
.26
.25
.24
.23
.22
.21
.20
.20
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IJIIAL II MKtAH DUALITY HIJU1INU MIIOtL
IIUIPIII PAliE NIJMHH)
•••• 3IEAOY 3TAIE SIMULAIIUN «•
I
cn
i
ro
o
HLH ELI
MUM MIIH
loi is 5
l« . 1
18.1 17.9
17.9 17.7
17.7 17 .b
17.5 17.3
17.4 17.1
17.1 16. 9
I b . 9 1 fa . 7
16.7 lb.5
lb.5 16.1
Ib. i Ib. 1
Ih.l IS. 9
I b . 9 15.7
Ib.7 15. b
Ib.'j 15.3
UXYGtN
HE A III
(1/UYI
1.21)
1.20
1.20
1.20
1.20
1.20
1.20
1.20
?. .6H
. 1 7
.1 1
. 1 7
.1 7
.1 7
. 1 I
.1 7
.1 7
.17
.17
. 17
. 1 /
.90
.63
.63
.63
.63
.63
.63
.63
.63
.63
.61
.61
.61
.63
.63
.63
.63
.63
.63
.6 )
.6 1
.61
.61
.63
.64
.64
.61
.61
.'i 4
Mini NH! NH2
ntfAY UEC'Y UECAY
li/nr) u/iiY) (I/IIY)
.3fl
. la
.3(
.if
. 4«
.3"
.if
.3fl
.38
.3H
. 311
.30
.IK
.38
. 11
.3B
.18
.3d
.JO
.3A
.IS
.25
.25
.25
.25
.25
.25
.25
.25
.25
.25
.25
.25
.25
.25
.25
.25
.25
.25
.25
.25
-2S
.25
.25
.25
.25
.25
.25
.25
.25
.01 .95
.CM .95
.01 .95
.01 .95
.01 .15
.01 .95
.01 .'15
.01 .95
.01 .95
.01 .95
.Ul .95
.(/I .95
.01 .95
.01 .95
.01 .95
.01 .95
.01 .95
.01 .95
.01 .95
.01 .95
.01 .95
.01 .95
.01 .95
.01 .95
.01 .95
.01 .95
.01 .95
.01 .95
.01 .95
.01 .95
.01 .95
.01 .95
.01 .95
.01 .95
.01 .95
.01 .95
.01 .95
.01 .95
.01 .'15
.01 .95
.01 .95
.01 .95
."I .95
.01 .95
.01 .95
.01 .95
.01 .95
.0| .95
.(II .95
.01 .95
CUL1
UECAY
(I/DY)
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.no
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.Oil
.no
.00
.00
.ou
.110
.00
.00
.00
.00
.00
.00
.00
.00
.no
A| I.AE ALUAE
liKIIHlll HI5PH
(I/on (i/uvi
.00 . o n
.on .00
.00 .00
.00 .00
.00 .00
.00 .00
.00 .00
.00 .00
.00 .00
.ou .on
.00 .01)
.00 .00
.00 .no
.00 .00
.00 .00
.00 .00
.00 .00
.00 .00
.00 .00
.00 .00
.00 .00
.00 .00
.00 .00
.00 .00
.00 .00
.00 .00
.00 .00
.00 .00
.00 .00
.00 .00
.00 .00
.00 .00
.00 .00
.on .00
.00 .00
.00 .10
.00 .(Ml
.00 .00
.00 .00
.00 .00
. (' 0 .00
.00 .00
.00 .00
.00 .00
.00 .00
.00 .00
.00 .00
.00 .00
.110 .1111
.mi .no
UHf,-N
(hG/L)
.31
.11
.13
.33
. 33
.11
.11
.11
. 11
.U
. 11
. 13
.31
. 13
.U
.33
.33
. 34
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.3!
.33
.33
.11
.33
. 33
.13
.13
. 11
.11
.11
.11
.33
.33
. 12
.32
.12
.1?
. 12
.32
. 32
. 42
. (2
. 12
. 12
. 12
. 42
. 42
. 42
. 42
. V
IIHG-N
III LAV
dn;/L)
.Oil
.no
.00
.00
.00
.00
.00
.00
.on
.00
.00
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.no
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.no
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.110
.1111
.00
.00
.00
.00
.00
.00
.00
. 00
CIIN-I
(MG/L)
.000
.000
.000
.000
.000
.000
.000
.001)
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.0110
.000
.000
.000
.000
.000
.000
.000
.000
.000
. 0 II 0
.000
.000
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.0110
.000
.000
.000
.000
.000
.01)0
.0110
.000
. (JIlO
.000
.000
.01)0
. IIIMI
IICN
(MB/L)
.002
.002
.002
.002
.002
.002
.002
.002
.002
.002
.001
.001
.001
.001
.001
.001
.001
.001
.001
.001
.00)
.001
.001
.001
.001
.001
.001
.001
.001
.001
.001
.001
.001
.001
.001
.001
.001
.001
.001
.001
.001
.001
.001
.001
.001
. noi
.001
.001
. Ull 1
.001
I'HENIIL
1MB/LI
.027
.027
.027
.027
.027
.027
.027
.027
.027
.027
.027
.027
.027
.027
.027
.027
.027
.027
.027
.027
.027
.027
.027
.027
,027
.027
.027
.027
.027
.027
.027
.027
.027
.026
.026
.026
.026
.026
.02b
.026
.026
.02b
.026
.026
.02h
.l)2b
.026
,02b
.Il2b
.02b
-------�
AH HIM I I f SI Mill til UN
II SIKt AH UIUI. |lr HI'll I INC. HUUtL
;,ltA!>l Sl»lf :i IHUL * I I UN • ••••
llllll'tll P«CF NUHIIEK
O
cn
•
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ro
IIHYGFH Mill) NIC 3 Mlia
HIM LLl
MUM MOM
51 ao 5
5«! aO b
5j ao 7
31 JO «
55 ao i
Sb ao to
57 ao ii
Sb ?u la
S9 ft 1
io PI a
SI 21 3
sc at 4
Si ai b
su ai b
f>b ei r
)>b ai «
b7 ai 9
bo ai 10
b9 aa i
7u aa a
71 a^ 3
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7i aa b
74 as i
75 as a
7b ?i i
77 as 4
7ii ai s
79 ii •>
flu as 7
HI aj B
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Hi ai ID
na ai u
85 as la
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u; an a
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90 ? .as .01 .95
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.4b .as .01 .95
.
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.1136
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.oab
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.oas
.oab
.oas
.oab
.oab
.oas
-------�
STKEAM DUALITY SIMULATION
(HIAL II STREAM DUALITY ROUTING MODEL
***** STEADY STATE SIMULATION *****
OUTPUT PAGE NUMBER
10
o
en
i
ro
RCH tLT
NUM NUM
?01
iOt?
?03
?U4
?05
206
?07
?oe
i09
210
PI 1
iltf
213
214
215
•i\t>
217
210
21V
??0
221
222
223
25
25
25
25
25
25
25
25
25
26
2b
2fa
2b
26
2b
26
26
26
2b
26
26
26
2b
9
10
11
12
13
14
IS
16
17
1
2
3
4
5
6
7
S
9
0
1
2
3
4
FROM
MILt
5.3
5.1
1.9
'(.7
4.5
4.3
4.1
3.9
3.7
3.5
3.3
3. 1
2.9
2./
2.5
2.3
2.1
.9
. /
.5
.3
.1
.9
IJXrGFN
TO REAIK
MILE (
5. 1
1.9
4.7
4.5
4.3
4.1
3.9
3.7
3.5
3.3
3.1
2.9
2.7
2.5
2.3
2.1
1 .9
1 .7
1.5
1.3
1 . 1
.9
.7
1/DY) (
.05
.05
.05
.05
.05
.05
.05
.05
.05
.04
.04
.04
.04
.04
.04
.04
.04
.04
.04
.04
.04
.04
.04
HUH NH3 NU2 CIIL1 ALGAE
DECAY UECAY DtCAY DECAY GROWTH
1/OY) (
.06
.06
.06
.06
.06
.06
.06
.06
.06
.06
.06
.06
.06
.06
.06
.06
.06
.06
.06
.06
.06
.06
.06
1/DY) (1/DY) (
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.95
.95
.95
.95
.95
.95
.95
.95
.95
.95
.95
.95
.95
.95
.95
.95
.95
.95
.95
.95
.95
.95
.95
1/DY) (
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.ou
.00
I/OY) (
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
ALGAE fJRG-N
RtSPK CIRG-N DECAY
CON-I
HCN
1/OY) CMG/L) (MG/L) (MU/L) (MG/L)
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.30
.30
.30
.30
.30
.30
.30
.30
.30
.30
.30
.30
.30
.30
.30
. 30
.40
.30
.30
.30
.30
.30
.30
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00
.00.
.00
.00
.00
.ou
.00
.00
.00
.00
.00
.00
.00
.00
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
.000
PHENUL
(MG/L)
.025
.025
.025
.025
.025
.025
.025
.025
.025
.025
.025
.025
.025
.025
.025
.025
.025
.025
.025
.025
.025
.025
.025
-------�
o
I
en
i
ro
co
1.1«
h.ftl <
O.IJ. 'I.H,M
(iir./Ll
•i. 1'ju
* *
MLF lit Ht AII ii^ morn
!•) = I Al (.(II A II II IIM., (It = I..I.ASIIMI II !)«!»
-------�
o
en
i
ro
H.ll.ll.
(HC/LI
ni.au Ib.tll li.tU 21.10 Pi.iO IH./U ll.rfd 9.711 5.20
Hulu MILL lu HfAII HF UF.tCH
(•) - L>lCllL*IKII IIAfA, (I) =
-------�
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ro
.770
.•»*V
UMUANIC-tt
IHKH.I
. SH'j
* «
• • * *
if. id II. 7
MIF ui IIE»II IIF
= CMCULtltll UATA, (X) =
-------�
I
en
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ro
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Nil]
(MG/U
1.1 111
-.00(1
Ob
il.iO II.Hi fi.SU IH.70
IJlVEh Milt th lit All I IF HMdl
I.1H S.il)
.70
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-------�
o
I
crt
.bil
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Nd
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ro
CO
6.106
Mil I.Jhd
(HK/LI
t.blt
.0110 • «
IS.fU II.iU
My.10
li p_\.?a IH./II \a.i
Mil t 111 HF.*» IjF HtACH
.ffl
(•) = r.ALflil MLD <>«!«, IX) 3 MtASllUbU l» 1 A
-------�
I
»
•t*
ro
10
piiii.i.
(MC/L)
I.M58
l.bJJ
.nir
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. ion
• • •
-.on it»----» »-—» «—
1-j.JU 1l.il) 3b.7W
:'.<>ii ("/.m si.c1!) M.rn
I'lvti. MII i in HEAD iif aftr.it
(•) = f. Al CHI « mi IIAIA, («| = MEASIIKKI) IKIA
-------�
o
i
en
-P>
o
HCN .an
INU/L)
.00%
.00.?
15.JO «l.20 36.Ml
RIVtK MILF Til Ht»0 llf HEACM
11.20 9.711 5.2(1 .JO
(<) = CALCIFLAIFII DMA, (X) = Mt«SHULI>
-------�
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en
co
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riii urn .010
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jb.rci
j.m a. no IH.IO ii.ao
vM' Milt- TM HF AD (IF IJI ALH
v.to s.sn .70
-------�
APPENDIX D-6
LONG-TERM BOD DATA
-------�
f>UD
IHG/L)
s; (I
J U
(1 S
10
45
30
as
20
15
10
5
Sep-h. 2.2., 1977
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i
.+
i
i
i
i
.*
t
i
i
i
.+
i
i
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i
.+
i
i
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.+
t
t
i
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.+
i
i
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i
. +
t
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i
f +
i
I E
I C * B *
I * * *
0. 5. 10.
SAMPLE NO. : 1 Rfyi ^~./2. Oi00S$U.iv| W/
I
I
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i
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»
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I
I
»
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+
I
I
I
I
I
I
I
I
+
I
I
C C
I
C +
I
I
CCA I
A A A A
A B B B B
B I
C C I
A I
C I
t
I
AABODDDO
* * 0 I
E E I
15. 20. 25. 30. 35. 10. 45. 50
TIME (DAYS)
A = luiiZ iMUMIrtirEil l.iILUTTON 0 = 60% UKINH] RITEO DILUTION C = 205! UNINHIBITED DILUTION
i) = IfHU I.IHl.'tlTEil OTLHTIuiM K = 20X IcJHIBntO DILUTION
-------�
IMb/L)
KP
cr>
i
cr f i
J U
'10
35
30
25
20
15
10
5
fl
Sept 23-//'?77 SAMPLL NO. : 2 £/y] 3.J7 U..S. ?
| l/«J/ey Creek
I
I
I
I
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I
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I
.+
I
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I
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.+
1
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I
.+ A
I A A B
I B 8
I
I A
.+ 8
I C
I C
I C C
I
.+
I
I *
I A B
I A DO
.+ 8 D D
I A H C 0
I AH* *
I * * * D
I ti * D
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I *
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I £
0. 5. 10. 15. 20. 25. 30. 35. 10.
*-eel S*«pli«
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+
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+
* C
B
+
I
I
D
0 I
+
I
I
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+
I
I
I
I
15. 50
TIME (DAYS)
A = 1UIU u'g INhltil VtO DILUTION 6 = 60X UNINHIBITED DILUTION C = 20X UNINHI3ITED DILUTION
U = 100X INHIBITED DILUTION E = 20X INHIBITED DILUTION
-------�
BOO
(Mb/L)
I
CO
J" jO T • ^J~. •§ 1 / ** 1 t iM J . • 5
i va.//ev C^eek
i '
i
15.+
I
1
I
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40.+
I
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35.+
I
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I
30.+
I
I
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I
25.+
I
I
I
I
20.+
1
I A
I
I
15.+
I
I
1 C
I C fi
10.+ A
I C A C
I A * D
1C**'* * E
1 B C E E
5.+ * * *
I
I 0
I « £
I *
('. 5. 10. 15. 20. 25.
J£W J.-77 W
-------�
HOD
a.
cr>
5 'J
45.
45.
50.
25.
20.
15.
10.
5.
t' •
5e/>*-. 0.3 /
-------�
cn
i
cn
f. 22 /977 SAMPLE NO. : 5
15.
1
9.+
I
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I
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6.+
t
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3.*
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ii.+
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10.
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D
.--+---_+.
20.
--*---
25.
-*• C —
30.
A
*
B
-..+.-.-+
35
IS.
50.
TIME (DAYS)
A r | uOX UNlfJhlrtl fEO DILUTION
0 = 100* IMlLiirEa
*STOP* 0
8 = 60X UNIWHIBITEO DILUTION
E = ?0% IMHI81TED DILUTION
C = 20X UNINHIBITED DILUTION
-------�
5ep1-. ii, /?77
SAMPLE NO. -. 6 $..(¥[, O.73 Hoppers
_---+—-+-.--t----+.___.f -._-+-_-_+-__.+-__-»__ f-ff- - - -+-
{ l/oJ/ey Creek
5
t)l>0
(Mb/L)
CT>
CD
i
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IS.t
t
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IP.*
i
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- + — ci
. _+. . _ _+_ _ . .+.
30. 35.
A
I
I
I
D
C
B
I
I
-- +
50.
S.
10.
15.
£0.
25.
10.
45.
TIME (DAYS)
A r 100% U.'JINr
D = lUUS iNHIi.
niLin ION
OILUTIulJ
B = feOX UNINHIBITED DILUTION
E - 20X INHIBITED DILUTION
C = 20X UNINHIBITED DILUTION
-------�
HUD
(MG/L)
i
CM
i
3»
45
40
45
_
25
2'>
15
10
5
i Vcu'/ey CofC-K.
i '
j
.+
i
t
i
i
.+
i
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TIMt (DAYS)
A = 101U UNII-rlluITEO OILUrillM B = 60X UMIMHI8ITEO DILUTION C = 30X UNINHIBITED DILUTION
I) = 10IIX INhlrflfEii DILUTION E = 30Z INHIBITED DILUTION
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TIME (DAYS)
A = 1001 lUll.'HI'iITELt DILUTION B = 60Z UN U'lH I (HI TED DILUTION C = aOZ UNINHIBITED DILUTION
II = 100Z H.-Hnl VE'i OTLUTIUN E = 20% INHIBITED DILUTION '
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45. 50
TIME (DAYS)
A = Iu02 UNIMMIiillEO niLUflON B = 60X UNUiHIR ITE.D DILUTION C = 20% UNINHIBITED DILUTION
D = 100* IMHl/HTEU DILUTIQM E = 20% INHIBITED DILUTION
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TIME (DAYS)
•UTtO IHLUTIUN 8 = bO% UM HiHI 8 1 Ttl) UILUTIGM C = 20X UNINHIBITED DILUTIOi>)
IEO OlLUTIUiM E = 20% INHIBITED DILUTION
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TIMh (DAYS)
A = 100% UNIMhloITEO DILUTION B = 60X UNINHIBITED DILUTION C = 20X UNINHIBITED DILUTION
D = 1«)OX INHIHITEJ DILUTION E = 20Z INHIBITED DILUTION
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15. 20. 25. 30. 35. HO. 45. 50.
TIME (DAYS)
A = HKU 'J'JIMnlrilTEO uILUTI'Jfo
0 = 1U04 INHli»nEn iHLUTIOM
fl =
fc =
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C = 30X UNINHIBITED OILUTIOfJ
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TIME (DAYS)
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24.
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A = !OOJ UIJIIJrHJbTTEO. OILUTIUN
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TIME (DAYS)
DILUTION
.TLUTION
H = 60X UNINHIBITED DILUTION
£ = 203C INHIBITED OILUTIOiM
C = 20Z UNINHIBITED DILUTION
-------�
SAKHLE MO. : 17 fcn] 4-0.3 Wood. BriJiaQ Q Qu.c^rry
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TIME (DAYS)
A = luOZ u-IINHti^l TEO OfLUTKlfo R = fcl'X UNIMH1BITEL) DILUTION C = 20% UNINHIBITED DILUTION
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15. 80. 35. 30. 35. 10. 45. 50
TIME (DAYS)
A = ion* u.-jiN'Uimen DILUTION ft - 60% UIMIIMHIIUTED DILUTION c = ao* UNINHIBITED DILUTION
0 = 100* INHHI1EJ DILUTION E = 2u% INHIBITED DILUTION
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SAMPLE MO. : 19 filYI 33.1 Wf- QJior\, Briciae
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TIME (DAYS)
C = 20Z UNINHIBITED DILUTION
-------�
Se/>*-- -23/^97 SAMPLE MO. : so RM -39.g- r/flile Creek
+ _1A.._ + ._wCt_ — _t + _ + -.-_ + .___»_._. + __._ + ._._T..._ + _. — + _..- + __--»--__ + ---- + --.- + ---- + --.-+
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0. S. 10. 15. 20. 25. 30. 35. 10. 15. 50.
TIME (DAYS)
A = 100Z IJNINHttilTEi) DILUTION B = bOX UNINHIBITED DILUTION C = 20% UNINHIBITED DILUTION
0 = 100'i INnMIIEl) DILUTION f. = 20X INHIBITED DILUTION
-------�
. 23 /977
SAMPLE Mfl. : it
33. |
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45.+
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30.+
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20. 25. 30. 35. dO. d5. 50
TIME (DAYS)
A = 1UOZ U^IMrilril I'CL) OILUrtUiM
0 = 1GOZ INHI3UEO DILUTION
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E = 20X INHIBITED DILUTION
C = 20Z UNINHiaiTEO DILUTION
(/
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TIME (DAYS)
A = 1 1)01
0 = liHU
UNINHIiJI TED DILUTION
INHlDlIEO DILUTION
8 =
E =
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20X
UNINHIBITED DILUTION
INHIBITED DILUTION .
C = 20% UNINHIBITED DILUTION
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SAMPLI; fco. : 25 .fYl. / 36
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0. 5. 10. 15. 20. 25. 30. J5. HO.
TIME (DAYS)
ntreo UlLIIUJW rt = bu% UNlM-iIBITtD DILUTION. C = 20X UNINHIBITED DILUTION
TED IHLUTIUM £ = 2Qi INhJSITEO DILUTION
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15. £0. 25. 30. 35. 00. 45. 5(
TIME (DAYS)
A = ion* uiJI"iHIHITE-0 DILUfluN
D = luo* iNHidirtij oiLunuiv
B = fell* UNINHIBITED DILUTION
£ = suz INHIBITED DILUTION
C = 20X UNINHIBITED DILUTION
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30.
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15.*
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15.
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TIME (DAYS)
30.
35.
10.
15.
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TIME (OAVS)
•JHt'D DILUTION S = 6U% UNINHIBITED DILUTION C = 20X UNINHIBITED DILUTION
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TIME (DAYS)
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TIME (DAYS)
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TIME (DAYS)
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TIME (DAYS)
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-------�
APPENDIX E
TOXIC SUBSTANCES
-------�
TOXIC SUBSTANCES
E.I. INTRODUCTION
This appendix presents a detailed discussion of those
potentially toxic substances* associated with the production of steel.
The generation of these substances and their disposition as regards
recovery and reuse is discussed in Section E.2. The following sections
pertain to specific chemicals and classes of chemicals and present
information concerning physical and chemical behavior, analytical pro-
cedures, toxicological properties, and treatment technologies.
E.2. GENERATION AND DISPOSITION OF TOXIC SUBSTANCES IN THE
PRODUCTION OF STEEL
The production of steel involves three major processes:
coke making, iron making, and steel making. Coke making consists of
the conversion of coal to coke. Iron making involves the combination
of iron ore with coke and limestone in a blast furnace to produce iron.
Steel making consists of the purification of iron to steel using either
an open hearth furnace, a basic oxygen furnace, or an electric arc
furnace. In a study of the steel making segment of the iron and
steel industry, the United States Environmental Protection Agency
(USEPA) determined the following subcategories (USEPA, 1974):
I. By-Product Coke Subcategory
II. Beehive Coke Subcategory
III. Sintering Subcategory
IV. Blast Furnace (Iron) Subcategory
V. Blast Furnace (Ferromanganese) Subcategory
VI. Basic Oxygen Furnace (Semi-Wet Air Pollution
Control Methods) Subcategory
VII. Basic Oxygen Furnace (Wet Air Pollution Control
Methods) Subcategory
VIII. Open Hearth Furnace Subcategory
IX. Electric Arc Furnace (Semi-Wet Air Pollution
Control Methods) Subcategory
Toxicity is defined only in the context of dosage.
E-l
-------�
X. Electric Arc Furnace (Wet Air Pollution Con-
trol Methods) Subcategory
XI. Vacuum Degassing Subcategory
XII. Continuous Casting Subcategory
Table E-l exhibits the pollutants identified as being
characteristic of the coke-making, iron-making, and steel-making
categories. Of these lists, those pollutants considered specifically
in this appendix are cyanides, phenols, ammonia, and various heavy,
metals: zinc, manganese, iron, copper, chromium, tin, and cadmium.
E.2.1. Coke Making
Two types of coke making can be distinguished, viz, bee-
hive coke making and by-product coke making. The first category re-
presents a much older technology in that no attempt is made to recover
any of the volatile materials generated. Conversely, the by-product
coke making process features recovery of many of the components of
the gases generated, e.g., ammonia, benzene, toluene, xylenes, naptha-
lene, phenols, pyridine, cresols, phenanthrene, anthracene, and the
tar residue. In the course of the chemical recovery operations, various
wastewaters are generated, e.g., excess ammonia liquor, contaminated
cooling water, light oil recovery wastes, and various, possibly con-
taminated, runoff streams. These wastewaters typically contain cyanide,
ammonia, and phenols.
E.2.2. Iron Making - Blast Furnace
In the blast furnace operations, iron ore is combined
with coke and limestone to yield the iron necessary for steel making.
Coke is used to chemically reduce the iron; the function of the lime-
stone is to form a slag with various impurities in the ore. Blast
furnaces utilize water for cooling and gas washing. The principal
source of wastewaters is the gas washing operation. These wastewaters
typically contain cyanide, ammonia, phenols, and heavy metals.
E.2.3. Steel Making - Basic Oxygen Furnace
In the steel making operation, the iron produced in the
blast furnaces is further purified to steel. Water usage in a basic
E-2
-------�
TABLE E-l
POLLUTANT PARAMETERS IDENTIFIED
IN THE PRODUCTION OF STEEL
I. Coke Making - By-Product Operation
II. Coke Making - Beehive Operation
Parameters
Acidity (Free and Total)
Alkalinity (Pht. and M.O.)
Ammonia
Berylium
BOD5
Chloride
COD
Color
Cyanide, Total
Dissolved Solids
Flow
Heat
Mercury
Nitrogen, Kjeldahl
Oil and Grease
pH
Phenol
Sulfate
Sulfide
Suspended Solids
Thiocyanate
TOC
Total Solids
Turbidity
T.O.N.
IV. Blast Furnace - Iron Making Operation
V. Blast Furnace - Ferromanganese Operation
Parameters
Acidity (Free and Total)
Alkalinity (Pht. and M.O.)
Aluminum
Ammonia
Berylium
BOD5_
Chloride
COD
Cyanide, Total
Dissolved Solids
Flow
Fluoride
Hardness, Total
Heat
Iron, Total
Manganese
Nitrate
Nitrogen, Kjeldahl
Oil and Grease
pH
Phenol
Phosphorus, Total
Potassium
Sodium
Sulfate
Sulfide
Suspended Solids
Thiocyanate
TOC
Total Solids
Color
T.O.N.
E-3
-------�
TABLE E-l (Cont'd)
POLLUTANT PARAMETERS IDENTIFIED
IN THE PRODUCTION OF STEEL
VI. & VII.
VIII.
IX & X.
Parameters
Basic Oxygen Furnace Operation
Open Hearth Furnace Operation
Electric Arc Furnace Operation
Acidity (Free and Total)
Alkalinity (Pht. and M.O.)
Aluminum
Color
Copper
Dissolved Solids
Flow
Fluoride
Hardness, Total
Heat
Iron, Total
Lead
Manganese
Mercury
Nitrate
Oil and Grease
pH
Phosphorus, Total
Silica, Total
Sulfate
Sulfide
Sulfite
Suspended Solids
Total Solids
Zinc
T.O.N.
Source: EPA, 1974.
E-4
-------�
oxygen furnace consists of cooling water for various components of
the process and influents to wet or semi-wet air pollution equipment.
Wastewaters are generated in steel making via spray-cooling and
quenching operations and wet or semi-wet air pollution controls.
These wastewaters from steel making operations, utilizing basic
oxygen furnaces, typically contain cyanide, ammonia, phenols, and
heavy metals.
E.3. CYANIDE
E.3.1. General
Cyanides are inorganic and organic compounds contain-
ing the functional group CN. Examples are presented in Table E-2.
The organic cyanides are called nitriles. With the inorganic cyanides,
further classification into simple cyanides or complex cyanides is
made. The latter group exists due to the ability of the CN group to
form complex ions with various heavy metals, notably Zn, Fe, Ni, Cu,
and Cd. Cyanide complexes play a large role in the chemistry of
cyanides and are important from solubility and toxicity considerations.
Inspection of Table E-2 reveals that simple cyanides
can be represented by the general formula, A(CN)n, where A is a metal
(Group IA - alkali, Group IIA - alkaline earth, transition or repre-
sentative) and n is an integer (the oxidation state of the metal).
Similarly, complex cyanides can be represented as A-|[B(CN)m]n where
A and B are metals and 1, m, and n are integers.
An evaluation of the chemistry of water-borne cyanides
requires a knowledge of solubilities and the ionization and stability
constants for the various species involved. The simple cyanides of the
alkali and alkaline earth metals are extremely soluble in water. Con-
sequently, their impact on the aquatic environment is due to the ionic
species present, plus the HCN generated as a result of the hydrolysis
of cyanide ion, CN". Given the pH of most receiving waters, the
cyanide is present almost entirely as HCN. With the other metal
cyanides, solubilities in water cover a wide range. Solubilities
E-5
-------�
TABLE E-2
TYPES OF CYANIDES
CH3CN
CH3CH2CN
CH2CHCN
CH3CH2CH2CH2CN
ORGANIC CYANIDES (NITRILES)
acetonitrile
propiom'trile
acrylonitrile
valeronitrile
Simple
INORGANIC CYANIDES
AgCN silver cyanide
NaCN sodium cyanide
KCN potassium cyanide
Zn(CN)9 zinc cyanide
Complex
Fe^[Fe(CN)g]3 ferric ferrocyanide
K^Fe(CN)g potassium ferrocyanide
Zn3[Fe(CN)g]2 zinc ferricyanide
K2Ni(CN)^ potassium nickelocyanide
E-6
-------�
for the cyanides of metals other than Groups IA and IIA, together with
equilibrium constants for important complex ions are presented in
Tables E-3 and E-4, respectively.
E.3.2. Analytical Procedures for the Detection of Cyanide
A discussion of the detection of cyanide requires clarifi-
cation of the several forms in which the cyanide group can exist in
aqueous environments. An equilibrium of major importance in the
evaluation of the impact of cyanide upon the environment is that
involving molecular hydrocyanic acid, HCN, and cyanide ion, CN".
1 ) HCN = H+ + CN-
2) Ki = [H+][CN-] = 7.2 x 10 ~10 mole/1 at 25° C
[HCN]
Rearrangement of Equation 2 yields:
3) DO].
CCN-] i
Consequently, a knowledge of the pH and K.J is sufficient
to compute the ratio of -the concentration of molecular HCN to that of
CN~. It is important to stress that Equations 2 and 3 are satisfied
regardless of the presence of other equilibria which feature CN~. The
total cyanide present in Equilibrium 1, i.e., HCN and CN", is referred
to as free cyanide. Using Equation 3, it is possible to compute the
percentage of the free cyanide which is HCN as a function of pH and
temperature (K-j).
4) [HCN]
4)
[HCN] + [CN-]
For a temperature of 25°C, K.J = 7.2 x 10 ~10 moles/1.
Table E-5 presents the percent of the free cyanide existing as HCN
as a function of pH at 25°C. Inspection of Table E-5 reveals that at
the pH values normally encountered in receiving waters, from approxi-
mately 90 to 99.8 percent of the free cyanide is present as molecular HCN.
Complexed cyanide is defined as that cyanide which is
bound chemically to other species in a complex and does not include any
contribution to free cyanide as a result of dissociation of the complex.
The terms free and complexed cyanide have meaning apart from any method
E-7
-------�
TABLE E-3
SOLUBILITIES OF THE CYANIDES OF SELECTED METALS
NOT BELONGING TO GROUPS IA AND IIA
Species
AgCN
Zn(CN)2
CuCN
Ni(CN)2
Cd(CN)2
Hg(CN),
SIMPLE CYANIDES
Solubility (g/1)
2.8 x 10"5
5.8 x 10
1.4 x 10
5.92 x 10
17
93
-3
-2
-2
Temperature (°C)
18
18
20
18
15
14
Species
Fe4[Fe(CN)6]3
Zn2Fe(CN)6
Zn3[Fe(CN)6]2
COMPLEX CYANIDES
Solubility (g/1)
2.5 x 10"4
2.6 x 10
2.2 x 10
-3
-5
Temperature (°C)
22
Not reported
Not reported
Source: ASTM, 1975 and Linke, 1958, 1965.
E-8
-------�
TABLE E-4
STABILITY CONSTANTS FOR COMPLEX IONS
INVOLVING CYANIDE
Equilibrium
Cd+2H
CO+2H
CU+ H
CU+2H
Fe+2H
Fe+3.
Pb+2H
Hg+2 H
Ni+2 H
4-
Ag H
Zn+2n
i- 4 CN" *
H 6 CN" *
H 3 CN" ^
H 4 CN" ^
H 6 CN" *
H 6 CN" *
i- 4 CN" *
H 4 CN" *
i- 4 CN" *
H 2 CN" *
h 4 CN" *
Cd(CN)4"2
Co(CN)6"4
Cu(CN)3"2
Cu(CN)4"2
Fe(CN)6"4
Fe(CN)6"3'
Pb(CN)4"2
Hg(CN)4"2
Ni(CN)."2
^r
Ag(CN)2~
Zn(CN)4'2
Ks (25"C)
7.1 x 1018
1 x 1019
4 x 1028
1 x 1025
1 x !024
1 x 1031
1 x 1010
3.1 x 1041
1 x 1022
91
1 x 1021
8.3 x 1017
Source: Bard, 1966.
E-9
-------�
TABLE E-5
PERCENT HCN VERSUS pH AT 25°C
[HCN] + [CN~]
x 100 pH
1.2 10
58.1 9
81.4 8.5
93.3 8.0
97.8 7.5
99.3 7.0
99.8 6.5
99.9 6.0
99.99 5.0
99.999 4.0
E-10
-------�
of detection. Conversely, the designations total cyanide and cyanide
amendable to chlorination (cyanide A) are tied to experimental analytical
procedures. Total cyanide is defined to be that amount of free cyanide
which is present after distillation with acid. Acid distillation has
been found to liberate much of the complexed cyanide as HCN. A notable
exception to this is the cobalticyanide complex. Cyanide A refers to
the cyanide which is amenable to oxidation by chlorine. Iron cyanide
complexes are exceptionally tightly bound and are resistant to oxidation
by chlorine. The iron cyanide complexes are not toxic; however, they
are capable of releasing cyanide ion through photodissociation in
strong sunlight. Other metal cyanide complexes, e.g., those of nickel,
silver, and gold, are not resistant to oxidation by chlorine; however,
their oxidations take place at different rates. Detailed analytical
procedures for the determination of total cyanide and cyanide A can be
found in the literature (USEPA, 1974; ASTM, 1976; and APHA/AWWA/WPCF,
1976).
E.3.3. Cyanide Toxicology
E.3.3.1. General Considerations
While it is accepted that cyanide toxicity is due to
the combination of CN" with Fe+3 present in enzymes instrumental in
oxygen metabolism, CN" is ineffective in permeating cellular membranes
due to its charge. Actual entry into the cellular environment is
effected through molecular HCN. Once HCN has entered the cell, the
equilibrium is reestablished and CN~ ions are liberated, to an extent
controlled by the pH. Cyanide ion combines with the Fe+3 present in
the porphyrin molecule responsible for the catalytic action of cyto-
chrome oxidase and, thereby, causes inhibition of the oxidation-
reduction processes necessary for oxygen metabolism. The result is
asphyxiation of the affected tissues.
The iron cyanide complex which results is very stable
and, consequently, therapy for cyanide poisoning aims at conversion
of the cyanide to a relatively non-toxic complex before inhibition
of the cytochrome oxidase system can take place. Natural cyanide
E-ll
-------�
detoxification occurs via conversion of the CN~ to thiocyanate, SCN~,
by the action of the enzyme rhodanase, with eventual elimination of
the resulting thiocyanate in the urine. This process is contingent
upon the availability of sulphur and the rate of the process is
relatively slow. Therapy for cyanide poisoning consists of providing
both sodium thiosulfate and sodium nitrite. Thiosulfate, S203~2,
acts as a source of sulphur in the conversion of CN~ to SCN-. Nitrite,
NOo, combines with hemoglobin to yield methemoglobin. The combina-
tion of thiocyanate and methemoglobin yields cyanmethemoglobin, a
complex of relatively low toxicity:
cyanide + thiosulfate —- thiocyanate
nitrite + hemoglobin —-methemoglobin
cyanmethemoglobin
E.3.3.2. Toxicity of Cyanides to Aquatic Organisms
Several assessments of the acute toxicity of cyanide
to various species of aquatic life (fish) have been performed using
both simple and complex cyanides in static and continuous-flow bio-
assays. Research designed to ascertain sublethal effects has been
scarce in comparison. Cyanide toxicity to aquatic life was the
subject of a recent, comprehensive review (Doudoroff, 1976). The
reader is also referred to Mater Quality Criteria (McKee and Wolf,
1963), Water Quality Criteria (NAS/NAE, 1972), and Quality Criteria
for Water (EPA, 1976) for more abbreviated summaries of the literature.
It is, perhaps, universally true that the impact of
a potentially toxic chemical on aquatic life is a function of many
environmental parameters; in particular, pH, temperature, dissolved
oxygen concentrations, water hardness, and salinity. Consequently,
it is imperative that researchers take great care in monitoring and
reporting the values of these parameters over the course of the bioassay,
Laboratory experiments using pure chemicals are useful in evaluating
E-12
-------�
trends and providing estimates of synergistic effects. However,
the actual assessment of the impact of a specific, complicated
effluent on the aquatic life is more realistic in the context of
laboratory experiments using the effluent itself and in the per-
formance of in-stream bioassays.
Table E-6 exhibits the vast variety of fish which
have been used in cyanide bioassay investigations. Table E-7
presents selected data from some of those investigations designed
to assess acute toxicity (Dourdoroff, 1976). It is well established
that the toxic component, in solutions of simple cyanides, is molecular
HCN. This was shown in a series of experiments which demonstrated
a decrease in toxicity with increasing pH (Wurhmann and Woker, 1948).
Several independent studies have shown that solutions of simple
cyanides become increasingly toxic as the dissolved oxygen is
reduced (Downing, 1954; Cairns and Scheier, 1958; Bardick, Dean,
and Harris, 1958). Experiments designed to expose fish to rapidly
lethal solutions at different temperatures have shown that the
toxicity of free cyanide increases with increasing temperature
(Southgate, Pentelow, and Bassindale, 1932; Alexander, Southgate,
and Bassindale, 1935; Wurhmann and Woker, 1953, 1955; Suman and
Doudoroff, 1938; Cairns and Scheier, 1963; etc.). Contradictory
evidence exists in the literature concerning the impacts of salinity
and hardness on the toxicities of solutions of simple cyanides
(Doudoroff, 1976).
Inspection of Table E-7 reveals the variety of responses
which have been observed. Extensive intestigations concerning the
toxicities of metal!o-cyanide complexes have demonstrated that, in
most cases, the complex is relatively non-toxic in comparison to
molecular HCN (Doudoroff, 1976). The ferro- and ferric-cyanide
complexes, while of high stability, are known to decompose photo-
chemically to yield free cyanide (Burdick and Lipschuetz, 1948).
Investigations concerning sub-lethal effects viz, effects on
swimming ability, growth, food consumption, food utilization,
E-13
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TABLE E-6
SCIENTIFIC AND COMMON NAMES FOR
FISH UTILIZED IN CYANIDE BIOASSAYS
Scientific Name
Common Name
Salvelinus fontinail's
Salmo gairdneri
Micropterus dolomieui
Lepomis macrochirus
Salmo trutta
Pimephales promelas
Poecilia reticulata
Gasterosteus aculeatus
Squalius cephalus
Micropterus salmoides
Lepomis cyanellus
Rhinichthys atratutus meleaqris
Chichiasoma bimaculatum
Rasbora heteromorpha
Pomoxis annularis
Lepomis auritus
Rutilus rutilus
Carassius auratis
Brachvdanio rerio
Fundulus heteroclitus
Phoxinus phoxinus
Tautoqolabrus adspersus
Laqodon rhomboides
Leucaspius delineatus
Acerina cernua
Phoxinus laevis
Perca fluviatilis
Gabusia affinis
Gyrpinus carpio
Ictalurus me! as
Rhodeus sericeus amarus
Umbra limi
Cottus bairdi
Ictalurus natal is
Etheostoma caeruleum
Esox americanus vermiculatus
Brook trout
Rainbow trout
Smallmouth bass
Bluegill
Brown trout
Fathead minnow
Guppy
Threespine stickleback
Chub
Largemouth bass
Green sunfish
Blacknose dace
Cichlid
Harlequin fish
White crappie
Redbreast sunfish
Roach
Goldfish
Zebra danio
Mummichog
European minnow
Cunner
Marine pin perch
Cyprinid
Percid
Minnow
Perch
Mosquito fish
Carp
Black bullhead
Bitterling
Mudminnow
Mottled sculpin
Yellow bullhead
Rainbow darter
Grass pickerel
E-14
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TABLE E-6(cont'd)
SCIENTIFIC AND COMMON NAMES FOR
FISH UTILIZED IN CYANIDE BIOASSAYS
Scientific Name Common Name
Ambloplites rupestris Rock Bass
Lepomis gibbosus Pumpkinseeds
Gillichthys mirabilis Longjaw goby
Onchorhynchus kisutch Coho salmon
Salmo salar Atlantic salmon
Oncorhynchus tshawytscha Chinook salmon
Semotilus atromaculatus Creek chub
Hybognathus regius Silvery minnow
Notropis atherinoides Emerald shiner
Perca flavescens Yellow perch
Notemigonus crysoleucas Golden shiner
Kuhlia sandvicensis Marine fish
Source: Doudoroff, 1976.
E-15
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TABLE E-7
SELECTED SUMMARY OF CYANIDE BIOASSAY STUDIES
Species
Brook Trout
Trout
Rainbow Trout
Rainbow Trout
Bluegill Sunfish
Trout
Trout
Bluegill Sunfish
Bluegill Sunfish
Rainbow Trout
Adult Chub
Trout
Adult Chub
Trout
Carp
Trout
Trout
Adult Chub
Bluegill
Bullhead
Bluegill
Bullhead
Cyanide
(mg/D
0.05
0.05
0.07
0.1 -0.2
0.12-0.18
0.126
4.0
0.18
0.176
0.2
0.33
0.42
0.50
1.0
10.0
0.02
0.084
0.20
2.25
0.375
0.4
0.5
Exposure Time
120-136 hr
5 days
74 hr
1-2 days
96 hr TLm
170 min m
4.8-64 min
24 hr TLm
11 min
2.5 hr
11 min
141 min
20 min
1.5 hr
27 days
96 hr
96 hr
Response
All Killed
Lethal
Overturned
MLD*
Overturned
Overturned
Toxic Limit
MLD*
Killed
Overturned
MLD*
All Killed
MLD*
Survived
Not Toxic
Survived
Survived
Survived
Survived
Survived
*Median lethal dose
Excerpt from: McKee and Wolf, 1963
E-16
-------�
embryonic development, respiration, and heartbeat and avoidance
reactions are discussed in the review by Doudoroff. A cyanide
level of 0.01 mg/1 was found to affect,the swimming ability of
salmonid fishes (Broderius, 1970J. u
In the publication entitled Water Quality Criteria
(National Academy of Science/National Academy of Engineering, 1972),
the following recommendation is made concerning cyanide in waters
classified for freshwater aquatic life and wildlife:
"Once a 96-hour LCg0 has been determined
using the receiving water in question and -.-
the most sensitive important species in
' 5>' '?
the locality as the test organism, a con-
centration of free cyanide (CN~) safe to
aquatic life in that water can be estimated •:>•,'
by multiplying the 96-hour LCcQ by an
application factor of 0.05; but no concentra-
tion greater than 0.005 mg/1 is recommended
at any time or place."
E.3.3.3. Toxicity of Cyanide to Terrestrial and Semi-Aquatic
Organisms
The results of several investigations concerning the
toxicity of molecular HCN to terrestrial and semi-aquatic organisms
are reported in Water Quality Criteria (McKee and Wolf, 1963).
Table E-8 summarizes ranges of lethal doses. Inspection of Table E-8
reveals that for humans weighing 165 pounds, the range of lethal dose
is .052 to .260 mg. Toxic doses for sheep have also been reported as
K05 mg per kg of body weight.
Rats were fed for two years with food containing 100 to
300 mg/kg of HCN with no resulting signs of cyanide toxicity (Howard,
1955). Samples of water containing 103 mg/1 of HCN were fatal to cows
and ducks (Clough, 1933; Anon., 1950). For NaCN, the approximate
minimum toxic dose and lethal dose to sheep were determined to be
4.15 and 5.22 mg per kg of body weight, respectively.
E-17
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TABLEE-8
TOXICITY (LETHAL DOSE) OF MOLECULAR HCN
TO TERRESTRIAL ORGANISMS
Organism Lethal Dose of HCN
Human* 52 - 260 mg
Cow 390 - 920 mg
Sheep 40 - 100 mg
Horse 390 mg
Dog 30 - 40 mg
Source: McKee and Wolf, 1963.
Corresponding to body weight of approximately 165 Ibs.
E-18
-------�
Water quality criteria for cyanide in public water
supplies were recommended on the basis of oral toxicity data of
cyanide to man ;(Table E-9), an assumed consumption of 2-liters of
water per day, and incorporation of a safety factor. The maximum
contaminant level for cyanide of 0.2 irig/1 has since been deleted :
from the primary drinking water regulations.
E.3.3.4. Treatment Technologies for Cyanide Removal
A variety of physical, chemical, and biological treat-
ment processes have been examined for cyanide removal including alka-
line chlorination, electrolytic decomposition, ozonation, complex-.
ation with metals, e.g., nickel, ion exchange, ion flotation, reverse
osmosis, dialysis, irradiation, permanganate oxidation* peroxide
oxidation, complexation with polysulfides, the Kastone process, liquid-
liquid extraction with primary and secondary amines, copper-catalyzed
activated carbon adsorption, and biological oxidation using trickling
filters and 'activated--sludge (USEPA, 1971; Patterson, T975). Many of
these treatment processes have been considered from the point of view
of low volume, highly concentrated effluents from metals finishing
plants. Some are beset with technical difficulties; others lack full-
scale demonstration.
In alkaline chlorination, cyanide ion is either oxidized
partially to cyanate, CNO", or completely to carbon dioxide, CC^, and
nitrogen, ^, under alkaline conditions (pH >10). Chlorine may be
administered either in the gaseous state, in which case it reacts with
water to form hypochlorite ions, OC1":
Cl2(g) + H20 * HOC1 + H+ + Cl"
HOC1 * H+ + OC1~
or directly as OC1" with sodium hypochlorite. The oxidizing agent in
both cases is OCT. Hypochlorite ion oxidizes CN~ to CNO" at a pH >10.
This oxidation is normally referred to as alkaline chlorination and
results in a species, CNO~, of very low toxicity. In general, a contact
E-19
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TABLE E-9
ORAL TOXICITY OF CYANIDE TO HUMANS
Dosage
Response
References
2.9 -4.7 mg/day
10 mg/, single dose
19 mg/1 in water
50 - 60 mg, single dose
non-injurious
non-injurious
calculated from safe
threshold limit for air
fatal
Smith, 1944
Bodansky & Levy,
1923
Stokinger &
Woodward, 1958
Merck Index, 1968
Source: NAS/NAE, 1972.
E-20
-------�
time of 0.5 to 2.0 hours ,is, required. Continuous mixing is
necessary to retard the formation of metal cyanide precipitates ,
which resist,oxidation. Further chlorination oxidizes CNO~ to
COg and ^ The initial conversion to CNO" is rapid, but the sub-
sequent oxidation to (X^ and ^ is very slow. Cyanate oxidation
can be greatly accelerated if the pH is lowered. Acid hydrolysis
converts CNO" to C02 and NH3. Cyanate oxidation at low pH requires
an excess of chlorine to prevent formation of toxic cyanogen chloride,
CNC1. Alkaline chlorination has been used to treat a 2,500 to 3,000
gal/hr flow containing cyanide. The cyanide was oxidized to cyanate
with a residual cyanide concentration of 0.1 mg/1 (Schink, 1968).
Ozonation has been seen to have potential as a means of
cyanide oxidation. Oxidation to cyanate is very rapid at pH values
in the range of 9 to 12, especially if copper is also present in the
wastewater (Green, 1972). Further oxidation of cyanate is much
slower. Ozone, has been shown to be effective in the oxidation of
zinc, nickel, and copper cyanide complexes; cobalticyanide was seen
to be resistant to oxidation by ozone (Patterson, 1975),
Ludzack and Schaffer (1962) performed continuous bench-
scale activated sludge investigations to determine the characteristics
of biodegradation of cyanide, and thiocyanate. The results of their
investigations were summarized in the following conclusions:
"1) Cyanide, cyanate, and thiocyanate are
effectively degraded by activated sludge
after two to three weeks of acclimation.
2) An additional source of metabolic energy,
such as dextrose in the feed, hastens
acclimation to the three feeds and improves
subsequent operation on cyanide and cyanate.
3) Activated sludge treatment of cyanide is
less effective above a feed concentration
of about 60 mg/1 CM; cyanide removal percent-
age and nitrification decrease while cyanide
stripping by aeration increases . . ."
E-21
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Murphy and Nesbitt (1964) reported an investigation
of cyanide removal in activated sludge systems in which no mixed
liquor suspended solids were wasted. Cyanide was the only source
of carbon and nitrogen. The maximum influent level was 120 mg/day
CN with observed removal of 99 percent.
E.4. HEAVY METALS
Various aspects of several heavy metals will be
discussed in the next sections. These metals include:
Cadmium
Chromium
Copper
Iron
Manganese
Tin
Zinc
Included in the discussion are the following topics: 1) chemistry
of heavy metals; 2) analytical methods; 3) toxicology; and 4) treat-
ment technologies for wastewaters containing heavy metals.
E.4.1. The Chemistry of Heavy Metals
Of 105 elements, 81 can be classified as metals. Metals
share similar physical and chemical properties. Important chemical
properties include: positive oxidation states; ability to act as good
reducing agents; and formation of hydroxides which are basic or
amphoteric. Table E-10 summarizes some important physical and chemical
characteristics of the seven metals under discussion. The metals are
considered individually below.
Cadmium is one of the metals of Group IIB, as is zinc.
The +2 oxidation state prevails in both cases. Cadmium forms a stable
oxide CdO, hydroxide Cd(OH)2> as well as stable salts such as chlorides
or sulphides, CdCl2 or CdS, respectively. Cd(CN)2 was discussed pre-
viously. With appropriate excesses of anions, cadmium forms stable
complexes such as [CdCl4]~2 or [CdI4]"2. Another important cadmium
i O
complex is the tetraamine complex, [Cd(NH3)4] . Solubility data on
cadmium salts and complexes are given in Table E-ll.
E-22
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TABLE E-10
SOME PHYSICAL AND CHEMICAL CHARACTERISTICS
OF THE SEVEN METALS
Metal Chenrical Symbol Atomic No. Atomic Wt. Oxidation States
Cadmi urn
Chromium
Copper
Iron
Manganese
Tin
Zinc
Cd
Cr
Cu
Fe
Mn
Sn
Zn
48
24
29
26
25
50
30
112
52
63.5
56
55
119
65
+2
+2 ,+3 ,+6
+ls+2,+3
+2 ,+3, +6
+2 ,+3 ,+4 ,+6 ,+7
+2 ,+4
+2
Source: Nebergall, Schmidt and Holtzclaw, 1972.
E-23
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TABLE E-ll
SOLUBILITY DATA
Metal
Cadmium
Chromium
Copper
Compound
or
Complex
Cd(OH)2
CdS
CdCO.
o
CdG20 3H 0
Cd (CN}2
[Cd(CN)4r2
[Cd(NH3)4f2
Cr(OH)3
Cud
CuBr
Cul
CuCNS
Cu2S
Cu(OH)2
CuS
CuC03
CuI2
CuCpO,
Cm ^
CuCn
[Cu(CN)4]-2
[Cu(CN)3F2
[Cu(CN)2]'1
[Cu(NH,)J+2
Ksp(25°C)
1.2 x 10"14
-9Q
3.6 x 10 **
2.5 x 10~14
1.5 x 10"18(@18°C)
4.5 x 10"3((315°C)
7.8 x 10"18
2.5 x 10"7
6.7 x 10"31
1.85 x 10"7
5.3 x 10"9
5.1 x 10"12
4 x 10"14
1.6X10'48
5.6 x 10"20
8.7 x 10'36
1.4 xlO'10
1.4 x 10"7
2.9 x 10"8
2.4 x 10~8(@ 20°C)
1 x 10"25
2.5 x 10"29
1 x ID'16
8.5 x 10"13
Solubility
of Metals
(9/1)
1.6 x 10"3
6.8 x 10"13
1.8 x 10"5
1.4 x 10"2
11.6
1.4 x 10"2
1.8
6.5 x 10"7
2.7 x 10"2
4.6 x 10"3
1.4 x 10"4
1.3 x 10"5
9.4 x 10"15
1.5 x 10"5
1.8 x 10'16
7.5 x 10"4
2.1 x 10"1
1.1 x 10"2
9.9 x 10"3
2.1 x 10"4
2.0 x 10"6
1.8 x 10"4
8.1 x 10"2
Reference
1
1
1
2
3
1
1
1
1
1
1
1
1
1
1
1
2
2
3
4
4
1
1
E-24
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TABLE E-ll (cont'd)
SOLUBILITY DAtA "
Metal
Iron
Manganese
Tin
Zinc
Compound
or
Complex
Fe(OH)2
FeC03
FeS
Fe(OH)3
FeC204
[Fe(CN)6]"4
[Fe(CN)6]'3
[Fe(CNS)5r3
Mn(OH)2
MnC03
MnS
Sn(OH)2
SnS
Sn(OH)4
ZnC03
Zn(OH)2
ZnS
ZnC20412H20
Zn(CN)2
Zn2Fe(CN)6
Zn3[Fe(CN)6]2
[Zn(CN)4]-2
[Zn(OH)4r2
Ksp(@25°C)
7.9 x 10"15
2.1 x 10"11
1 x ID'19
1.1 x 10"36
2.1 x 10"7
1 x 10-37
1 x ID'44
3.1 x 10"4
4.5 x 10"14
8.8 x 10"11
5.6 x 10"16
5 x 10~26
8 x 10"29
* 1 x ID'56
6 x 10"11
4.5 x 10"17
1.1 x 10"21
1.35 x 10"8(18°C)
4.9 x 10"13
1.8 x 10"15
6.1 x 10'36
1 x 10~19
3.5 x 10"16
Solubility
of Metals
(9/1)
7.0 x 10"4
2.6 x 10"4
1.8 x 10"8
2.5 x 10"8
2.6 x 10"2
6.2 x 10"5
6.2 x 10"6
3.8
1.2 x 10"3
5.2 x 10"4
1.3 x 10"6
2.8 x 10"7
1.1 x 10"12
5.7 x 10"10
5.0 x 10"4
1.4 x 10"4
2.2 x 10"9
2.4 x 10"3
3.2 x 10"3
9.9 x 10"4
6.9 x 10"6
3.4 x 10"3
1.7 x 10"2
Reference
1
1
1
1
2
1
1
1
1
1
1
1
1
1
1
1
1
2
3
5
5
1
1
E-25
-------�
References:
1) Nebergall, et. al., 1972
2) Weast, 1968
3) ASTM, 1976
4) Band, 1966
5) Linke, 1958; 1965
E-26
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The chemistry of zinc is quite similar to that of
cadmium. Common zinc salts include the oxide ZnO, the hydroxide
Zn(OH)2» the chloride ZnCl2 and basic chloride Zn^C^. the sulphate
and sulphide ZnS04 and ZnS, respectively. Zinc also shows a strong
tendency to form complex ions. The most frequently encountered are
the halo, cyano and amine complexes. Again, solubility data are pre-
sented in Table E-ll. An important characteristic of zinc is the
amphoteric nature of some of its compounds. An amphoteric compound
can behave as either an acid or a base. Zinc hydroxide can be
dissolved either in an acid or a base:
Zn(OH)2 + 20H"—- [Zn(OH)4]"2 (zincate ion)
Zn(OH)2 +' H+ Zn+2 + H20
Chromium belongs to Group VIB. Chromium is a transition
metal which shows several oxidation states and forms stable complex
ions. The main oxidation states are +2, +3, and +6. Solutions of
chromium (II) salts include the chloride, sulfate and acetate. It
should be noted that the hydroxide of Cr+2 is basic. However, the
hydroxide of chromium III is amphoteric:
Cr(OH)3 + OH"—-[Cr(OH)4]"1 (chromite ion)
Cr(OH)3 + 3H+—-Cr+3 + 3H20
The best known salts of trivalent chromium are the sulfate (octade-
hydrate), Cr2(S04)~-18H20 and the chloride (hexahydrate), CrCl3-6H20.
Chromium in the +6 oxidation state usually forms the
oxide, Cr03, or the oxyanion chromate, Cr04~2 or dechromate, Cr207"2.
Dominance of one oxyanion species is a function of pH, i.e.:
Zr2°7~' + 20H"== 2Cr207"2 + H20 (basic solution)
2Cr04"2 + 2H+ = Cr207"2 + H20 (acidic solution)
E-27
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In very strong acid solutions, the chromate ion can be further
condensed to produce tri chromate ions, Cr30-jQ~2. Chromium compounds
and complexes tend to be highly colored. Solubility data for chromium
compounds are given in Table E-ll .
Copper is found in the Group IB metals, commonly
called the coinage metals. Although copper can exhibit +1, +2 and
+3 oxidation states, the +2 state is the most common. Copper can
-2 +2
form several stable complexes such as [Cu(CN)..]" , [Cu(NH,).] ,
P 2 *f o ^
[CUC14J , and [Cu(OH) ] when copper is in the +2 state or
[Cu(CN)3]~2, [Cu(CN)2]"1, [Cu(NH3)2]+1, and [CuXg]" where X is a
halide, when copper is monovalent. Divalent copper complexes are
colored, while most copper (I) complexes are not.
Copper (I) hydroxide is unstable and decomposes into the
oxide and water. Copper (II) hydroxide is somewhat amphoteric forming
_2
[Cu(OH)4] in basic solutions. Other copper compounds include: copper
(I): CuCl , Cu2S, CuCN CuBr, Cul; and copper (II): CuSO. and hydrates,
CuCl2, CuBr2. CuS- CuI2 does not exist. Solubility data are given in
Table E-ll.
Iron is a metal in Group VII. Iron exhibits oxidation
states of +2, +3, and +6. The +6 state is rare and unimportant. Iron
is magnetic and tends to form colored compounds and complexes. The
hydroxides of iron (II) and (III) are basic and have little or no acid-
forming tendencies. The oxides of iron are well known: FeO from iron
II; FSpOo' hematite from iron (III); and loadstone, a mixture of iron
II and III oxides, Fe30. or FeO-Fe-O., common iron (II) salts include
the chloride with various waters of hydration, the carbondate, the
sulfide and the ammonia sulfate. Important iron III salts include
the chloride and its hydrates (FeCl3, [Fe(H20)g]Cl3); sulfate and alums
(Fe2(S04)3), NH4Fe(S04)2-12H20; thiocyanates, Fe(NCS)+2; tannates; and
ferrocyanide (also called hexacyanoferrate (III) ion) complexes,
-4
[Fe(CN)6]-, such as KFe[Fe(CN)6]-H20.
E-28
-------�
Manganese is part of the periodic Group VIIB. Mangan-
ese forms compounds in which it exhibits oxidation states of +2, +3,
+4, +6, and +7. Table E-12 summarizes the information on the correspond-
ing oxides and hydroxides of the five oxidation states of manganese.
However, the only stable cation is the +2 state. The common soluble
manganese (II) salts are the chloride, nitrate, and sulfate. Mn(OH)2
is completely basic in nature.
The chlorides of Mn+3 arid Mn , as well as the sulfate,
are unstable. However, the complex salt KpMnFe is not readily decom-
p
posed. The radical manganate MnO^ exhibits managnese in its +6
state. It is stable only under alkaline conditions. The permanganate
anion is a strong oxidizing agent. It exhibits manganese in its +7
state, MnO^"1. Solubility data are given in Table E-ll.
Tin belongs to Group IVA. Tin exhibits both a +2 and
+4 oxidation state. The hydroxide of the +2 state is amphoteric. Upon
dissolution in a base it produces stannite:
Sn(OH)2 + 20H -Sn(OH)4~2
Other common compounds of tin include the oxides (II and IV); chlorides
(II and IV) and corresponding hydroxychloride, Sn(OH)Cl and HgSnClg,
hexachlorostannic acid; and sulfides (II and IV). Tin forms stable
p
complexes, also. These include: thiostannate, SnSg fc and the
stannites and hexachlorostannates discussed earlier. Solubility data
are given in Table E-ll.
E.4.2. Analytical Methods for the Determination of Metals in
Aqueous Media
The analytical procedures are basically the same for
the seven metals under discussion. The principle means of quantifying
metals is atomic absorption spectrophotometry or AA.
AA is based on the fact that elemental metals will absorb
light of the same wavelength they emit when excited. When radiation
from an excited metal is passed through a flame containing ground state
E-29
-------�
TABLE E-12
OXIDES AND HYDROXIDES OF MANGANESE
Oxidation State Oxide
+2 MnO
+3 Mn»0n
+4 Mn02
+6 Mn03
+7 Mn«07
Hydroxide
Mn(OH)2
Mn(OH)3
H2Mn03
H2Mn04
HMn04
Character
Moderately
Basic
Weakly
Basic
Weakly
Acidic
Acidic
Strongly
Acidic
Source: Nebergall, Schmidt and Holtzclaw, 1972.
E-30
-------�
atoms of that metal, the intensity of the transmitted radiation will
decrease proportionately according to the amount of ground state
metal in the flame. A hollow cathode lamp (whose cathode is made
from the metal under analysis supplies the radiation. The metal
from the sample is placed in the beam of radiation by aspirating
the sample into a flame of oxidizing fuel. A monochromator isolates
the characteristic radiation from the hollow cathode lamp. A photo-
sensitive device measures the transmitted radiation. Standards are
run for quantitative determination.
Table E-13 lists the concentration range for the seven
metals of interest applicable for flame AA when samples are in aqueous
media. Included in this table are optimum operating parameters and
additional comments.
AA is the state of the art procedure of choice for
routine analyses of metals.
E.4.3. Toxicity of Heavy Metals to Aquatic Organisms
The aquatic chemistry of heavy metals is extremely compli-
cated. Depending upon environmental conditions, e.g., pH, presence of
chelating agents, etc., a variety of dissolved and precipitated,species
can exist. Some of the possible complexes and compounds are toxic to
aquatic life; others are not. Furthermore, in addition to determining
the types of metal species present, environmental conditions have an
impact on the resulting toxicity. The relationship between water hard-
ness and acute toxicity, for example, is well established for certain
heavy metals (Figure E-l). The following recommendation, contained in
Water Quality Criteria (NAS/NAE, 1973), reflects the difficulties en-
countered when attempts are made at predicting the amount of a given
metal which will be toxic for a particular set of environmental
conditions:
Since forms of species of metals in water
may change with shifts in the water quality,
and since the toxicity to aquatic life may
concurrently change in as yet unpredictable
ways, it is recommended that water quality
E-31
-------�
TABLE E-13
DETERMINATION OF METAL CONCENTRATION BY AA
I
co
ro
Metal
Cadmi urn
Chromium
Copper
Iron
Manganese
Tin
Zinc
Cone. Range
(mg/1)
0.05-5.0
0.2-20.0
0.1-20.0
0.1-20.0
0.04-10.0
10.0-200.0
0.02-3.0
Detection Limit
(mg/D
0.002
0.02
0.01
0.02
0.01
0.8
0.005
Wave Length Fuel Oxidant
(mm)
228.8
357.9
324.7
248.3
279.5
286.3
213.8
P H Air
Urtflrt r\ 1 1
CpHo Nitrous
Oxide
C2H2 Ai r
. C2H2 Air
C2H2 Ai r
C2H2 Air
C2H2 Ai r
Comments
Use flameless AA
if <20ug/l
Use flameless AA
if <200 yg/l
Use flameless AA
if <50 yg/l
Use flameless AA
if <20 yg/l
References
1,3,4
1,3,4
1,3,4
1,3
1,3
2
1,2,3,4
1
ASTM, 1976.
2EPA, 1974.
3APHA/AWWA/WPCF, 1971.
*EPA, 1977.
-------�
a
£
5
2
1
0.5
0.2
0.1
0.05
0.02
0.01
1
'^»— ' — ~~
^X
^X"^
^
/
/
'
LEAD
**~^
^
j/S'
^
/
X
*^
x
x^^
X
/
x
-
-
"
X
x
X
^X
x
/
COPPER
^S
X
X
X
X
X
x
x
"*
0 20 50 100 200 50
5000
1000
500
o
M
a.
200
100
50
20
Total Hardness, mg/1 as CaCoj
FIG. E-1. THE 48 HOUR LETHAL CONCENTRATIONS OF THREE HEAVY METALS
FOR RAINBOW TROUT (Salmo gairdneri). (Simple Relationships Exist For Other
Species Of Fish.)
Source: NAS/NAE , 1973 .
E-33
-------�
criteria for a given metal be based on
the total amount of it in the water, re-
gardless of the chemical state or form
of the metal, except that settleable
solids should be excluded from the
analysis (Standard Methods 1971). Addition-
ally, hardness affects the toxicity of
many metals (see Figure E-l).
Metals which have collected in the
sediments can redissolve into the water, and
such redissolved metals should meet the
criteria for heavy metals. To protect aquatic
life, amounts likely to be harmful should not
occur in the sediments.
It is recommended that any metal species
not specifically mentioned in this report but
suspected of causing detrimental effects on
aquatic life be examined as outlined in the
section on Bioassays.
The following discussions pertain to specific metals.
Cadmium. Cadmium is neither essential nor beneficial to
biological systems. It is believed to have a high toxic potential and
appears to exhibit synergism when present with zinc and/or cyanide. Con-
tinuous flow-through bioassay investigations designed to assess both acute
toxicity and to provide information over life cycles are reported in the
literature for a variety of fish, using both "hard" and "soft" water
(Pickering and Gast, 1972; Eaton, 1972; Spehar, 1974). Species of fish
utilized include the fathead minnow (Pimephales promelas), bluegill sun-
fish (Lepomis macrochirus), channel catfish fry (Ictalurus punctatus).
brook trout (Salvelinus fontinalis), brown trout (Salmo trutta), lake
trout (Salvelinus namaycush), northern pike (Esox lucius), white sucker
(Catastomus commersoni), smallmouth bass (Micropterus dolomieui), and coho
slamon (Oncorhynchus kisutch). Cadmium concentrations varied from 0.4 to
2,140 yg/1.
E-34
-------�
Several investigations have also been performed concerning
the toxicity of cadmium to various macroinvertebrates. Anderson, et al, (1975)
in a soft water, continuous flow-through bioassay, determined a 10-day LC5Q
of 3.4 yg/1 for the midge (Tanytarsus dissimilis). Eisler (1971) deter-
mined that, for the hermit crab (Pagurus longicarpus), the grass shrimp
(Palaemonetes vulgaris), and the sand shrimp (Crangon septemspinosa), the
96-hr LC50 values were in the range of 320 to 420 yg/1.
The results of these investigations support a distinction
in the recommended water quality criteria for cadmium on the basis of water
hardness as follows (EPA, 1976):
Criteria for the Protection of Freshwater Aquatic Life
Soft Water Hard Water
0.4 yg/1 1.2 yg/1 cladocerans and salmonid fishes
4.0 yg/1 12.0 P9/1 for other, less sensitive, aquatic life
Soft water denotes water having a hardness (mg/1 as CaCO.,) in the range
of 0 to 75. Hard water has a hardness in excess of 75 mg/1 as CaC03
(EPA, 1976).
Iron. Iron is essential to plants and animals in trace
quantities. Its behavior in aquatic environments depends upon pH, dis-
solved oxygen, and the presence of other species, e.g., natural and
synthetic chelating agents, cyanide, etc. Iron, in a dissolved state,
i p -|.O
can exist in two oxidation states: Fe (ferrous) and Fe (ferric).
+2 +3
Of the two, only Fe is soluble, Fe forming an insoluble hydroxide.
Fe , in the presence of suitable amounts of dissolved oxygen is rapidly
oxidized to the ferric state. Iron forms complexes (ferrocyanide and
ferricyanide) with cyanide. While these complex ions are associated
with very high stability constants, they will decompose photochemically,
in the presence of strong sunlight, to yield free cyanide and iron ions.
E-35
-------�
The toxic impacts of iron and aquatic life are due
to coating of the gills by ferric hydroxide and ferric oxide floes
and smothering of fish eggs and bottom-dwelling organisms by settled
iron precipitates. Table E-14 presents some observations and responses
of aquatic life to various concentrations of iron. The recommended
water quality standard for iron to protect freshwater aquatic life
is 1.0 mg/1.
Zinc. The acutely toxic impact of zinc on fish is
believed to be the result of formation of insoluble compounds with
the mucous covering the gills, damage to gill epithelium, or internal
poisoning. Chronic toxicity is revealed by general enfeeblement,
widespread histological changes in many organs (other than gills),
and retardation of growth and maturation. The impacts of zinc on
fish vary with the species, age, and condition of the fish, water
quality parameters, especially hardness, temperature, pH, and dissolved
oxygen levels, and the presence of components which exhibit antagonis-
tic and synergistic effects with zinc (EPA, 1976; McKee and Wolf, 1963).
Zinc toxicity is increased with increases in temperature
and reductions in dissolved oxygen levels. The solubilities of many
zinc compounds and complex ions vary with pH. The antagonistic effect
of hardness on zinc toxicity has been demonstrated by several investi-
gators (Figure E-l). On the basis of investigations performed by the
Water Pollution Research Board, concerning the toxicity of zinc to
sticklebacks in soft water to which has been added calcium chloride or
calcium carbonate, it appears that the antagonistic effect is due to
the presence of the calcium ion rather than the carbonate ion. Zinc
appears to exhibit synergism with copper (soft water), other heavy metals,
and cyanide (EPA, 1976; McKee and Wolf, 1963).
Several investigations, using both static and continuous
flow-through bioassays to assess zinc toxicity to a variety of fish under
different environmental conditions (pH, hardness, etc.) are reported in
the literature and summarized in review articles (McKee and Wolf, 1963;
E-36
-------�
TABLE E-14
OBSERVATIONS AND RESPONSES OF AQUATIC LIFE TO
VARIOUS CONCENTRATIONS. OF IRON
Concentration of Iron,
in mg/1 Remarks
0.2 Threshold concentration for lethality to
three types of fish
0.9 Carp will die at this concentration if pH
is 5.5 or lower
1-2 Death of pike, tench, and trout at pH 5.0-
6.7
1-2 No deaths among dogfish during one week
1-2 Indicative of acid pollution and other
conditions unfavorable to fish
5 Killed dogfish in 3 hours
10 Caused serious injury or death to rainbow
trout in 5 minutes
40 Not lethal to fingerling channel catfish
in 96 hours when added as ferrous di-
sodium versanate
50 Upper limit for fish life
E-37
-------�
Skidmore, 1964; Middlebrooks, et al, 1973; EPA, 1976). For soft water,
concentrations of zinc in the approximate range of 0.1 to 8.0 mg/1 have
been determined to be lethal for exposure times in the range of 8 hours
to 6 days. With bluegill sunfish in soft water, for example, the 96-hr
is in the range of 1.9 to 3.6 mg/1 of zinc. For hard water, the 96-hr
for bluegill sunfish is in the range of 10.1 to 12.9 mg/1 of zinc
(McKee and Wolf, 1963).
Bioassays using young pond snails (Physa heterostropha)
in soft (20 mg/1 as CaCOJ and hard (100 mg/1 as CaCO-J water yielded
O O
96-hr LC5Q values of 303 yg/1 and 434 yg/1 of zinc, respectively (Wurtz,
1962). Warner and Bell (1969) determined a 10-day LC5Q of 16 mg/1 of
zinc to mayflies (Ephemerella subvaria) in water having a hardness of 44
mg/1 as CaCOo- Biesinger and Christensen (1972) determined a 48-hr LC5Q
of zinc of 0.1 mg/1 to Daphia magna in water having a hardness of 45 mg/1
as CaC03-
For the protection of freshwater aquatic life, the recom-
mended water quality standard is 0.01 of the 96-hr LCr0 which is deter-
mined through bioassay using a sensitive resident species (EPA, 1976).
Manganese. Manganese is an essential element in trace
quantities to both plants and animals. Relatively little data exist in
the literature concerning its toxicity to aquatic life. McKee and Wolf
(1963) report that fish have survived concentrations of manganese ranging
from 1.0 to 2,700 mg/1 for exposure times in the approximate range of 50
hours to 7 days. Since manganese ions are rarely found at concentrations
in excess of 1 mg/1, manganese is not considered to be a problem in
freshwaters and no water quality standard for the protection of freshwater
aquatic life has been recommended (EPA, 1976).
Tin. Tin is believed to be beneficial to fish in trace
quantities. Finkel and Allec (1940) found that the growth of goldfish
was accelerated by stannous ions at a concentration of approximately 0.6
mg/1. Goldfish have been reported to survive 626 mg/1 of tin (as SnCl2)
in soft water at pH 3.5 for 1.0 to 1.5 hours and in hard water at pH 3.8
for 4 to 5 hours. A concentration of tin of 1.2 mg/1 was survived by
E-38
-------�
young eels for over 50 hours; however, a concentration of 6.0 mg/1 proved
to be lethal for an exposure period of 2.8 hours (McKee and Wolf, 1963).
The threshold of SnCl2 to Daphnia in Lake Erie dilution water was reported
to be 25 mg/1 (Anderson, 1948). There is no recommended water quality
standard for tin to protect freshwater aquatic life.
Chromium. The toxicity of chromium to aquatic life is
dependent upon the species, the oxidation state of chromium and pH. Also
chromium appears to be slightly less toxic in hard water than in soft
water. In investigations, using static bioassays and fathead minnows
(Pimephales promelas), bluegill (Lepomis macrochirus), goldfish (Carassius
auratus) and guppies (Poecilia reticulata), Pickering and Henderson (1966)
found 96-hr LC50 values for hexavalent chromium ranging from 17.6 mg/1
(fathead minnows) to 118 mg/1 (bluefill) in soft water (20 mg/1) and from
27.3 mg/1 (fathead minnows) to 133 mg/1 (bluegill) in hard water (360
mg/1). Hexavalent chromium concentrations of 0.2 mg/1 have been shown to
reduce significantly both growth and survival of Chinook salmon (Oncorhynchus
kisutch) (Olson, 1958). However, Olson observed no detrimental effects on
salmon alevins with trivalent chromium at a concentration of 0.2 mg/1.
Daphia magna in soft water (45 mg/1 as CaCOo) were seen to undergo
reproductive impairment at trivalent chromium concentrations of 0.33
mg/1 (Beisinger and Christensen, 1972). The recommended water quality
standard for the protection of freshwater aquatic life for chromium is
0.1 mg/1 (EPA, 1976).
Copper. Copper is essential in trace quantities to plants.
It has proven abilities in the control of algae and has been shown to be
concentrated by plankton from surrounding waters by factors ranging from
1,000 to greater than 5,000 (Morgan, 1961). Concentrations of copper in
the range of 0.1 to 0.5 mg/1 have been shown to be toxic to bacteria and
other microorganisms.
The toxic impact of copper on aquatic life is a function
of the species of aquatic life, and several water quality parameters,
especially hardness, alkalinity, temperature, turbidity, level of C02»
and the presence of chelating agents and synergistic components, e.g.,
E-39
-------�
zinc and cadmium. Copper appears to exhibit synergism with zinc
when both are present in relatively high concentrations in soft
water. No synergism between zinc and copper was evident in hard
water (Water Pollution Research Board of London, 1961). The
formation of copper carbonate and other insoluble compounds in
hard (high alkalinity) water reduces the toxicity of copper.
Concentrations of copper in range 0.015 to 3.0
mg/1 have been shown, particularly in soft water, to be toxic
to a variety of fish, Crustacea, mollusks, insects, and plankton
(McKee and Wolf, 1963). The results of several bioassay investiga-
tions are reported in the literature (EPA, 1976; McKee and Wolf, 1963).
On the basis of these investigations, together with a realization of
the complicated aquatic chemistry exhibited by heavy metals in general,
the following recommendation has been made concerning the determination
of water quality criteria for copper sufficient to protect freshwater
aquatic life (EPA, 1976).
The concentration of copper that has
been associated experimentally with no harm-
ful effect for several aquatic species is
about 5 to 15 yg/1. This is very close to
the average ambient freshwater concentration
now found where copper occurs in measurable
quantity. In waters with high alkalinity
and/or with much organic material many
species will be able to tolerate higher
ambient copper concentrations. In such
cases, the criterion should not exceed
0.1 of the 96-hr LC5Q (the approximate mean
application factor from tests reported above)
as determined through bioassays using sensi-
tive resident species.
E-40
-------�
E.4.4. Treatment of Metal-Containing Wastewater
The methodology options and corresponding treatment
procedures are essentially the same for the seven metals under
discussion. Common methods include precipitation of the metal as
the hydroxide or sulfide, ion exchange, evaporative recovery, electro-
lytic recovery, or reverse osmosis. Specific operating requirements
will vary from metal to metal and waste to waste, making one option the
most attractive. A brief discussion of the waste treatment alternatives
for metals is presented below. It should be emphasized that many of
these methods apply to fairly concentrated wastestreams such as those
emanating from metals finishing plants. Often, in these cases, metals
recovery is economically feasible.
E.4.4.1. Cadmium
Common methods for the treatment of cadmium-bearing
wastes are precipitation and ion exchange (Patterson, 1975). Precipita-
tion of cadmium as the hydroxide at pH values in the range of 9.5 to
12.5 is very effective (Maruyama, 1972; Cotton, 1962; Jenkins, 1964;
Gulp, 1974). Co-precipitation with iron hydroxide (Anderson, 1971;
Weener, 1967) or aluminum hydroxide improves cadmium removal (Gulp,
1974). Table E-15 lists residual cadmium concentrations after various
precipitation methods. It should be noted that cadmium is difficult
to precipitate in the presence of complexing agents. Consequently,
pretreatment for cyanide, ammonia and chelating agents is often
required (Weiner, 1967; Eden, 1950; Lancy, 1967; Mi near, 1972). Other
removal processes include the precipitation of cadmium as the oxide
(Anon, 1971) and as the sulfide (Larsen, 1973; Shimoriizaka, 1972).
There are many ion exchange resins with a high specifi-
city for cadmium (Matlock, 1968). Ion exchange can be used as a
polishing treatment or recovery process (Patterson, 1975). In many
cases, capital expense can be offset by the recovery value of the
cadmium (Digregorio, 1968; Mattock, 1968; 01 dan, 1956; Zieves, 1971).
E-41
-------�
TABLE E-15
RESIDUAL CADMIUM AFTER TREATMENT
Process
Residual Cadmium
(mg/1)
Reference
Hydroxide precipitation
Hydroxide precipitation
plus filtration
Co-precipitation with
ferrous hydroxide
Sulfide precipitation
Freeze concentration
0.1-1.0
0.0007-0.08
0.044-0.050
0.008
0.4
Jenkins, 1964
Hansen, 1959
Gulp, 1964
Donnelly, 1974
Chalmers, 1970
Maruyama, 1972
Larsen, 1973
Campbell, 1972
E-42
-------�
E.4.4.2. Chromium
In aqueous media, chromium can exist in the trivalent
(Cr ) or hexavalent (Cr+ ) states. Hexavalent chromium is primarily
present in the form of chromate (Cr04"2).or dichromate (Cr207"2).
The most common form of hexavalent chromium treatment is reduction to
the +3 valence (oxidation state) and precipitation of the hydroxide.
Reduction of the hexavalent chromium is performed by
lowering the pH of the waste to 3.0 or below and adding a reducing
agent such as sulfur dioxide, which is most common (Stone, 1972;
Raise, 1960), sodium bisulfite (Aurutskii, 1961, 1969), ferrous sulfate
(Donovan, 1970; Heynike, 1969; Stoner, 1971; Bennett, 1972), metabi-
sulfite (Werner, 1972; O'Neill, 1970), etc. The reduction step is
sensitive to pH, reaction time, nature and concentration of reducing
agents. The trivalent chromium is precipitated by lime (MacDougall,
1954; Besselievre, 1969).
Ion exchange processes are reported to be economical
for the treatment of chromium-bearing wastes (Ross, 1968). The
trivalent metal is removed on the cation exchanger. The anion exchange
removes the chromate and dichromate species. Sodium chromate is eluted
from the anion exchange resin during regeneration. This, in turn, can
be passed through cation exchange with recovery for reuse as chromic
acid (Dvorin, 1960). The pH is a critical factor in the use of ion
exchange of chromates because of the conversion to dichromate. Anion
exchange resins are less selective for dichromate, and leakage
occurs (Anderson, 1974).
Other methods which have treated wastes containing
hexavalent chromium include: various electrochemical reductions
(Joster, 1973; Chase, 1974; Duffey, 1974); evaporative recovery (Pummer,
1973; Culotta, 1970); reverse osmosis (Cruver, 1973); and freeze
concentration (Donnelly, 1974). An alternative to the treatment of
hexavalent chromium, the use of trivalent chromium, could be investigated.
E-43
-------�
Table E-16 summarizes the results of the various treat-
ment processes. As mentioned earlier, trivalent chromium is often
removed as the hydroxide by percipitation with caustic soda or lime.
Optimal pH is 8.5 to 9.5 (Besselievre, 1969). Coagulant aids do
improve chromium removal (Hansen, 1959; O'Connor, 1962).
Typically, large quantities of sludge are produced in
the precipitation of metal hydroxides from industrial wastes. Although
the sludges may settle rapidly, they are not very compact, containing
2 to 3 percent solids. Consequently, sludge concentration and disposal
techniques must be investigated. Options include lagooning, vacuum
or pressure filtration, or centrifugation. Advantages and problems
exist for each process (Anderson, 1971). There is, however, a growing
emphasis on filtration of metal hydroxide sludge in conjunction with
more stringent suspended solids standards.
Ion exchange for the removal of trivalent chromium is
not extensively developed. This is due in part to the fact that most
industrial waste contains the hexavalent chromium and, if recovery is
employed, it removes the chromate or dichromate directly. One problem
with purifying chromic acid with ion exchange is that in high concentra-
tions (250 to 400 mg/1) it will attach and destroy the resin (Ross, 1968;
Thompson, 1971).
Table E-17 lists the results of various precipitation
procedures to remove trivalent chromium from wastes.
E.4.4.3. Copper
As discussed for previous metals, the treatment pro-
cesses for the removal of copper from wastewaters include: precipita-
tion and solids removal, or recovery by ion exchange, evaporation,
electrolysis. The latter group is desirable because of the increasing
value of copper. Precipitation is applicable in the concentration
range of 1 to 1,000 mg/1; ion exchange, <200 mg/1; electrolytic recovery
>10,000 mg/1 (Dean, 1972).
E-44
-------�
TABLE E-16
RESIDUAL Cr+6 AFTER TREATMENT
Process
Residual Cr"1"6
(rng/1)
Reference
Reducti on
Di oxi de
- Sulfur
Reduction - Bisulfite
Reduction - Ferrous
Sulfate
Ion Exchange
Freeze Concentration
0.01-1.3
0.05-1.0
Reduction - Metabisulfite 0.001-0.4
1.0
0.0-0.9
0.225
Stone, 1972
Shink, 1968
Teer, 1972
Curry, 1972
Lewin, 1972
Aurutskii, 1969
Anon, 1971
Landy, 1971
Werner, 1972
Cheremisinoff, 1972
O'Neill, 1970
Bennett, 1972
Richardson, 1968
Rothstein, 1958
Anon, 1973
Campbell, 1972
E-45
-------�
TABLE E-17
SUMMARY OF TRIVALENT CHROMIUM TREATMENT
Method
pH
Chromium (mg/1)
Initial Final
Reference
Precipitation
Precipitation
Precipitation
Precipitation
Precipitation
Precipitation
with sand filtration
—
8.8
12.2
7-8
—
8.5
—
650
650
140
1,300
7,400
7,400
0.75
18.0
0.3
1.0
0.06
1.3-4.6
0.3-1.3
Anderson, 1968
Anderson, 1968
Wang, 1973
Aurutskii , 1969
Hansen, 1959
Stone, 1967
Stone, 1967
Precipitation
2.2
0.02 Teer, 1972
Source: Patterson, 1975.
E-46
-------�
Copper is usually precipitated as the hydroxide
using lime. Optimum pH is 9.0 to 10.3 (Stumm, 1970). Co-precipi-
tation increases removal (Gulp, 1974), whereas organic and inorganic
copper hydroxide sludges contain 0.13 to 6.0 percent dry weight copper
in 20 to 40 percent total solids (Jackson, 1972). Cuprous oxide
sludges are very dense (40 to 60 percent solids) and settle well
(Volco, 1971; Crowle, 1971; Jackson, 1972). Treatment of the waste
with a reducing agent and sodium hydroxide forms the cuprous oxide.
This is recommended by several authors (Valco, 1971; Crowle, 1971;
Jackson, 1972; Curry, 1972), as it is also a readily marketable
sludge.
Evaporative recovery has been practiced for over 20
years (Culotta, 1970). Modification of a wastestream segregation
and flow reduction is usually essential. This results in high reuse
and recovery benefits (Dept. of Interior, 1969), as well as water
savings (Barnes, 1968; Domey, 1970).
Ion exchange can produce very low residual copper
concentrations, even from initially dilute wastes (Botham, 1953).
When compared to other treatment methods for cases where metal
recovery is not feasible, ion exchange does not appear a viable
alternative because of costs (Anderson, 1971; Lancy, 1972; Sievers,
1971). When recovery is feasible, reclamation of copper can pay
for the treatment system within four years (Schore, 1972).
Copper metal can be recovered by the direct electro-
lysis of concentrated solutions. Power requirements are too great
to treat dilute (<2,000 mg/1) solutions (Jackson, 1972). The plating
industry often employs copper cyanide baths. Electrolysis can recover
copper and simultaneously destroy cyanide (Pinkerton, 1962; Easton,
1967; AES, 1969).
Other process development includes: "cementation"
(percolation of copper wastewater through scrap iron), (Jester, 1973;
Case, 1974; Anderson, 1972); electrodialysis (Bovet, 1970); carbon
filtration (Maryuyama, 1972; Nilsson, 1971); and reverse osmosis
(Donnelly, 1974).
E-47
-------�
TABLE E-18
RESIDUAL COPPER AFTER TREATMENT
Process
Residual Cu
(mg/1)
Reference
Hydroxide Precipitation
(Lime)
Hydroxide Precipitation
(Lime)
with sand filtration
Oxide Precipitation
Co-Precipitation (Lime)
Ion Exchange
0.0-7.8
0.0-0.5
0.09-0.25
0.155-0.352
0.03
Nyquist, 1959
Stone, 1967, 1972
Talmange, 1965
Teer, 1972
Watson, 1954
Ogawa, 1972
Martin, 1973
Maruyama, 1972
McGarvey, 1952
Botham, 1953
E-48
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E.4.4.4. Iron
Iron can exist in the +2 or +3 oxidation state,
depending upon pH and dissolved oxygen concentrations. At a pH of 7
and with oxygen present, Fe+2 is oxidized to Fe+3 and the insoluble
hydroxide forms. At pH <6, the oxidation is very slow. Also, at
pH >12, the hydroxide resolubilizes to yield Fe(OH)^. Formation of
complex ions (e.g., with cyanide) also solubilizes the iron. Organic
compounds with hydroxl or carbonyl functional groups reduce the Fe+2 -»•
Fe+3 oxidation rate (Jobin, 1972).
Industrial wastes are often acidic. Neutralization
not only increases treatment costs, but also generates large quantities
of precipitated gypsum (calcium sulfate). Gypsum forms from the com-
bination of ambient sulfuric acid (common industrial acid) and the lime
addition. This adds to the sludge disposal problem (Armco, 1971; Haney,
1964). One alternative would be the combination of acidic and basic
wastes followed by the co-precipitation of metals (Cupps, 1961). More-
over, to achieve low effluent iron levels, it is frequently necessary
to filter the clarifier effluent.
Other past waste treatment alternatives include: deep
well injection for concentrated waste liquors (Anon, 1970); reverse
osmosis (Rex, 1972); evaporative recovery of acids and iron (Delanie,
1966; Besselievre, 1969); and reduction of ferrous chloride in acid
liquor to free iron or ferric oxide by hydrogen gas (Jackson, 1972).
Table E-19 summarizes the residual iron data from the various treatment
procedures.
E.4.4.5. Manganese
Since manganese exhibits five oxidation states, it can
occur in many forms and compounds. Only the manganous (+2 oxidation
state) salts and permanganate anions are soluble. Under normal
circumstances the permanganate anion is reduced to manganese dioxide,
which is insoluble (Nebergall, 1972).
In the mid-sixties, five popular treatments for the
removal of manganese were: 1) aeration; 2) manganese greensand;
3) chlorination; 4) chlorine dioxide; and 5) potassium permanganate.
E-49
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TABLE E-19
SUMMARY OF TREATMENT PERFORMANCE
Process
Iron Concentration, mg/1
Influent Effluent Reference
MUNICIPAL
Chlorination, alum-lime-sodium
silicate precipitation, sand
filtration
Aeration, lime, sand filtration
Aeration, sand filtration
Aeration, coke bed filtration,
sedimentation, sand filtration
Lime, aeration, diatomite
filtration
ACID MINE DRAINAGE
Limestone slurry
Lime
Soda Ash
1.5 0.05 (Haney, 1964)
2.4 0.0 (Haney, 1964)
2.5 0.13 (Gardner, 1964)
5.7 0.13 (McCracker, 1961)
10 0.1 (Collin, 1962)
145 5
157 1.6
126 2.3
(Wilmoth, 1970)
(Wilmoth, 1970)
(Wilmoth, 1970)
E-50
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The first two treatments represent early removal technology. The
last three procedures have been developed within the past 35 years
(North, 1966). Table E-20 lists and comments on various manganese
removal processes (Welch, 1963).
The use of chemical oxidants to convert the manganous
ion to the insoluble manganese dioxide followed by coagulation and
filtration is frequently recommended. Filtration problems do occur,
however, (Borgren, 1962). Some suggested oxidants include: chlorine
or chlorine dioxide (Welch, 1963); with lime coagulation (Owens, 1963)
potassium permanganate (Haney, 1964); and ozone (Netzer, in press).
Filtration techniques include rapid sand (Owens, 1963) and vacuum
diatomite (Costabile, 1971).
The manganese greensand filter involves passing the
waste through a filter of greensand (glauconite, a natural resin),
manganese sulfate and potassium sulfate. When manganous ion contacts
the system, oxidation reduction occurs. Insoluble manganese dioxide
is formed and stays in the filter. The system is periodically re-
oxidized with permanganate and the solids are backwashed (North,
1966; Wiley, 1963; Ailing, 1963).
The chemistry of the removal of manganous ion is as
follows (Applebaum, 1956):
K20-Z-MnO-Mn207 + 2Mn(HC03)2 +
K20-Z-5Mn02 + 4C02 + 2H20
where:
Z is the greensand resin
Ion exchange removes manganese cations along with other
metal ions in its non-selective process. Moreover, the manganese remains
in soluble form as the brine. Also, air can oxidize the manganous ion
to form the precipitate oxide and clog the system (Sato, 1972).
Table E-21 lists the resultant' residual manganese con-
centrations after treatment by various processes.
E-51
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TABLE E-20
MANGANESE REMOVAL PROCESSES
Process
Comments
1. Aeration
2. Chlorine and
Hypochlorite
Oxidation
3. Adjustment of pH
4. Catalysis
5. Ion exchange
6. Chlorine Dioxide
7. Manganese Dioxide or
Potassium Permanganate
8. Direct Potassium
Permanganate Addition
Slow and ineffective below pH 9.
Not effective for organically bound
manganese.
Lime-soda type treatment gives removal
at pH 9.5
Copper ion enhances air oxidation.
Effective for small quantities of
iron and manganese. Resins quickly
fouled by iron and manganese oxides.
Rapidly oxidizes manganese to the
insoluble form, but expensive.
Regeneration, greensand filter
process. Economic disadvantage of
requiring excess permanganate.
Requires filtration (sand, diatomite,
or mixed media).
Source: (Patterson, 1975)
E-52
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TABLE E-21
RESIDUAL MANGANESE CONCENTRATIONS
Process
Residual Manganese
(mg/1)
Reference
Neutralization/
Precipitation
Oxi dati on/(Coagulati on
filtration)
Greensand
Ion Exchange
0.5
0.02-0.05
0.00
0.0-0.1
Hill, 1972
Haney, 1964;
Holland, 1964;
Costabile, 1971
Ailing, 1963
Alzenter, 1963
E-53
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E.4.4.6. Zinc
The treatment of zinc-containing wastes is removal
by chemical precipitation, with disposal of resultant sludge or
recovery. Recovery is most applicable to plating wastes and may
be achieved through ion exchange, evaporative recovery or reclama-
tion of relatively pure sludges.
The most frequently employed procedure is the
addition of lime and precipitation of zinc hydroxide. If the
sulfate concentration is high, CaSO. may also precipitate. Caustic
may also be used. Cyanide destruction (to eliminate complexation)
and chromium reduction must precede the metal precipitation (Minear,
1972). Filtration helps the final effluent quality. Another
approach is the precipitation of zinc as the sulfide (Baneyee, 1952;
Rosehart, 1972). Kastone is a proprietary process developed by
DuPont (Anon, 1971; Lawes, 1973). This system is used for the
destruction of ambient cyanide by oxidation and formation of the
metal oxide.
Zinc recovery for the metal alone is usually not
economical unless it is in high concentrations or it is associated
with other materials which are costly to treat or replace. When
zinc is relatively pure and at a high concentration, precipitation
and acid regeneration are usually satisfactory (Saxena, 1968). Zinc
recovery through ion exchange has been used with varying degrees of
success (McGarvey, 1952; Sharda, 1968; Kantawala, 1964, 1968).
Evaporative recovery of zinc, coupled with appropriate
plant modifications, have proved successful at plating facilities
(Culotta, 1968, 1969; Lancy, 1967; Gallo, 1972; Zievers, 1971).
Table E-22 lists some residual zinc concentrations
resulting from various treatment processes.
E-54
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TABLE E-22
RESIDUAL ZINC CONCENTRATIONS
Process
Residual Zn, mg/1
References
Hydroxide Precipitation
Hydroxide Precipitation
with filtration
0.08-5
0-6
1.16
Sulfide Precipitation
Lime/Sulfide Precipitation 0.2
Kastone 0.29-2.9
Ion Exchange £ 20
Anon, 1971; Chalmers, 1965;
Nyquist; 1959, Anon, 1972;
Volvo, 1971; Am. Enka Co.,
1971; Rock, 1970; Sharda,
1968; Harrison, 1974
Nemerow, 1963; Chalmers,
1970, Stone, 1967
Rosehart, 1972
Larsen, 1973
Lawes, 1973
Sharda, 1968
E-55
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E.5. AMMONIA
E.5.1. Introduction
Under conditions of standard pressure and temperature,
ammonia (NH-) is a colorless gas with a characteristic odor and high
•J
solubility in water. It is just one of many forms through which nitrogen
is cycled in the environment (Figure E-2). The importance of ammonia in
the environment is due to several factors:
1. Ammonia may contribute to the eutrophication
of lakes and reservoirs due to its impact on
algae growth.
2. Ammonia may exert an oxygen demand if it is
biologically oxidized to nitrite (N0~ ) and
nitrate (N03~).
3. Ammonia has been shown to have toxic impacts
on aquatic life when present alone in sufficient
concentrations or when involved synergistically
with other pollutants e.g., phenols and heavy
metals.
Ammonia is typically found in the wastewaters associated
with coke making, iron making, coal chemicals recovery, and a variety of
inorganic and organic chemicals manufacturing operations. In addition to
industrial sources, municipal discharges and non-point source runoff both
provide ammonia loadings to the aquatic environment.
E.5.2. Analytical Procedures for the Determination of Ammonia
Free ammonia is defined to be all nitrogen existing in the
following equilibrium.
NH3 + H20 j NH4+ + OH"
The USEPA publication Methods For Chemical Analysis of
Water and Wastes presents information concerning three methods for the
determination of free NH3-N (ammonia-nitrogen), using a distillation
procedure, with recommended ranges as follows:
1. Colorimetric Method; 0.05 to 1.0 mg/1 NH3~N
2. Titrimetric Method; 1.0 to 25.0 mg/1 NH-^-N
3. Electrode Method; 0.05 to 1400.0 mg/1 NH3-N
E-56
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Chemicu
Manufacture
(FIXATION)
ATMOSPHERIC
NITROGEN
ANIMAL
PROTEIN
ORGANIC
N
PLANT
PROTEIN
ORGANIC
N
y
FIG. E-2 . THE NITROGEN CYCLE
E-57
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All samples are distilled into boric acid to minimize
interferences. The distillate is then either analyzed colorimetrically
by comparison to a series of Nessler tube standards, titrated with
.02N HoSO., or analyzed using a specific ion ammonia probe.
£ •
Total Kjeldahl Nitrogen (TKN) provides a measure of all
nitrogen containing compounds which are converted to ammonium sulfate in
an acid digestion procedure using concentrated sulfuric acid, potassium
sulfate and mercuric sulfate. TKN includes free ammonia nitrogen and
that organic nitrogen which undergoes the above conversion, e.g., organic
nitrogen compounds of biological origin. TKN may not include some of the
organic nitrogen compounds present in industrial wastewaters. Following
the acid digestion step, the sample is distilled and analyzed using one
of the three methods discussed above to yield TKN values. Organic nitrogen
is obtained by the difference between the TKN and free ammonia-nitrogen
values. Nitrate and nitrite-nitrogen (NGI-N and NOZ-N) are determined
colorimetrically (USEPA, 1974; APHA/AWWA/WPCF, 1976; ASTM, 1975).
E.5.3. Toxicity of Ammonia to Aquatic Organisms
E.5.3.1. General
The ability of ammonia to behave as a toxicant is well
known. Only unionized ammonia (NFU) is significantly toxic to both
freshwater and marine organisms. The amount of unionized ammonia present
depends upon both the pH and the temperature. Equilibrium constants for
both ammonia and water as functions of temperature are presented in Table £-23.
This information, and pH, is sufficient to calculate the amount of unionized
ammonia.
While the amount of unionized ammonia depends only on the
temperature and pH, a determination of the efficiency of unionized ammonia
as a toxicant to freshwater organisms requires consideration of several
other environmental parameters, e.g., free carbon dioxide, dissolved
oxygen, hardness, alkalinity and temperature.
E-58
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TABLE E-23
IONIZATION CONSTANTS FOR AMMONIA AND WATER
AT DIFFERENT TEMPERATURES
a,b
Temperature (°C)
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
K. (Ammonia)
1.480x10"?
1.490x10"?
1.500x10"?
1.515x10 ?
1.530x10"?
1.550x10 ?
1.570x10 ?
1.582x10 ?
1.595x10"?
1.610x10"?
1.630x10 ?
1.652x10"?
1.660x10"?
1.673x10 ?
1.690x10 ?
1.700x10 ?
1.710x10"?
1.733x10"?
1.750x10"?
1.765x10"?
1.780x10"?
1.810xlO"3
KW (Water)
1. 735x1 0~]jj
1.846x10",'?
2.038x10";?
2.243x10 ;?
2.450x10",'?
2.680x10 {?
2.920x10 ,'?
3.221x10 J?
3.451xlO"J?
3.787xlO"J?
4.152x10 I?
4.505xlO"j?
4.890x10",'?
5.260x10 \l
5.725x10 ,?
6.240x10 ,'?
6.809xlO"J?
7.350x10",'?
7.950xlO"j?
8.680x10";?
9. 370x10",' *
1. 008x1 O"'4
Taken from R. P. Trussell (1972).
[NH3]
^(water) = [H+] [OH"]
E-59
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E.5.3.2. Free Carbon Dioxide. Lloyd and Herbert (1960) suggested
that it is not the pH value of the bulk of the solution which was important
in determining the toxicity of ammonia, but the pH value of the water at
the gill surface. This depends on both the respiratory carbon dioxide
produced by the fish and the concentration of free carbon dioxide
already present in solution. If the concentration of free carbon
dioxide in the water is very low, the amount excreted by the fish will
considerably reduce the pH value at the gill surface, but the extent
of this pH change will decrease as the level of free carbon dioxide
rises in the bulk of the water. Thus, where ambient free carbon
dioxide levels are low and the pH values high, the toxic concentrations
of unionized ammonia may be about five times greater than those appli-
cable to polluted waters where the free carbon dioxide is likely to be
high and the pH value low. So far, this effect has only been demon-
strated'for rainbow trout (Salmo gairdnerii).
E.5.3.3. Dissolved Oxygen. A reduction in the level of dissolved
oxygen in the water increases the toxicity of several poisons to fish.
This has been found to be the case for ammonia by Downing and Merkens
(1955). These authors showed that a reduction in the oxygen content of
the water to 50 percent of the saturation value reduced the survival
times of several species of fish in lethal solutions to one-third of
the survival time in oxygen saturated water. Lloyd (1961) showed that
the effect of low oxygen concentrations on the LC5Q for ammonia was
greater than its effect on other poisons. In field situations a lowering
of the dissolved oxygen levels is likely to be 'accompanied by an increase
in free carbon dioxide and a reduction in pH. This pH reduction is likely
to reduce the toxicity of ammonia to a greater extent than the increased
toxicity caused by low oxygen levels. In the experiments which have been
reported here, fish have been transferred directly from clean aerated
water to ammonia solutions of lower oxygen content. Similar experiments
with fish already acclimated to the low dissolved oxygen level of the water
have not been made (EIFAC, 1973).
E-5.3.4.. Hardness. Herbert (unpublished data referred to in
Herbert, 1961) using rainbow trout, showed that variations in the hardness
E-60
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of the water had no effect on the toxicity of ammonia to these fish
(EIFAC, 1973).
E.5.3.5. Alkalinity. Alkalinity (bicarbonate form) only affects
the toxicity of ammonia by its part in determining the pH value of the
water in conjunction with the level of free carbon dioxide present.
E-5-3-6 Temperature, it can be seen (Table E-23) that the increase
in temperature will increase the proportion of unionized ammonia present
in an ammonia solution. It has been shown that although survival times
of test fish at constant levels of unionized ammonia decreased with a rise
in temperature, the threshold LC5Q remained the same (Herbert, 1962).
However, it is possible that these findings only apply to
temperatures above 10°C. Burrows (1964) showed that at lower temperatures
unionized ammonia for rainbow trout is about half that at 10°C, which
would cancel the effect of temperature on the dissociation of ammonia.
E.5.3.7.. Acclimation to Low Ammonia Concentrations. It is well
established that exposure of fish to sub-lethal levels of ammonia increases
their subsequent resistance to lethal concentrations (Lloyd and Orr, 1969).
The resistance obtained by rainbow trout is held for at least one day, but
is lost after three days. None of the data available allow an estimate to
be made of the maximum concentration to which fish can be acclimatized
(EIFAC, 1973).
E.5.3.8. Other Factors. It has been shown by Herbert and Shurben
(1963) that the resistance of rainbow trout to ammonia poisoning was
decreased as the specimen increased its swimming speed above a velocity
equal to three times its body length per second.
There is some circumstantial evidence (Lloyd and Orr, 1969)
that the physical handling of fish immediately before exposing them to
ammonia increases their resistance to this poison (EIFAC, 1973).
E.5.3.9. Determination of LCso for Unionized Ammonia. Consequently,
given a value for the concentration of unionized ammonia, ambient environ-
mental conditions will determine the effective toxicity due to the combina-
tion of the effects of several variables on the metabolism, respiration,
and general well-being of the test organisms.
E-61
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The publication, Water Quality Criteria, 1972, developed
by the National Academy of Sciences, National Academy of Engineering
(NAS/NAE) puts forth recommendations concerning those concentrations of
various toxicants which present hazards to freshwater and marine environ-
ments. For freshwater environments the recommendation for ammonia is
as follows:
"Once a 96-hour LC50 nas been determined using the
receiving water in question and the most sensitive
important species in the locality as the test organism,
a concentration of unionized ammonia (NHg) safe to
aquatic life in that water can be estimated by multi-
plying the 96-hr LC^g by an application factor of
0.05; but no concentration greater than 0.02 mg/1 is
recommended at any time or place."
Bioassays have been carried out to determine LC5Q values
for ammonia singly and in combination with other poisons.
Several fish species have been used for ammonia bioassay.
Coarse fish include perch (Perca fluviatilis). roach (Rutilus rutilus).
gudgeon (Gobio gobio (L)), Rudd (Scardinius). Bream (Lepomis) and stickle-
back (Gasterosteus aculeatus). Game fish include rainbow trout (Salmo
gai'rdnerii Richardson), Atlantic salmon (Salmo salar), Chinook salmon
(Oncorhynchus tshawrtscha), and striped bass (Morone saxatalis).
Table E-24 presents a summary of organisms studied and
LC5Q values determined in several investigations surveyed in the develop-
ment of the aforementioned water quality criteria recommendations for
ammonia (NAS/NAE, 1972).
E.5.4. Treatment Technologies for Removal of Ammonia
A variety of treatment technologies exist for the reduction
of ammonia in wastewater including biological treatment, ammonia stripping.
breakpoint chlorination, ozonation, reverse osmosis, ion exchange,
electrodialysis, and evaporation. The technical and economic feasibility
of each of these technologies is a function of several parameters,
e.g., the raw waste ammonia loading and the composition of the wastewater
with respect to other pollutants.
E-62
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TABLE E-24
ACUTELY TOXIC CONCENTRATIONS OF
UN-IONIZED AMMONIA FOR VARIOUS FISH SPECIES
Species
Acute
Morality
-C50
Time Span
LC50
Author
Stickleback
(Gasterosteus aculeatus)
Striped bass
(Morone saxatalis)
Rainbow trout
Perch (Perca sp)
Roach (Hesperdeucus)
Rudd (Scardinius)
Bream (Lepomis sp)
Rainbow trout
Rainbow trout
Atlantic salmon
(Salmo salar)
Rainbow trout
1.8-2.1
96-hr Hazel et al, 1971
96-hr Hazel et. al_, 1971
Lloyd & Orr, 1969
Ball, 1967
100-hr
47.5-hr
58.3-hr
21.6-hr
1.9-2.8
0.39
0.29
0.35
0.36
0.41
0.41
0.42-0.89 500 min Lloyd & Herbert, 1960
0.38 24-hr Herbert & Shurben, 1965
Ball, 1967
Ball, 1967
Ball, 1967
Ball, 1967
0.38
24-hr Herbert & Shurben, 1965
Source: Water Quality Criteria, 1972.
E-63
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E.5.4. Biological Treatment
Use of microorganisms to remove biodegradable organic material
and NH3-N from wastewaters is a demonstrated technology, provided the selected
treatment process chain is not prone to upsets such as those which would
occur if the influent wastewater contained material toxic to the microoganisms.
Removal of carbonaceous BOD is achieved using a variety of processes, e.g.,
oxidation ponds, activated sludge, trickling filters, etc. The biologically
mediated conversion of NH^-N to N2(g) is often possible in a treatment process
chain known as nitrification-denitrification:
(5) nitrification: NH4+ + 202 ^ N03" + 2H+ + H20
(6) denitrification: 6N03~ + 5CH3OH =^ 5C02 + 3N2
+ 7H20 + 60H
Equation 5 describes the overall conversion of NH--N to N0~~ under
aerobic conditions. Equation 6 describes the reduction of NO ~ to
O
N-, using methanol as a carbon source, under anoxic conditions.
Both BOD removal and NhU-N nitrification can be achieved in a
single-stage activated sludge system, provided there is not a problem with
inhibition. If inhibitors are present or effluent NH--N levels of less
than 5 mg/1 are desired, BOD removal and nitrification may be best achieved
using a two-stage system, with nitrification following BOD removal. The
following equation can be used to describe the kinetics of the nitrification
process:
J* - exp <-w)
0
where:
Ne = desired effluent NH3-N concentration in mg/1
NQ = influent NhU-N concentration in mg/1
k = overall nitrification rate constant in 1/mg-day
Xy = concentration of VSS (volatile suspended solids)
in aeration basin in mg/1
t = hydraulic detention time in days
E-64
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The rate constant, k , is a function of N , temperature, dissolved oxygen,
and pH, and varies widely with different wastewaters. Due to the effect
of these variables, together with reductions in k due to the presence of
inhibitors, it is recommended that kn be determined experimentally for each
wastewater.
E.5.4.2. Ammonia Stripping
Dissolved ammonia exists in equilibrium with ammonia ions
in wastewaters as follows:
NH3 + H20 ==± NH4+ + OH"
For the above equilibrium, the equilibrium constant is given by:
. [NH/][OH"]
LNH3J
and, consequently, the ratio [NI-L ]/[NH3] is dependent upon both the pH and
the temperature, T. The ammonia stripping process utilizes pH adjustment
to convert essentially all of the NH3-N to NH3> followied by counter or
crosscurrent contacting of the wastewater with large volumes of air. Figure
E-3 shows the relationship between ammonia and ammonium ions as a function
of pH and temperature. Inspection of this figure reveals that, at a tempera-
ture of 20°C and a pH of 11, essentially all of the NH3-N is present as
dissolved unionized ammonia.
A serious drawback encountered in the ammonia stripping process
is the very high solubility of ammonia in water; it is greater than 1,000
times more soluble in water, than carbon dioxide. In counter-current contacting
at 20°C, the minimum air volume requirement to remove 90 percent of the
ammonia from wastewater is approximately 220 cfg. Typically, values of
approximately 500 cfg are used. Because of the high air to water volume
ratio required, it is necessary to use stripping towers with very low pressure
drops. Mass transfer of ammonia is increased at high temperatures since the
solubility of ammonia in water decreases with increasing temperature.
E-65
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100
80
60
40
20
8
10
pH
12
0
40
60
80
00
14
FIG. E-3 . DISTRIBUTION OF AMMONIA AND AMMONIUM
ION WITH pH AND TEMPERATURE
E-66
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Complications which must be considered in evaluation of the
ammonia stripping process include:
1. Potential air pollution.
2. Scale formation and corrosion problems resulting from
high dissolved solids levels. Scale formation can be
minimized by using NaOH to control pH.
3. Reduced efficiency in cold weather operation.
E.5.4.3. Breakpoint Chlorination
Breakpoint Chlorination, as a method of oxidation of ammonia-
nitrogen (NhL-N) to nitrogen gas, has been applied successfully to water
supplies and as a polishing step to treat effluents from secondary treatment.
It has also been used to treat domestic wastewaters having NH--N concentrations
of approximately 20 mg/1. In principle, there is no limit to the amount of
NH3-N which can be oxidized in the breakpoint Chlorination process. However,
the costs will be in direct proportion to the amount of NH3-N which must be
removed.
Chlorine reacts with water to yield hypochlorous acid. The
hypochlorous acid ionizes slightly to give hydrogen ions and hypochlorite
ions:
C12 (g) + H20 ^= HOC1 + H+ + Cl"
HOC! ^=^ H+ + OC1"
Hypochlorous acid reacts with NH3-N to yield a series of chloramines:
NH4 + HOC! ^ NH2C1 + H+ + H20
NH2C1 + HOC! — NHC12 + H20
NHC12 + HOC1 ^ NC13 + H20
The species of chloramine which predominates'is dependent -upon
the pH and the initial weight ratio of chlorine to NH--N. Monochloramine
is the predominant species at a pH of 7 and is oxidized by excess chlorine
to nitrogen gas:
E-67
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2NH2C1 + HOC! ^ N2(g) + 3H+ + 3CT + H20
Stoichiometric considerations reveal that the "breakpoint",
i.e., the point at which all of the NH3-N is oxidized to N2(g)» occurs
when the initial weight ratio of C12:NH3-N is 7.6:1.0. In practice, break-
point chlorination requires C12:NH3-N weight ratios of 8:1 to 10:1.
E.5.4.4. Ozonation
Recently there has been much interest in ozonation due to
the ability of ozone to oxidize many refractory organic compounds. Further-
more, the disinfecting capabilities of ozone are attractive in light of the
the emergence of problems associated with the formation of chlorinated
organics. In addition to reduced COD and BOD from ozonation, ozone has been
shown to oxidize NH3-N to N03-N in studies with effluents from secondary
treatment (Wynn, 1973).
E.5. PHENOLS
E.5.1. General
The term phenols or phenolics denotes the derivatives of
benzene, napthalene, etc., containing one, two, or three hydroxyl (OH)
groups which are bonded directly to the carbon atoms forming the ring.
Additional ring substitutions utilizing, for example, alkyl groups,
amino groups, etc., are common. Table E-25 exhibits some common phenolic
compounds.
Phenols are commonly isolated from coal tar which is
formed in the destructive distillation of coal. Due to their wide usage
in commerce, there is a demand for their synthesis as well. Phenolic
compounds are found in photographic operations, plastics manufacturing,
dyeing operations, soaps, Pharmaceuticals, and disinfectants.
The chemistry of phenolic compounds is mainly due to the
resonant (delocalized) electronic structure of the benzene ring with the
hydroxyl substitution. Resonance structures can be utilized to describe
the weak acidic behavior of most phenolic compounds. Dissociation con-
stants for many phenols are on the order of 1 x 10 . Phenol (hydroxyl-
benzene) has a dissociation constant of 1.3 x T0~ . The acidity of a
given phenolic compound will depend upon the nature and position of any
E-68
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TABLE E-25
SOME COMMON PHENOLS AND THEIR DISSOCIATION CONSTANTS
(AS WEAK ACIDS)
formula
H,O, 2S°C
H,C
phenol
p-cresol
/Miitrophenol
picric acid
catechol
resorcinol
hydroquinone HO
f-aminophenol H2N
QHjOH
OH
OH
OH
OH
1.3 x 10-10
1.5 x 10-'°
6.5 x 10-8
6x 10-
3.3 x 10-10'
3.6 x 10 -10'
1 x 10-|0
OH 6.6 x 10-»«
salicylaldehyde ^ /OH
CHO
3.0 x 10-
/>-hydroxybenzal-
dehyde HO
1-naphthol
2-naphthol
CHO 2.2 x 10-
4.9 x 10-10
2.8 x 10 -'
At IS'C.
Source: Roberts, et al, 1971
E-69
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additional substituents to the ring structure. An additional feature
of importance in the chemistry of phenols is the phenomenon of eno-keto
tautomerism:
OH
Phenols exhibit hydrogen bonding both intermolecularly
and intramolecularly, when other substituent groups are present, e.g.,
nitro, CHO, etc:
H,C*°--H
/
,o
O-H 0-H
Compounds exhibiting intramolecular hydrogen bonding are said to be
"chelated." Intermolecular associations generally reduce reactivity
and alter physical properties, e.c., solubility and melting point.
Intramolecular hydrogen bonding reduces intermolecular attractions and
reduces boiling points, increases solubility in nonpolar solvents, etc.
Phenolic compounds also form complexes with metals, e.g.,
iron, lead, and aluminum. These complexes are highly colored and occur
naturally, e.g., in flowers.
The importance of phenols in the environment is due
mainly to their acute and sub-lethal toxic impacts on aquatic life
and their ability to taint fish flesh and impart taste and odor to
public water supplies. The presence of phenols can also impair the
quality of industrial water supplies and have an adverse impact on waters
classified for recreational use.
E-70
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E.5.2. Analytical Procedures for the Detection of Phenols
The USEPA publication entitled "Methods for Chemical
Analysis of Water and Wastewater" recommends automated and nonauto-
mated procedures for the determination of phenolic compounds. The
nonautomated procedure is applicable to drinking, surface, and saline
waters and domestic and industrial wastewaters containing phenols in
the concentration range of 5 to 1,000 yg/1.
Phenolic compounds react with 4-aminoantipyrine at a pH
of 10 in the presence of potassium ferricyanide to yield a stable red-
dish-brown dye. The intensity of color is dependent upon the initial
concentration of phenolic compounds. However, the color response is
not the same for various phenols. Since samples often contain several
phenolic compounds, the color response of phenol, CgHgOH, is used as the
standard and any color produced is reported as phenol. Consequently, if
mixtures of phenols are analyzed, the results will represent a minimum
concentration of phenols present. Distillation is usually required,
prior to the reaction with antipyrine to remove interfering materials.
E.5.3. Impacts of Phenolic Compounds on Water Quality
E.5.3.1. Toxicity of Phenols to Aquatic Organisms
The impacts of phenolic compounds on aquatic life are
twofold. Firstly, there is a toxic impact. Secondly, phenols have been
found to taint fish flesh. Due to the wide variety of materials which
are classified as phenols, the toxicity of a given effluent is best
assessed using bioassays involving the effluent itself. This is espe-
cially the case since phenols are known to experience synergism and
antagonism with other constituents, e.g., cyanide and heavy metals. The
results of several bioassay investigations utilizing both pure phenol
and effluents containing phenols are reported by McKee and Wolf. Table E-26
presents examples of these investigations.
Inspection of Table E-26 reveals the wide range in reported
toxicities which demonstrates the need for bioassays given a particular
effluent which contains phenolic compounds. Table E-27 presents concentrations
E-71
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TABLE E-26
TOXICITY OF PHENOLS TO FISH
Species
Minnows
Sunfish
Trout
Trout
Trout
Sunfish
Salmonidae embryos
Brook trout
Yearling trout
Goldfish
Bluegill sunfish
Perch
Stickleback
Fingerling catfish
Roach
Carp
Fathead minnows
Trout
Exposure Time
30 min
1 hr
12 hr
10 hr
24 hr
1 hr
24 hr TLm
24 hr
1 hr
72 hr
96 hr TLm
156 min
48 hr TL
m
96 hr TLm
110 min
24 hr TLm
48 hr TL
m
15 min
Phenol Concentration (m ./I )
0.079
0.71
4.3
5.0
5.0
5-20
5.0
6.2
6.2
10
11.5-20
12
15.5
16.7
20
24.9
40
400
Source: McKee and Wolf, 1963.
E-72
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TABLE E-27
CONCENTRATIONS OF PHENOLS SURVIVED BY FISH
Species
Goldfish
Stickleback
Brook trout
Capr
Minnows
Exposure Time
100 hr
48 hr
156 min
6 hr
24 hr .
Phenol Concentration (mg/1)
1.0
3.0
9.0
10
17.1
Source: McKee and Wolf, 1963.
E-73
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of phenols which were survived by fish for the indicated exposure
times. In many cases, phenolics impart taste to fish flesh when
present at levels below those at which they exert an adverse physio-
logical impact. The NAS/NAE publication entitled Water Quality Criteria
contains the following recommendation for the aquatic life and wildlife
classification:
In view of the wide range of concentrations
of phenolics which produce toxic effects in fish
and generally lower levels which taint fish
flesh, it is recommended that taste and odor
criteria be used to determine suitability of waste
receiving waters to support usable fish populations.
Where problems of fish kills occur or fish are
subjected to occasional short-term exposure to
phenolic compounds, a 96-hour LC50 should be
determined using the receiving water in question
and the most sensitive important fish in the
locality as the test animal. Concentrations of
phenolic compounds safe to fish in that water
can then be estimated by multiplying the 96-hour
LC50 by an application factor of 0.05; but no
concentration greater than 0.1 mg/1 is recommended
at any time or place. Tests of other species will
be necessary to protect other trophic levels.
E.5.3.2. Impacts of Phenols on Public Water Supplies
Phenolic compounds are known to affect the organoleptic
properties of water. Also, the halogenated phenols are especially
odorous and may be generated as a result of the water treatment (chlori-
nation. Consequently, the recommendation for public water supplies
is as follows (NAS/NAE, 1972):
"Because the defined treatment process may
severely increase the odor of many phenolic
compounds, it is recommended that public
water supply sources contain no more than
1 yg/1 phenolic compounds."
E-74
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E.5.4. Treatment Technologies for the Removal of Phenolic
Compounds
Phenolic compounds are found in the wastewaters from a
variety of industries (Table E-28). Existing treatment technologies can
best be classified on the basis of the concentrations of phenolic materials
initially present in the raw waste (Patterson, 1975).
Waters containing over 500 mg/1 of phenols are designated
"highly concentrated." In such cases, phenol recovery is employed. Many
recovery methods are based on extraction of the phenols into a water
immiscible organic solvent (Heller, 1957; Fisher, 1965). Although recovery
efficiencies are high, the residual phenol concentrations can be signifi-
cant (Wurm, 1968).
An "intermediate" classification denotes those wastewaters
containing phenolic compounds in the range of 5 to 500 mg/1. Given the
absence of inhibitory materials, e.g., heavy metals and other toxic compo-
nents, biological treatment processes can be employed to treat wastewaters
in the intermediate range. Activated sludge is preferred over aerated
lagoons, trickling filters, etc. Other treatment processes in this range
include activated carbon, chemical oxidation, chlorination, ozonation,
and hydrocarbon stripping.
Wastewaters having phenol concentrations less than 5 mg/1
are classified as "dilute." Treatment processes utilized for these waste-
waters include ozone, activated carbon, and other physical-chemical
technologies.
E-75
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TABLE E-28
INDUSTRIES WITH PHENOL-CONTAINING WASTEWATERS
Aircraft Maintenance
Chemical Plants
Coal Tar Distilleries
Coke Ovens
Explosive Manufacture
Fiberboard Factories
Gas Production Works
Glass Manufacture
Insecticides Manufacture
Oil Refineries
Orion Manufacture
Photographic Developers
Plastic Manufacture
Resin Manufacture
Wood Distilleries
E-76
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APPENDIX F
RESIDUALS COMPOSITION AND DISPOSAL SITES
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COMPOSITIONS OF RESIDUALS AND DISPOSAL SITE LOCATIONS
Facilities
Residual
Composition
Disposal Site Location
Wire Mill
Electric & Utilities
Division
Hot Roller Division
Coke and Coal
Chemical Division
Tin Division
Central Maintenance
Division
Wastewater Treatment Plant
Wire Drawing Grease
Wire Drawing Soap
Nail Quench Sludge
Trichloroethylene Degreaser
Sludge
Tin Mill Waste Treatment Plant
Filter Cake
Reclaim Water Skimmer Waste Ofl
Final Effluent Control Pond
Waste Oil
Roller Grinder Sludge
Q-BOP Vacuum Filter
Cake
Q-BOP Rake Classifier Sludge
Q-BOP Flux Spill
Absorbant
Residue from Tar
Production
Wastewater Treatment Plant
Oily Grit
Hot Strip Mill & Coal Roll
Reduction - Roll Shop Grinder
Sludge
Roll Reduction Shop Blast Grit
Fairfield Tractor Shop
Degreaser Sludge
Fairfield Machine Shop
Degreaser Sludge
Proprietary
Proprietary
Si0 0.22%;
1.35
CaO 0.5%; MgO .28%; C 1.7%;
N 0.12%; Cl 5.8%
Not Available
H20 50%; FeO 15%; CaC03 15%
Fe 5%; Oil I Grease 10%;
Other 5%
H20 40%; Oil 55%;
H20 40%; Oil 60%
Fe
FeO 5%
Lime 11.2%;
Fe 48.9%; HjO 31.
C 2.6%; Si 2.4%; Magnesia
13,000 ppm; Mn 9,000 ppm;
Alumina 9,000 ppm; S 1,000 ppm
Fe 21.1%; Lime 48%; H20 12.9%;
Si 10.2%; Magnesia 3.8%;
C 13,000 ppm; Mn 12,000 ppm;
P 8,000 ppm; Alumina 7,000 ppm
CaC03 81.8%; M§2C03 4%; Si^
1.3%; Calcium Fluoride 9.2%;
H20 3.6% P 100 ppm; KjO 280 ppm;
Fe 410 ppm; A1203 230 ppm
Not Available
Si02 3.32%; Fe^ 7.03%; Al^
1.85%; CaO 19.2%; MgO 22.64%;
K20 nil; S 11.68%; Chloride
0.21%; C 2.53%; NHjO 0.01%;
Hydrogen 1.19%
Not Available
Jefferson County Dump
Jefferson County Dump
In-Plant Dump at Wire
Mill
Jefferson County Dump
Exum Dump
Exum Dump
Exum Dump
Exum Dump
Exum Dump
Exum Dump
In-Plant Dump Off
Dolomite Road
Coke Plant Lagoon
Coke Plant Lagoon
Coke Plant Lagoon
H20 50%; Fe 10%; Si02 20%; Exum Dump
A10 3%; C 3%; Oily Matter 5 ppm
H20 0%; Fe 96%; Si02 1.5%;
A1703 1.8%; C 1.2%
Oil 25%; Grime 75%
Oil 25% Grime 75%
In-Plant Dump (#5)
Exum Dump
Exum Dump
F-l
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