Dioxin Analysis Of Philadelphia Northwest Incinerator Summary Report Volume 2 Appendices A Thru F


                                            903R85004
     PB86162013
Information is our business.
 DIOXIN ANALYSIS  OF PHILADELPHIA  NORTHWEST
 INCINERATOR. SUMMARY REPORT.  VOLUME 2.
 APPENDICES  A - F
 MIDWEST RESEARCH INST.
 KANSAS CITY, MO
 31 OCT 1985
HWTIC


TD
796
.M54
v. 2
      DEPARTMENT OF COMMERCE
      onal Technical Information Service

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                                                                    PBB61 6
                                                                         61621
                                                                         III!
        *                                                            " ^	
        V.I
                                         EMISSIONS TEST REPORT:
                                   CITY OF PHILADELPHIA NORTHWEST  AND
                                   EAST CENTRAL MUNICIPAL INCINERATORS
                                                   By

                                              Roy Neulicht
                                       Midwest Research Institute      <\/
                                      Kansas City, Missouri  64110
                                      VOLUME  I - TECHNICAL REPORT

                                      EPA  Contract No.  68-02-3891
                                       MRI Project No.  8281-L(1)

                                            October 31,  1985
            Regional ( entet tor t m ironmcnlal Tntprmnlior

                  I S FPA Region III

                   !<>SO Arch S(

                 Philadelphia. T.\ 1910?
                                                   For

                                           Mr.  Victor Guide
                                              Region  III
                                 U.S. Environmental Protection Agency
                                          841 Chestnut Street
                                   Philadelphia,  Pennsylvania  19146
                                          REPRODUCED BY
                                          U.S. DEPARTMENT OF COMMERCE
                                                 NATIONALTECHNICAL
                                                INFORMATION SERVICE-
                                                SPRINGFIELD. VA 22161

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                                  PREFACE
     This final report presents the results  for emission tests  conducted by
Midwest Research Institute at  the  City of Philadelphia Northwest and East
Central Municipal  incinerators.  The objective of the project was to quan-
tify the polychlorinated dibenzo-p-dioxin and polychlorinated dibenzofuran
emissions from these two facilities.   The work was conducted under EPA Con-
tract No. 68-02-3891.  Primary  responsibility for the project resided within
the Environmental Systems Department with analytical support provided by the
Chemical and Biological Sciences Department.  Mr. Roy Neulicht was project
leader.  Mr. Tom Walker was responsible for  supervising all emissions test-
ing; Drs. John Stanley and Tom  Capps acted as task leaders for  the analyti-
cal aspects of the project.  Ms.  Carol Green, Mr. Scott Meeks,  and Mr.  Jack
Balsinger monitored quality assurance for the project.
Approved for:
MIDWEST RESEARCH INSTITUTE
Chatten Cowherd, Director
Environmental Systems Department
October 31, 1985
                                     3.1

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                                 CONTENTS
Volume I

Preface	   ii
Figures	    v
Tables	   vi
Abbreviations	viii
Acknowledgment 	   ix

     1.0  Introduction 	    1
     2.0  Summary of Results	    4
     3.0  Process Descrip-tion	    8
               3.1  Description of City of Philadelphia Northwest
                      and East Central incinerators	    8
               3.2  Incinerator operation	   10
     4.0  Results and Discussion of Results	   17
               4.1  Polychlorinated dibenzo-p-dioxins (PCDDs) and
                      polychlorinated dibenzofurans (PCDFs)	   17
               4.2  Particulate matter and hydrogen chloride
                      emissions	   27
               4.3  Continuous emission monitoring 	   27
               4.4  Opacity	   30
               4.5  Quality assurance	   30
     5.0  Sampling and Analysis Procedures 	   48
               5.1  Sampling locations 	   48
               5.2  Sampling and sample handling procedures	   52
               5.3  Analytical procedures	   60

Volume II

Appendix A.   Particulate calculations	A-l
Appendix B.   Laboratory report - chlorides 	  B-l
Appendix C.   Laboratory report - polychlorinated dioxin/furans .  .   .  C-l
Appendix D.   Quality Assurance Unit report 	  D-l

Volume III

Appendix E.   Field data	E-l
Appendix F.   Modified Method 5 calibration data	F-l
I
                                    111

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                           CONTENTS (continued)

                                                                                1
                                                                      Page

Volume IV                                                                       {
                                                                                •
Appendix G.  Continuous emission monitoring data records 	  G-l

Volume V

Appendix H.  Chromatograms - Modified Method 5 samples ........  H-l

Volume VI

Appendix I.  Chromatograms - fly ash samples	J-l

Volume VII

Appendix J.  Chromatograms - bottom ash samples	J-l

Volume VIII

Appendix K.  Chromatograms - reruns	K-l

Volume IX

Appendix L.  Second laboratory report	L-l
                                     IV

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                                                FIGURES

              Number                                                                Page

                1        Simplified  schematic  of  Northwest  incinerator	     9

•              2        Method  5, MM5,  and  continuous monitoring  sampling  loca-
*                        tions, Northwest  facility	    50
                13       Continuous emission monitoring sampling location East
                          Central incinerator	   51
 M              4       Ash sampling locations NV facility	   53
 *              5       Ash sampling locations East Central facility 	   54
 • "            6       Modified Method 5 (MM5) train	   55
                7       Simplified schematic of continuous monitoring system ...   58
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                                 TABLES


                                                                     Page

 1       Test Log	     3

 2       Summary of Results  	     5

 3       Summary of Process  Operating  Data,  NW Unit  No.  1	    11

 4       Summary of Process  Operating  Data,  NW Unit  No.  2	    12

 5       Summary of Process  Operating  Data:   EC Un.it Nos.  1  and 2 .    13

 6       Summary of Indicated Versus Measured Grate  Speeds	    15

 7       Refuse Charge Rate  to Feed Hopper	    16

 8       Summary of Total Tetra-Octa Dibenzo-p-Dioxin and  Dibenzo-
           furan Emissions,  NW Unit No.  1	    18

 9       Summary of Total Tetra-Octa Dibenzo-p-Dioxin and  Dibenzo-
           furan Emissions,  NW Unit No.  2	    19

10       Summary of Emissions of 2,3,7,8-Substituted Dibenzo-p-
           Dioxin and Dibenzofuran Isomers,  NW Unit  No.  1	    20

11       Summary of Emissions of 2,3,7,8-Substituted Dibenzo-p-
           Dioxin and Dibenzoburan	    21

12       Summary of Total Tetra-Octa Dibenzo-p-Dioxin and  Dibenzo-
           furan Concentration in Fly  Ash,  NW Unit Nos.  1  and 2 . .    23

13       Summary of Total Tetra-Octa Dibenzo-p-Dioxin and  Dibenzo-
           furan Concentration in Fly  Ash,  EC Unit Nos.  1  and 2 . .    24

14       Summary of Total Tetra-Octa Dibenzo-p-Dioxin and  Dibenzo-
           furan Concentration in Bottom Ash, NW Unit Nos.  1 and 2.    25

15       Summary of Total Tetra-Octa Dibenzo-p-Dioxin and  Dibenzo-
           furan Concentration in Bottom Ash, EC Unit Nos.  1 and 2.    26

16       Summary of Par'iculate and HC1 Emissions	    28

17       Summary of Continuous Emission Monitoring Results	    29

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                            TABLES (continued)

Number                                                                Page

 18       Summary of Opacity Observations:  6-min Average Opacity. .    31

 19       Summary of Opacity Observations:  Total Minutes at
            Specified Opacity Level	    32

 20       Particulate/HCl Blank Results	    34

 21       Results of Audit Samples	    35

 22       Results of Replicate Analysis for ESP Fly Asb Samples.  . .    36

 23       Results of Surrogate Recovery for Fly Ash Samples	    38

 24       Results of Replicate Analyses for Bottom Ash Samples ...    40

 25       Results of Surrogate Recovery for Bottom Ash Samples ...    41

 26       Results of Replicate Analyses for Modified Method 5
            Samples	    42

 27  '     Results of Surrogate Recovery for Modified Method 5
            Samples	    43

 28       Results for NBS Dust and Eastern Fly Ash	    45

 29       Second Laboratory (Triangle Laboratories, Inc.) Results. .    47

 30       Sampling and Analysis at Four City of Philadelphia
            Incinerators 	    49

 31       Summary of Continuous Monitoring Parameters	    59

 32       Sample Composites - Bottom Ash	    61

 33       Modified Method 5 Sample Fractions and Spiking Scheme.  . .    63

 34       Spiking Solution 	    64

 35       Instrument and Operating Parameters for HRGC/MS-SIM
            Analyses of PCDDs/PCDFs	    67

 36       Analytical Standards and Sources 	    68

 37       2,3,7,8-Substituted Dioxin/Furan Isomers 	    71
                                     vii

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                     LIST OF ABBREVIATIONS AND SYMBOLS
ABBREVIATIONS
GEMS      -- Continuous Emission Monitoring System
dscf      -- dry standard cubic feet (68°F, 29.92 in.Hg)
EC        -- east central incinerator
ESP       -- electrostatic precipitator
°F        -- degrees Farenheit
ft        -- feet
g         — gram
gr        -- grain
hr        — hour
kg        — kilogram
Ib        — pound
M3        -- Reference Method 3 (40CFR 60 Appendix A)
MM5       — Method Method 5
mg        -- milligram
ng    •.    -- nanogram
Nm3       -- Normal cubic meter (20°C, 760 ramHg)
NW        — northwest incinerator
ppm       — parts per million (volume/volume)
QA        — Quality Assurance
sec       -- second

SYMBOLS

CO        -- carbon monoxide
C02       — carbon dioxide
HC1       -- hydrogen chloride
HxCDD    — hexachlorodibenzo-p-dioxin
HxCDF    -- hexachlorodibenzofuran
HpCDD    — heptachlorodibenzo-p-dioxin
HpCDF    — heptachlorodibenzofuran
NO        — nitrogen oxide
02X       — oxygen
OCDD      — octachlorodibenzo-p-dioxin
OCDF      -- octachlorodibenzofuran
PCDD      — polychlorinated  dibeazo-p-dioxins
PCDF      — polychlorinated  dibenzofurans
          -- pentachlorodibenzo-p-dioxin
          — pentachlorodibenzofuran
S02       — sulfur dioxide
TCDD      — tetrachlorodibenzo-p-dioxia
TCDF      — tetrachlorodibeozofuran
TKC       — total hydrocarbon
°i         — percent
                                      Vlll

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                              ACKNOWLEDGMENTS
     The assistance provided  to  MRI by City of Philadelphia personnel is

acknowledged.  Specifically,  the assistance provided by Mike  Mora,  John

Gill, and Tom Mitchell during the testing is greatly appreciated.
 |                 Assistance  with  Quality  Assurance review  by Mr. John  Austin  and

               Ms.  Diana  Pickens  of EPA's  Central  Regional  Laboratory is  also  acknowledged

 •            and  appreciated.
                                     IX

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                                SECTION 1.0
                               INTRODUCTION
     The primary objective of  this  project was to quantify  emissions  of
polychlorinated dibenzo-p-dioxins (PCDDs)  and polychlorinated dibenzofurans
(PCDFs) at four City of Philadelphia municipal incinerator units operating
under normal conditions.  The  project  involved sampling and analysis for
PCDDs and PCDFs at the City of Philadelphia's Northwest (NW)  Unit 1,  NW Unit
2, East Central (EC) Unit 1,  and EC  Unit 2.

     Work at all  four  incinerator units included sampling and analyses of
ESP fly ash and incinerator bottom ash for PCDDs  and  PCDFs;  continuous  moni-
toring of stack gas emissions for carbon monoxide (CO), carbon dioxide  (C02),
oxygen  (02), total  hydrocarbons  (THC),  nitrogen  oxides (NO  ), and sulfur
dioxide (S02);  and recording of incinerator operating parameters.  In addi-
tion, the project included emissions sampling by  Modified  Method 5  (MM5) to
determine the PCDDs, PCDFs,  total particulate matter, and  hydrogen chloride
(HC1) stack emissions from NW Unit 1 and NW Unit  2.   Two identical  Modified
Method 5 (MM5) sampling  trains  were used during the  test program;  these
trains are referred to as the "A" train and the "B"  train.   One sample  train
was analyzed for PCDDs and PCDFs; the other train was analyzed for  particu-
late matter and HC1.

     Although stack gas  emissions of PCDD, PCDF, and particulate were  not
sampled from the EC units because of limited project  resources,  the NW  and
EC units are very similar in design.  The intent  of  the study was to  gather
the monitoring data  (CO, C02, 02, and THC),  opacity  observations, and pro-
cess operating data  from all four units to verify that both the EC and NW
units were operating  similarly.   If the units operate in a  similar manner
                                     1

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and the  monitored  emissions  are similar, one  could  hypothesize that the
PCDD and PCDF emissions are similar (same order of magnitude).  This report
presents the results of the emissions tests, but does not compare data from
the different units, nor  draw any  conclusions  regarding  the measured  emis-
sions levels.

     The emission tests were conducted by MRI during the period of February 27
through March 7, 1985.  Table 1  is a  log of  the test runs conducted during
the study.
                                                                            i
     A summary  of  results  is presented in Section 2.  Section  3 presents  a
brief description of the facilities tested and a summary of the process op-
erating parameters  during the test period.   Section 4 presents the complete
results of  the  emissions  tests  and provides a discussion of the  results;
quality assurance results also are summarized in this section.   Descriptions
of the sampling and analysis protocols are provided in Section 5.

     The appendices for this project are  presented in eight separate volumes.
The contents of the appendices are listed in the Table of Contents.

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TABLE 1.  TEST LOG

Run
No.
1A
IB
1A/B
2A
2B
2A/B
3A
3B
3A/3
4A
4B
4A/B
5A
SB
5A/B
5C
6A
6B
6A/B
7
3
Date
2/27/85
2/27/85
2/27/85
2/28/85
2/28/85
2/28/85
3/01/85
3/01/85
3/01/85
3/02/85
3/Q2/85
3/02/85
3/03/85
3/03/85
3/03/85
3/03/85
3/05/85
3/05/85
3/05/85
3/07/85
3/07/85
Facility
NW2
NW2
NV2
NW2
NW2
NW2
NW2
NW2
NW2
NW1
NW1
NW1
NW1
NW1
NW1
NW2
NW1
NW1
NW1
EC1
EC2
Start
time
1545
1547
1545
1200
1212
1200
0935
0941
0935
1130
1132
1130
0940
0942
0940
1610
1340
1342
1340
1150
1646
End
time
1721
2006
2006
1712
1710
1712
1425
1427
1427
1710
1712
1712
1410
1412
1412
1902
1850
1852
1852
1516
2012
Type of test
Dioxin
Particulate/HCl
GEMS /fly ash/bottom
Dioxin
Particulate/HCl
GEMS/ fly ash/bottom
ParticulateC/HCl
Dioxin
CEMS/fly ash/bottom
Dioxin
Particulate/HCl
CEMS/fly ash/bottom
Dioxin
Particulate/HCl
CEMS/fly ash/bottom
Particulate/HCl
Dioxin
Particulate/HCl
CEMS/fly ash/bottom
CEMS/fly ash/bottom
CEMS/fly ash/bottom

ash
ash
ash
ash
ash

ash
ash
ash

a NW1
NV2
EC1
EC2
= Northwest Unit No
= Northwest Unit No
= East Central Unit
= East Central Unit
Continuous
. 1
. 2
No. 1
No. 2
emission monitoring for

02, C02,

CO, THC, S02) N0x.

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                                SECTION 2.0

                            SUMMARY OF RESULTS
     Table 2 summarizes  the  test results for  all  four incinerator units.
Total tetra-octa chlorinated dibenzodioxin (PCDDs), total tetra-octa chlori-
nated dibenzofuran  (PCDFs),  2,3,7,8-tetraCDD,  and  2,3,7,8-tetraCDF results
are reported for the  stack emissions,  electrostatic precipitator (ESP)  fly
ash, and bottom ash.  Particulate matter, HC1, opacity, and continuous emis-
sion monitoring (02, C02, CO, THC, S02, and NO ) results also are presented.

     For the two NW incinerator units,* the measured total tetra-octaCDD con-
centrations range from 1,000 to 4,700 nanograms/normal cubic meter  (ng/Nm3),
resulting  in measured emission rates of  41,000  to 170,000 ng/sec; total
tetra-octaCDF concentrations  range  from  1,000 to  5,000 ng/Nm3,  resulting
in measured emission, rates of 41,000 to 180,000 ng/sec.

     Measured particulate matter  concentrations  corrected  to  127, C02  range
from 0.21  to 3.5 g/Nra3  (0.09  to  1.5 gr/dscf).  All measurements  except
Test IB at NW Unit  2  were in the  0.21  to  0.43  g/Nm3 (0.09  to  0.19  gr/dscf)
range.   Calculated  particulate matter emission  rates  range  from 13 to
175 kg/hr  (29 to 385  Ib/hr); without Test IB, the range is 13 to 24 kg/hr
(29 to 52  Ib/hr).   Measured  HC1 emission rates  range  from  7  to  32  kg/hr.

     For the four incinerator units, the  measured average oxygen concentra-
tion ranged from 13.4 to 16.6%, and the measured average carbon dioxide con-
centration ranged from 3.3 to 5.6%.   Average carbon monoxide concentrations
ranged from 16  to 240 ppm, while the average total hydrocarbon concentration
ranged from less than 1  (< 1) ppm to 7 ppm.
                                                                               i-c

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     The total tetra-octaCDD  measured  in the ESP  fly  ash samples ranges
from 720 to  2,100  ng/g;  the measured total  tetra-octaCDF ranges  from 270
to 1,600 ng/g.  The  total  tetra-octaCDD  measured  in  the  bottom  ash samples
ranges from  7.0  to 260 ng/g;  the measured total tetra-octaCDF ranges from
< 3 to 160 ng/g.

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                                SECTION 3.0

                   INCINERATOR DESCRIPTION AND OPERATION
     The City of Philadelphia's municipal incinerators are briefly described
in Section 3.1.  The operating conditions of the incinerator during the test
period are presented in Section 3.2.

3.1  DESCRIPTION OF  CITY  OF  PHILADELPHIA NORTHWEST  AND EAST  CENTRAL  INCIN-
       ERATORS

     The City  of Philadelphia  northwest incinerator plant  operates  two
refuse furnaces  which  can each process  up  to  375  tons  of trash per day.
The operation  of the units  is designed  to  achieve  a  90% volume  reduction
in refuse.  Each furnace  consists  of  a  single  (primary)  excess air combus-
tion chamber with air cooled walls.  Exhausts from each furnace pass through
cooling sprays,  two  evaporation towers, a  two-stage  (field) ESP, and  the
stack.  Figure  1  is a  schematic  of  the northwest  incinerator furnace.

     An elevated crane  with  a clam-shell bucket lifts the refuse from the
storage bin into a  charging  hopper and  water-cooled gravity  chute.  Refuse
drops from the  chute onto  the inclined  traveling grate,  which  continuously
feeds the refuse onto  a horizontal traveling grate.  Each grate is driven
by independent  variable speed motors.   The  total effective grate area  pro-
vided by the two grates is 480 ft2 per furnace.  Combustion air (taken from
outside the building)  is  provided to each furnace by a 50 hp forced draft
fan.   The underfire/overfire air ratio is adjusted by dampers in the forced
draft ductwork.  The refractory lined furnaces  are  designed  to operated at
a maximum temperature of 2100°F.

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     Incinerator  residues  drop  off the edge of  the  horizontal grate and

fall  through  a series of  residue-quenching  sprays  and onto a  submerged

residue  conveyor.   The ESP fly ash also  is  discharged onto  the  submerged

residue  conveyor.  Residue is discharged into trucks.



     Furnace flue gases exit the furnaces through spray chambers where air-

atomized water  cools  the  gases to the designed ESP operating temperature.

The  cooling water evaporates  in the two  evaporation towers  so that flue

gases entering  the  ESP  are between 550°  and 600°F.   The  cyclonic  flow  in

the  towers is  also  designed to remove the largest particles from the flue

gases prior to their entry into the ESP.



     Flue gases leave the towers and travel through the precipitator breech-

ing  where  turning vanes  and baffle plates  ensure even gas  distribution

throughout the device.  Treated flue gases are drawn from each precipitator

by an induced  draft variable speed fan  and exit  the  plant through  a  single

stack.



     The EC incinerator units  are similar in design to the NW incinerator

units, with only minor differences.



3.2  INCINERATOR OPERATION



     The incinerator  and  electrostatic precipitator operating conditions

during the tests  are  summarized in Tables 3, 4,  and 5  for NW Unit 1, NW

Unit 2,  and EC Units 1 and 2,  respectively.



     The purpose of the test primarily was to determine PCDD, PCDF, and par-

ticulate emissions  from the incinerator during normal operation.  Two main

criteria were agreed upon by the EPA and  the City of Philadelphia as indi-

cating normal operation:
                                     10
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    TABLE 5.  SUMMARY OF PROCESS OPERATING DATA:  EC UNIT NOS. 1 AND 2
Run
Date
Time period
     7
  3/07/85
 1150-1513
     8
  3/07/85
 1646-2012
Unit

Indicated inclined grate speed, avg. ft/hr
                                (range)

Measured inclined grate speed, avg. ft/hr
                               (range)

Indicated horizontal grate speed, avg. ft/hr
                                  (range)

Measured horizontal grate speed, avg. ft/hr
                                 (range)

Furnace temperature, avg. °F
                     (range)

Furnace draft, avg. in. H20
               (range)

Field A, primary voltage, avg. volts
                          (range)

Fiel'd A, primary current, avg. amps
                          (range)

Field A, secondary current, avg. MA
                            (range)

Field B, primary voltage, avg. volts
                          (range)

Field B, primary current, avg. amps
                          (range)

Field B, secondary current, avg. MA
                            (range)
    80
   (80)

    101
 (91-103)
    147
 (145-150)

   1840
(1740-1940)

   0.15b
 (0.1-0.2)

    240
 (190-280)

    115
 (70-175)

    390
 (300-600)

    360
 (360-380)

    170
 (150-190)

    720
 (670-790)
    79
  (62-83)

    84
  (72-98)
    160
   (160)

   1890
(1760-2000)

   0.20
(0.10-0.20)

    230
 (220-230)

    145
   (145)

    590
 (550-600)

    430
 (410-450)

    195
 (180-200)

    840
 (790-880)
   No working indicator.

   Gauge at  furnace, not at control panel.
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     1.   Furnace temperature between 1400° and 1800T; and

     2.   An indicated inclined grate speed of 70 ft/hr.

The Inclined grate speed is used as the indicator of feedrate to the incin-
erator.   Another  indicator of feedrate  is  the number of  charges  (crane
loads) per  hour  to  the charge hopper.  Previous tests at  these facilities
indicate  20  charges  per  hour is normal.  Both these parameters were moai-
tored  during the  emission testing in order to verify  that the  facilities
were -operating normally.   Actual measurements of the weight of refuse being
charged to the incinerator were not taken.

     With the exception of run 4 on NW Unit 1, the furnace temperature dur-
ing the  tests  averaged between  1600° to 1800°F.  Occasional excursions
above  1800°F to as high as 2100°F were noted.   The furnace high temperature
warning is at 2100°F.
                      •
     The  indicated  inclined stoker speeds  ranged  from 60 (one test)  to
70 ft/hr at the NW Units 1 and 2.  During the tests, the indicated inclined
stoker speeds for both East Central units was 80 ft/hr.  During the testing
a discrepancy between the indicated grate speeds and the observed (measured)
grate  speeds was noted.  Therefore, the grate speeds were occasionally mea-
sured by timing the number of grate sections passing a fixed point.  Table 6
summarizes the comparison  of  the measured and indicated grate  speeds  for
each unit;  speeds for both  the inclined  and the horizontal grates  are  pre-
sented.

     Table 7 summarizes  the observed  charging rate (crane loads/hr)  of
refuse to  the  feed hopper.  Hourly  readings  of  observed  charging rates
ranged from  12 to 24  charges per hour, and averaged 18.5 charges per hour.
                                     14
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TABLE 7.  REFUSE CHARGE RATE TO FEED HOPPER
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Run Facility
1AB NW No. 2



2AB NW No. 2





SAB NW No. 2




4AB NW No. 1





5AB NW No. 1




5C NW No. 2


6 NW No. 1



7 EC No. 1


8 EC No. 2


Date
2/27/85



2/28/85





3/01/85




3/02/85





3/03/85




3/03/85


3/05/85



3/07/85


3/07/85


Begin time
1545
1645
1820
1920
1200
1300
1400
1500
1600
1700
0930
1030
1130
1230
1330
1115
1215
1315
1415
1515
1615
0940
1040
1140
1240
1340
1610
1710
1810
1348
1448
1655
1755
1206
1306
1406
1707
1807
1907
End time
1645
1730
1920
2000
1300
1400
1500
1600
1700
1715
1030
1130
1230
1330
1430
1215
1315
1415
1515
1615
1715
1040
1140
1240
1340
1410
1710
1810
1901
1448
1548
1755
1855
1306
1406
1506
1807
1907
2007
Observed charges
(charges/hr)
17
12/45 min
20
11/40 min
20
18
17
21
18
3
18
20
18
18
17
24
24
15
19
18
18
12
21
16
18
9/30 min
18
21
15/50 min
22
21
23
17
19
19
19
17
13
12

                       16
-------
                                SECTION 4.0

                     RESULTS AND DISCUSSION OF RESULTS
4.1  POLYCHLORINATED DIBENZO-p-DIOXINS (PCDDs) AND POLYCHLORINATED DIBENZOFTJRANS
       (PCDFs)

4.1.1  Stack Gas Emissions

     Tables 8 and 9 present the PCDD and PCDF results of the stack emissions
measurements from NW Units 1 and 2, respectively.  Low surrogate recoveries
were obtained during analysis of Run 6A.  Although the results are reported,
the results should be considered an estimate.  The particulate sample taken
simultaneously, Run 6B,  currently  is  being analyzed for PCDDs  and PCDFs.
The results of this analysis will be reported as an addendum to this report.
Results for the field blank sampling train also are reported in Table 9; no
blank problems were identified.

     Tables 10 and 11 present the 2,3,7,8-substituted tetra-octa isomers of
dibenzodioxin  and  dibenzofuran measured in the  stack  gas  emissions  from
NW Units 1 and 2, respectively.  These results were obtained by identifying
the chromatogram peaks  for the  specific  isomers  of  interest  by  their  rela-
tive retention times.  Results for the specific isomer were then calculated
using the  response  factor for the homol'og group, in general; the response
factors for  each  homolog group were calculated from the calibration stan-
dard.   A  more  detailed explanation  of  the  analyses  and  calculations
conducted is presented in Section 5.
                                     17
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     With the exception of the low surrogate recoveries for Run  6A, no  seri-
ous anomalies in  sampling or analysis were  noted for the measurement  of
PCDDs and PCDFs in the stack gas emissions.

4.1.2  ESP Fly Ash Samples

     Tables 12 and 13 report the PCDD and PCBF concentrations measured  in the
ESP fly ash samples from the NV and EC facilities, respectively.  Where ap-
plicable, results are reported for replicate analyses and/or multiple GC/MS
injections.  Results  for  replicate  sample analyses  (i.e., extraction and
analysis of multiple  aliquots  of the sample) are reported as Replicate 1,
Replicate 2, etc.   Multiple analyses of the same aliquot (i.e.,  same sample
extract) are reported as  Replicate  1A,  IB, etc.  Note that,  in  some cases
(e.g., Table 12, Run  1A/B,'Replicate 2B), replicate analyses are reported for
only some homologs.  This situation occurs because multiple GC/MS injections
are required to quantitate the five PCDD  and PCDF homologs; in  some cases,
all the injections required to quantitate all homologs were not  replicated.

     The only anomaly related to the  sampling  and analysis of fly ash  sam-
ples noted  during  the study,  was that samples from runs 1 aod 5 contained
considerable amounts  of charred paper flakes.  This  resulted in  composites
of a fairly nonhomogeneous nature.

4.1.3  Bottom Ash Samples

     Tables 14 and  15 report  the PCDD and PCDF concentrations measured in
the bottom  ash  samples taken from the NW and EC facilities,  respectively.
Note that the bottom ash samples were often nonhomogeneous; relatively large
pieces of inert materials (e.g.,  pebbles) and unburned refuse (e.g.,  metal)
often were contained in the ash samples.  Large objects such as pebbles and
pieces of metal were  removed from the sample aliquot prior to extraction by
sieving.  The calculated  concentration  (ng/g)  is  based on  the final weight
of the  sample fraction after sieving.  The  final  sieved fraction which  was
extracted ranged from 26 to 73% of the original aliquot weight.   More  detail
of the  procedure  used to prepare the bottom  ash  samples  for analysis is
presented in Section  5.

                                     22
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4.2  PARTICULATE MATTER AND HYDROGEN CHLORIDE EMISSIONS

     Table 16 presents the results of the particulate matter and HC1 stack
emissions measurements from NW Units 1  and 2.  Run 3A failed the final  leak
check because of  a  broken probe liner.  The results of this test run are
reported, although  the run technically is invalid.  An additional particu-
late test run (5C)  on NW Unit 2 was conducted to obtain three valid tests.

     The particulate matter results from Run IB on Unit No. 2 are signifi-
cantly higher (an order  of magnitude)  than  for the other five test runs.
The measurements and calculations  for this test were rechecked and found to
be valid.  Visual examination  of  the filter during reweighing revealed  a
wax-like substance on the filter.

     The results  of blank  analyses  for particulate matter and HC1 are re-
ported with  the Quality  Assurance  Results,  Section 4.5.1,  Table 20; no
problems with sample blanks were identified.

4.3  CONTINUOUS EMISSION MONITORING

     Table 17 presents a  summary of all continuous emission monitoring  re-
sults.  The  results are  reported as the average concentration for the test
period; the  range of concentrations measured during the  test run also  is
reported.

     An NDIR analyzer was used to monitor the S02  emissions.  When using an
NDIR, moisture can  interfere with the measurement of pollutants at low lev-
els.  Consequently,  the  S02 measurements  are suspect and  are  likely biased
high.  Moisture  interference  is not a major concern with the C02 measure-
ments because of  the high  level of  C02 in  the  stack gas  (i.e., percent  in-
stead of ppm).  To  assure no interference from water or carbon dioxide dur-
ing  the  CO  measurements, an ascarite  scrubber  was  used  prior to the CO
monitor.
                                     27
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     The data  were  recorded on a data logger; measurements recorded every
3 sec were used to calculate 1-min averages.  A continuous strip chart rec-
ord  also was  obtained.   The data  logger printouts  (l-min  averages)  and the
strip charts are included as Appendix G of this report.  Calibration results
for  the monitors also are reported in Appendix G.

4.4  OPACITY

     Tables 18 and  19 present  results of visual  readings  of the  opacity  of
emissions recorded  during  each test run.   The data are tabulated as 6-min
averages  (Table  18)  and total  minutes  observed at  each opacity level
(Table 19).  The visual  emission  readings  were taken  and recorded  by EPA
observers.

4.5  QUALITY ASSURANCE

     The Quality Assurance  (QA) program for  this  project was extensive.
The  QA program included analyzing blank samples,  spiked  samples, control
samples, and blind  audit samples.  All samples were spiked with internal
standards and surrogates.  Duplicate analyses were conducted to assess pre-
cision.  Depending upon the type of sample, accuracy was assessed by several
different means  including:   (a) analysis of audit  samples;  (b) analysis  of
spiked blanks; and (c) surrogate recovery.   In addition, several of the sam-
ples were analyzed by a second laboratory.

     This section is divided into two subsections;  Section 4.5-1 summarizes
the QA results of MRI's laboratory; and Section 4.5.2 summarizes the results
of the second laboratory, Triangle Laboratories,  Inc..   All results  obtained
by MRI in regards to Quality Assurance are  reported along with the analyti-
cal  results  for the samples in Appendix C--Laboratory Report:   Dioxins.
Appendix L provides the complete report of  results  from Triangle Laboratories,
Inc.
                                     30
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4.5.1  MRI Quality Assurance Results

4.5.1.1  Particulate/HCl—
     Table 20 reports the results of the blank analyses for the particulate
and HC1 sampling.   No problems were identified.

4.5.1.2  PCDD/PCDF Analyses —

     Audit results

     Prior to initiating  analysis  of any samples,  accuracy was checked by
analyzing^blind audit  samples provided by MRI's Quality  Assurance Unit.
Two different samples were submitted to the laboratory; one sample was ana-
lyzed on  two  separate  occasions.   Results of the blind audit analyses are
presented in Table 21.   All accuracy results were within the range of 88 to
134%; the quality  assurance objective of 60 to 115% accuracy, as assessed
by the audit samples, was exceeded for some analyses.

     ESP fly ash

     Precision of  the  analysis for  PCDDs  and PCDFs  in  fly  ash  was  assessed
by conducting duplicate  and triplicate analyses; accuracy was assessed by
calculating percent  recovery  of  the  spiked  surrogate.  Table  22  summarizes
the  results  of  replicate analyses for the  four  ESP fly ash  samples  which
were  analyzed  in duplicate.  For  each sample  analyzed in duplicate  the
range percent difference was  calculated for each homolog.   Range percent is
calculated as follows:
                                     33
-------
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-------
TABLE 21.  RESULTS OF AUDIT SAMPLES

Cone, (ng/pl)
Sample
QA-1
QA-1
QA-2
QA-2
QA-1
QA-1
QA-2
QA-2
QA-1
QA-1
QA-1
QA-1
QA-1
QA-1
Analyzed
04/09/85
04/09/85
04/25/85
04/25/85
04/09/85
04/09/85
04/25/85
04/25/85
05/02/85
05/02/85
05/02/85
05/02/85
05/02/85
05/02/85
Analyte
Tetra CDD
Tetra CDF
Tetra CDD
Tetra CDF
Penta CDD
Penta CDF
Penta CDD
Penta CDF
Hexa CDD
Hexa CDF
Hepta CDD
Hepta CDF
Octa CDD
Octa CDF
Actual
17
17
122
122
17
17
122
122
87
87
87
87
173
173
Found
17.9
17.7
141
145
22.8
17.2
159
155
83
87
91
91
176
153
Accuracy (%)
106
104
116
119
•134
101
130
127
95
100
105
105
102
88
                      35
                            44<
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TABLE 22.  RESULTS OF REPLICATE ANALYSES FOR ESP
             FLY ASH SAMPLES
                       Range percent difference
                        _for replicate analyses
Analyte
2,3,7,8-TCDD
Tetra CDD
Penta CDD
Hexa CDD
Hepta CDD
Octa CDD
2,3,7,8-TCDF
Tetra CDF
Penta CDF
Hexa CDF
Hepta CDF
Octa CDF
Mean
22
22
30
46
38
34
16
26
33
32
39
30
Range of values
(8-33)
(14-35)
(9-51)
(19-77)
(0-71)
(5-56)
(0-37)
(9-41)
(8-56)
(6-59)
(6-63)
(14-47)

 Mean of range percent calculated for replicate
   analyses of four samples [runs 1,5,7,8].
                         36
                                          45 -c
-------
                            R% = ^	=* x 100
                                    C
where:    C± - highest value determined
          C2 = lowest value determined
          C = mean value of set
and
                                     n  C.
                                  *  Z  -i
where:    C. = ith determination
          n  = number of determinations
The four precision  values  for each homolog obtained from the four samples
were averaged to  calculate the mean value  reported in Table  22.  The  range
of values  for the calculated precision (range percent difference) of the
four samples also are reported for each homolog in Table 22.  For example,
for 2,3,7,8-TCDD  the  range  percent difference for the duplicate analyses
of samples  from runs  1, 5, 7, and  8 were 40,  8, 33, and 25%,  respectively.
Therefore,   the mean precision value is  [(40%  + 8% + 33% + 25%) -r 4 =  27%];
the values  ranged  from  (8  to 40%).  The results generally were within the
QA precision objective  of  S 30% for 2,3,7,8-TCDD/TCDF,  tetra CDD/CDF, and
octa CDD/CDF, and  i 60% for the penta, hexa, and hepta CDD/CDF homologs.

     Accuracy of  the  fly ash analyses  was  assessed by calculating the per-
cent recovery for the surrogate  37C14  TCDD.   Table 23 reports  the recovery
results for the ESP fly ash.  The calculated recoveries are very good and
within the  QA objective of 60 to  115%.  The  surrogate recovery of 37C14-
1,2,3,4,6,7,8-HPCDD could not be measured because of interference due  to the
large  (relative to  the  spiked amount)  quantity of  1,2,3,4,6,7,8-HPCDD in
the samples.  This  is also true for the bottom ash and MM5 stack emission
samples.                                                                      \
                                     27
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                             TABLE 23.   RESULTS OF SURROGATE RECOVERY
                                          FOR FLY ASH SAMPLES
 •                                 Run                      % Accuracy3
                            1A/B (replicate 1)                   105
                            1A/B (replicate 2)                    73
                            1A/B (replicate 3)                   102
                             3A/B                                 NAb
                            2A/B                                 90



•                          4A/B                                 79

                            f5A/B (replicate 1)                    82
                            5A/B (replicate 2)                   101

                            6A/B                                 96
                            7  (replicate  1)                       95
                            7  (replicate  2)                       69

                            8  (replicate  1)                       89
                            8  (replicate  2)                       97
                            8  (replicate  3)                       82
                            8  (replicate  4)                       99
                              Percent  recovery  of  37C14 TCDD.

                              Not  available;  sample being  reanalyzed.
-------
     Two fly ash  method  blanks  and a field  sample bottle blank were ana-
lyzed; all results were below detection limits.
                                                                              !
     Bottom ash

     The same procedures  that were used to assess precision and accuracy for
the ESP fly ash samples were used for the bottom ash samples.   Table 24 re-
ports the precision results for  replicate analyses and Table 25 reports the
accuracy results as surrogate percent recovery.

     The precision for the bottom ash samples is not as good as the precision
measured for the fly ash samples.  The nonhomogeneity of the bottom ash sam-
ples  is expected  to  be the cause of the greater imprecision.   The percent
accuracy (surrogate  recovery) is very good and witain  the desired  range of
60 to  115%, with  the exception of sample  4A/B (replicate 1) which  was  53%.

     Two bottom ash  method blanks and  a  field  sample bottle  blank were
analyzed;  all results were below detection limits.

     Stack emissions
                                                                 *
     Precision for the analysis  of MM5 stack emissions samples was assessed
by analyzing spiked blanks.  Two filters and two XAD resin traps were  spiked
and analyzed.  Table 26 reports  the results of the analyses.  The range per-
cent differences were all less than 30%, except for one analyte which  was 34%.

          Accuracy for the  MII5 samples  was assessed by calculating percent
recoveries for  the surrogate 37C14-TCDD for each emissions sample and the
spiked blanks.  Table  27  reports  the  surrogate  recovery results.   With the
exception of run 6A, the surrogate recoveries were within the QA objectives
(60  to  115%).   Because the surrogate recovery  on run 6A is so  low (21%),
the results from this sample should be  considered as estimates.
                                      39
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     TABLE 24.  RESULTS OF REPLICATE ANALYSES
                  FOR BOTTOM ASH SAMPLES
                        Range percent difference
Analyte
2,3,7,8-TCDD
Tetra CDD
Penta CDD
Hexa CDD
Hepta CDD
Octa CDD
2,3,7,8-TCDF
Tetra CDF
Penta CDF
Hexa CDF
Hepta CDF
Octa CDF
Mean"
54
41
68
71
51
37
42
51
65
64
61
29
Range of values
(16-76)
(6-69)
(36-96)
(32-98)
(40-78)
(6-68)
(25-64)
(41-63)
(43-95)
(9-99)
(24-100)
(0-81)

a
   Mean of range percent calculated for replicate
   analyses of four samples [runs 1,  5, 7,  8].
-------
 TABLE 25.  RESULTS OF SURROGATE RECOVERY
              FOR BOTTOM ASH SAMPLES
       Run                      % Accuracy3
1A/B (replicate 1)                   85
1A/B (replicate 2)                   99

2A/B •                                89

3A/B                                 85

4A/B (replicate 1)                   53

5A/B (replicate 1)                   96
5A/B (replicate 2)                   94

6A/B                                 89

7A/B (replicate 1)                   87
7A/B (replicate 2)                   92

8A/B (replicate 1)                   78
8A/B (replicate 2)                   95
8A/B (replicate 3)                   69
   Percent recovery of 37C14 TCDD.
-------
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TABLE 26.  RESULTS OF REPLICATE ANALYSES FOR
             MODIFIED METHOD 5 SAMPLES

Range percent difference



Analyte
2>3,7,8-TCDD
Tetra CDD
Penta CDD
Hexa CDD
Hepta CDD
Octa CDD
2,3,7,8-TCDF
Tetra CDF
Penta CDF
Hexa CDF
Hepta CDF
Octa CDF
for replicate
Spiked filter
blank
(%)
21
21
13
29
34
25
7
7
ND
c
c
28
analyses
Spiked XAD
resin blank
(%)
1
1
10
5
18
3
2
2^
ND
c
c
13

 Two samples.
 Not detected.
 HxCDF and HpCDF not spiked.
-------
Run
1A
2A
3B
4A
5A
6A
XAD spike (1)
XAD spike (2)
Filter spike (1)
Filter spike (2)
Blank train
% Accuracy3
58
96
100
122
96
21
80
100
101
102
103

Percent recovery of 37C14 TCDD.
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     A MM5 "blank  train was set up  in  the field and the recovered sample
analyzed along with  the  emissions  sample.  The  results  of  this  blank  train
were reported in  Table 9.   With the exception  of  two analytes  where  very
low  levels were  found (contamination from previous  GC/MS  injection sus-
pected) all analytes were below the detection limit.

     Control samples

     In order to  obtain data comparable to data obtained by other labora-
tories, two control samples were analyzed.  The samples were National Bureau
of Standards  (NBS) urban dust and  a  fly  ash composite  ("Eastern Fly Ash").
The  eastern fly ash  (EFA)  was provided by MRI and  had been previously ana-
lyzed by MRI  and  other laboratories.  Results of the analyses are provided
in Table 28.   Previously reported results for the NBS dust are 0.12 ng/g for
2,3,7,8-TCDD  (plus four  isomers)  and 0.28 ng/g for TCDD.  The  previously
reported result for  the  EFA  is  2.0 ng/g  for 2,3,7,8-TCDD.  The  results  ob-
tained during this project compare reasonably well with the results reported
for the NBS dust and compare very well with the previously reported results
for the ETA.

4.5.2  Second Laboratory Results (Triangle Laboratories, Inc.)

     Samples  from test run 5 were split and submitted to a second laboratory
for analysis.   The eight samples which were split and sent were:

     1.   ESP fly ash, replicate 1
     2.   ESP fly ash, replicate 2
     3.   Bottom ash, replicate  1
     4.   Bottom ash, replicate  2
     5.   NBS urban dust
     6.   Eastern coast fly ash  (EFA)
     7.   MM5  extract
     8.   MRI  calibration standard
                                     44
-------
            TABLE 28.   RESULTS  FOR  NES  DUST AND EASTERN PLY ASH
                                     Concentration ng/g

2,3,7,8-TCDD
TCDD
PCDD
HxCDD
HpCDD
OCDD
2,3,7,8-TCDF
TCDF
PCDF
HxCDF
Hp CDF
OCDF
NBS
replicate 1
0.063
0.12a
2.2
3.8
19
67
0.21
1.4
3.1
d
4.7
2.6 -
NBS
replicate 2
b
b
b
5.3
16
61
b
b
b
0.94
4.9
5.3
EFA
replicate 1
2.3C
75
230
b
b
b
4.0
110
160
b
b
b
EFA
replicate 2
1.9C
71
220
112
68
96
4.2
120
170
108
76
19
*
Data reported by L.  Lamparski and T.  J.  Nestrick (Anal.  Chem.  1980,  52,
2045-54); TCDD (0.28 ng/g)  and 2,3,7,8-TCDD  plus four  isomers  (0.12  ng/g).

Not analyzed.

Data reported by Kuehl et al. (4th International Dioxin  Symposium, Ottawa,
October 1984); 2,3,7,8-TCDD (2.0 ng/g).

Not detected.
                                     45
                              54-
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     The fly ash, bottom ash, NBS urban dust, and EFA were sent to the sec-

ond laboratory  for  extraction and analysis; aliquots of the extracted MM5

sample and the  calibration sample were sent  for  analysis.   Table  29  sum-

marizes the results of the analyses by the second laboratory.  MRI' s results

for the same samples also are presented in Table 29 for comparison.  Percent

accuracy of the  second lab compared to MRI's standard was calculated; the

accuracy for the different homologs ranged from 27% (HxCDF) to 298% (HpCDD)).
                                     46
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                                SECTION 5.0
                     SAMPLING AND ANALYSIS PROCEDURES
     This section,  briefly  describes  the  sampling,  sample  recovery/prepara-
tion,  and  analytical procedures used during  the  test program.   Table 30
presents an overview of the sampling/analysis protocol.

     Section 5.1 identifies  the sampling locations.  Section 5.2 presents
the  sampling procedures and  the sample recovery/handling  procedures.   Sec-
tion 5.3 briefly describes the  analytical procedures.

5.1  SAMPLING LOCATIONS

5.1.1  Stack Emissions

     Figure 2 identifies the  MM5 sampling locations for the NW Units 1 or
2  (units are nearly identical).  The sample  was  collected  at 24 traverse
points chosen according to EPA  Reference Method 1  (40CFR60).  The CEM  sam-
pling  location  for the NW units also is  shown in Figure 2;  the CEM sample
was taken from a single point in the stack of each unit.

          The continuous  emission monitor  sampling location for the EC
Units 1 or 2 is  depicted  in Figure 3; the sample  was taken  from a single
point in the breeching of each unit.
                                     48
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                                                         METHOD 5
                                                         MODIFIED METHOD 5
                                                         SAMPLING LOCATION
                                                             CONTINUOUS
                                                             MONITOR
                                                             SAMPLING
                                                             LOCATION
              Stoinlni St*>l Srasx
                                                  Dio Nipal*. -*"
                                                 Protruding 1,2' Into S'aek
                Flaw Sf
                ana Turning
Figure 2.  Method 5,  MM5,  and continuous monitoring  sampling  locations,
               Northwest facility (Units 1 and 2 identical).


                                        50
-------
                            Stack
            Stack
                                                                    t
                                               ES?
                                   Ground Level-
                                                         CEMS —
                                                         Sample
                                                         Location
                                                                  oooo
                                                                  i      >
                                                                   Fan
            End View
Side View
Not To Scale
       Figure 3.  Coatinuous emission monitoring sampling  location
                    East Central incinerator.
                                    51
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1
5.1.2  Fly Ash

     For both  units  the ESP fly  ash  is  discharged to  the  atmosphere just
above the  wasting pit.   The fly  ash samples were  taken from the discharge
of the ESP hoppers before the ash entered the wasting pit.

     Figure 4  shows  the ESP ash  sampling locations  for  the NW facility.
Sampling locations for Units 1 and 2 are essentially the same.  The  fly ash
samples were  taken from locations C and D  (Figure 4);  grab samples were
taken alternately  from locations  C and D.

     Figure 5  shows  the ESP fly  ash  sampling  location  for  the  East  Central
incinerator Units  1  and 2.   The  units  are essentially  the  same.  At the EC
facility there is  a single ESP screw feed (for each unit) to the waste pit;
therefore, all ESP fly  ash  samples  were taken from point  C  (Figure 5).

5.1.3  Bottom Ash

     The bottom  ash  samples  were  taken from the  inclined grate at the  dis-
charge end of  the waste pit; the location is depicted as location E, Fig-
ure 4, for the NW facility  units; the  bottom  ash sampling  location  for the
EC units  is  depicted as location D, Figure 5.  Note that at this sampling
location the bottom ash  is composed of both the ESP fly ash and the  furnace
bottom ash.

5.2  SAMPLING AND SAMPLE HANDLING PROCEDURES

     Table 30 summarized the sampling  procedures  used  during the test  pro-
gram.  The following  paragraphs  briefly  describe  the  sampling and  sample
handling procedures used in  the field.

5.2.1  Fly Ash Sampling

     Individual grab samples of the fly ash were collected at  1/2-hr inter-
vals during the test period.
                                     52
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   All Impingerj ore of the Modified Grocrtburg-Smith Type

   Imoinger 1 and 2 Contain 100 ml Water
   Impinger 3 Contain! 100 ml 0.1 N KCH
   Impinger 4 Confaint 200-300 Grams Silica G«l

   All Joinrj Up to and Nof  Including t+ie Second Imoinger Hove Vlton
   "O" Ringj, All Other Joirtrj UM Apiezon "L"
Figure 6.    Modified  Method  5  (MM5)  train.
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                         Impinger 1:  100 mL water
                         Impinger 2:  100 mL water
                         Impinger 3:  100 mL 0.1 N KOH
                         Impinger 4:  200 g silica gel

One of the requirements of the method is that no grease be used for sealing
joints in  the  train.   Viton®  0-rings were used  to  seal  all joints prior  to
and including  the first impinger; Apeiezon  "L"  grease was used  for  sealing


1,


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i

the remaining impinger joints.


With the exception of Run 1, the sampling time for each test was 4-hr
(240 min);
test 1 was 192 min long. The sampling time was increased after
test 1 to increase the sample volume collected to over 3 m3 .

Sample
procedures .

Container 1

•
Container 2
Container 3
Container 4


Container 5

Container 6
Container 7
Container 8


recovery — Both sampling trains were recovered using identical
The containers recovered included:

: Probe, nozzle, and filter front half rinse (hexane/

acetone)
: Filter
: XAD resin cartridge
: Hexane/acetone rinse of filter back half, condenser, and
glassware connecting the filter and condenser ("organic
> tf *\
rinse")
: First impinger condensate and organic rinse of impinger

: Second impinger condensate and impinger rinse
: Third (KOH) impinger contents and impinger rinse
: 25-mL aliquot of first impinger condensate (for HC1
analyses)
     The contents of all four impingers were gravimetrically measured dur-
ing sample recovery to  calculate stack gas percent moisture.
                                     56
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     All samples were  recovered  in the field laboratory;  the samples were
stored in chilled containers in the field, during transport to the labora-
tory, and at the laboratory.

     Oxygen measurement

     An integrated bag sample was  collected according to the procedures of
EPA Reference Method  3.   The  bag sample, was collected from a single point
in the stack throughout the duration of the MM3 test.  The sample was ana-
lyzed for oxygen  and  carbon  dioxide by Orsat immediately after the  test.
The measured carbon dioxide concentration was used to correct the measured
particulate concentration to  a 12% C02  concentration basis.

5.2.3.2  Continuous Emission  Monitoring—
     Stack effluent gases were continuously monitored during each 4-hr test
period.  The gas sample was drawn from a single point in the stack through a
single heated Teflon  line  to a common  sampling manifold mounted in a  field
van.   The gas sample  was  split from the manifold so  that all monitors con-
tinuously obtained a sample of the gas.  Figure 7 is a simplified schematic
of the continuous emission monitoring  system.  Gases monitored and the in-
struments used are shown, in Table 31.   Prior to initiating any testing,  the
calibration of  each  monitor  was  checked and documented by  a three-point
calibration.  All calibration gases were certified calibration gases  (certi-
fied i2*  accuracy by  the  manufacturer); to verify monitor calibration, one
of the three gases used for calibration of each monitor was an EPA protocol
gas.   Before every  run,  each monitor was zeroed and spanned with zero and
high level calibration gases.   At the completion of every run, the calibra-
tion of  each instrument  was rechecked,  and documented using  the same zero/
span gases.  Sample line integrity was verified prior to each run by plugging
the  sample  line inlet and monitoring  the  gas volumetric flow rate at the
manifold to assure a no-flow condition.
                                     57
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TABLE 31.  SUMMARY OF CONTINUOUS MONITORING PARAMETERS
                                          Instrument
Parameter            Monitor                range
  C02            Horiba PIR-2000        0-15%
  CO             Horiba PIR-2000        0-1,700 ppm
  02             Beckman 741            0-25%
  S02            Beckman 865            500 ppm
  THC            Beckman 402            10 ppm propane
  NO             Bendix 8101-R          5 ppm with
    X                                     1:50 dilution
                             59
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5.2.3  Opacity--
     A certified  (Method  9)  opacity  reader  recorded  stack  opacity  readings
every 15 sec  per  EPA Method 9.  The visible  emission  observers  were EPA
inspectors from Region III.

5.3  ANALYTICAL PROCEDURES

5.3.1  PCDD/PCDF Analyses

     A brief  summary of  the procedures used  for  compositing,  extracting,
and analyzing  the  samples for  PCDDs  and PCDFs  are presented  in the  follow-
ing paragraphs.

5.3.1.1  Sample Compositing—

     Fly ash

     For each test run, 10 g of each of the 10 grab samples were composited
to form  a  single  composite  fly ash sample.  Therefore, the final composite
fly ash  sample  was 100 g, except for  run 1 which was  80 g  (run 1  was a
shorter test);  a  10  g aliquot of the  composite was  taken  for  extraction.

     Bottom ash

     The bottom ash  samples presented some problems for compositing since
the samples were very wet and contained materials of varying  size fractions
(glass, wire, bottle tops,  etc.).   In order  to achieve more uniform com-
posites,  the  bottom  ashes were air  dried and separated  into  three size
fractions.   A 0.250-in. mesh screen was used to separate the  largest pieces
of debris  (fraction  1) from  the composited materials.  A second cut of the
bottom ashes using a 0.0937-in. sieve resulted in the removal of additional
fragments of  glass,  rock, paper,  etc. (fraction 2).   The resulting sieved
materials  (fraction  3) were  mixed well and were analyzed as  the final com-
posites.   Table 32 provides  the masses of the  three  size fractions  for the
composited bottom ash samples.
                                     60
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              TABLE  32.   SAMPLE  COMPOSITES  -  BOTTOM ASH

Composite
Run No. fraction
1 Fraction 1
fraction 2
Fraction. 3
Total
2 Fraction 1
Fraction 2
Fraction 3
Total
3 Fraction 1
Fraction 2
Fraction 3
Total
4 Fraction 1
Fraction 2
Fraction 3
Total
5 Fraction 1
Fraction 2
Fraction 3
Total
6 Fraction 1
Fraction 2
Fraction 3
Total
7 Fraction 1
Fraction 2
Fraction 3
Total
8 Fraction 1
Fraction 2
Fraction 3
Total
Mass
c
196 g
373 g
569+g
c
195 g
330 g
525+g
c
111 g
198 g
309+g
111 g
147 g
238 g
496 g
341 g
249 g
410 g
1,000 g
23 g
48 g
206 g
282 g
128 g
131 g
176 g
435 g
105 g
127 g
167 g
399 g
Laboratory,
sample No.
120-BA-8281
220-BA-8281
320-BA-8281
420-BA-8281
520-BA-a281
620-BA-8281
720-BA-8281
820-BA-8281
Extract
sample No.
121-BA-8281-14
122-BA-8281-15
(duplicate)
220-BA-8281-16
320-BA-8281-17
420-BA-8281-18
521-BA-8281-19
522-BA-8281-20
(duplicate)
620-BA-8281-21
721-BA-8281-21
722-BA-8281-22
(duplicate)
821-BA-8281-23
822-BA-8281-34
823-BA-8281-35
(triplicate)

Contents of all field samples were combined, mixed, and allowed to air
dry.  Each composited sample was sieved through a 0.250-in. mesh screen.
The residual materials from this step are classified as fraction 1.
The sieved material was taken through a second sieve (0.0937 in.).  The
retained material is considered fraction 2 and the sieved material is
fraction 3.
Fraction 3 was given the laboratory sample number.
were returned to the sample bottles.
Tractions 1 and 2
This material was erroneously discarded prior to weighing.

                                   61
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     MM5 samples

     The MM5 sample fractioas for each test run were:

     a.   filter
     b.   XAD resin
     c.   first impinger contents/rinse ("condensate")
     d.   back-half organic rinse
     e.   front half probe rinse

For each  run,  the back-half organic rinse and the  front-half probe  rinse
were  combined  prior to  extraction.  All  other fractions were extracted
separately,  and  the extracts combined for analysis (see Section 5.3.1.2
for extraction procedures).

5.3.1.2  Sample Extraction—

     MM5 trains

     Each MM5 sample consisted of the components  presented in Table 33.  For
each run, one component of the MM5 train was  spiked with 20 uL of a solution
containing the internal  standards and surrogates as specified in Table 33.
The composition of the spiking solution is presented in Table 34.   The final
impinger contents  (water/hexane) were allowed to come to room temperature,
spiked as necessary,  and transferred to 1-L  separatory funnels.   The con-
tents were shaken vigorously, allowed to separate,  and the hexane fractions
were removed.  The  aqueous  condensates were each extracted with three ali-
quots of 60 mL of methylene chloride (Burdick and  Jackson,  distilled in
glass).  The methylene chloride extracts were combined with the  hexane frac-
tion and the combined extracts were back extracted with Milli-Q  water.  The
organic layers were  separated,  dried over sodium sulfate,  and stored in a
walk-in cooler until combined with the remaining train component extracts.

     The organic rinses and MM5 probe rinses  were spiked (20 pL  of internal
standards and surrogates solution),  where necessary, and were concentrated

                                     62
                                                                    71
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   TABLE  33.  MODIFIED  METHOD  5  SAMPLE FRACTIONS AND  SPIKING  SCHEME
    Sample fraction
                                           Fraction suiked
                                                 Run
Blank
Filter

XAD resin

First impiuger condensate
  and rinse

Organic/probe rinse
                                   53
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                                       TABLE 34.   SPIKING SOLUTION
                                                           Mass of compound
_                                 Compound                     in 20 pL
 •'
                              13C12-2,3,7,8-TCDD                 2.5 ng
 P                           37Cl4-2,3,7,8-TCDD                12 ng
 w*"
 _                           13C12-2,3,7,8-TCDF                 2.5 ng
 •'                           37Cl4-l,2,3,4,6>7,8-HpCDD         10 ng
 '•                           13C12-OCDD.                        10 ng

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using flowing  prepurified  nitrogen to approximately 5 ml.   The  extracts
and associated particulate were quantitatively transferred to 6-dram vials
with additional hexane rinses and were concentrated to  1  ml.

     The MH5 filters and particulate were placed  in Soxhlet apparatus.   The
filter samples for runs 1 and 6 were spiked with  20 pi  of the surrogate and
internal standards.  The combined organic rinses and MM5 probe rinses were
added to the  respective  filter extractions.   The extractors were charged
with 350 ml of benzene  and the systems were allowed to  cycle for 16 hr.
The extracts from  this procedure were combined with the first impinger ex-
tracts and were  concentrated to 2 mL using Kuderna-Danish evaporators  and
flowing prepurified nitrogen.

     The contents  of  the MM5 XAD-2 resin cartridges were  transferred  to
large Soxhlet  extractors.  Samples  from runs 2 and 5 were each spiked with
20 pL of the internal standard and surrogate spiking solution.  The Soxhlet
apparatus were charged with  500 ml of benzene (Burdick and Jackson, dis-
tilled in glass)  and  were  allowed to extract for at least 16 hr.  The re-
sulting extracts were  combined with the extracts from  the other MM5 train
components and reduced  in  volume to 1 ml using Kuderna-Danish evaporators
and flowing prepurified nitrogen.

     One complete  MM5  field  blank was prepared along with the actual sam-
ples.  In addition, a  laboratory method blank was prepared to parallel all
actual sample preparations.

     Fly ash/bottom ash samples

     Ten-gram  aliquots of  the composite fly ash samples  were each mixed
with anhydrous sodium sulfate, spiked with 200 pL of the internal standard/
surrogate spiking  solution,  and transferred to Soxhlet extractors.  Each
extractor was charged with 350 mL of benzene and the samples were extracted
overnight (16 hr).  The extracts were removed and concentrated as described
above.
                                     65
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     Replicate sample analyses were completed for runs 1, 5, 7, and 8.  Two
fly  ash  method  blanks and one field  blank were extracted along with the
actual  samples.   However, only  20  uL  of  the internal standard/surrogate
spiking  solution was added to the blanks.

     Bottom ash samples were prepared following the same procedures as dis-
cussed for  the  fly ash except 20-g aliquots of the bottom  ash composites
were spiked with 20 |JL of the internal standard/surrogate spiking solution.

5.3.1.3  Extract Cleanup--

     All sample extracts were cleaned using z two-part column chromatography
procedure.  The first column (1 x 30 cm) was packed with 1.0 g of silica gel
and 4.0  g of 40% (w/w) sulfuric acid modified silica gel.  The second column
(1 x 30  m)  was packed with 6.0 g of acidic alumina topped with 1  cm of an-
hydrous  sodium sulfate.   The sample extracts were added at approximately 1-tnL
final volume in benzene to the silica/sulfuric acid modified silica column,
followed by 90 ml  of  hexane.  This  eluent  was collected  and  eluted through
the acidic alumina column, followed by 45 ml of additional hexane and 20 mL
of 20% methylene  chloride in hexane.   The 20% methylene chloride fraction
was collected for PCDD/PCDF analysis.   The extracts were concentrated using
flowing prepurified nitrogen and transferred to 1-mL reactivials.  The final
extracts were concentrated just  to dryness and refrigerated until HRGC/MS
analysis.

5.3.1.4  High Resolution  Gas Chromatography/Mass  Spectrometry (HRGC/MS)
           Analysis--
     The sample extracts were analyzed by high resolution gas chromatography/
mass spectrometry with selected ion monitoring (HRGC/MS-SIM) using the para-
meters specified in Table 35.  The level of the PCDDs  and PCDPs were  calcu-
lated by comparison of the response of the samples to  calibration standards
which contained the compounds listed in Table 36.
                                     66
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   TABLE 35.   INSTRUMENT AND OPERATING PARAMETERS FOR HRGC/MS-SIM ANALYSES
                OF PCDDs/PCDFs
Instrument:

Column:


Column temperature:


Carrier gas:

Injector:

Mass resolution:

Ions measured:

  Homolog
       Finnigan MAT 311A

       60-m fused silica, wall-coated with SP-2330
         (TCDD/F-P5CDD/F) or with DB-5 (HxCDD/F-OCDD/F)

       1108C hold 2 rain, 10°C/min to 340°C, hold 10 min
         (HxCDD/F-OCDD/F)

       Helium

       Grob type split/splitless (1-pL injection)

       •v 1,000 (M/AM, 10% valley)
Dioxins (m/e)   Furans (m/e)
    PFK      Diphenyl ether
(reference)    Interference
Tetrachloro-
Pentachloro-
Hexachloro-
Heptachloro-
Octachloro-
319.9/321.9
355.9/357.9
389.8/391.8
423.8/425.8
457/459.7
303.9/305.9 330.9
337.9/339.9
373.8/375.8 380.9
407.8/409.8
441.7/443.7
373.8
407.8
443.7
477.7
511.7
Internal standards
Tetrachloro-
(37C14)
Tetrachloro-
(13c12)
327.9
331-9/333-9
330.9
315.9/317.9

 Heptachloro-
    (37C14)
 Octachloro
    (13C12)
329/331

469.7/471.71
  380.9
                                     67
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TABLE 36. ANALYTICAL STANDARDS AND SOURCES

•

Analyte


Tetra-CDD


37C14-
Tetra-CDD
Tetra-CDF

Penta-CDD

Penta-CDF

Hexa-CDD
Hexa-CDF

Hepta-CDD

37C14-
Hepta-CDD

Hepta-CDF

Octa-CDD
Octa-CDF


3 The 13C


Compounds in
calibration standard


2,3,7,8-TCDD


37Cl4-2,3,7,8-TCDD

2,3,7,8-TCDF

1,2,3,7,8-P5CDD

1,2,3,8,9-P5CDF

1,2,3,4,7,8-HxCDD
1,2,3,4,7,8-HxCDF

1,2,3,4,6,7,8-HpCDD

37C14-1,2,3,4,6,7,8-
HpCDD
'
1,2,3,4,6,7,8-HpCDF

OCDD
OCDF


12-2,3>7,8-TCDD, 13C12



Source


EPA QA Materials
Branch

KOR Isotopes

Cambridge Isotope
Laboratories
Cambridge Isotope
Laboratories
Cambridge Isotope
Laboratories
Cambridge Isotope
Laboratories
Cambridge Isotope
Laboratories
Cambridge Isotope
Laboratories
KOR Isotopes


Cambridge Isotope
Laboratories
Ultra Scientific
Ultra Scientific


-2,3,7,8-TCDF, and the


Internal
quantitation standard


2,3,7,8-TCDD-13C12a


2,3,7,8-TCDD-13C12

2,3,7,8-TCDF-13Cl2

2,3,7,8-TCDD-13Cl2

2,3,7,8-TCDF-l3Cl2

OCDD-13C12
OCDD-13C12

OCDD-13C12

OCDD-13C12


OCDD-13C12

OCDD-13C12
OCDD-13C12


13C12-OCDD were
from Cambridge Isotope Laboratories.








68



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     Concentrations of each dioxin or furaa homolog were calculated by first
calculating a relative response factor, then calculating a final concentra-
tion in  nanograms  per sample using the  following  equations,  which are  an
example for TCDD.
                                              A
             Relative Response Factor (RET) =  ('Std) x
                                              A(IS)    L(std)
where:    A,   ,-. = area of ions m/z 320 and 322 for the unlabeled
                     2,3,7,8-TCDD in the standard
          A(IS)  = area of ions m/Z 332 and -334 for
                     in the standard
          CCIS)  = concentrati011 of 13Cj.2-2,3,7,8-TCDD in the standard
          C,   .» = concentration of unlabeled 2,3,7,8-TCDD in the standard
                     (ag)
                      c         - ^sample) __ C(IS)
                      L(sample) ~ A,           RRJ
where:    C,    . « = total concentration of all TCDD isomers in  the
           (sample)
                        sample (ng)
          Af    . , = total area of ions m/z 320 and 322 for all  TCDD
           (sample)
                        isomers in the sanple
          Ax,.--.     = area of ions m/z 332 and 334 for the  13C12-2,3,7,3-
                        TCDD in the sample
                    = concentration of 12Ci2-2,3,7,8-TCDD in the  sample  (ng)

     The concentration of total TCDF was calculated with the above  equations
using the  response  of ions m/z  304 and  306  to  measure  the  concentration of
unlabeled TCDF and  the response of ions m/z 316  and 313 for the  13C12'2,3,7,8-
TCDF.  Similar procedures were used for each of  the PCDD/PCDF homologs.  Ta-
ble 36 indicates the  internal standard used to calculate the RRJ  values  for
each of the PCDD/PCDF horaologs.
                                     69
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     The calibration standard included 2,3,7,8-TCDD and 2,3,7,8-TCDF; there-
fore, concentrations of these isomers in the stack gas emissions were deter-
mined by quantifying directly against the internal standard.

     Stack  gas  concentrations  of specific 2,3,7,8-substituted isomers for
the penta-hepta dioxin and furau homologs also were of interest.  There are
thirteen 2,3,7,8-substituted dioxin/furan isomers; these are  listed  in Ta-
ble 37.  Nine of the 13 isomers were identified by matching their retention
times to the retention time of the isomer included in the calibration stan-
dard.   Information on relative  retention times  was  provided by the  two
sources:

     1.   Rappe, C. ,  "Analysis  of  Polychlorinated  Dioxins and Furans,"
          Environ.  Sci. Tech.,  _18, 78A-90A (1984).

     2.   Hale, D. H. , F.  D.  Hileman, T. Mazer, T.  L. Shell, R. W.  Noble,
          and J. J. Brooks, "Mathematical Modeling of Temperature Programmed
          Capillary Gas Chromatographic Retention Indexes of Polychlorinated
          Dibenzofurans," Anal. Chem., 57 640-648 (1985).

     Once the  isomer peaks were  identified,  concentrations  were calculated
using peak areas and the relative response factor previously calculated for
each homolog.

5.3.2  Particulate Matter Concentrations

     The probe  rinse and particulate  filter  from  the  separate sample  train
designated as  the  particulate sample  (train  B, except run 3) were analyzed
gravimetrically according to EPA Reference Method 5 procedures.  The  probe
rinse was transformed  to  a  tared 250 ml beaker,  evaporated to dryness at
room temperature,  desiccated for 24 hr and  weighed to a constant weight.
The  filter  was desiccated for  24 hr and weighed to  a  constant weight.
                                     70
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 TABLE 37.   2,3,7,8-SUBSTITUTED DIOXIN/FURAN ISOMERS
      Isomer                   Results reported
1,2,3,7,8 P5CDD            Yes
1,2,3,7,8 P5CDF            Yes (with 1,2,3,4,8 PCDF)
2,3,4,7,8 PSCDF            Yes
1,2,3,4,7,8 HxCDD          Yes
1,2,3,6,7,8 HxCDD          No
1,2,3,7,8,9 HxCDD          No
1,2,3,4,7,8 HxCDF          Yes
1,2,3,6,7,8 HxCDF          Yes
2,3,4,6,7,8 HxCDF          No
1,2,3,7,8,9 HxCDF          No
1,2,3,4,6,7,8 HpCDD        Yes
1,2,3,4,6,7,8 HPCDF        Yes
1,2,3,4,7,8,9 HpCDF        Yes
   Stack gas concentration results are reported in
   Tables 10 and 11.
                             71
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5.3.3  HC1 Analysis



     The first, second, and third impinger contents/rinse of the designated

particulate sampling train were analyzed for Cl .   A Technicon autoanalyzer

was used  to  conduct  the analyses by the colorimetric, ferricyanide method

(Method 325.2, "Methods  for  Chemical Analysis of Water and Wastes," EPA-

600/4-79-020, March 1979).  '
                                     72
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SUBJECT:


FROM:


TO:

THRU:
          Ambient
          for the
         UNITED STATES ENVIRONMENTAL PROTECTION AGENCY
                         REGION III
                     841 Chestnut Building
                 Philadelphia. Pennsylvania 19107

        Air Dioxin Concentration  Predictions
        Philadelphia  Northwest  Incinerator
Alan J. Cimorel1i
Source Emissions &
Ap.
 E/alu
                                               DATE:  JAN  10
luation Section (3AM12)
W. Ray Cunningham, Director
Air Management Division  (3AMOO)

James E. Sydnor, Chief  /^r,
Air Programs Branch (3AMIO)'

Lewis K. Felleisen, Chief ^ jf^#^~
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                             -2-
      In order  to address  the questions raised, an  analysis
of ambient concentrations  impacts  and  risk,  were  performed
for both  the NWI & ECI.   It  is  important  to  note,  at  the
outset, that results  derived from  the  ECI analysis are  open
to question since stack tests for  dioxin  were conducted
only  at the NWI.

      Given the proximity of the two incinerators,  and a
desire to define their separate impacts three distinct
analyses were  performed.  They are:

          (1)  Impact  due  to the NWI alone,

          (2)  Impact  due to the ECI alone,

          (3)  Impact  due to the combined  operation of
               the two  incinerators.

SOURCE DATA

     At each of the two facilities there  exist two inciner-
ator  units each serviced by separate but  identical stacks.
Since the distance separating the two stacks is small and
the exit gas parameters are the same for  each unit it was
possible to model each facility's total emissions  as  if
they emanated  from a  single stack.

     The total dioxin emissions used in modeling the NWI
were  provided  by David Cleverly.  The procedures that were
used  are fully documented in the previously cited memo.
These emissions were  derived from the results of a stack
test conducted by Midwest Research Institute (MRI) in March,
1985 and from  subsequent calculations using the toxic
equivalency method.

     With regard to the ECI, an assumption was made that
the ratio of the emissions from the ECI to the emissions
from the NWI would be equal to the ratio of charging rates
of the two incinerators.  The charging rates of the
two facilities were found to be 300 tons/day and 340 tons/day
for the ECI and the NWI respectively.  Therefore,  it was
assumed that dioxin emissions from the ECI would be approxim-
ately 88% of the emissions from the NWI.
-------

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                            -3-
     Table 1, presents For each facility, a complete list-
ing of the source parameters and total emissions data used
in this study •

     An analysis was performed to determine if the dry
deposition of dioxin would be significant and thus would
need to be accounted for in the modeling analysis.  It was
assumed that  the entire mass of dioxin emitted was adsorbed
onto the surface of the particulate matter emission.  Then,
usinq a typical particle size distribution for ESP-controlled
municipal' incinerators a transformation was performed which
took the distribution from a weight percent by volume to a
weight percent by surface area.  This transformation provided
a means of estimating how the total mass of dioxin emissions
would distribute itself among particle sizes.   Then, knowing
the percentage of the mass within a particular size range
that, upon encountering the ground surface, would reflect,
(i.e., eddy reflection coefficient) the maximum percentage of
emitted dioxin mass that could dry deposit was estimated.
This was determined to be 0.78%.  Therefore, for purposes of
the air modeling analysis,  it was assumed that the dioxin
emissions acted as a qas and thus would not dry-deposit as a
result of gravitational settling.  This above-described
analysis is presented, in detail, in Appendix  A.

MODEL SELECriON;

     In order to determine the most appropriate modeling
technique, for any given situation an analysis must be made
of: the relationship between terrain heights and stack/plume
heights.  Such an analysis was performed for the area around
each incinerator.  Maior results are presented below:

     Northwest Inc inerator:

         (1)  Terrain in most directions achieves  stack height
             at about 500 m from the plant.

         (2)  There does not exist any terrain  within at least
             25 km which could be impacted by  a stable plume.

        (3)   Considering the quite typical condition of "D"
             stability 5.0  m/s  wind speed, in  general,  the
             terrain rises approximately 50% of the plume's
             height above stack top.
                              85-
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                             -4-
     East Central  Incinerator;

    (1) Terrain  in  the entire N.W. quadrant  achieves  stack
        heiqht within  5.0  km of  the  nlant.

    (2) There exists a piece of  terrain  13 km  to  the  N.W.
        which could he impacted  under  a  condition of  " F"
        stability  2.5 m/s  wind speed.

    (3) Considering the meteoroloqical condition  of  "n"
        stability  5.0 m/s  wind speed,  terrain  in  the  N.W.
        quadrant beyond about 7  km,  in qeneral, rises
        apnrox imately  509;  of the  plume's heiqht above  stack  top.

     Pased on the  above results,  and considerinq  present  aaency
Guidance, it was determined that  two models  were  needed  in
order to appropriately consider  the  substantial amount of
terrain which exists between stack heiqht and  plume heiqht.
Poth a simple and  complex  terrain model  were run  on this
"in-between" type  of terrain.  The hiqher of the  two  predic-
tions were then  used to represent  the  predicted concentration
at each terrain  location.  This  procedure produced hybrid
concentration fields which were  then provided  as  input to  the
HEM model .

     In addition to the oeneral  type of  models needed  it  is
necessary to determine the appropriate modes (urban/rural)
for runninq the models.  Tn order  to do  this the  Auer  '7R
classification scheme was  applied, as required by aqency
ouidance, to the area surroundinq each of the  two inciner-
ators.  For the  East Central Incinerator the area was deter-
mined to be urban.  For the Northwest  Incinerator the area
was determined to  be rura] .  Therefore,  all model  runs for
the Fast Central and Northwest incinerators were  made usinq
the urban and rural modes of the models  resoectively.

     Considerinq the above discussion  it was determined that
the ISCLT s, T.OMnz models would be most applicable in this
study.  A brief rationale  for their  selection  is  as follows:

     ISCLT:
       Can be run in either an urban or rural mode.

       Can account for effects on qround level concentrations
       produced by buildinq down wash.

       Is capable of considerinq all terrain hpiqhts up
       to stack top.
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                              -5-
     LONGZ;-

     . Can be run  in either an urban or rural mode.

     . LONGZ is capable of considering all terrain above
       stack top.

     . Is the only readily available, agency sponsored, complex
       terrain model which can produce an output that can
       serve as input to HEM.

     A brief description of each of these models can be
found in Appendix B.

METEOROLOGY:
     Based on data availability and the height of the plume
above terrain it was felt that meteorological data taken from
the Philadelphia airport's National Weather Service (NWS)
station would be representative of the two sites.  Since
long-term average predictions of concentration are needed for
risk assessment purposes, a 17 year joint frequency distribution
of the necessary meteorological parameters was used.  This data
set was chosen since it is the largest set readily available
from the Philadelphia airport.  Appendix C provides a complete
listing of the meteorological data set.

RECEPTOR GRIDS:

     Two polar receptor grids were used in the modeling
exercise.  One centered on the East Central Incinerator and
the other centered on the Northwest Incinerator.  Each grid
was designed to contain 16 radials in order to be consistent
with the input requirements of the HEM model.  The number and
location of the rings for each grid were designed specific to
the needs of the analysis of each incinerator.  Specific ring
placements for each grid are as follows:

     East Central Polar Grid (ECG ) :
     This grid contains  13 rings located as follow:

     .  0.3 km - downwash considerations.

     .  0.78 km, 1.0 km, 1.3 km, 1.8 km, 2.3 km, 3.0 km, 4.1 km,
       5.3 km & 7.0 km - based on agency modeling guidance.

     .  10.0 km - Chosen to include higher terrain receptors.

     .  20.0 km & 50.0 km - chosen to extend the analysis to
       the limit of modeling capability and thus include the
       largest possible affected population.
                                  8

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                             -6-
     Northwesit Polar Grid

     This arid contains 15  rinqs located  as  fol]ows:

     .  0.? km - downwash considerations.

     .  0.5 km, 0.65 km, O.R5 km, 1.7 km,  1.5 km,  2.0  km,
       ?. f km, 3.4 km 5 4.5 km - based on  aqency  mod el inn
       guidance .


     .  9.0 km, 10.0 km f, 12.0 km - chosen  to include  hioh
       population areas.


     .  nn.o km & 5n.n km -  choosen to extend the  analysis
       to the limit of modelino caDability and thus include
       the laroest possible affected population.


MOPFLTNG APPROACH :

     As was stated previously three distinct analyses
were performed.  They are:

     (I) Impact due to NWI  alone

    (II) Impact due to RCI  alone


   (III) Impact due to the combined operation of  the  two
         incinerators.

     Presented below is the approach which was followed for
each of the three analyses.

     (I) Northwest Alone:
         . This analvsis considered only the impacts of
           the Northwest Incinerator on the M.W. qrid.

         . The LONH? & ISCTT models were run separately
           on the M.H. qr id .
               the ISOLT run, all terrain elevations
           qreater than stack heiaht were modeled at stack
           height: whereas, for the LONGZ model actual
           terrain heiqhts were used in the analysis.


         .  Roth models were run in their rural modes.

         .  Results of the two runs were compared at each
           receptor and the higher of the two concentrations
           was assirjned to the q iven receptor.
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                            -7-
    (II) East Central Alone;

         . This analysis considered only the impacts of the
           East Central Incinerator on the East Central grid.

         . The LONGZ & ISCLT models were run separately
           on the E.C. grid.

         . For the ISCLT run, all terrain elevations greater
           than stack height were modeled at stack height;
           whereas, for the LONGZ model actual terrain
           heights were used in the analysis.

         . Both models were run in their urban modes.

         . Results of the two runs were compared at each
           receptor and the higher of the two concentrations
           was assigned to the given receptor.

   (Ill) Combined Impacts;

         In order to determine the combined impacts of the
two incinerators it was necessary to sum the impacts of the two
sources on each of the two grids.  The procedure used is as
follows:

         (A)   Combined Impacts - E.C. Grid:

              . The Northwest Incinerator was modeled on the
                E.C. grid with LONGZ & ISCLT separately.

              . Terrain was cut-off at stack top to accomplish
                the ISCLT run.

              . Both models were run in their rural modes.

              . The highest of the two modeled concentrations
                at each receptor point was  assigned to the given
                receptor.

              . The results of this analysis were  added, receptor
                by receptor, to the results of the analysis
                for the East Central Incinerator alone.   This
                produced the combined impacts from both
                incinerators on the E.C.  grid.
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                             -8-
          (B)  Combined  Impacts  -  N.W.  Grid;

              .  The  East  Central  Incinerator  was modeled
                 on the  N.W.  grid  with  LONGZ and  ISCLT
                 separately.

              .  Terrain was  cut-off  at stack  top to
                 accomplish the  ISCLT run.

              .  Both models  were  run in their urban modes.

              .  The  highest  of  the two modeled concentrations
                 at each receptor  point was assigned to  the
                 given receptor.

              .  The  results  of  this  analysis  were added,
                 receptor  by  receptor,  to the  results  of
                 the  analysis for  the Northwest Incinerator
                 alone.  This  produced  the combined  impacts
                 from both incinerators on the N.W.  Grid.

     In order to determine both individual risk and  annual
incidence  the HEM model was  run to evaluate each of  the  three
cases described  above.  Documentation  of the  procedures
followed,  the results determined, and  the conclusions formed
can be found in  the  previously mentioned memorandum  by  David
Cleverly.

Results:
     A complete listing of  the results found in each of  the
three analyses are presented in Appendix D.

     In summary, the highest concentrations found are as
follows:

     (I) NWI alone - 1.39 (picogms/m3}

    (II) ECI alone - 0.7 (picogms/m3)

   (III) Combined Impacts - 1.4 (picogms/m3)
cc:  I).  Barnes  (OPTS/ DC TS-788)
     J.  'Sydnor (3AM10)
     L.  Felleisen (3AM12)
     D.  Cleverly (OAQPS, RTF MD-12)
     J.  Pearson (OAQPS, RTF MD-14)
     I.  Milner (3AM12)
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                           Appendix A

    This appendix presents the analysis performed  to  determine
whether the dry-deposition of dioxin emission could be
s i nn i f i r3 r».f flnri fhprpfnrp wnu 1 r5 nopH t- n hp srrnnnhpH  fnr  in  <-hf
air modeling.
 I
 I                                       Appendix  A

               •whether the dry-deposition or dioxin emission could be
               significan-t and therefore would need to be accounted for in the

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    The first portion of the analysis is a derivation of  the
transformation need to convert a volume weight-based particle
size distribution to a surface area weight-based particle size
distribution.  With this transformation a typical volume-based
distribution, for ESP controlled municipal incinerators was
converted, to a surface-based distribution.  The surface-based
distribution provides an approximation of how the weight of
dioxin is distributed among existing particle sizes.  Basic to
this approximation is the assumption that the vast majority of
the emitted dioxin mass is adsorbed on the sur.face of the
fly-ash particles.

    As particles of a particular size approach the ground
surface, a portion of these particles could dry-deposit with
the complement portion eddy reflecting.  The fraction of
particles which will reflect is a function of particle size and
can be defined by the parameter (y ); the eddy reflection
coefficient.  A functional relationship between £f  and particle
size can be found in the ISCLT Users Manual.

    Once the distribution has been transformed to a surface
area base, the percentage of the weight which resides in each
size range can be multiplied by (1-2T) to determine the maximum
amount of dioxin that could dry-deposit from the particular
size category.  Summing the maximum deposition over each size
category produces an estimate of the maximum percentage of
emitted dioxin one would expect to dry-deposit.

    The detailed results of this analysis are presented in
Table Al.  Examination of the Table indicates that the maximum
weight percent expected to dry-deposit is 0.78%.  Therefore it
was assumed that the emitted dioxin would act as a gas
exhibiting essentially no settling.
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The following is a derivation of the previously discussed
transformation .
The percentage of the weight of the total distribution of
particulates which resides in the i th category ( V"^ ) is
given by:
where :
Vii, "=" precentage of weight by volume
Vi, «CTotal weight within the £*K category
VT 
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                      If  we  assume that the mass of interest resides on  the

                  surface of the particles then the percentage of the weight  of

                  the  total  distribution which resides in the  t.'^category is

                  given by:
                           where:



                                        I,  S Percentage of weight by surface area
                           since:


                                                 M
                           then:
                     substituting  (1)  into  (2):
                                           n  I
•                   This expression  allows  one  to  transform a distribution of
                 weight percent  by  volume  to a distribution of weight percent b;
                 surface area.




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                            TABLE Al - MAXIMUM  EXPECTED DEPOSITION
   SI7E RANGE
      (u)
               MASS  MEAN
                RADIUS
                  (u)
HEIGHT PERCEOT
  BY VOLUME
  V%  x 100
WEIGHT PERCEOT
  BY SURFACE
   S%i X 100
I   0.7  >
   1.0
   1.6
   3.1
   4.8
    .0
7.0 -
  10
  16,
 *( Co limn 6)  = (Column 5) x (Column 4)
FRACTION    EXPECTEC
DEPOSITED   WEIGHT
(1 -^ )      PERCRNTT
            DEPOSIT!:
| 0.7
0.7 | 0.9
1.0
1.3
1.6 | 2.5
3.1
4.8
7.0
4.0
6.0
8.8
10.3 | 13.7
16.5

20.0

31
24
11
3
3
1
4
3
20

53
32
10
1.4
0.9
0.2
0.5
0.3
1.2
1
0
0
0
0
0.1
0.15
0.21
0.29
0.39
TOTAL =
0
0
0
0
0.09
0.03
0.105
0.087
0.468
0.78%
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                                      APPENDIX B
     The following paragraphs provide a brief description
of the two models which were used in the study;  namely,
LONGZ and ISCLT.


                           LONG_Z



     The LONGZ computer program is designed to calculate
long-term,  ground-level pollutant concentrations produced at
a large number of receptors by emissions from multiple
stack,  building and area sources.


     LONG?,  uses statistical wind summaries to calculate
long-term (seasonal,  annual or longer)  average concentrations.
The LONGZ program is applicable primarily to areas of
complex terrain: i.e.,  areas where terrain elevations exceed
stack-top elevations.


     A summary of the major capabilities of this model follows
                            B-l
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Reference: -
Availability:
Abstract:
Bjorklund, J. R., and J. F. Bowers.  "User's Instructions
for the SHORTZ and LONGZ Computer Programs.   Volumes 1
and 2," EPA 903/9-82-004, U.S. Environmental Protection
Agency, Region III, Philadelphia, Pennsylvania 19106,  1982.

The model is available as part of UNAMAP  (Version 6).  The
computer code is available on magnetic  tape  from:

          Computer Products
          National Technical  Information  Service
          U.S. Department of  Commerce
          Springfield, Virginia  22161

          Phone (703) 487-4763

The accession number of the UNAMAP  tape is PB

LONGZ utilizes the steady-state univariate Gaussian  plume
formulation for both urban and rural areas in  flat or
complex terrain to calculate  long-term  (seasonal and/or
annual) ground-level ambient  air concentratins attribut-
able to emissions from up to  14,000 arbitrarily placed
sources (stacks, buildings  and area sources).  The output
consists of the total concentration at each  receptor due
to emissions from each user-specified source or group of
sources, Including all sources.  An option which considers
losses due to deposition (see the description of SHORTZ) is
deemed inappropriate by the authors for complex terrain,
and is not discussed here.
    Input Requirements

    Source data requirements are:   for point, building or area, sources,
    location, elevation, total  emission rate  (optionally classified by
    gravitational  settling velocity)  and decay coefficient; for stack
    soruces, stack height, effluent temperature, effluent exit velocity,
    stack radius (inner), emission rate,  and  ground elevation (optional);
                                                   B-2
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for building sources, height, length and width,  and orientation;  for
area sources, characteristic vertical  dimension, and length,  width
and orientation.

Meteorological data requirements are:   wind speed and measurement
height, wind profile exponents, wind direction standard  deviations
(turbulent intensities), mixing height, air temperature,  vertical
potential temperature gradient.

Receptor data requirements are:  coordinates,  ground elevation.

Output

Printed output includes:

           Total concentration due  to  emissions  from user-specified
           source groups, including the combined emissions  from all
           sources (with optional  allowance for  depletion by  deposi-
           tion) .

Type of Model

LONGZ is a climatological Gaussian  plume model.

Pollutant Types

LONGZ may be used to model primary  pollutants.   Settling  and  deposition
are treated.

Source-Receptor Relationships

LONGZ applies user specified locations for  sources  and receptors.

Receptors are assumed to be at ground  level.

Plume Behavior

Plume rise equations of Bjorklund and  Bowers (1982)  are used.

Stack tip downwash (Bjorklund and Bowers, 1982)  is  included.

All plumes move horizontally and will  fully intercept elevated
terrain.

Plumes above mixing height are ignored.

Perfect reflection at mixing height is assumed for  plumes below the
mixing height.

Plume rise is limited when the mean wind at stack height  approaches
or exceeds stack exit velocity.
                                                  B-3
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Perfect  reflection at ground is assumed for pollutants with no
settling velocity.

Zero reflection at ground is assumed for pollutants with finite
settling velocity.

LONGZ does not simulate fumigation.

Tilted plume is used for pollutants with settling  velocity  speci-
fied.

Buoyancy-induced dispersion is treated (Briggs,  1972).

Horizontal Winds

Wind field is homogeneous and steady-state.

Wind speed profile exponents are functions of both  stability class
and wind speed.  Default values are specified in Bjoriclund  and
Bowers (1982).

Vertical  Wind Speed

Vertical  wind speed is assumed equal  to zero.

Horizontal Dispersion

Pollutants are initially uniformly  distributed within each wind
direction sector.   A smoothing function is then  used to remove
discontinuities at sector boundaries.

Vertical  Dispersion

Vertical  dispersion is derived from input vertical  turbulent inten-
sities using adjustments to  plume height and rate of plume growth
with downwind distance specified in Bjorklund and Bowers (1982).

Chemical  Transformation

Chemical  transformations are treated  using exponential decay.  Time
constant is input  by the user.

Physical  Removal

Gravitational  settling and ary  deposition of particulates are treated

Evaluation Studies

Bjorklund, J.  R.,  and J. F.  Bowers.   "User's Instructions for the
    SHORTZ and LONGZ  Computer Programs," EPA-903/9-82-004,  Environ-
    mental Protection Agency,  Region  III, Philadelphia, Pennsylvania
    19106, 1982.
                             B-4
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                           ISCLT
     The Industrial Source Complex  (ISC) Dispersion Model
combines and enhances various dispersion model algorithms
into a set of two computer programs that can be used to
assess the air quality impact of emissions from the wide
variety of sources associated with an industrial source
complex.  For plumes comprised of particulates with
appreciable gravitational settling velocities, the ISC
Model accounts for the effects on ambient particulate
concentrations of gravitational settling and dry deposition.
Alternately, the ISC Model can be used to calculate dry
deposition.  The ISC long-term model (ISCLT) is a sector-
averaged model that extends and combines basic features of
the Air Quality Display Model (AQDM) and the Climatological'
Disoersion Model (COM).  The long-term model uses statistical
wind summaries to calculate seasonal (quarterly), annual
and/or longer term, ground-level concentration or deposition
values.

     A summary of  the  major capabilities of  this model
follows:
                                       B-5
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Reference:     Bowers, J. R. ,  J.  R.  Bjorklund  and C. S. Cheney.  "Indus-
               trial Source Complex  (ISC) Dispersion Model User's Guide,
               Volumes 1  and 2."   Publication  Nos.  EPA-450/4-79-030,
               031 (NTIS  Numbers:  Volume 1, PB-80-133044; Volume 2, PB-
               80-133051; Magnetic tape, PB-80-133036) Office of Air
               Quality Planning and  Standards, U. S. Environmental
               Protection Agency,  Research Triangle Park,
               North Carolina  27711,  1979.

Availability:   This model is  available  as part of UNAMAP (Version 6).
               The computer code  is  available on magnetic tape from:

                            Computer Products
                            National Technical Information Service
                            U.S.  Department of Commerce
                            Springfield, Virginia  22161

                            Phone (703) 487-4763

Abstract:       The ISC model is a  steady-state Gaussian plume model
               which can  be used  to  access pollutant concentrations  from
               a wide variety  of  sources associated with an industrial
               source complex.  This model can account for settling  and
               dry deposition  of  particulates, downwash area, line  and
               volume sources, plume rise as a function of downwind
               distance,  separation  of  point sources,  and limited ter-
               rain adjustment.   It  operates 1n both long-  and short-
               term modes.
                                                                     1GO<
                                                    B-6
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Input Requirements

Source data requirements are:  location,  emission  rate,  pollutant
decay coefficient, elevation of source,  stack  height,  stack exit
velocity, stack inside diameter, stack exit temperature,  particle
size distribution with corresponding settling  velocities,  surface
reflection coefficient, and dimensions of adjacent buildings.

Meteorological data requirements are:   for short term modeling,
hourly surface weather data from the EPA  meteorological  preprocessor
program.  Preprocessor output includes hourly  stability  class, wind
direction, wind speed, temperature,  and mixing height.   For long-term
modeling, stability wind rose (STAR  deck), average afternoon mixing
height, average morning mixing height, and average air temperature.

Receptor data requirements are:  coordinates of each receptor.

Output

Printed output options Include:
                              B-7
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           program control parameters, source data and receptor  data;

           tables of hourly meteorological  data for each specified  day;

           "N"-day average concentration or total  deposition  calcu-
           lated at each receptor for any desired  combinations of
           sources;

           concentration or deposition values calculated for  any
           desired combinations of sources  at all  receptors for any
           specified day or time period within the day;

           tables of highest and second-highest concentration or
           deposition values calculated at  each receptor for  each
           receptor for each specified time period during an  "N"-day
           period for any desired combinations of  sources; and

           tables of the maximum 50  concentration  or deposition
           values calculated for any desired  combinations of  sources
           for each specified time period.

Type of Model

ISC is a Gaussian plume model.

Pollutant Types

ISC may be used to model  primary pollutants.   Settling and deposi-
tion are treated.

Source-Receptor Relationships '

ISC applies user-specified locations for  point, line, area and
volume sources, and user-specified receptor locations or receptor
rings.

Receptors are  assumed to be at  ground  level,  and must be at eleva-
tions not exceeding stack height.

Actual separation between each  source-receptor pair is used.

Plume Behavior

ISC uses Briggs (1971,  1972)  plume rise equations  for final  rise.

Stack tip downwash (Bjorklund and Bowers, 1982) and building downwash
(Huber and Snyder,  1976)  are used.

For rolling terrain (terrain not above  stack  height), plume centerline
is horizontal  at height of final  rise  above source.

Fumigation is  not treated.
                                                   102<
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  •                  Rural  dispersion  coefficients  from Turner (1969) are used, with no
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                      Perfect reflection 1s assumed at the ground.
 I                   Chemical Transformation
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Horizontal Vlinds
Constaat, uniform (steady-state) wind is assumed for an each hour.
Straight line plume transport is assumed to all downwind distances.
Separate wind speed profile exponents (Irwin, 1979)  for both rural and
urban cases are used.
Vertical Wind Speed
Vertical wind speed is assumed equal  to  zero.
Horizontal Dispersion
adjustments for surface roughness or averaging  time.
Urban dispersion coefficients from McElroy and  Pooler  (1968), as
formulated by Briggs (1974) are used.
Buoyancy induced dispersion (Pasquill,  1976)  is included.
Six stability classes are used, with Turner class 7 treated as class 6.
Vertical Dispersion
Rural  dispersion coefficients from Turner  (1969) are used, with no
adjustments for SL.-face roughness.
Urban dispersion coefficients from McElroy and  Pooler  (1969), as
formulated by Briggs (1974) are used.
Buoyancy induced dispersion (Pasquill,  1976)  is  included.
Six stability classes are used, with Turner class 7 treated as class 6.
Mixing height is accounted for with multiple  reflections until the
vertical coefficient equals 1.6 times the  mixing height; uniform
vertical mixing is assumed beyond that  point.
                     Chemical  transformations are treated using exponential  decay.  Time
                     constant  is  input by the user.
                             B-9
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Physical Removal

Settling and dry  deposition of particulates are  treated.

Evaluation Studies

Bowers, J.  F.,  and A.  J.  Anderson.   "An Evaluation Study for the
    Industrial  Source  Complex  (ISC)  Dispersion Model," EPA-450/4-81-
    002, U.S. Environmental  Protection Agency, Research Triangle
    Park, North Carolina  27711,  1981.

Bowers, J.  F.,  A.  J. Anderson,  and W. R. Hargraves.  "Tests of
    the Industrial  Source Complex (ISC) Dispersion Model at the
    Armco Middletown,  Ohio Steel Mill,"  EPA-450/4-82-006 (NTIS PB
    82-257-312),  U..S.  Environmental Protection Agency, Research
    Triangle Park,  North  Carolina 27711, 1982.

Scire, J. S., and L. L. Schulman.  "Evaluation of the BLP and ISC
    Models  with SF6 Tracer Data  and S02 Measurements at Aluminum
    Reduction Plants,"  APCA  Specialty Conference on Dispersion
    Modeling for  Complex  Sources, 1981.
                          B-10
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                                           flPPENDIl C


                             ''he  following series of tables provides  a
                             co«olete list of Meteorological data
                             which »as mout to the Models.
                                      HETEDROLDGICftL INPUT DflTfl
                               fWBIENT ftlR TEKPERflTURE (DEBREES KELVIN)


                   STABILITY  STflBILITY  STABILITY  STABILITY   STABILITY  STflfllLITY
                            1  CflTEBORY 2 CflTEBORY  3 CflTEBQRY *  CflTESORY 5 CflTEBOHY &
                     2S6.0000   286.0000   2B6.0000   2B&.0000   286.0000   286.0000
                                      HIZINE LAYER HEISfT  OCTDE)
                      UIND SPEED  UIND SPEED   UIND  SPEED   WIND SPEED  UIND SPEED  UIKD SPEED
                      CflTEBQRY 1  CflTEBORY  2   CflTEBORY  3   CflTEBORY 4  CflTEBORY 5  CflTEBORY 6


STflBILITY CATEBORY 1 .160000+004 .180000+004  .180000+004 .180000+004 .160000+004 .160000+004
S'RBlLlTY CflTEBORY 2 .160000+004 .160000+004  .160000+004 .160000+004 .160000+004 .160000+004
STflBILITY CflTEBORY 3 .140000+004 .140000+004  .140000+004 .140000+004 .140000+004 .140000+004
STABI.ITY CflTEBORY 4 .100000+004 .100000+004  .100000+004 .100000+004 .100000+004 .100000+004
STABI_I~Y CATEGORY 5 .100000+005 .100000+005  .100000+005 .100000+005 .100000+005 .100000+005
STABILITY CflTEBORY 6 .100000+005 .100000+005  .100000+005 .100000+005 .100000+005 .100000+005
                                                          C-l
                                                                                             5
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FDEDUDCY OF ODCURREJCE OF WIM) SPEED, DIRECTION AND STflBILITY


                   STWILITY CflTEBORY 1
     SPEED  WIND SPEED  WIND SPEED  WIND SPEED  HIM) SPEED  HIM) SPEED
CflTEBORY 1  CfiTESORY 2  CflTEBORY 3  CflTEBORY 4  CflTEBORY 5  CflTEBORY 6
DIRECTION
(DEE WEES)
.000
22.500
45.000
67.500
90.000
112.500
135.000
157.500
160.000
202.500
225.000
2*7.500
270.000
232.500
315.000
337.500
( .7500HPSH

.00004493
.00002900
.00003399
.00003000
.00008899
.00003599
.00009099
.00010798
.00013398
.00008499
.00015797
.00013198
.00007299
.00004699
.00007499
.00005099
2.50QOMPSM

.00016197
.00006799
.00004699
.00008099
.00015498
.00022196
.00017497
.00020897
.00032295
.00026896
.00041693
.00037594
.00029595
.00010798
.00016797
.00014098
4.3000KPSM

.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
6.8000WSH

.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
9.5000WS)

.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
U2.5000WS:

.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
                  STABILITY CRTEGDRY 2


UIND SPEED   UIW SPEED  WIfffl SPEED  U1W) SPEED  UIH) SPEED  HIND SPEED
CflTEBORY  1   CflTEBORY 2  CflTEBORY 3  CflTEBORY 4  CflTEBORY 5  CflTEBORY 6
DIRECTION
(DEGREES)
.000
22.500
45.000
67.500
90.000
112.500
135.000
157.500
1 BO. 000
202.500
225.000
247.500
270.000
292.500
315.000
337.500
( .7500WSM

.OCO&009Q
.00016097
.00023896
.00018697
.00060090
.00046892
.0004%92
.0005319!
.00054686
.00053191
.00072188
.00072088
.00095185
. 00047&92
.00048392
.00037094
2.5000MPSH

.0012220
.00039594
.00040294
.00061090
.00126180
.00122880
.00122180
.00098684
.00151676
.00128179
.00291253
.00255059
.00186570
.00126880
.00124680
.00114082
4. 3000MPS) (

.OQ12£SSO
.00030895
.00028895
.00039594
.00091985
.00052392
.00052392
.00046393
.00069789
.00115481
.00344245
.00240261
.00151076
.00084586
.00106783
.00089986
6.8000HPS)

.OOOOOOCO
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
( 9.5000HPS)!

.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.ooccoooo
.00000000
I12.5000WS

.00000000
.00000000
.00000000
.00000000
.OOOOOOCO
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
                            C-2
                                                         106'
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                   STABILITY CflTEBORY 3


 UIND SPEED  WIND SPEED  UIND SPEED  WIND SPEED  UIND SPEED  UIND SPEED
 CRTE60RY 1  CflTEBORY  2  CflTEBORY 3  CflTEBORY 4  CfiTESORY 5  CATEGORY 6
DIRECTION
(DEEREES)
.000
22.500
45.000
67.500
90.000
112.500
135.000
157.500
180.000
202.500
225.000
247.500
270.000
292.500
315.000
337.500
( .7500KPSM

.00035594
.00013496
.00012096
.00013598
.00034594
.00036294
.•00039394
.00044893
.00052991
.00036094
.00055291
.00051692
.00066789
.00039694
.00032195
.00027096
2.5000KPSH

.00196668
.00063090
.00063090
.00067189
.00157075
.00118781
.00105363
.00104683
.00148976
.00109382
.00365741
.00316749
.00253059
.00125580
.00144977
.00133579
4.3000WSH

.00543613
.00150376
.00110082
.00224164
.00355643
.00134878
.00117481
.00122880
.00240261
.00267757
.01089825
.00881758
.00542213
.00424132
.00478523
.00410734
6.8000KPSM

.00107383
.00020697
.00020897
.00030895
.00042293
.00006799
.00014798
.00012098
.00032895
.00059790
.00196668
.00138978
.00102684
.00116181
.00140277
.00098684
9.500CWS)

.00002100
.00000700
.00000000
.00002100
.00000700
.00000000
.00000000
.00000000
.00000000
.00000700
.00010796
.00002100
.00005399
.00006099
.00008099
.00004099
(12.500WPS

.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000700
.00001400
.00000700
.00000700
                  STftBILITY CflTEBORY *


UIND SPEED  UIND SPEED  UIND SPEED UIND SPEED  UIND SPEED  UIND SPEED

CATEGORY 1  CflTEBORY 2  CftTEBQRY 3 CflTEBORY 4  CflTEBORY 5  CflTEBORY 6
DltCTIOS
(DEBREE5)
.000
22.500
45.000
67.500
90.000
112,500
135.000
157.500
180.000
202.500
225.000
247.500
270.000
292.500
315.000
337.500
( . 7500f.PS) (

.00088586
.00039594
.00047692
.00077488
.00174472
.00157875
.00165473
.00148276
.00186070
.00088086
.00122780
.00120082
.00153175
.00067786
.00078487
.00060590
2.5000WPSH

.00620700
.00173872
.00251058
.00526116
.00940849
.00724784
.00628799
.00585206
.00648896
.00342245
.00800571
.00661694
.00658294
.00357743
.00322148
.00347644
4.3000NPSM

.01709826
.00673092
.00834166
.01794312
.01659402
.00724084
.00670392
.00722784
.01620540
.00971044
.02680070
.01331986
.01382378
.01101223
.01060930
.00653563
6.BOOOMPSM

.01826606
.00779775
.00918653
.01639337
.01043532
.00222864
.00228863
.00339545
.01156313
.00751579
.01677631
.00909954
.02144656
.02711665
.02780054
.01662133
9.5000WS)

.00173172
.00094685
.00149676
.00240261
.00122180
.00013498
.00017497
.00046992
.00111482
.00069189
.00151076
.00068489
.00481123
.00827467
.00724084
.00274456
ULSOOOWS:

.00011498
.OC01W33
.000228%
.00031595
.00012798
.00004099
.00000700
.00002700
.00023496
.00008099
.00016197
.00024196
.00153675
.00186570
.00132879
.00040993
                                                                                         107 <
                                                                r-3
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                   STflBILITY  CflTEBORY 5


UIND SPEED  UIND SPEED  WIND  SPEED  UIND  SPEED   UIND SPEED   HIND  SPEED
COTE60RY  1  CftTESORY  2  CflTEBORY 3  CATEGORY 4   CRTEHJJ7Y 5   CfiTEECRY 6
DIRECTION
(DEBREE5)
.000
32.500
45.000
67.500
90.000
112,500
135.000
157.500
1BO.OOO
202.500
225.000
247.500
270.000
292.500
315.000
337.500
( .7500HPSH

.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
: 2.5000WPSH

.00438230
.00065386
.00112782
.00202068
.00371140
.00314749
.00344945
.00425432
.00666393
.00361042
.00835158
.00648896
.00689183
.00401336
.00268457
.00283234
4.3000HPSM

.01138117
.00258359
.00117481
.001B1271
.00158375
.00068483
.00090685
.00124180
.00497920
.00337936
.01177011
.00513418
.01415873
.01155515
.00637466
.00591205
6.BOOOKPSM

.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
9.5000HPS)

.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
(12.5000WS

.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
                   STflBILITY CflTEBORY 6


HIND SPEED  MIND SPEED  UIND SPEED  UIHD SPEED  UIND SPEED  HIND SPEED
CflTEBORY 1  CRTEBORY 2  CflTEBORY 3  CflTEBORY 4  CflTEBORY 5  CflTEBORY 6
DIRECTION
(DESREES)
.000
22.500
45.000
67.500
90.000
112.500
135.000
157.500
180.000
202.500
225.000
247.500
270.000
292.500
315.000
337.500
( .TSOOflPSH

. 00303451
.0009%64
.00100384
.00109982
.00199068
.00180371
.00222164
.00263158
.0044892B
.00277455
.00441929
.00544413
.00691089
.00313650
.00280755
.00246260
2.5000HPSX

.00969141
.00167773
.00104683
.00140977
.00230863
.00190669
.00202068
.00232653
.00589905
.00402035
.01176311
.01071628
.01596444
.00803270
.00630099
.00590505
4.3000HPSH

.00000000
.ocoococo
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
6.9000KPSH

.00000000
.ccoccooo
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
9.5000KPS>

.00000000
.00000000
.00000000
.00000000
.OOOOOC30
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
(12.5000WS

.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
.00000000
                                                                     C-4
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   •                     .              Appendix D
                    The following Tables present the result of the
   •           concentration predictions for each of the three analyses.
               For the combined impacts analysis there are two tables since
   •           the combined impacts were modeled on each of the two grids.
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•
™

•
•











1
















1
1
1
1
1




IWWCT RUM
NOOTHE5T IttlNOHTOR CLDC
OXENTOTID6 IN UB/M3


S
SSU
su
USU
u
uw
m
MM
N
ItC
1C
ec
£
ESE
SE
SSE

S
SSU
su
USU
u
INI
Ml
wu
N

we
1C
9C
E
ESE
SE
SSE





.200 ta
1.3519-012
6.7120-013
6.0570-013
1.3645-012
1.0896-011
2,9799-011
1.4061-010
5.7808-010
fl. 4867-011
2.6969-010
6.6144-010
1.6963-010
1.9587-010
1.2657-010
7.7934-012
2.4147-012
8.000
4.9219-008
1.6233-006
2.4995-008
4.5647-008
4.8914-008
2.4997-006
2.2067-006
2.5366-008
4.5290-008

2.9246-008
9.7119-008
5.7395-006
7.1809-008
5.3063-008
4.8550-008
13746-006





.500
11298-009
5.6876-010
4.7891-010
1.6257-009
8.9136-009
5.6711-009
6.5717-008
1.2478-007
1.4137-007
1.8213-007
4.8433-007
3. 1613-007
1.3946-007
3.6189-008
1.1282-008
8.4890-009
10.000
4.3356-008
1.3866-006
2,0433-006
2.7958-008
4.1153-008
1.5241-008
1.472S-OOB
2.5697-008
19200-008

2.3051-008
6. 2564-008
17245-008
5.2903-008
4.5300-008
4.0607-008
2.9040-008




_-
.650
7.8687-009
2.0861-009
1.8598-009
10912-009
5.8778-009
1.2630-008
9.4536-006
2.5066-007
4.1900-007
10170-007
8.0194-007
5. 1274-007
4.5251-007
14028-007
1.2730-007
1.1643-006
12.000
18358-008
1.2001-006
1.6386-006
2.8145-008
15198-008
1.3326-006
1.3227-008
2.2882-006
10824-008

1.9675-008
7.1341-008
14253-006
4.7459-008
19238-008
14960-008
2.5340-006





.850
2. 4638-006
4.9281-008
1.3021-007
1. 1437-007
2.0523-008
1.4667-008
4.7662-008
1.6636-007
9.5419-007
5.2998-007
[l.3962-0o4
8.0010-007
6.0224-007
2.6462-007
1.996S-007
2.2576-008
20.000
2.5420-008
7.5110-009
9.6757-009
1.7652-008
2.1379-008
9.4339-009
9.4642-009
1.4746-008
2.9726-008

1.7124-008
17612-008
2.3027-006
12973-008
2.4900-008
2.1665-008
1.6431-008





1.200
1.1006-007
1.2099-007
2.7620-007
2.9573-007
18256-007
11953-008
2.2626-007
1.9055-007
7.5124-007
4.9400-007
9.9451-007
6.4257-007
8.8395-007
6.9970-007
10597-007
6.1954-006
50,000
1.0519-008
2.9103-009
L9636-009
5.9191-009
7.8251-009
5.2045-009
5.4964-009
6.4949-009
1.1921-008

7.5274-009
1.7997-006
1.0664-008
1.4890-008
9.9335-009
6.4639-009
6.7B57-009





1.500
12321-OC7
6.1771-OOa
2.9291-007
14102-007
4.1648-007
4.8577-008
1.7680-007
2.1949-007
7.SC7S--OC7
4.1204-007
9.5918-007
19357-007
4.9400-007
5.1933-007
2.7973-007
6.6781-008























2.000
4.329S-007
1.6262-007
1.9992-007
2.9728-007
2.0686-007
1.0609-007
1.7673-007
2.7122-007
5.51E9-C07
10191-007
7.0681-007
4.1010-007
4.6170-007
4.6134-007
2.6269-007
1.2626-007























2.600
2.7581-007
9.703C-COa
1.2550-007
1.6352-007
2.2532-007
1.0547-007
1.1021-007
1.6579-007
16195-007
1.9911-007
16854-007
2.6464-007
2.8612-007
10431-007
2.0958-007
1.7625-007























1400
2.33*3-007
6.9E27-OOS
6.1923-006
1.3326-007
1.6921-007
9.1700-008
6.6407-006
9.6062-006
2.13fi6-007
1.0853-007
13334-007
2.3797-007
10155-007
2.0059-007
1.5716-007
1.4400-007























4. SCO
1.4A56-007
4.4144-OM
4.9662-008
8.2622-008
1.1135-007
6.7140-008
4.7269-006
6.6182-006
1.1585-007
8.7266-008
3,1345-007
1.6039-007
1.9711-007
1.3296-007
9.4341-008
9.8774-006






















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.300 KB
3.3907-008
1.0691-008
1.1341-008
1.8941-008
2.2448-008
1.0170-008
1.0410-006
1.0345-008
2.0147-008
2.3340-008
6.7684-008
4.7364-008
4.8674^006
4.8624-008
4.9426-008
3.0606-008

10.000
3.5247-006
1.1590-006
1.2693-006
2.5632-008

2.9208-008
1.4664-008
1.2889-008
1.6153-COa
3.3606-008
2.1658-008
4.8250-006

2.6620-008
4.4046-008
3.6838-006
3.7354-008
2.4199-008




.780
4.7223-007
1.7289-007
2.1382-007
3.9489-007
3.9495-007
1.7398-007
1.5680-007
1.7180-007
3.6397-007
2.5131-007
6.6127-007
4.3533-007
5.6467-007
5.4833-007
5.3886-007
3.5897-007

20.000
1.9598-008
6.0428-009
6.2012-009
1.2642-008

1.4447-008
7.6808-009
7.4298-009
8.225E-009
1.6303-008
1.0306-008
2. 5327-008

1.6120-008
2.3125-008
1.9933-008
1.7735-008
1.3176-008



.
1.000
5.0881-007
1.7761-007
2.1113-007
3.8943-007
4.1479-007
2.0316-007
1.8620-007
2.0318-007
4.0786-007
2,7179-007
7.0460-007
4.7117-007
6.1622-007
5.4820-007
5.2590-007
3.6556-007

50.000
6.4506-009
1.9269-009
2.0091-009
3.8771-009

4.6467-009
2.6725-009
2.6111-009
2.9199-009
5.3807-009
3.3799-009
8.6620-009

5.8670-009
8.0015-009
6.0951-009
5.3815-009
4.1352-009




1.300
4.7291-007
1.5671-007
1.7941-007
3.3914-007
3.6991-007
2.0471-007
1.9334-007
2.1179-007
3.9411-007
2.5460-007
6.4978-007
4.4574-007
5.8992-007
4.8391-007
4.5187-007
3.2649-007
























1.800
3.6081-007
1.1395-007
1.2601-007
2.3134-007
2.7563-007
1.6330-007
1.6117-007
1.7355-007
3.1519-007
1.9802-007
4.9386-007
3.4955-007
4.6696-007
3.5663-007
3.2465-007
2.4274-007
























2.300
2.6626-007
8.2182-008
8.9316-006
1.6117-007
1.9756-007
1,2404-007
1.2474-007
1.3228-007
2.3817-007
1.4755-007
3.6432-007
2.6286-007
3.5225-007
2.5965-007
L 3345-007
1.7753-007
























3.000
1.7897-007
5.4391-008
5.6392-008
1.0389-007
1.3008-n07
8.333J-008
8.4449-006
9.2328-006
1.6121-007
1.0014-007
2.4504-007
1.7963-007
2.4102-007
1.7312-007
1.5432-007
1.1679-007
























4.100
1.0563-007
3.1774-008
3.3816-008
5.9220-006
7.5699-008
4.8289-006
4.9235-008
5. 4793-006
9.8169-008
6.0283-008
1.4477-007
1.0753-007
1.4431-007
1.0167-007
9.0102-008
6.9966-006
























5.300
6.6394-008
1.9878-008
2.1069-006
3.6876-006
4.8047-006
2.9939-008
3.0363-008
'3.4<43c-006
6.1472-008
3.8469-006
9.106£-006
6.6147-006
9.2819-006
6.3771-008
5.6770-008
4.395B-008
























7.000
4.5216-006
1.5413-006
1.6894-008
3.5296-006
3.9310-006
1.7B47-OG6
1.8108-008
2. Cool -003
4.2532-006
2.6015-006
5.9223-006
4.0793-008
6. 0305-008
5.0907-008
4.6237-006
3.1569-008























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.300 KB
6.6020-006
4. 2865-008

4.4235-006
5.1629-008
5.5484-008
4.3553-008
4.4082-OOG
4.4196-006
5.4041-006

5.7086HD06
1.0116-007
8.0576-008
8.1584-008
8.1209-008
8.1749-008
6.2766-008

10.000
5, 1418-008
11883-008
4.0270-008
5.9819-006
6.4049-006
1.0606-007
1.7615-007
1.8568-007
8.981H30fl
6.7318-008
B. 4690-008
5.7265-008
6.7501-006
5.7631-008
5.6380-006
4.1525-006





.780
5.0302-007
2.0385-007

2.4525-007
4.2705-007
4.2801-007
2.0999-007
1.9163-007
2.0705-007
19898-007

2.8582-007
6.9510-007
4.6843-007
5.9709-007
5.8022-007
5.7017-007
18969-007

20.000
12260-008
2.4254-008
1.8938-006
2.0562-008
2.8953-008
4.7B70-008
13246-008
19675-OOfl
6.8344-006
18042-008
4.9950-008
4.0725-008
4.1246-008
14741-008
10862-008
2.4771-008





1.000
5.3903-007
2.0602-007

2.4211-007
4.2132-007
4.4785-007
2.3746-007
2.2159-007
2.3903-007
4.4339-007

10664-007
|7. 3857-007]
5.0421-007
6.4841-007
5.7972-007
5.5677-007
19594-007

50.000
1.4069-008
8.0695-009
4.8341-009
7.8977-009
1.29H-008
1.0665-006
9.9605-009
1.3541-006
1.6377-OOfl
1.8825-008
2.0313-008
1.7547-008
1. 8968-008
1.3825-008
1.2046-006
9.8527-009





1.300
5.0237-007
1.8639-007

2.0978-007
17065-007
4.0293-007
2.3939-007
2.2951-007
2.4848-007
4.3034-007

2.8992-007
| 6. 8394-007
4.7869-007
6.2179-007
5. 1494-007
4.8216-007
15616-007























1.800
18907-007
1.4245-007

1.5534-007
2.6215-007
10871-007
1.9860-007
1.9871-007
2. 1170-007
15264-007

2.3412-007
5.2830-007
18233-007
4.9830-007
18687-007
15401-007
2.7130-007























2.300
2.9340-007
1.0955-007

1.1761-007
1.9121-007
2.3022-007
1.5993-007
1.6376-007
1.7199-007
L 7687-007

1.6440-007
19900-007
2.9545-007
18307-007
2.8913-007
2.6193-007
2.0506-007























1000
2.0467-007
8.0263-006

B. 5238-006
1.3274-007
1.6221-007
1.1994-007
1.2571-007
1.3439-007
2.0171-007

1.3800-007
2.7999-007
2. 1192-007
2.7112-007
2.0158-007
1.8161-007
1.4497-007























4.100
1.2928-007
5.5492-008

5.8436-008
8.3996-008
1.0655-007
8,5667-008
9.4455-008
1.0092-007
1.4160-007

9.9603-008
1.7998-007
1.3925-007
1.7327-007
1.2862-007
1.1568-007
9.4235-008























5.300
ft. 8061-006
4.1462-008

4.4399-008
6.4440-006
7.8642-008
6.7361-008
8.1229-006
8.5655-006
1.0815-007

7.9237-008
1.2633-007
9.9130-008
1.2055-007
8.9223-008
8.0700-006
6.6419-006























7.000
6.4566-008
15260-008

4.2303-008
6.7129-006
7.7254-008
6.2647-008
8.6589-008
8.8766-006
9.3869-008

7. 1171-008
9,5071-008
7.0545-008
8.6384-006
7.4474-008
6.8143-006
5.1690-008






















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              UNITED STATES ENVIRONMENTAL PROTECTION AGENCY
                    Office of Air Quality Planning and Standards
                   Research Triangle Park, North Carolina 27711
MEMORANDUM

SUBJECT:  Risk Assessment of Emissions of CDDs/CDFs from
                                                         ,.
the Philadelphia Northwest Municipal  Incinerator      ,  /'•'//   //
                                            ^   - 1 r- n"1'* 7/
D                                           '. / .*' •'  vj   '       "
                                            -f
FROM:     David H. Cleverly, Environmental  Scientist
          Pollutant Assessment Branch, SASO

TO:       Donald Barnes
          Chairperson/Chlorinated Dioxin Workgroup

          W. Ray Cunningham, Director
          Air Management Division, Region III

     On January 3, 1986, the Chlorinated Dioxin  Work Group  (CDWG)  reviewed
and approved the preliminary risk assessment  of  emissions  of  CDDs/CDFs  from
the Philadelphia NW municipal  incinerator.  The  following  is  a  synopsis  of
the risk assessment methodology used in estimating the risks.  The contractor,
MRI, was able to resolve the speciation of  2,3,7 ,8-chlorine substituted
compounds within each homologue group, thus providing a  unique  application
of the toxic equivalence method in risk assessment.

Description of City of Philadelphia Northwest  Incinerator

     The City of Philadelphia  Northwest Incinerator  plant  operates two
refuse furnaces which can each process up to  375 tons of trash  per day.
The operation of the units is  designed to achieve a  90%  volume  reduction
in refuse.  Each furnace consists of a single  (primary)  excess  air
combustion chamber with air cooled walls.  Exhausts  from each furnace pass
through cooling sprays, two evaporation towers,  a two-stage (field)  ESP,  and
the stack.  Figure 1 is a schematic of the  northwest incinerator furnace.

     An elevated crane with a  clam-shell  bucket  lifts the  refuse from the
storage bin into a charging hopper and water-cooled  gravity chute.  Refuse
drops from the chute onto the  inclined traveling grate, which continuously
feeds the refuse onto a horizontal  traveling  grate.   Each  grate is driven
by independent variable speed  motors.   The  total  effective  grate area pro-
vided by the two grates is 480 ft^ per furnace.   Combustion air (taken from
outside the building) is provided to each furnace by a 50  HP  forced  draft
fan.  The underfi re/overf ire air ratio is adjusted by dampers in the forced
draft ductwork.  The refractory lined  furnaces are designed to  operate at
a maximum temperature of 2100°F.

     Incinerator residues drop off the edge of the horizontal grate  and
fall through a series of residue-quenching  sprays and onto  a.  submerged
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             residue conveyor.   The ESP  fly ash  also  is  discharged  onto-the  submerged
             residue conveyor.   Residue  is  discharged into  trucks.

                  Furnace flue  gases exit the furnaces through  spray  chambers where  air-
             atomized water cools  the gases to the designed ESP operating  temperature.
             The cooling water  evaporates in  the two  evaporation towers so that flue
             gases entering the ESP are  between  550°  and 600°F. The  cyclonic flow in
             the two towers is  also designed  to  remove the  largest  particles from the flue
             gases prior to their  entry  into  the ESP.

                  Flue gases leave the towers and travel  through the  precipitator breech-
             ing where turning  vanes .and baffle  plates ensure even  gas distribution
             throughout the device.  Treated  flue gases  are drawn from each  precipitator
             by an induced draft variable speed  fan and  exit the plant through a single
             stack.

             Risk Assessment Methodology

                  Stack tests for  PCDO/PCDF emissions were  completed  for both the Unit
             1  furnace and Unit 2  furnace in  March, 1985.   Tables 8 and 10 (copied from
             the MRI  test report)  report the  homologue specific and isomer specific
             analysis of emissions from Unit  1.   Tables  9'and 11 report the  same analysis
             for Unit 2.

                  The risk assessment  procedure  utilized  the method discussed in Interim
             Procedures for Estimating Risks  Associated with Exposures to Mixtures of
             (Thlorinated Dibenzo-p-Dioxins  ancl Dibenzofurans (CDDs and CDFsJ, October
             1985, initially produced  by the  COWG and reviewed  and endorsed  by the Risk
             Assessment Forum.   In general, an assessment of the risk to human health of
             mixture  of CDDs and CDFs, using  the TEF  approach,  involves the  following steps:

                  1.   Analytical determination of the CDDs  and  CDFs in the sample.

                  2.   Multiplication of congener concentrations  in the sample by the toxic
                      equivalence  factors (TEFs)  in Table I to  express the concentration
                      in terms  of  2378-TCDD equivalents.

                  3.   Summation of the products  in step 2 to obtain the total 2378-TCDD
                      equivalents  in the sample.

                  4.   Determination  of human  exposure to the mixture  in question, expressed
                      in terms  of  equivalents  of 2,3,7,8-TCDD.

                  5.   Combination  of exposure  from step 4 with  the carcinogenicity potency
                      estimate  for 2378-TCDD  to  estimate  risks  associated with the mixture.
                      In this case in which the  concentrations  of the fifteen congeners
•                    of concern are known:

             2378-TCDD  Equivalents - sum of:   (TEF of  each 2378-CDD/CDF congener x the
I                                             concentration of  the respective congener)
                                             +  (TEF  of each non-2378 CDD/CDF congener x
                                             the concentration of the respective congener)
 I

kl
-------
     The contractor laboratory  providing  analytical  quantitation  of the
stack samples did not have isotopic standards  to speciate  some  of the  2378-
substituted congeners listed in Table 1.   Therefore,  estimates  of mass
emission rates of 1,2,3,7,8,9,-HxCDD, 1,2,3,6,7,8-HxCDD, 1,2,3,7,8,9-HxCDF and
2,3,4,6,7,8-HxCDF were made by  averaging  the emission rate  of the quantitated
compound in the homologue by:   (1)  observing the concentration  of the  known
compound(s) within the homologue group, and  (2)  averaging  these concentrations
for the stack tests at the same unit. This  average  concentration of the
quantitated compounds was assumed to represent the concentration  and emission
rate of the non-quantitated 2378-CDD/CDF  of  concern.   Refer to  Tables  2 and
3 for the calculated results of all  the congeners, including the  non-
quantitated compounds, in the  stack  emissions  of both Units 1 and 2.   For
example, the emission rates for 1,2,3,4,7,8-HxCDF and 1,2,3,6,7-HxCDF  in
test 4A are 1.8 pg/sec. and 2.2 ug/sec.,  respectively.  The average of the
emissions for these isomers is  2.0  ug/sec.,  and  therefore,  was  used to
estimate the emission rate of  the other two HxCOF isomers  in test 4A.  When
only one compound is known, then the emission  rate of this  compound is
assumed to be the emission rate of  the unknown compound.  Again referring
to Table 2, since only 1,2,3,4,7,8-HxCDD  is known, the emission rate of
this isomer is used to estimate the  emission rate of  the other  HxCDD
compounds not speciated by the  contractor laboratory. In  test  6B (Table 2)
the ^1,2,3,7,8-PeCDD compound was estimated by  observing the percent dis-
tribution of this compound relative  to the PeCDD homologue  in tests 4A and 5A.
The average percent distribution of  the reported 1,2,3,7,8-PeCDD  compound in
in those tests is 8%.  The 8%  was multiplied by  the  PeCDD  homologue con-
centration of test 6B in Table  8 (39 ug/s) to  estimate the  emission rate
of 3.12 ug/s shown for 1,2,3,7,8-PeCDD in test SB (Table 2).  A similar
procedure was used to estimate  1,2,3,7,8  and 2,3,4,7,8-PeCDF in test 6B, Table
2, as well as 1,2,3,4,7,8-HxCDF in  test 3B, Table 3.   Although  emissions of
CDDs/CDFs were reported by the  EPA  contractor  for the stack sample designated
6A of unit 1, the laboratory reported only a 20% recovery  of the  isotopic
standard used in the analysis.   This low  recovery rate does not fall within
the range of acceptability (50% to  120% recovery rate), and therefore  was
not included in the risk assessment.

     The Philadelphia incinerator plant operates two incineration units,
therefore the 2,3,7,8-TCDD equivalent emission rate  at each unit  was combined
to estimate the total emission  rate from  the complex. About 4.4  micrograms
2,3,7,8-TCDD equivalence are estimated to be emitted each  second  of plant
operation, or about 16 milligrams 2,3,7,3-TCDD equivalence per  hour.   This
emission rate was estimated by  averaging  the three tests at each  unit, and
summing the emissions of unit  1 and unit  2.  If  the  incinerator is
operational 365 days each year, then approximately 0.14 kg 2,3,7,8-TCDD
equivalence are emitted into the atmosphere  in a year.

     A modeling procedure described in detail  is given in  Alan  J. Cimorelli's
memorandum  ("Ambient Air Dioxin Concentration  Predictions  for the Philadelphia
Northwest Incinerator") to W.  Ray Cunningham dated January 10,  1986.   The
procedure was used to estimate the  maximum annual ground-level  concentration
of 2378-TCDD equivalence resulting  from  the  estimated mass emission  rate.
The procedure used both the ISCLT and LONGZ  air  diffusion  models. The
                           116 <
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1
                                  TABLE I

                   COO/CDF ISOMERS OF MOST TOXIC CONCERN3
                      DIOXIN
Isomer
TEFb
         DIBENZOFURAN

Isomer                   TEF
2,3,7,8-TCDD 1
1,2,3, 7,8-PeCDD 0.5
1,2,3,4,7,8-HxCDD 0.04
1,2,3,7,8,9-HxCDD 0.04
1,2,3,6,7,8-HxCDD 0.04

1,2,3,4,6,7,8-HpCDD 0.001


2,3,7,8-TCDF
1,2,3,7,8-PeCOF
2,3,4,7,8-PeCDF
1,2,3,4,7,8-HxCDF
1,2,3,7,8,9-HxCDF
1,2,3,6,7,8-HxCDF
2,3,4,6,7,8-HxCDF
1,2,3,4,6,7,8-HpCOF
1,2,3,4, 7,8, 9-HpCDF

0.1
0.1
0.1
0.01
0.01
0.01
0.01
0.001
0.001

a/   In each homologous group the relative  toxicity  factor  for  the  isomers
     not listed above is 1/100 of the value listed above.

b/   TEF = toxic equivalence factor = relative  toxicity  assigned.
-------
                                 TABLE  2
        CALCULATION  OF  STACK  EMISSION RATE  (MICROGRAMS/SECOND) OF 2378-TCDD
    EQUIVALENT  CONCENTRATION  OF  CDDs/CDFs DURING THE OPERATION OF UNIT 1
 Congener

 2378-TCDD
 Other TCDDs
 1,2,3,7,8-PeCDD
 Other PeCDOs
 1,2,3,4,7,8-HxCDD
 *l,2,3,7,8,9-HxCDD
 *l,2,3,7,8-HxCDD
 Other HxCDDs
 1,2,3,4,6,7,8-HpCOD
 Other HpCDD
 2378-TCOF
 Other TCDFs
 1,2,3,7,8-PeCDF
 2,3,4,7,8-PeCDF
 Other PeCDFs
 1,2,3,4,7,8-HxCDF
 *1,2,3,7,8,9-HxCDF
 1,2,3,6,7,8-HxCDF
 *2,3,4,6,7,8-HxCDF
 Other HxCDFs
 1,2,3,4,6,7,8-HpCDF
 1,2,3,4,7,8,9-HpCDF
 Other HpCDFs
       2378-TCDD Equivalence:
         Test
          5A
         Test
          68
1
.01
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.04
.04
.04
.0004
.001
.00001
.1
.001
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.1
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.01
.01
.01
.0001
.001
.001
.00001
0.19
6.70
1.80
20.20
1.40
1.40
1.40
6.8
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0.95
18.05
2.20
2.70
18.10
1.80
2.00
2.20
2.00
*•*•
2.6
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0.190
0.067
0.900
0.100
0.056
0.056
0.056
0.003
0.002
**
0.095
0.018
0.220
0.270
0.018
0.018
0.020
0.022
0.020
**
0.003
**
**
0.16
5.34
1.27
14.73
1.50
1.50
1.50
6.5
2.8
**
0.54
12.46
1.50
1.90
11.60
1.40
2.10
2.80
2.10
**
3.3
0.25
**
0.160
0.053
0.635
0.074
0.060
0.060
0.060
0.003
0.003
**
0.054
0.130
0.150
0.190
0.012
0.014
0.021
0.028
0.021
**
0.003
**
•**
0.260
18.74
3.12
35.88
2.60
2.60
2.60
15.20
4.60
**
1.20
37.8
6.6
5.12
55.
7.0
5.8
4.6
5.8
18.8
8.1
.31
**
0.260
0.187
1.560***
0.179
0.100
0.100
0.100
0.006
0.005
**
0.120
0.038
0.660***
0.512***
0.006
0.070
0.060
0.080
0.060
0.002
0.008
**
-**
2.13
1.73
4.11
 *  Estimated values;  refer to  text  for  method  used.
 ** Emission rate considered too small
    to factor into the analysis
*** Estimated by mutiplying the average  percent distribution  of the  reported
    congener in tests  4A and 5A by  the  homologue in which  the  unreported
    congener is grouped.
-------
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                                               TABLE 3

                 CALCULATION OF STACK EMISSION RATE (MICROGRAMS/SECOND) OF 2378-TCDO
                EQUIVALENT CONCENTRATION OF CDDs/CDFs DURING THE OPERATION OF UNIT 2
Congener
2378-TCDO
Other TCDDs
1,2,3,7,8-PeCDD
Other PeCDDs
1,2,3,4,7,8-HxCDD
*l,2,3,7,8,9-HxCDD
*l,2,3,7,8-HxCDD
Other HxCDDs
1,2,3,4,6,7,8-HpCDO
Other HpCDO
2378-TCDF
Other TCDFs
1,2,3,7,8-PeCDF
2,3,4,7,8-PeCDF
Other PeCDFs
1,2,3,4,7,8-HxCDF
*l,2,3,7,8f9-HxCDF
1,2,3,6,7,8-HxCDF
*2,3,4,6,7,8-HxCDF
Other HxCDFs
1,2,3,4,6,7,8-HpCDF
1,2,3,4,7,8,9-HpCDF
Other HpCDFs
TEF
1
.01
.5
.005
.04
.04
,04
.0004
.001
.00001
.1
.001
.1
.1
.001
.01
.01
.01
.01
.0001
.001
.001
.00001
Test
1A
0.14
4.26
1.10
8.90
2.50
2.50
2.50
10.50
3.30
•**
0.35
6.55
0.39
0.52
9.09
2.50
1.38
0.25
1.38
12.49
4.40
0.35
*•*
TCDD
Equiv
0.140
0.043
0.550
0.045
0.100
0.100
0.100
0.004
0.003
**
0.035
0.007
0.039
0.052
0.009
0.025
0.013
0.003
0.013
0.001
0.004
**
**
Test
2A
0.28
8.62
2.20
22.80
1.40
1.40
1.40
7.80
2.80
**
0.76
17.24
2.40
2.40
19.20'
1.60
1.60
1.60
1.60
**
**
0.48
*•*
TCDD
Equi v
0.280
0.086
1.100
0.114
0.056
0.056
0.056
0.003
0.003
**
0.076
0.017
0.240
0.240
0.019
0.016
0.016
0.016
0.016
**
**
0.001
•**
Test
3B
0.17
3.83
1.10
12.90
1.50
1.50
1.50
8.50
3.40
**
0.52
10.48
1.05
2.10
11.50
1.20
1.90
2.60
1.90
**
2.3
**
*•*
TCDD
Equi v
0.170
0.038
0.550
0.066
0.060
0.060
0.060
0.003
0.003
**
0.052
0.011
0.105*
0.210
0.012
0.012**
0.019
0.026
0.019
**
0.002
**
**
                   2378-TCDD Equivalence:
1.29
2.41
1.48
             *  Estimated values
             ** Emission rate considered too small  to  factor  into  the  analysis
            *** Estimated by multiplying the average percent  distribution  of
                the reported congener in tests  1A and  2A  by the  homologue  in
                which the unreported congener is  grouped.
-------
modeling results were provided  as  input  to  the  risk  assessment.  The Human
Exposure Model  (HEM) was used for  the computation  of estimates of maximum
individual  lifetime excess  cancer  risk,  and the  estimated annual cancer
incidence in the population living within a 50  km  radius of the  incinerator.
Table 4 summarizes the results  of  this analysis.   The lifetime excess
cancer risk to the most exposed individuals is  estimated to be about 5
chances in  100,000 (5 x 10~5).   The upper limit  excess annual cancer incidence
is estimated to be about 0.07 cases per  year (or about 1 case every 14
years) in the exposed population of 5 million living within 50km of the
Philadelphia NW incinerator.

     The City of Philadelphia operates a second  municipal incinerator,
Philadelphia East Central  incinerator (ECI) located  13 kilometers southeast
of the Philadelphia NW (NWI)  incinerator.   This  incinerator has  not been
stack tested for emissions  of CDDs/CDFs. However, the two incinerators are
of similar  design, and are  operated in a similar manner, and, therefore, EPA
Region III  has requested that estimates  of  emissions  and risk be made based
solely on measured emissions  of CODs/CDFs at the Philadelphia NW incinerator
(NWI).  To  estimate a mass  emission rate (grams/second) of 2,3,7,8-TCDD
equivalence at ECI, an assumption  was made  that  the  ratio of the emissions
from the ECI to the emissions from the NWI  would be  equal to the ratio of
charging rates of the two incinerators.  The charging rates of the two
facilities  were 300 tons/day  and 340 tons/day for  ECI  and NWI, respectively.
From this ratio it is assumed that the emission  of 2,3,7,8-TCDD  equivalence
from the ECI is approximately 88%  of the measured  emission of 2,3,7,8-TCDD
equivalence at NWI.  Therefore  the estimated emission rate of 2,3,7,8-TCDD
equivalence is about 3.9 ug/s at ECI.

     The estimated maximum  annual  ground level  concentration of  2,3,7,8-
TCDD equivalence in the vicinity of ECI  is  0.7  picograms/nP.  This corresponds
to an estimated maximum lifetime excess  cancer  risk  to the most  exposed
individuals of about 2 chances  in  100,000  (2 x  10'5). The upper
upper limit excess annual  cancer incidence  is estimated to be about 0.06
cases per year (or about 1  case every 17 years)  in the exposed population
of 5 million living within  a  50 km radius of the incinerator.

     Estimates of the risks associated with CDD/CDF  emissions from both the
ECI and NWI operating in the  City  of Philadelphia  were made on the basis of
combined impact.  The estimated maximum  annual  ground level concentration
resulting from the combined impact of 2,3,7,8-TCDD equivalence from ECI and
NWI is about 1.4 picograms  2,3,7,8-TCDD  equivalence  m^ of air.   The
estimated maximum lifetime  excess  cancer risk to the most exposed individuals
is about 5 chances in 100,000 (5 x 10"^).   The  upper limit excess annual cancer
incidence resulting from the  combined impact of  CDD/CDF emissions from ECI
and NWI is  estimated to be  about 0.12 cases per  year (or about 1 case every
8 years) in the exposed population of about 5 million people living within
a radius of 50 km of the incinerators.

     This memorandum is intended to present a summary of the risk assessment.
The reader is referred to the emissions  test report  for descriptions of
analytical  and test protocols used to estimate  emissions of CDDs/CDFs  (MRI,
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                                  TABLE 4
             Maximum Individual  Lifetime Risk  At Receptor Where
              Residences Could Be Located,  Including Expected
               Annual Cancer Incidence Within  The Population
          Residing Within 50 km of the Philadelphia  NW Incinerator
       x             /  »                                ,  x       Annual
       )'     Distance(b)                  Max  Individual (c>       Cancer
(pg/m3)        (km) _   Direction      Lifetime  Risk           Incidence

  1.40         0.85            NE            5.0  x  1Q-5              0.07
(a)  MAAGL = maximum annual  ground  level  concentration  of 2,3,7,8-TCDD
    equivalence at receptor where  residences  could  be  located.

(b)  Distance MAAGL is  from  source.

(c)  Maximum individual  lifetime  risk  of  cancer  resulting from continuous
    70-year exposure to (a),  based  upon  the unit cancer risk estimate
    for inhalation exposure to 2,3,7,8-TCDD of  3.3  x lO"5  (pg/m3)'1
    as  derived  by  assuming  100%  of  2,3,7,8-TCDD is  adsorbed onto particulate;
    75% of the  inhaled  particles are  absorbed into  the human system; a
    breathing rate of  20  m^ of air/day  for a  70 kg  person.  These assumptions
    factored with  the  carcinogenic  potency slope of 1.56 x 10^  (mg/kg-day)"^
    for 2,3,7,8-TCDD equals the  unit  risk estimate.

(d)   Annual  incidence  is  the aggregate  of risks from PCDD/PCDF  exposure to
     people living within the vicinity  of the plant expressed as the number
     of cancer  cases expected per year.  There  are  5 million people residing
     within 50  km  of the  incinerator.
-------
                                     10
Emission Test Report:   City  of Philadelphia Northwest and East Central
Municipal Incinerators.  Vol  I - Technical Report.  EPA Region III. October 31)

cc:   R. Campbell
     L. Felleisen (Region  III)
     S. Garg (WH-565-E)
     6. Kellam
     E. Li 11 is
     J. Mil liken  (WH-562A)
     J. O'Connor
     D. Patrick
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R-585-11-M1
A FIELD TRIP REPORT FOR
NORTHWEST INCINERATOR DIOXIN SCREENING
PREPARED UNDER
TDD NO. F3-8410-02
EPA NO.
CONTRACT NO. 68-01-6699


FOR THE
HAZARDOUS SITE CONTROL DIVISION
U.S. ENVIRONMENTAL PROTECTION AGENCY
FEBRUARY 11, 1985
NUS CORPORATION
SUPERFUND DIVISION


SUBMITTED BY REVIEWED BY APPROVED BY
/I/ 7 / ./^ i //y

ANDREW FREBOWITZ WILLIAM WENTWORTH GARTH GLENN
ENVION. ENGINEER ASST. MANAGER, REPORTS MANAGER, FIT III


•8 *>*"•*__
.L/c. t <^
-------
                                            Site Name: Northwest Incinerate
                                            TDD No.: F3-8410-02
                     TAoLE OF CONTENTS
SECTION

 1.0       INTRODUCTION
 1.1       AUTHORIZATION
 1.2       SCOPE OF WORK
 1.3       SUMMARY

 2.0       FIELD TRIP REPORT
 2.1       SUMMARY
 2.2       PERSONS CONTACTED
 2.2.1     PRIOR TO FIELD TRIP
 2.2.2     AT THE SITE
 2.3       SYNOPSIS OF DAILY EVENTS
 2.4       SAMPLE LOG
 2.5       SITE OBSERVATIONS
 2.6       PHOTOGRAPH LOG

APPENDICES
                                          PAGE

                                           1-1
                                           1-1
                                           1-1
                                           1-1

                                           2-1
                                           2-1
                                           2-1
                                           2-1
                                           2-2
                                           2-3
                                           2-5
                                           2-6
 A

 6
1.0  COPY OF TDD

1.0  MAPS/SKETCHES
1.1  SITE LOCATION MAP
1.2  ON-SITE SAMPLE LOCATIONS
1.3  OFF-SITE SAMPLE LOCATION
A-l

6-1
                              u
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•                     .         ...           SECTION!
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                                                      Site Name: Northwest Incinerator
                                                      TDD No.: F3-S410-02

1.0 INTRODUCTION
                                                                                    t
                                                                                     *
1.1 Authorization
                                                                                    •
NUS Corporation  performed  this  work under  Environmental  Protection  Agency
Contract No.  68-01-6699.   This specific report was prepared in  accordance  with
Technical Directive Document No. F3-8410-02 for  the Northwest Incinerator site
jocated in Philadelphia, Pennsylvania.

1.2 Scope Of Work

NUS FIT III was tasked to conduct  a dioxin screening at the Northwest Incinerator
site, and to conduct an off-site sampling within a 2-kilometer radius of the site.

1.3 Summary

The  Northwest  Incinerator  is an  active  incinerator  used for the  reduction  of
municipal solid  waste  from  the city  of  Philadelphia.   The  site is owned and
operated by the  city of Philadelphia.  The incinerator consists of 2 burner units
designed to reduce waste volume by 85 percent.  Furnace no.  1 was shutdown for
rebricking on  October 12,  1984; however,  furnace  no.  2 is inoperation.  Each unit
has emissions  controlled by electrostatic precipitators (ESP).   The incinerator fly
ash is collected  and mixed  with the reduced waste, bottom ash.  The ratio of ESP
fly ash to bottom ash is 1:250.

The  residue  is  collected and stockpiled  on  site.   The  pile  under  investigation
consists of 200,000 cubic yards of residue, approximately 1 year's accumulation.
Residue from  the City of Philadelphia's East-Central Incinerator is also stored  at
the Northwest Incinerator pile.  The city of Philadelphia contracts for the  removal
and disposal of the waste pile.                                                        «»

The analysis of samples of ESP fly  ash  taken in August 1984, revealed the presence
                                                                                    •
of 2,3,7,8-TCDD (dioxin).  The levels of dioxin in furnace no. 1 fly ash were as high
as 28.2 parts  per  billion (ppb).  The  concentrations of dioxin in  furnace no.  2 fly
ash ranged from 3 to  5 ppb.

                                      1-1
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                                                      Site Name: Northwest Incinerator
                                                      TDD No.: F3-8410-02
FIT III conducted a sampling of the waste pile and bottom ash and  tiSP fly ash from

the operating burner (furnace no. 2).  In addition, off-site samples were collected

within a  2-kilometer  radius  of the  site, at locations determined by  an EPA

meteorological  study.   All samples were collected  and processed in accordance

with established protocol.

-------
SECTION 2
-------
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                                                      Site Name: Northwest Incinerator
                                                      TDD No.: F3-S410-02
2.0 FIELD TRIP REPORT


2.1 Summary



From Tuesday, October  16 through Thursday, October  18, 1984,  NUS  FIT  III staff

members  Andrew  Frebowitz, 3effery Case, Michael  Nalipinski,  Thomas  Pearce,

Charles Meyer, Mark  Volatile,  James Strickland, and  Robert Howell  visited  the

Northwest Incinerator site to conduct a dioxin screening.  Weather for the duration

of the sampling was clear and  mild  with  morning low temperatures of 55°F  and

afternoon highs near 70°F.



The  team collected 38  on-site samples; 32 samples  were from the  waste pile,

including  3 samples from a  4.5 foot trench dug into the top of the  pile by  the

Philadelphia  Streets Department.   Three samples each were  collected of bottom

ash and ESP fly ash. Off-site sample were collected from 38 locations   within a 2-

kilometer radius  of the  site.   Split  samples were  processed and custody of  the

samples was  given  to the New Jersey Department of Environmental Protection (3

on-site samples) and to the city of Philadelphia (all samples).



2.2 Persons Contacted
2.2.1  Prior to Field Trip
    Walter Lee
    EPA Region III
    Sixth and Walnut Streets
    Philadelphia, PA 19106
    (215)597-6623
    Richaro Zipin
    City of Philadelphia
    of Public Health
    500 South Broad Street
    Philadelphia, PA 19146
    (215) 686-5151
Al Cimorelli
EPA Region III - Meteorologist
Sixth and Walnut Streets
Philadelphia, PA 19106
(215) 597-6563
Bruce Gledhill
Philadelphia Streets Department
Municipal Services Building
15th and 3FK Boulevard
Philadelphia, PA
(215)686-5554
                                                      2-1
-------
                                                     Site Name: Northwest Incineratoi
                                                     TDD No.: F3-8410-02
2.2.2  At the Site

    Walter Lee
    EPA Region III
    Sixth and Walnut Street
    Philadelphia, PA 19106
    (215)686-5131
    Richard Zipin
    City of Philadelphia
    Department of Public Health
    500 South Broad  Street
    Philadelphia, PA 19146
    (215) 686-5151
    William Lowry
    Senior Environmental Specialist
    N3DEP
    8 East Hanover Street
    Trenton, NJ
    (609)  984-3068
Bruce Gledhill
Philadelphia Streets Department
Municipal Services Building
15th and JFK Boulevard
Philadelphia, PA
(215) 686-5554

Charles Elmendorf
Senior Environmental Specialist
New Jersey Department of Environmental
Protection (N3DEP)
8 East Hanover Street
Trenton, NJ
(609) 984-3068
                                      2-2
-------
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                                                                       Site Name: Northwest Incinerator
                                                                       TDD No.: F3-8410-02
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2.3 Synopsis of Daily Events
 Date:
 Weather:
 Personnel:
 October 16,
 Clear, 60-70°F
 FIT  III:  Frebowitz,  Case,  Nalipinski,  Volatile,  Meyer,
 Strickland, Pearce, and Howell
 Other:  Lee, Elmendorf, Lowry, Gledhill, and Zipin
Activities:
      7:15 AM
      7:15-7:50 AiM
      8:15 AM
      8:ftO AM
      9:50 AM
      1:00 PM
      1:30 PM
 FIT III arrived on site
 Command post set up
 First team downrange; sampling begins
 Hot line declared; blenders in
 Janet Luffy (EPA), Channels 3 and 6 arrived on site
 Sampling ends
 Blenders out; equipment breakdown, leave site
All waste pile  samples,  except Trenches A-C, were collected.   ESP fly ash and
bottom ash samples were also obtained.
Date:
Weather:
Personnel:
October 17, 198*
Clear and cool, 55°F; afternoon highs of 70°F
FIT   III:  Frebowitz,   Case,  Nalipinski,   Volatile,   Meyer,
Strickland, Pearce, and Howell
Other:  Lee and Zipin
Activities:
     7:<*0 AM
     7:^0-8:00 AM
     8:10-1:25
     9:05 AM
     1:^5 PM
     2:00 PM
FIT III arrived on site
Command post set up
Off- and on-site samples collected
Hot line declared; blenders in
Blenders out; equipment breakdown
Team off site
                                                      2-3
-------
                                                     Site Name: Northwest Incinerator
                                                     TDD No.:  F3-8410-02
Twenty-six off-site samples collected.  Trench samples A, b, and C collected.  ESP
no. 2 and bottom ash no. 2 obtained.
Date:
Weather:
Personnel:
October IS,
Cloudy, 55-6QQF
FIT  III: Frebowitz,  Case,  Nalipinski,  Volatile,  Meyer,
Strickland, Pearce, and Howell
Other:  Lee and Zipin
Activities:
     8:05 AM
     8:05-8:30 AM
     8:10-11:50 AM
     11:05 AM
     12:35 PM
     12:45 PM
FIT III arrived on site
Command post set up
Off- and on-site samples collected
Hot line declared; blenders in
^lenders out; equipment breakdown
Team off site
Twelve off-site samples were collected.  ESP no.  3 and  bottom ash no. 3 samples
were also collected.
        136-
                                      2-4
-------
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-------
                                                      Site Name: Northwest Incinerate
                                                      TDD No.: F3-S41Q-Q2
2.5 Site Observation
    o   The site  is active.  Furnace no. 2 is operating,  while  furnace no. 1 is
        shutdown for repairs.

    o   Residue is stockpiled on site.

    o   Residue from  the East-Central Incinerator is also stored on site.

    o   The waste pile was approximately 200  feet  by  4-00 feet.  Its  maximum
        elevation was 80 feet.

    o   The slope of the waste pile was approximately 30 to 40 percent.

    o   Waste material in the pile consists of  burnt metal and glass and compacted
        ash.  Paper, which  was not destroyed by the incineration process, was also
        seen in the waste pile.

    o   The pile is compacted by a bulldozer.
                                                                       •
    o   No HNU or mini-alert readings were recorded above background.

    o   There is a diversion ditch on the western side of the waste pile.

    o   The northern end of the pile extends to a rock wall.

    o   A water-treatment pond is immediately east of the pile.

    o   The site  is fenced  on  all but the northern end.  The  rock  wall prevents
        access from the north.

    o   Off-site samples were collected from  the city property (within 10 feet of
        the curb)  in  residential  areas.   Consent by  property  owners  was  given
        before collection of any samples from  private property.
                                      2-6
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-------
2.6  PHOTOGRAPH LOG

            Phoro 1  - Charles Mever collecting

            TP6A sample.                  e
                    ••--•*=-3 •• r-.v- "'----'^ '* '^v-f'r^jS.Ttt»^i'"<-«»';

                    ^^MS-^^^^®^1^^
                    •w£J#g$£*^-:.f ':^'<&*^g&
                     •4JS3, •>>'":*^'~^ --cr*->'?"*-•*Ti"l^r. «




                    ^l^^^^^^^*53^^«?au^«5:?i
            Phoro 2 - View of TP5A and TP5B

            samples locations.
                            _4B<
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Photo 3 - Sampling at locations TP4A and_
TP4B.
 Photo 4 - James Strickland collecting
 sample TP2A.
                                                      "1
                                                       &-
                             47<
-------
_   Photo 5 - Thomas Pearce and Chuc'  reye_r_
    at sample locations TP3A and TP3"'>
       •~^ ""x^.:.

    '"^^-c-r.^'^i''
    ^r^l^' >_-.„ *
         fjfl*'
  Photo 6 - James Strickland collecting
  TP1B sample.
-------
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    Photo 7 - Collection of samples S2A
~   and S2B.
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   Photo 8 - Sample locations S3A and
   S3B.
                                                    143-
-------
    Photo 9 - Sampling of East-Central
—   Incinerator residue.

    Photo 10 - Thomas Pearce collecting
    sample S4A.
-------
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    Photo 11  - Collecting samples S5A and
~   S5B.
       Photo 12 - Sampling at locations S7A
       and S7B.
-------
_   Photo 13 - Thomas Pearce collecting
    sample no. 7.
   Photo 14 - Jeffrey Case collecting sample
   no.  1 at Saul High School.
-------
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    Photo 15 - Surveying and collecting off-
~   site location no. 17.
     Photo 16 - Station no, 16, sampling 712
     Shawmont  Avenue.
                                                     153-
-------
~~  .Photo 17 - Off-site sampling location
—   no. 13.
  Photo 18 - Thomas Pearce collecting
  sample no. 21 at Schuylkill Valley Nature
  Center.
-------
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    Photo 19 - Thomas Pearce collecting
~~   off-site location no. 1 sample.
                             Photo 2C - Michael Nalipinski and Thomas"
                             Pearce at off-site location no. 2.
                                                             1
-------
                                                             -  ••>
                 Photo 21 - View of trench diprgins and
                 sampling. Taken from com.rKITnd cost.
156-
              —  Photo 22 - James Strickland collecting    —
              _  off-site sample no. 5 at Channel 57.  '     	
                 Incinerate: is in background.
-------
1








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   Photo 23 - View of command post and

   blending/decontamination area.
_  Photo 24 - View of sample processing.     	
                                                          -H c;i"H*«
                                                          JL«J a
-------
APPENDIX A
-------
I
          COST CENTER:
        ACCOUNT NO..
                                               REM/FIT ZONE CONTRACT
                                         TECHNICAL DIRECTIVE DOCUMENT (TOO)
                                                                             2. NO,.
                                                                                  F3-8410-02
        3. PRIORITY
               HIGH

               MEDIUM

               LOW
                 4. ESTIMATE OF
                   TECHNICAL HOURS:

                         450*
                 4A. ESTIMATE OF
                    SUBCONTRACT COST:
   5. EPASITEID
   5A. EPA SITE NAME:
    Northwest Inclnerajor
                                                     Roxborough, PA
6. COMPLETION DATE:
                                                              4 wks after field
                                                              work	
7. REFERENCE INFO..

   QYES  QNO
     ATT ACHED
                                                                                            Contact Waltei
        8. GENERAL TASK nFsrmpTiriN-    Perform dloxin sampling at the subject site (enforcement support)
       9. SPECIFIC ci EUCMTC-  1.)  Obtain all available background information from EPA.

           2.)   Perform field recon of site to determine sample locations.	
           3.)
	All sampling to be performed according to the most recent dloxin protocol

	as written by EPA Region VII.	

4.)   EPA (Walter Lee) will coordinate lab analysis.	

5.)   Triple splits will  be provided for all on site samples. Doable splits wfll be
	provided for all off site samples.	
6.)   Maintain chain of custody for all samples.	
7.)   Document all sampling and related  activities.	
8.)   Drum for proper  disnosal  all contaminated clothing and materials, drums
                                                                                10. INTERIM
                                                                                   DEADLINES:
       11 DESIRED REPORT FORM:          FO RMAL REPORT Q
           w'll remain on site, EPA will arrange.
           9.)   EPA w:.l arrange for spiked samples.
        OTHER (SPECIFY):	
                                                  LETTER REPORT
                                   FORMAL BRIEFING
           10.)  Prepare and submit field trip report including photo documentation.
                Coordinate activities with Walter Lee.
                   'Authorized overtime for field sampling if needed.
        13. AUTHORIZING RPO:
                                                                            14. DATE:
        15. RECEIVED BY:
                                     ACCEPTED WITH EXCEPTIONS
                                   (CONTRACnTRRPM SIGNATURE)
                                                                           REJECTED
                                                                            16. DATE:
                      She«t 1
                      ShMt 2
                    White - FITL Copy
                    Canary - DPO Copy
Sheet 3    Pink - Contracring Officer's Copy (Wajhington. D. C. )
Sheet 4    Goldenrod - Project Officer's Copy (Washington, D. C. )
-------
     APPENDIX B
1&0<
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                                  ./  .j  I  J?ss  3
                                  , • i f&'XZtT   I     * ,'> .
                                              ,.  (WPBS-TV).f ,-

                                              '         'r"   -C^  «•  -^
                                              -' ' A'lBflTv'l 4   "' ..;. *  "i
                                               "—.=-.   - Piaygronruv
                                                                    .   -V fct.  3^-^
                                                                   ^1"  *^r c«w
                                         MOO    3000   4000   MOO    MOD    7000
SOURCE:(7.5 MINUTE SERIES) USGS GERMflNTOWN a NORRISTOWN, PA QUADS.

                    SITE LOCATION  MAP

       NORTH WEST PHILA. INCINERATOR, PHILA., PA.

                       SCALE  1:24000
FIGURE
CXDF=»=)CDRATON
                                                                A Halliburton Company
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MAINTENANCE
 BUILDING
      ON SITE SAMPLE LOCATION
NORTH WEST PHILA. INCINERATOR, PHILA.,PA.
               (NO SCALE)
                       CORPORATOR
                     A Halliburton Compan
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                                                i v   f*.   _~" j^3^.
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                                                     -'
         1000
                200C
                            3000
•4000
5000
6000
'000 FEET
        OFF SITE SAMPLE LOCATIONS
NORTH WEST PHILA. INCINERATOR,PHILA.,PA.
                                              CORPCFlAnC
                                            A Halliburton Compa
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                                                                                     DEC 27'
                     UNITED STATES ENVIRONMENTAL PROTECTION AGENCY
                                       Region III - 6IH 4 Walnut SIS
                                        Philadelphia, Pa 19106


            EPA Laboratory Analysis
SUBJECT:    Dixoin Concentration - Ash Storage                       DATE:
            Philadlephia NW Incinerator


FROM:      Robert Kramer, Coordinator   ;
            NSWS (3ESOO)                 \


TO:         Bruce Smith, Chief
            Hazardous Waste Enforcement Branch (3ES10)


            Ray Cunningham, Director
            Air Management Division (3AMOO)
                 Attached are the analytical results  of  dioxin  concentration.
            The analytical results have been quality  assured and can.be used
            to answer all questions regarding dioxin  concentration.


                 Please note that eight sample results are being provided instead
            of the nine that were planned.   Sample  location S7B  (Sample //DC009702)
            wasn't sent to the EPA labs for analysis.
                                         164-
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                                                       DEC I 7 1984
-Ms. Georgi Jones   ,           .   \ . .:  .
'Chamblee 28 S      - -   .--                                     -
 Poom 9 , S.I .G.
 Center for Disease Control
 Atlanta. GA  30333

 Dear Ms. Jones :

      As a follcwup to our telephone conversation  on December
 13, 1984, the  information you requested  regarding Phi ladelprua1 s
 incinerator ash disposal site and material  characteristics
 are presented below:

      Waste Characteristics - The majority of  combined bottom ash
 and flyash samples from the Philadelphia Northwest and East-
 Central Municipal 'Incinerators are expected to  yield non-
 detectable levels of dioxin.  There is a possibility that sone
 samples may be in the range of very low  concentrations not to
 exceed 3-5 ppb of 2,3,7,8 TCDD.

      Expected Information on Disposal Site  -

      Facility Name:  Sanitary Landfill Company, Inc.
           PA  15fl62
      facility Location:  v»«~ straoreland County,  PA

      PA Dept. of Environmental Resources Landfill  Pern it  »100277
      Landfill Fng inoer ing C^sractt-r i st ics :  Ncitjral  cl-iy  1 inr.t
 with a pecniiabi 1 i ty of 10~  CTI/S^C. gravity flow  ieachats
 collection system with i r-t^rc^^ t ion , tr*-atp>.-?nt  and "' isc^artjfc .


      Please not^ that other landfills with similar eng inhering.
 character istiacs are being considered as possiole ctisfosal  sides,
                                                              /
      In addition, I nave enclosed information coll«.-cted duri'ng  oth
 municipal incineratcr stucUes dealing with measurements of  dioxin.
      ^%"-?n though w.-> do not h^vu th^ final dioxin asn  sample  rssults
 tor  the Northwest and East-Ce-ntral Incinerators, we  tuli^  expect
 those sajnples to be within the range stated abov^.            •  \'
      As  we  discuKsea durir.ij o'jr telepnorio conversation or
 13,  1984,  I ask  that you consider tris inronaation during  your
 health assessn*>r. t subject to verification when additional  ash   '  N
 ?djr\ples  (9) become availaM- during th«> week of Decenoer 23, 19')4.">-
 I ^ at all  possible, we wculd appreciate your response by December ;V
 1^ .  1984.                                        "               • {
-------
-------

     If you have further questions concerning either the information
presented in this correspondence or the sample results when they
become available, please do not hesitate to call W. Pay Cunningham
(215/597-9390) or me at (215/597-9812).

     EPA appreciates your cooperation in this matter.

                                  Sincerely,
                                  Stanley L. Laskowski
                                  Deputy Regional Administrator

Enclosure
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      facility
Ccnbined results
of 5 municipal
incinerators
        Typical
  Stack Concentration
        ng/dson
                    Total TCDD
N.D.- 8.5
            2,3,7,8, TCDO
N.D. - 3.5
                2,3.7,8, TCDD       |
              Flyash Concentration,  |
                     ppb      _      |
Hot EJetormined
                             Total TCDD
                         Flyash Concentrati
                                ppb
Not Deterrained
VA incinerator
240
 50
1.4 - 2.9
   170
Incinerator C
                             2.0
                                             7.3
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                                                           ,  PubNc Ke:lih,£\.'rvic8,(

DEPARTMENT OF HEALTH L HUMAN SERVICES	^ ^D^*^

                                                             Memorandum
December 26, 1984
Aaeistent Administrator
       for Toxic Substances and Disease
Review of Horthwost Incinerator Dioxin Screening Results of Ash Pile
Philadelphia, Pennsylvania

Charles J. Walters
Public Health Advisor
KPA Region III


As requested, the Center for Environmental Health, Centers for Disease
Control has reviewed the subject data provided on Deceaber 26, 1984, on the
torthvsst Incinerator to determine if the concentrations detected would
prohibit movement and storage of the ash in the landfill as described in the
eowaanication from Stanley L. Laskowski, Deputy Regional Administrator EPA
d*ted December 14, 1984.

It is our understanding that the level of detection used in the analysis of
the specimens was 20 parts per trillion 
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                                                                    Public Health Service
          EPARTMENT OF HEALTH A HUMAN SERVICES                        Aa«ncy for Tox* Substances
                                                                      and Disease Registry

                                                                    Memorandum

Dan     December 26,  1984


From    Assistant Administrator
        Agency for Toxic Substances  and Disease Registry

Subject   R,vi»w of Northwest Incinerator Dioxin Screening Results  of Ash  Pile
        Philadelphia,  Pennsylvania

To      Charles J.  Walters
        Public Health Advisor
        KPA legion HZ


        As requested,  the  Center for Environmental  Health,  Centers for Disease
        Control has reviewed the subject data provided  on December 26, 1984,  on  the
        Vorthwest Incinerator to determine if the concentrations  detected  would
        prohibit movement  and storage  of the ash in the landfill  as described in the
        comnunication from Stanley L.  Laskowaki, Deputy Regional  Administrator EPA
        dated December 14, 1984.

        It IB our understanding  that the level of detection used  in the  analysis of
        the specimens  was  20 parts per trillion (ppt) of 2,3,7,8  TCDD  and  that usual
        and customary sampling and analytical procedures were used.  We  further
        understand that full quality control and quality assurance checks  have been
        successfully  passed.

        Given the values ranging from  non-detect to 89  ppt  of 2,3,7,8  TCDD we do not
        feel that a significant  public health threat will be posed by  the  dioxin
        utilizing the  proposed disposal plan,   this assumes that  the usual
        compaction and cover practices at the sanitary  landfill are maintained.
                                                       Houk, H.D.
                                                            r~<
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                                          1 "J
  Ci <:>' of  Philade 1 ph. i,-j
  Room 154O  MSB
  Philadelphia, PA  I"l0e
                                                               '/
                                                                        L.JI''r"1
     dvicaster  Caboratones
                                                      .LI
                                                              I
                                                     D .-., t ,= p e r-> o r t .---- r|
                                                     D^le llutjmv 1: f-c-'d
                                                     D i  sc.j rd  l~J--it.=
                                                     p . n . r IG .
                                                     Collected  by  i" 1 I/--D t
                                                              1 .-? / 1 4
                                                              1 ^/ i 0
                                                               L •' 14
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 EP Toxicity Leachats of Solid  Wact>
 Collected on  13/10/84  (0830) by BG

5                       AS RF.CF.T'.'En
ANALYSTS

PH
Ammonia Nitrogen
Oil  .?/. Grease
PhRnolics
An**" imony
Arsenic
Ba r i urn
5
1
2
0
0
i "*,
Q
"0
0
0
1
r.
O
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0
o
•'U
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£0
.07
1>
.
. 007
.004
.'X>'i
. !•>
.571
.05
.°B
.7?
. OO 1
. L
. S'j
. 1
.01
. 7
.02
.

m^
mg
1 1 r 4
mg
TTi-J
mg
m-j
mg
m aval en'. C h rom i UTTI
  Total Org. Halogen
The  above analyses  U)I:-T>=> performed  an  ^n
submitted waste prepared according to tt
Federal  Register    Ma/ 1'"? 19HO   P. 33127.
Leachate Preparation:
     1SO.O grams uaste  / 2400 ml  distilled uia t-e r
      Initial pH = 3.07        324  ml  of 0.5 N Acetic Acid 'jar.  u-ed
       to maintain the  pH at 5.0    Final,  volume was.    3000 ml.
The  characteristic  of  EF Toxicity  is  d*=termin&-d  t:/  whet her :.n/ of  th>~
contaminant concentrations (mg/1)  \n  thp? l^cichat? eiceed thi= t-'o I It .iui n-^
maxima  ( 10O X's Primnry Drinking Water "^tand -ir -\-~ •> •      Arsenic S.O;
 Barium  IOO.Q; Cadmium l.O; Chromium  5.O; Lead 5.0    ;  Mercury 0. r:;
 Selenium 1.0; Silver   5.0; flndrin O.OcJ Liddane O.4;  Mf-->thox/chlc-r  10
 ToxTphene 0.5; 2,4-D  1O.O; 2f4,c>-TP  l.O
rhp»  tbove analyses  indicate th^it the  ••>( il'tni *• t^-d s.^mpl-3 l.)Ot-.S Ni.VI r'-pj  =r.pt.'Ci tritr'"l  :. n
SEE REVERSE SIDE FOR EXPLANATION OF SYMBOLS AND ABBREVIATIONS

   '  •  ' -  •    Continued on P.-jqir? c:
                                              i rS^roduced Horn
                                               best availablecopy_
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                                      ANALYSIS REPORT

L-jiiLLister  Laboratories
  City of Philadelphia
  Room 1540 MSB
  rhiladplphiar PA '  191.OS
          EP Taxi city  Leachate of Solid W«=5t
          Collected an 12/10/84 (0830) by BG

  ANALYSIS                       AS RECEIVED
  1 COPY-TO   City  of  Philadelphia
                                                     i L T ':-I..iiup 1 e MI j .  TL
                                                0 -:.. 1- < ^> r.u t?m 1 1: •* ecJ   I ::: /' 1 C-
                                                0 t =C,T rd D %-;:,-      I •' ] 4
                                                P .  0 . No .
                                                Ojl 1 r .,-- l,-.,l h .-  •". 1 i.-.n-i:
                                                               I..AC CD
                                          Attn:  Mr.  T/ler Wren  1'Jep  Ci
SEE REVERSE SIDE FOR EXPLANATION OF SYMBOLS AND ABBREVIATIONS
                                            PL '^F--?-: t f i.i
                                            P f • .' i L--IU ~-f1  a i >
                                             ; . l-Ji L -,r)n  ! !
                                            T n v i r '-tur.i--n t
                                                               si it 'in i i i .--d
                                                              ii , i • i 1 i -ir i - • -: ,


                                                               Apr- r >." •. i- ' I t .
                                                              - -I ,>- ,  t-| /; . r
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•                                                         TASK FORCE REPORT
                                                         JANUARY, 1986
*
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  NORTHWEST INCINERATOR

OPERATING PROCEDURES AND

     CONDITIONS STUDY
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                                    TABLE OF CONTENTS

                                                                       Page
        INTRODUCTION	      1


        PURPOSE AND SCOPE	      2


        TASK FORCE ORGANIZATION	      3


        FINDINGS


 I
             Agency Records Review    ........      4

             Plant Records Review .........      6

             On-Site Observations .........      9

             Literature Review    .........     13
I




        RECOMMENDATIONS	15


•      REFERENCES       	18


I      APPENDIX A - OBSERVATION PROCEDURES	A 1


I      APPENDIX B - FACILITY DESCRIPTION	B 1


I      APPENDIX C - DATA AND CALCULATIONS	Cl
t

I

m                                              174
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                                    INTRODUCTION


The Northwest Incinerator was constructed in 1960. During the twenty-four years that this
facility has been utilized for trash disposal by the City of Philadelphia, air pollution control
efforts have been primarily directed toward reducing and maintaining the emission of
particulates and odorous gases to compliance levels.  Several fly ash collection and
combustion control improvements have been implemented to achieve this goal.

Numerous stack tests have been  conducted during the past ten years to determine
particulate emission  concentrations. Several of the reported results exceed the compliance
standard (.10 gr/DSCF at 12%  C02)- However, values obtained  during the most recent
particulate emissions testing, conducted in 1981, are well within the above standard.

Inspections, visible emissions observations and investigations of  odor and flyash complaints
have been routinely conducted by Air Management Services and intermittently by the
Pennsylvania Department  of Environmental Resources and/or the Environmental Protection
Agency, to evaluate the effectiveness of air pollution control measures. These activities
identified the need for the previously noted improvements and have indicated areas of
continuing concern - temperature fluctuations, equipment breakdowns, residue removal
problems, defective control panel gauges and the lack of continuous emission monitoring
equipment.

On  August  1 and 2, 1984, an EPA contractor conducted testing at the Northwest incinerator.
The testing included analysis of flyash samples to determine dioxin levels.  The dioxin
content of two samples taken from the unit #2 collector was higher than anticipated.

As a result of questions raised  by the above testing and prior environmental concerns, an
assessment of Philadelphia's trash incineration facilities  was undertaken in November, 1984.
The above assessment included an examination of operating practices related to air
contaminant emissions.

This report contains the findings  and recommendations resulting from the operating
practices examination.
                                                           -fi
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                                 PURPOSE AND SCOPE



PURPOSE

To evaluate operating procedures and process parameters related to:

1.   Oxidation/thermal destruction of combustible air contaminants

2.   Control of particulate emissions and odors

SCOPE

The study included the following activities:

Agency Records Review

Prior inspection findings, descriptions of equipment/operating modifications and stack test
reports contained in Air Management Services' and Department of Environmental  Resources'
files were reviewed to extract background operating practices/control information,

Plant Records Review

Plant records (temperature charts, draft charts, precipitator data and maintenance log)
covering operations during the third quarter of 1984 were analyzed to obtain a profile of
incinerator operating conditions and maintenance procedures.

On-Site Observations

Extensive on-site observations of  operating procedures and process conditions were
conducted on December 3, 1984 (night shift), December 4, 1984 (evening shift) and
December 5, 1984 (daylight shift). Data available from on-site instruments was
supplemented with volumetric flow measurements.

Literature Review

Reports of dioxin studies available in recent literature publications were reviewed to obtain
emission/control information pertinent to municipal incinerator operations.

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                           TASK FORCE ORGANIZATION
Primary Group

     William Thompson*
     Blaine DeHaven
     John Egan
     Norman Glazer
     Rao Kona
     John Knauber
     Doug  Lesher
     Hartwin Weiss
     Deborah Woltjen

Agency Records Review Team

     Rao Kona*
     James Keil
     Richard Ruhl

Plant Records Review Team

     Hartwin Weiss*
     Doug  Lesher

On-Site Observation Team

     John Egan*
     James Keil
     Doug  Lesher
     John Pitulski
     Diane Simini
     Deborah Woltjen

Literature Review

     John Knauber*
DER - Air Quality Control
DER - Air Quality Control
DER - Air Quality Control
Philadelphia - Air Management Services
DER - Air Quality Control
DER - Air Quality Control
DER - Air Quality Control
DER - Air Quality Control
EPA - Air Management Division
DER - Air Quality Control
DER - Air Quality Control
DER - Air Quality Control
DER - Air Quality Control
DER - Air Quality Control
DER - Air Quality Control
DER - Air Quality Control
DER - Air Quality Control
DER - Air Quality Control
Philadelphia - Air Management Services
EPA - Air Management Division
DER - Air Quality Control
*Coordinator
                                       - 3 -
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I.    AGENCY RECORDS REVIEW


     Finding #1 - During the twenty-four years that the Northwest Incinerator has been
     utilized as a trash disposal facility, several flyash collection and combustion control
     improvements have been implemented to reduce and/or maintain the emission of
     particulates and odorous gases to compliance levels.


     Discussion- The significant air pollution control initiatives that have been previously
     implemented are summarized below:


     Flyash Collection Improvements


     1.    Replacement of the original cyclone collectors with electrostatic precipitators.


     2.    Installation of baffles at the precipitator inlet to improve gas distribution.


     3.    Installation of additional water sprays between the combustion chamber and the
           cooling towers to improve furnace exhaust gas temperature control.


     4.    Rebuilding of  the gas cooling and drying towers to improve performance and
           reliability.


     5.    Development of a new Operation and Maintenance Manual for the precipitators.


     Combustion Control Improvements


     1.    Revision of operating procedures to avoid loss of the feed chute seal.


     2.    Installation of new furnace discharge chutes and an automatic water level
           control in the  quench tank to prevent combustion upsets resulting from loss of
           the discharge  chute water seal.


     3.    Relining of the furnaces to reduce air leakage and improve temperature control.


     In addition to the above, the electrostatic precipitators were  rebuilt to increase
     collection efficiency and taller stacks were erected to improve pollutant  dispersion.


     Trash and Residue Flow Improvements


     1.    Installation of warning lights to signal seal breaks in the feed hopper.


     2.    Modification of cooling tower bottoms to prevent water seal breaks.


     3.    Rebuilding of  the residue conveyors to reduce breakdowns.


     4.    Purchase of new residue trucks to improve residue loadout.


     Finding #2 - The results of numerous stack tests conducted during the past ten years
     to determine particulate emission concentrations indicate several exceedances of the
     compliance standard.


     Discussion - The results of particulate emission testing conducted at the Northwest
     incinerator since 1976 are listed in the table on the following  page.
                                                  - 4 -

                                                                        178<
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STACK TEST RESULTS
PARTICULATE EMISSION CONCENTRATIONS
Test Date(s)


June 22-24, 1976(D
Air Management Services


May 25 - June 1, 1978<1)
Air Management Services


December 19, 1978^)
Air Management Services
January 31, 1979^)
Air Management Services
June 28 - July 3, 1979^)
Air Management Services


December 1-8, 1980
Engineering Science



*August 5-7, 1981
Engineering Science
*Measured ESP efficiencies
**AMS STD. for compliance
Unit


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2

1
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2
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during these three
is .10 gr/DSCF at
(l)Incinerator operating data not available for








**Results at 12% CO 2


.0398 gr/DSCF
.0458 gr/DSCF
.0469 gr/DSCF
.0567 gr/DSCF
.1189 gr/DSCF
.1201 gr/DSCF
.3608 gr/DSCF
1.1500 gr/DSCF
.1367 gr/DSCF
.1100 gr/DSCF
.0443 gr/DSCF

.0484 gr/DSCF
.0478 gr/DSCF
.1045 gr/DSCF
.0355 gr/DSCF
.1034 gr/DSCF
.1074 gr/DSCF
.1560 gr/DSCF
.0471 gr/DSCF
.1008 gr/DSCF'
.0475 gr/DSCF
.052 gr/DSCF
.059 gr/DSCF
.039 gr/DSCF
(3) tests varied from 95.8% to 96.1%.
12% CO 2. (Reg. XI, Section III(a)>.
these tests.




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Finding #3 - Ambient odor problems have been significantly diminished.
Discussion - Improved housekeeping and general operations, e.g., better
of feed chute and residue discharge seals, have diminished odor problem
Very few odor complaints have been received since mid 1983.



maintenance
complaints.

Finding 14 - Measured concentrations of the 2,3,7,8-TCDD dioxin isomer in flyash
samples taken from the #1 furnace in early August 1984 were found to
expected.

be higher than


Discussion - The results of 2,3,7,8-TCDD dioxin testing conducted at the Northwest
incinerator on August 1 and 2, 1984 are summarized below:

LEVELS OF 2,3,7,8-TCDD IN ASH SAMPLES*

Date Furnace # 2,3,7,8-TCDD-pob
8/1 1 ' 28.2
8/1 2 3.2
8/2 2 3.4
8/2 1 16.7
8/2 2 4.4
8/2 1 23.0

*Taken from sampling and analysis report prepared by
Engineering Science.
II. PLANT RECORDS REVIEW

The following records were reviewed:
1. Circular Charts (Units 1 and 2, August/September/October, 1984)
- Furnace Temperature
- Precipitator Inlet Temperature
- Furnace Draft
- Inclined Stoker Speed
2. Precipitator Data (hourly readings, same period as #1 above)
- Primary Voltage
- Primary Current
- Secondary Current













J




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3. Preventative and Corrective Maintenance Log for 1982, 1983 and 1984
4. Operation and Maintenance Manual

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Finding 15 - During August, September, and October,  1984, the two units provided for
a combined 128 operating days (unit #1 was not operating for the second half of
October). Over 80% of the operating days (103) contained reports of a total of
320 upset conditions
                                                           Number of Occurrences

      1. Wet Rubbish                                                    82
      2. Hopper (jam-ups  or empty unrelated
         to crane operation)                                            80
      3. Crane Operation (malfunction or operator absence)                57
      4. Other (restarts, emergencies, fan problems, etc.)                  41
      5. Conveyor                                                       34
      6. Precipitator                                                    15
      7. Trucks                                                         11

        Total                                                         320

Discussion

The primary objective of the plant records review was to determine the type and
frequency of operating problems occurring at the incinerators. The data and
information contained in  this finding focuses upon the above parameters and should not
be interpreted as directly proportionate to the cumulative upset time resulting from
the widely variable duration of the identified upset conditions.

1.     Wet Rubbish Problems

      This problem,  accounted for more than a quarter of all upset  conditions. The
      operating log does not indicate efforts are undertaken to mix wet rubbish with
      dry rubbish. Operating adjustments are apparently not properly utilized to
      prevent or remedy combustion problems resulting from wet trash, e.g., the
      inclined stoker speed is not used to  compensate for unusual conditions by speed
      adjustments.  Instead, the stoker speed almost-always is maintained at a constant
      setting.  It is totally shut off when furnace temperature is too high which would
      cause gaps in the refuse  rather than a thinner bed.

      The following example illustrates the  problem.  Monday, August 6,  1984, start-up
      occurs for both units with wet rubbish, 1400°F is not reliably  reached for Unit #1
      in 17 hours and for Unit  #2 for 12 hours.  The incline stoker for #1  was shut down
      four times during the first two hours and ran for the remaining time between 64
      and 68 fph. The #2  incline stoker was shut down once during the first hour and
      rant at a constant 75 fph for the remaining time.

2.     Hopper Problems

      Upset conditions caused by low trash levels in the feed hoppers, empty feed
      hoppers and jammed feed hoppers were frequently recorded. The above
      conditions cause breaks of the feed  chute air seal and  voids on the furnace grate.

      Lack of trash in the  feed hopper indicates operator absence or improper use of
      the pit as a buffer.
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      Jamming problems were often reported to have been caused by large objects like
      refrigerators, metal doors, and other items which should be separated prior to
      charging. Stress to cranes and stokers caused by such objects will promote
      frequent failures of such mechanical equipment. The problem is compounded by
      the use of the crane grapple as a ramming device to force trash through the
      hopper.  The grapple has been reported stuck inside the  hopper. This condition
      aggravates the jamming problem and is potentially damaging to both the grapple
      and the hopper.

3.    Crane Operating Problems

      Cranes are recognized as being subject to frequent breakdown in this type of
      operation and,  therefore, require a great deal of preventative maintenance and
      care.  Crane problems will have an effect on the operation only in case of
      simultaneous breakdown of both units or  operator absence, both of which make
      this the third most frequent cause for upset conditions.

4.    Other Problems

      This area covers a variety of malfunctions {restarts, fans, emergencies, etc.).
      There were  21  occasions (other than after weekends) that an  incinerator had to
      be restarted after the fire  was allowed to go out. Restarts can give rise to
      excessive emissions of air contaminants.  Many of these problems appear to  be
      related to operational and maintenance practices.

      At the present  time, operational and maintenance practices are such that
      corrective action is frequently required after an unusual event has taken place.
      The records do not document that preventative actions (i.e., slowing of stoker
      speed in response to a decrease in temperature is at or~below criticaj levels) are
      undertaken.

5.    Conveyor Problems*

      A review of the operator logs indicates that three areas of concern need to be
      addressed relative to  residue conveyors.

      a.    Winter time  breakdowns are frequently caused by freezeups after weekend
           shutdowns.

      b.    On several occasions  unburned rubbish resulted in residue conveyor
           jamming problems. Wet  leaves are  frequently mentioned in  the logs  as
           culprits.

      c.    Jamming caused by large objects is similar to  that which causes feed
           hopper jammings and is often caused by the same objects.

6.    Truck Problems*

      These problems seem  to affect  incinerator operation when residue removal
      cannot take  place.  A disabled vehicle may block access or all vehicles may be
      disabled. The log books reveal a large number of breakdowns although only some
      cause operational pro'biems for the incinerator.
8
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 7.    Electrostatic Precipitator

      These units may be considered oversized or overdesigned and capable of full
      control of a normally operated incinerator. The records show a relatively high
      degree of reliability. The logs do not, however, substantiate that preventative
      maintenance as required by the compliance agreement plan is taking place.


      *As noted on page 4, the residue conveyor's were rebuilt and new residue tracks
      were purchased following the period covered by the plant records review.
      On 15 of the total 128 operating days reviewed, precipitator problems of one
      type  or the other were reported. Incinerator operations frequently continued
      during the time required to correct  the precipitator problems.  In August, the #
      precipitator "B" field was reported out  for up to 8 consecutive days. The
      incinerator appears to have been operated during most of the time the "B" field
      was down.
ON-SITE OBSERVATIONS

Finding f 6 - Operating conditions during the observed Monday morning start-up
(following the routine weekend shutdown) were Inadequate to achieve good combustion
and resulted in excessive visible emissions.

Discussion - The #1 furnace was restarted at approximately 12:40 a.m. on December 3,
1984 following the weekend shutdown.

Prior to lightoff, the auxiliary systems (induced draft fan, residue conveyors,
electrostatic precipitator, precipitator hopper heaters, insulator blower and flyash
conveyor) were activated.  Refuse was then fed to the charging hopper and the
inclined stoker was run until the refuse reached the discharge end.

There is a free fall from  the inclined stoker to the horizontal stoker of approximately •
3 feet. An opening below the inclined stoker discharge provides  access to this free fall
area. The opening is about 8' wide by 2' high and is equipped with two loose fitting,
free swinging  metal flaps.

For light off, the flaps covering the above opening were opened and crumpled
newspapers  were inserted on the horizontal stoker grate below the discharge end of
the inclined stoker. The  newspaper was set on fire to ignite the  refuse and the forced
draft fan was turned on with the inlet dampers set in an almost fully closed position.
The fire was allowed to spread up the inclined stoker before the  stokers were turned
on.

Refuse levels in the plants holding pits were very low.  Wet leaves were a major
constituent of the remaining material and, therefore, a large portion of the refuse fed
to the unit at startup and for several hours thereafter consisted of wet leaves.

In the early  stages of operation after  light off, the operator had  to continually check
the fire through the rear  view port and make adjustments accordingly.  The speed of
both stokers was gradually increased as was the volume of forced combustion air. The
ID fan modulated automatically to maintain a relatively constant furnace draft. The
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               operator started and stopped the inclined stoker and varied the speed of that stoker
  ._           numerous times between light off and 2:00 a.m., at which time the speed was fixed at
  •           66 feet per hour.
               The precipitator inlet  temperature reached 400°F within 20 minutes from light off and
f               within 40 minutes of light off the precipitator inlet temperature stabilized at
               approximately 560°F.  It required one hour and 10 minutes from light off for the
               Furnace to mnpratnpp tn rpar*h IJOftOF.

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               The average grate loading, based upon the 15.9 tons/hr. charging rate, was
               66.25 Ibs./ft.Z/hr. Assuming an  average refuse heating value of  4,400 BTU/lb., the
               calculated volumetric  heat release for the furnace was approximately
               15,000 BTU/hr./ftA These grate loading and furnace  heat release values are within
               accepted design limits for this tyoe of incinerator.  However, the above loading is
               considerably above the 40 Ibs./ft.Vhr. grate loading recommended by EPA in its "Field
               Surveillance and Enforcement Guide:  Combustion and Incineration Sources"
               (APTD - 1449, 1973, pg. 9-3).
               The most surprising observations were the thickness of the bed at the discharge end of
               the horizontal stoker and the large quantities of unburned and partially burned
                furnace temperature to reach

                One inspector observed the incinerator exhaust stack during startup. Darkness
                prevented reading accurate opacities, but it was observed that excessive smoking
                occurred during the first hour following light off.

                Finding #7 - Bulky and/or non-typical trash items were frequently charged to the
                incinerator.

                Discussion - Bulky and/or non-typical items, i.e., large pieces of furniture, mattresses,
                carpets, tires, etc. were frequently included in the refuse charged to the incinerator.
                Some  of these materials resulted in diminished burning of localized  areas of  the refuse
                bed and appeared to contribute  to the discharge of partially combusted and/or
                uncombusted materials  from the furnace grate.

                Finding #8 - Combustion of the refuse bed was observed to be incomplete and  the
                residue discharged from the furnace grates contained significant quantities of
                unburned and/or partially burned trash,

                Discussion - Failure to achieve  effective burnout of the  refuse bed appeared to be, in
                part, due to  the Limited mixing  action inherent in the grate design.  Observed charging
                procedures and stoker operating practices also appeared to contribute significantly to
                the burnout problem.

                The clam shell buckets used for charging have a 3 yard**  volume. However, it was
                typical for the bucket to pick up 1? times its closed volume. During the 3 days of
                observation, the  charging rate was 18.9 buckets/hr.  Plant records indicate that the
                average mass charging weight for the week beginning December 3, 1984 was
                15.9 tons/hr.  These values yield a trash density of approximately 560 Ibs./yd.^, based
                upon a 3 yard** bucket volume.  Given the >3 yard^ actual pickup volume, it is
                reasonable to conclude that the actual trash density was somewhat less than the above
                value, but near the high end of municipal trash densities referenced in the literature.
                (Reference densities range from 270-540
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 materials being discharged to the residue sump.  Occasionally, the bed appeared to be
 as much as 4 feet deep and typically was at least 2$ feet deep at the point of
 discharge. At times, observers estimated that as much as 50% of the residue consisted
 of unburned refuse. It is important to note that the bed depth and trash burnout
 conditions described above depict refuse that had been in the furnace chamber for
 approximately 45 minutes.

 As the residue was discharged from the stoker, newly exposed material would quickly
 flame up as if it had been starved for oxygen and it was obvious that some of the
 refuse was being totally insulated from combustion conditions. An automobile tire was
 observed in the residue that had apparently been buried on the grate in  a standing
 position.  The top portion was completely burned away to the reinforcing wires while
 the entire bottom section of side wall and tread remained totally intact.  Plastic soda
 bottles  which hadn't been burned or melted were observed in the residue along with
 partially burned newspaper, rags and branches.

 Given the above conditions, it  is possible that materials that could contribute to the
 formation or release of organic air contaminants may not be exposed to combustion
 conditions until just prior to discharge.  Air contaminants released at this point may
 not be exposed to adequate retention time/temperature  conditions for complete
 oxidation as the area at the discharge end of the stoker is also the shortest distance
 from the furnace gas exit and lies outside the normal flame path.

 Finding f 9 - Numerous large pieces of entrained refuse blown from the  refuse bed or
 drawn from the stoker discharge area were  observed to be incompletely combusted and
 still burning as they were exhausted from the furnace and entered the quench spray
 area.

 Discussion -"Velocity traverses  were made during the observation inspections
 conducted on December 3, 4 and 5, 1984. The volumetric flow rates determined by
 these under normal operating conditions were consistent. The following flow rates are
 representative of these measurements:

     Traverse Site                                  Volume SCFM
     Exhaust Stack                                     67,000

     Under fire air-inclined stoker                      11,000
     Under fire air horizontal stoker                     19, OOP

     Total underfire                                    30,000

     Over fire                                            7,000
     Wall cooling air duct                                 3,000

     Total forced draft air                              40,000

     Unaccounted for induced air*                       27,000

"Signficant quantities of air were drawn into the  combustion chamber through the
flaps beneath the inclined stoker.  Other sources, e.g., the access door  at the rear of
the  furnace, view ports, etc. were also noted.   It is reasonable to conclude that the
unaccounted for induced air entered from these sources and air leaks occurring in the
system down stream of the furnace.
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 Calculation of an actual underfire to overfire air ratio is complicated by the
 uncertainties regarding1 air volumes induced through door flaps and other openings.
 Based upon the air volumes delivered by the forced fan system, the underfire to
 overfire air ratio would be in the  range of 3.5:1 to 4.0:1.  An underfire to overfire air
 ratio of 1:2 to 1:1, depending upon the moisture content of the refuse, is recommended
 by the reviewed municipal incineration reference literature. If it is assumed that 50%
 of the unaccounted for air is induced into the combustion chamber as overfire air, the
 underfire ratio would be reduced to approximately 1.25:1. This circumstance could not
 be confirmed from the available measurements or observations.  Given the
 uncertainties resulting from the large volume of unaccounted for air, the actual
 underfire to overfire air could not be precisely determined.  However  both the values
 determined from delivered air rates and observations indicate the underfire to overfire
 air ratio may be signifinantly above the recommended range.

 Theoretical combustion air for municipal refuse is, of course, dependent upon the
 combustibles content and  composition of the refuse.  Based upon typical municipal
 refuse composition and the 15.9 tons/hr. charging rate, it is reasonable to expect that
 the theoretical air requirement during the observed intervals was within the 15,000 to
 20,000 scfm range.  Based upon the above, fan delivered combustion air  would
 represent aproximately  125% of theoretical air requirements.  It is important to  note
 that significant quantities of combustible materials were not burned, and excess  air
 levels for the refuse actually undergoing combustion would therefore be significantly
 higher than the 125 to 150% range as determined by theoretical requirements for the
 refuse charged.

 The average measured stack exhaust volume was measured to be approximately
 67,000 scfmn. However, it is important to recognize that only 40,000  scfm was
 introduced to the furnace  by the combustion air delivery system.  A significant portion
 of this 27,000 scfm  may have entered the system downstream of the combustion
 chamber and the workroom air that was drawn into the furnace  through  observed
 openings could not be considered overfire air and, at least in part, may not have been
 effectively available for combustion.

 Finding 910 - Temperatures in the expanded section at the exhaust end of the
 combustion chamber were consistently maintained at levels above 1400°F.

 Discussion - The operators were able to consistently maintain relatively high furnace
 temperatures, primarily by adjustment of both overfire and underfire air dampers.
 This was apparently a priority objective that overshadowed consideration of the other
 factors required for complete combustion.

The necessity to maintain  required temperature levels was explained as  the basis for
 not reducing stoker speeds during the frequent occasions when significant quantities of
unburned refuse  were being discharged from the discharge end of the stoker.  (The
records  indicate that stoker speeds are sometimes reduced without loss of
temperature, e.g., during the 12 to 8 shift on December 4, 1984  the recorded inclined
stoker speed was 40 ft/ht and furnace temperatures were maintained within the
 1500°F to 1700°F range.)

Gas mixing and retention time are also critical factors that must be considered to
access the combustion effectiveness that  can be achieved at a given furnace
temperature level. The  internal furnace configuration does not  appear to provide the
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     turbulence needed to achieve good mixing of the combustion gases and the actual
     flame pattern inside the furnace appeared to follow a nearly straight line from the
     stoker to the furnace exhaust gas exit.

     Finding 111 - Particulate  emissions appeared to be well controlled.

     Discussion - With the exception of the previously noted start up emissions, visible
     emissions appeared to be minimal at the stack exit, although a light colored emission
     could be seen trailing off from the dissipating steam plume. Precipitator performance
     is undoubtedly enhanced by the low gas velocity through the collector.  (The actual
     average flow rate of approximately 168,000 acfm is well within the 219,300  acfm
     design capacity.)  The effective gas conditioning provided by the quench sprays also
     contributes to the good  performance of the particulate emission control system.

     No significant precipitator operating or  maintenance problems were observed during
     the on-site inspection.
IV.   LITERATURE REVIEW
     Finding 112 - The studies published in currently available literature indicate that
     emission of dioxins and furans from municipal incinerators can be controlled to a level
     that is protective of public health by controlling temperature, retention time,
     combustion air and the turbulence of the gas stream within the combustion chamber.

     Discussion  - The references reviewed for toxic emissions from municipal refuse
     incineration are  listed on Page 17.

     Municipal waste  incineration  and potention emissions are extensively reviewed in the
     "Hart Report," which was prepared by a consultant for the New York Department of
     Sanitation. This study was  undertaken as a result of New York's proposal to construct
     an incinerator at the Brooklyn Navy Yard.

     Incinerator operating conditions and resultant emissions are also detailed in the Pilot
     Study Information of Specific Compounds from Combustion Sources.

     Several studies of European resources recovery incinerators have also been published.
     However, the reports of this work that were available for review do not contain
     complete operating conditions and sampling procedures information.

     The above studies indicate that combustion gas temperatures  in the 1600°F -  1800°F
     range maintained for approximately two (2) seconds is sufficient for destruction of
     dioxin and furans, provided  adequate gas mixing and proper oxygen levels are  also
     maintained. These conditions cannot be maintained if waste fuel feed rates are too
     high to achieve effective combustion.

     Finding f 13 - High efficiency collection of particulate emissions may be required to
     control dioxin and furan compounds that are condensed on flyash particles,

     Discussion - It has been suggested that the apparently high absorption of dioxin and
     furans on the surface of flyash particles may be a key factor in the control of these
                                        -13 -               187-
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substances.  The condensation/absorption of dioxin is increased as the gas is cooled to
the 500°F - 700°F range.


Finding #14 - Insufficient data is available to quantitatively relate operating
conditions to dioxin emission rates or guideline ambient concentrations.


Discussion - The ambient guideline for dioxin adapted by the City of Philadelphia is
35 pg/M^. The results of stack tests conducted in early 1985 to determine dioxin
emissions should provide the data required  to evaluate the level of destruction and/or
collection achieved,  and any impact upon ambient levels.
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                                 RECOMMENDATIONS

 Recommendation II - Perform an accurate assessment of the weight and volume of refuse
 being charged to the units and the weight and volume of residue being discharged from the
 units over a given period of time while operating utilizing current practices.

 The operating practices identified by this study appear to  be directed at feeding refuse at
 fixed predetermined stoker speeds and maintaining combustion chamber temperatures within
 certain parameters irrespective of residue burnout.  As a result, poor burnout - i.e., weight
 and volume reduction of the refuse was observed. The information obtained should be used
 as a baseline for comparison with similar assessments to be conducted following
 implementation of modifications to current furnace firing procedures as recommended
 herein.

 Recommendation 12 - Implement changes in the furnace firing procedures aimed at
 achieving maximum refuse burnout while maintaining combustion chamber temperatures
 above 1600°F.  Refuse feed rates, stoker speed rates and overfire and underfire air
 distribution settings should be adjusted to optimize furnace combustion conditions while
 achieving proper refuse burnout.  (Proper refuse burnout should  yield a trash to residue
 weight rate reduction in the range of 70 to 75%.)

 Incomplete refuse burnout contributes to less than optimum furnace combustion conditions
 regardless of furnace  chamber temperatures and could contribute to the formation of
 organic air contaminants.  During the  study observations it was  noted that due to high
 furnace grate loadings some materials were being totally insulated  from combustion
 conditions until the actual point of discharge from the furnace.

 Recommendation 13 - Identify air infiltration points and associated volumes. To the degree
 feasible, eliminate significant air leaks.

 Traverses conducted as a part of the on-site evaluation determined that the stack exhaust
 to be approximately 27,000 scfm greater  than the volume attributable to delivered air,
 moisture evaporation  and combustion products.  Air supply measurements were limited to
 delivered air  and the distribution of leaked air entering through  openings/leaks in the
 combustion chamber and/or downstream of the furnace exhaust  is not known. This
 information and control of infiltrated air  is important to further assessment of combustion
 conditions and adjustment of the parameters identified in Recommendation #2.

 Recommendation 14 - Undertake a study to determine the feasibility of physically
 modifying the furnace and overfire injection system to increase residence time and
 turbulence in the combustion chamber.

The current furnace design does not include a gas  mixing or secondary combustion chamber
and the current overfire air distribution system  does not appear to provide good mixing of
the combustion gases.  Adequate gas mixing and retention  time are required to significantly
improve furnace exhaust gas oxidation.

Recommendation #5 - Implement improved measures to control the type of material
deposited and the segregation of waste in the refuse pit.

Large bulky non-combustibles (water heaters, refrigerators, etc.) and difficult to burn
materials (grass clippings,  wet leaves,  etc.) should be excluded from the trash to the
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 maximum extent possible. These items should be diverted to alternative disposal facilities,
 i.e., landfills, composts.

 Combustion and/or charge chute jamming problems result from the current practice of
 dumping large, bulky combustibles such as sofas, mattresses, etc. directly into the refuse
 pit. These items should be diverted to a landfill or pre-processed in a shredder.

 The trash pit frequently contains segregated deposits and the existing stoker design does not
 provide significant mixing of the refuse in the furnace. It is, therefore, important that
 pre-mixing be implemented  to achieve a  more homogenous distribution of the feed refuse.
 Improved refuse distribution can be  accomplished by utilizing the charging bucket to more
 thoroughly mix the waste in  the pit.

 Recommendation 16 - Install a CEM to monitor visible emissions in accordance with DER
 provisions.

 The above equipment is needed to monitor and evaluate smoke emissions. This capability is
 particularly important to assess emissions during startups, restarts and upset conditions.

 Recommendation #7 - Discontinue the current practice of shutting the incinerator down
 over the weekend.

 There are several problems associated with shutting the incinerator down on the weekend.
 These include cold conditions at startup, smoke emissions during restart, thermal shock to
. the equipment and low refuse levels in the pit that are more likely to consist of wet
 materials that sink to the bottom, e.g., wet leaves. Continuous operation for longer periods
 (30 to 60 days) would greatly reduce the above problems and may be  required if
 implementation of Recommendations #1 and #2 results in reduced charging rates. The
 operational cost  increase may be, at least in part, offset by reduced  residue  disposal costs
 resulting from improved burnout.

 Recommendation #8 - Place  increased emphasis upon proper crane operation and charging
 practices.

 The crane operator should avoid charging  the items identified in Recommendation #5. In
 addition to previously identified problems, these items have caused jamming of the charging
 chute, combustion upset and  breakdowns.  These circumstances have sometimes been
 exacerbated when the clam shell was used as a ramming device to drive  jammed  material
 through the chute.  Efforts should be undertaken to assure that reasonably dry refuse is
 available for startup and vigilance of the  refuse level in the charging chute should be
 maintained to assure that the feed seal is  not broken.

 Recommendation #9 - Implement timely operational adjustments to minimize air
 contaminant emissions following  the occurrence of process upsets and/or equipment
 breakdowns.

 Failure to undertaken appropriate actions to reduce air contaminant  emissions during
 upset/breakdown conditions was noted during review of plant records. Continued  operation
 of the furnace at the normal  rate during periods when the residue removal system was down
 and continued operation  of the  furnace during precipitator field outages  are examples of this
 problem.
                                                -16-
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Recommendation #10 - Place greater emphasis upon preventative maintenance to reduce
breakdowns.

Scheduled maintenance as outlined in existing maintenance manuals should be continued. In
addition, increased emphasis should be placed upon preventative checks of equipment known
to be subject to breakdown (charging cranes, residue removal system trucks and
precipitators). For example, one of the charging cranes is usually sufficient to  maintain
required feed rates, permitting alternation of use each shift or day. This circumstance
provides an excellent opportunity to routinely inspect and maintain both cranes when they
are rotated to standby status.  Warning signs, i.e., unusual observations, sounds  and
instrument readings,  should be used whenever possible to undertake corrective action before
actual breakdown occurs.  If the recommended seven days/week  operation is implemented,
periodic shutdowns should be scheduled to provide for inspection and  maintenance of all
system components.

Recommendation #11 - Implement  an ongoing combustion principles and practices training
program for supervisor and operators.

This training is important to the development of skills and abilities directly related to the
primary objective of plant operations, i.e., good  combustion of municipal refuse.
                                                 -17-
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References
Principles <5c Practices of Incineration, edited by Richard Corey, John Wiley 
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                                     APPENDIX A
                             OBSERVATION PROCEDURES

The Northwest Incinerator facility includes two combustion chambers with identical design
features and capacities.  The #1 furnace was selected for the purpose of conducting on-site
evaluations of operating practices.  Typically five team members were on-site during the
observation periods.  Assignments were  rotated intermittently to increase familiarity with
the overall process.  During the first day of observation and a portion of the second day a
sixth team member was also present for the purpose of off site observation of visible
emissions.

The first individual was positioned on the charge hopper floor and counted every load
delivered to the #1 furnace feed hopper throughout the observation shift.  This  individual
also made notes regarding the time  that the charge took place, any unique materials
included in the charge and  provided an estimate of the volume of the charge in  terms of a
closed bucket  volume.

The second individual was located at the #1 furnace control panel on the stoker floor level
of the  incinerators. This individual  recorded the readings from each  instrument on the
control panel at 15 minute  intervals. Along with the panel readings this observer also
checked and recorded the various windbox damper and overfire air duct damper positions
and intermittently observed the conditions inside of the furnace through the two available
viewports.  Notes were made regarding  the general atmosphere inside of the furnace
including flame pattern and flame position along the horizontal grate, entrained flyash,
excessive smoke, the depth of the burning refuse bed and any unique  items observed in the
bed.  Intermittently this individual would also walk out on the platform above the residue
troughs'and conveyors and observe and make notes regarding the condition of the residue.

Individuals 3 and 4 were responsible for  conducting the various velocity traverses performed
in each of the  combustion air delivery ducts, the wall  cooling air delivery duct and in the
furnace exhaust stack.  The traverses were performed using a calibrated S type pitot tube
and a liquid manometer.  Each of the traverses was done  according to the EPA Method 1
requirements.  These individuals also performed Orsat and Fyrite  analyses on exhaust  gas
samples at a location in the breeching connecting the  furnace outlet  and the first quench
tower inlet downstream from the quench spray nozzles.

Individual #5 supervised and coordinated the other team members and spent considerable
time observing, evaluating  and making notes regarding general overall aspects of the facility
equipment and operation, spent time discussing the operations with plant  personnel and staff
members from the City Streets Department, filled  in for other members as necessary,
performed additional Fyrite analysis on  the furnace flue gas, physically inspected the
operation of the electrostatic precipitator and spent considerable time looking at the  refuse
being charged, looking  inside the incinerator, looking at the residue being discharged  from
the unit and observing the stack discharge for visible emissions.

As mentioned previously, the sixth individual, when available, performed off site visible
emissions observations.

Most of the operating data  presented in  this report was obtained direcltly using on-site
and/or DER instrumentation. The design data (capacities, dimensions) and certain operating
data (weight rate charged, quench water flows) were obtained from plant  representatives.


                                          A-l
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                                     APPENDIX B
                               FACILITY DESCRIPTION

The facility includes two identical  Tynan continuous feed, refractory-lined incinerators.
Construction of the facility was completed in 1960. In 1974, electrostatic precipitators
were retrofitted onto each of the furnaces.  The facility is reported to handle only municipal
refuse and each unit is currently rated to handle 375 tons per day.  Waste is charged to the
furnaces from either of two 500 tons holding pits to overhead cranes equipped with clam
shell-type buckets.

Stokers

Each furnace is equipped with a water cooled gravity feed charging chute and two travelling
grate stokers.

     grate area -

     The feed stoker is inclined 20° from horizontal and measures 22 feet in length by
     8 feet in width. The second stoker is the horizontal stoker measuring 40 feet in length
     by 8 feet in width.  The combined  effective grate area for each furnace is 480 feet^.

     stoker speed -

     The speed of the  inclined and horizontal stokers  can be independently varied. A speed
     range of 12 to 100 ft./hr. is reportedly available  for both stokers. The speed of the
     inclined stoker determines the feed rate to the incinerator and the speed of the
     horizontal stoker determines  the depth of the burning refuse bed.

     The speed of the  inclined stoker is continuously recorded by a circular chart recorder
     located on the  furnace control panel, while a speed gauge for the horizontal stoker is
     located near the discharge end of the furnace. The speed rate settings of  both of the
     stokers must  be manually adjusted.

Combustion Chamber

Each furnace consists of a single combustion chamber  approximately 55 feet long by 8 feet
wide.  From the feed end the first 34 feet of the chamber measures roughly 17 7 feet in
height  above the surface of the horizontal stoker grate.  The roof of the chamber then
increases  to a height of over 30  feet above the horizontal stoker grate for the remainign
21 feet of the length of the furnace.  Exhaust gases leave the combustion chamber  through
an opening on the upper rear wall measuring 12  feet, 8 inches high by 8 feet wide. The total
furnace combustion chamber volume is reported to be  9,360 feet^. A sketch of  the furnace
is attached.

Combustion Air

Combustion air is provided by a single forced draft fan rated to deliver over 50,000 SCFM at
4^ inches static pressure.  Three separate ducts deliver the air from this fan to  different
zones in the furnace. One supplies underfire air to the inclined stoke, one supplies underfire
air to the  horizontal stoker and one supplies to the overfire air system.

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There is a pneumatically controlled louver-type inlet damper on the forced draft fan which
is activated by a manual switch on the furnace control panel. A draft gauge on the furnace
control panel which indicates the  forced draft static pressure.  The furnace operator varies
the total combustion air flow rate by adjusting the control switch damper position.

     underfire air -

     There are individual  dampers on each of the four air zones under the inclined stoker
     and on each of the six air zones under the horizontal stoker. By manually changing
     these damper positions, the  operator can control the quantity of combustion air being
     delivered to any grate area thereby adjusting the actual location of the fire in the
     furnace as well as to some degree the intensity of the fire.

     At one time, there were individual draft gauges for each of the horizontal stoker
     underfire air zones.  These are now all inoperable.  The operators only reference,  other
     than the total combustion air draft  gauge, is to visually observe the fire and adjust the
     windbox dampers accordingly based upon experience.

     overfire air  -

     The overfire air system includes three delivery ducts each of which feeds a series of
     seven approximately 4"  diameter feed pipes distributed in three rows in the roof of the
     lower first section of the combustion  chamber. The first two rows are located above
     the inclined  stoker while the third row is located over the beginning of the horizontal
     stoker.  Each of the  three overfire air delivery ducts has a manually adjustable damper
     which is set  in either the full open or  full closed position.

     Originally, there were additional overfire air injection  ports located in both side walls
     of the furnace about li - 2  feet above the horizontal stoker grate.  Refractory now
     covers the openings of these ports into the furnace and on one  side, the delivery duct
     has been sealed.

     auxiliary air -

     These incinerators have air-cooled refractory  walls, and all of  the cooling air is being
     injected into the combustion chamber through 114 small (approximately 2i" inch dia.)
     openings located on both sidewalls of  the stoker. The supply fans for the  wall cooling
     system on each furnace are direct drive blowers rated to deliver 3600 SCFM at
     6 inches static pressure. Since all of the wall  cooling air ends up in the combustion
     chamber, it  must be  included as combustion air. The wall cooling fans  run at all times
     and the  operator makes no adjustments or variations to these systems.

     Furnace Temperature Control

     There are two separate  thermocouples located on the upper side wall in the large  rear
     section  of the combustion chamber. These thermocouples monitor the combustion
     chamber temperature and are  each  tied to a continuous recorder, one a circular chart
     recorder on  the furnace control panel and the other a strip chart recorder located in
     the plant superintendent's office.  There are no automatic controls tied to these
                                         B-2
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furnace temperature sensors.  The operator must constantly monitor the temperatures
on the circular recorder and decide what adjustments to make, if any, to the furnace
controls.

Furnace Exhaust Gas

draft -

One of the few automatic controls on the furnace is a draft controller.  The controller
senses the furnace draft in the upper area of the combustion chamber and signals
changes to the systems 400 HP variable speed  induced draft fan.  There is a draft
gauge located on the furnace control panel as well as a circular chart recorder which
provides a continuous record of the furnace draft. The automatic controller appears
to be set to maintain the furnace draft within  a range of approximately 0.2"
During typical operation the furnace draft  is maintained at about 0.3 to 0.5"
Because the ID fan speed is constantly varying to maintain the draft, the fan motor
amperage is monitored continuously and recorded on a circular chart recorder on the
furnace control panel.  It is also  tied into a high  current motor shut off to protect the
motor.

cooling -

As the exhaust gases leave the furnace, they pass through  a section of refractory-lined
breeching connecting the furnace to the inlet of  the first of two  quench towers.  A
series of air atomized water spray nozzles  are located in this breeching immediately
following  the furnace  exit. These nozzles can  provide up to 200  gpm for quenching the
furnace exhaust gases. The actual water flow  rate to the  nozzles is controlled by
another of the few automatic  controls on the furnace.  An array  of thermocouples
located in the duct at the  inlet to the electrostatic precipitator, downstream from the
quench towers, signals the controller to adjust the quench  water  spray rate to maintain
a relatively constant precipitator inlet temperature. A circular  chart recorder on the
furnace control panel  continuously records  the precipitator inlet temperature and a
continuous strip chart recorder on the control panel records the actual water flow
rate. The precipitator inlet- temperature is typically maintained at approximately
550°F.  Excessive inlet temperatures will first sound an alarm and then shut down the
system ID fan.

Flyash Collection

The  incinerators are equipped  with electrostatic precipitators to control flyash
emissions.  The precipitators on both furnaces  are identical two-field units
manufactured by Combustion Engineering.  Design values for  each unit are
summarized below:

           Collection plate area -      45,000 ft.2
           Volumetric flow -           219,000 ACFM at  550°F
           Gas velocity -               4 ft-/sec.
           Gas reduction time -         6 seconds

The two quench towers which precede the precipitator were installed at the same time
and provide adequate time  for quenching the gases while also  acting as precleaners
removing  much of the larger flyash particles exhausted from the furnaces.


                                    B-3
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Both fields of the precipitators are equipped with instrumentation for monitoring
primary voltage, primary current and secondary current.  The instruments are located
on the furnace control panel and the furnace operator records all of the precipitator
gauge readings hourly. There are also timer controllers located on the control panel
for activating the precipitator rapping systems.

The collection hoppers in both precipitator fields are equipped with resistance heaters.
Temperature controllers for these heaters are located on the furnace control panel.
There is a single blower which provides preheated air from a resistance heater to the
insulators on both fields of each precipitator. An ammeter is located on the furnace
control panel for monitoring the insulator blower motor current.

Flyash/Furnace Residue Sump System

The flyash collected in the preicipitators is discharged  via sealed drag conveyors and
gravity chutes directly into the same wet sumps which  receive the  residue discharged
from the furnaces.  Gravity chutes located below the discharge end of the horizontal
stokers terminate below the top of the water level in the wet sumps sealing the
residue discharge area from the furnace draft. The quench towers  are also equipped
with wet bottom sumps which overflow into the main sump on each system.

The combined residue is pulled up an inclined drag conveyor from the bottom of the
main sump and excess water from the residue drains back into the sump.  The  residue
itself is discharged from the end of the drag conveyor into waiting  20 yard^ residue
receiving trucks.  A. dedicated number of these vehicles are kept on-site.

The residue  and ash handling systems on each furnace are totally independent  and
material from one furnace  cannot be diverted to the sump on the other, therefore, any
extended breakdown on the residue system dictates a shutdown of the  feed to  that
furnace.  The plant discharges between 200-300 gpm of wastewater to the city's
sewage system.
                                    B-4
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      APPENDIX C

DATA AND CALCULATIONS
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Date:
Time:
  PHILADELPHIA NORTHWEST INCINERATOR TRAVERSE DATA

December 3, 1984
           Traverse
             Site
Exhaust Stack
Under-Fire Horizontal Stoker
Over Fire Air Duct
Under-Fire Inclined Stoker
Wall Cooling Air Duct
8:00 A.M.)
Traverse
Time
2i51 A.M. -3:19 A.M.*
4:55 A.M. - 5:08 A.Mr,
4:21 A.M. - 4:35 A.M. > a
3:59 A.M. - 4:15 A.M. \
3:30 A.M. - 3:45 A.M.J
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Ave. Ts
op
486
43
45
40
76
Reproduced from it'll
best available copy. %[^
Ave. Vs
Ft./Min.
•••••••MHiW
48.0
53.0
17.0
33.9
31.5
Volume
ACFM
108065
19497
6213
12441
3365
Date: December 4, 1984
Time: Second Shift (4:00 P.M.
RV *J
Traverse A "^,
Site
- 12:00 A.M.) First Series of Traverse
Traverse Ave. Ts
Time °F
Exhaust Stack 5:04 P.M. - 5:30 P.M.3 505
Under-Fire Horizontal Stoker 6:15 P.M. - 6:30 P.M.") 37
Over-Fire Air Duct 6:42 P.M. - 6:52 P.M. ( i 40
Under-Fire Inclined Stoker 6:57 P.M. - 7:07 P.M. j 40
Wall Cooling Air Duct 7:17 P.M. - 7:23 P.M/ 101
Second Series of Traverses
Traverse jj -7 Traverse Ave. Ts
Site */" * Time °F
Exhaust Stack
Under-Fire Horizontal Stoker
Over -Fire Air Duct
Under-Fire Inclined Stoker
Date: December 5, 1984
Time: Third Shift (8:00 A.M. -
Traverse ^ iJ
Site ^ V
Exhaust Stack
Under-Fire Horizontal Stoker
Over -Fire Air Duct
Under-Fire Inclined Stoker
Wall Cooling Air Duct
9:03 P.M. - 9:36 P.M. ~^, 513
10:04 P.M. - 10:22 P.M. ' 36
10:37 P.M. - 10:49 P.M. ". ~ 37
10:56 P.M. - 11:07 P.M. / 36
4:00 P.M.) First Series of Traverses
Traverse Ave. Ts
Time °F
8:49 A.M. - 9:26 A.M. M 493
10:04 A.M. - 10:16 A.M.") 38
10:23 A.M. - 10:31 A.M.? ^ 40
10:35 A.M. - w*:46 A.M. ) 40
10:54 A.M. - 11:01 A.M/ 108
                                                                 Ave. Vs
                                                                 Ft./Min.

                                                                   63.0
                                                                   50.4
                                                                   16.7
                                                                   25.8
                                                                   29.8
                                                                 Ave. Vs
                                                                 Ft./Min.

                                                                 •  75.0
                                                                   49.7
                                                                   17.7
                                                                   26.5
                                                                 Ave. Vs
                                                                 Ft./Min.

                                                                   66.0
                                                                   47.4
                                                                   18.8
                                                                   27.9
                                                                   27.0
                                                                 Volume
                                                                 ACFM

                                                                 142074
                                                                   18515
                                                                    6124
                                                                    9494
                                                                    3182
                                                                 Volume
                                                                 ACFM

                                                                 169547
                                                                   18279
                                                                    6495
                                                                    9755
                                                                 Volume
                                                                 ACFM

                                                                 148765
                                                                   17408
                                                                   6919
                                                                   10269
                                                                   2900
                                     o r?-r  ?rt<
                                     ci=- TV.-/.
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                Second Series of. Traverses
                 Traverse
                   Site  •
      Exhaust Stack
      Under-Fire Horizontal Stoker
      Over -Fire Air Duct
      Under-Fire Inclined Stoker
                                               Traverse
                                                Time
                                       1:20 P.M. - 1:43 P.M.
                                       2:32 P.M. - 2:44 P.M.
                                       2:52 P.M. - 3:02 P.M.
                                       3:08 P.M. - 3:18 P.M.
Ave. Ts
  QF

  514
   39
   40
   40
Ave. Vs
Ft./Min.

  73.8
  41.3
  22.9
  30.4
Voiurm
ACFV

 16635
  1519
   840
  1117
                                                                               we.
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THEORETICAL AIR

I. Based on average characteristics of Mum
Moisture: 0.26 Ib/lb waste
Ash: 0.258 Ib/lb waste
Combustibles: 0.482 Ib/lb waste
It is assumed that combustibles consist
plastics.
PVC: 0.05 Ib/lb waste

C-18
CALCULATIONS

cipal Solid Waste at Akron OH.


of cellulose type waste and PVC type


Cellulose: 0.432 Ib/lb waste
BTU as Received: 4100 Btu/lb

Combustion Air Requirements:



A. Cellulose: 02 in air combines with cellulose stoichiometri cal ly
C6 H10 05 + 602
162 + 192
1 + 1.185
As received lb. 0.432 + 0.512
1 Ib 0;? requires 4
0.512 x 4.32 = 2
B. PVC
C ~CH2CH - CHpCH ]n + n 50
Cl Cl
n 125 + n 160 -> n 176
1 * 1.28 -> 1.408
As received lb 0.05 + 0.064 -> 0.0704
fl Ofid •!• 1 ">0 - n 0-7fi^ lh -M r rrnrl

Total stoichiometric air reqd: 2.212 + 0
Feed rate : 15.9 tons/hr.
Stoichiometric air = 2.489 x 15.9 x 2000
60
One mole of any gas occupies 359ft^ at 14.
Stoich. air volume: 1318.90 * 03-04 * joT

Total forced draft ai r = 40000 scfm
Excess air = 40000 - 17fi8fi = 223143
% excess ai r = 126%


-> 6C02 + 5H20
-> 264 + 90
-> 1.63 + 0.555
-> 0.704 + 0.24
.32 lb air
.2 12 lb air reqd.

2 -> n [4 C02 + 2 H20 + 2 HC1 1

* n 36 + n!3
+ 0.288 + 0584
+ 0.0144 + 0.0292
•
.2765 = 2.489 Ib

= 1318.9 Ib/min
7 psia and 32°F
= 176857 scfm


scfm



-------
I
I
I
                                                                          C-19
    Products of  Combustion  (PC):
                Cellulose    PVC
Dry Gas:   C02    0.704   -t-  0.0704         = 0.7744 Ib/lb  waste
          N2     2.1885  -  (0.512 + 0.064) = 1.9125 Ib/lb  waste
Moisture:  H20 from  waste                   = 0.26 Ib
*" ^B
r
1
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H20 from air: 2.4885 x 0.0063 0.0156 Ib
0.0063 Ib H20/lb dry ai r 9 60% RH + 60°DB
H20 from combustion 0.2544 Ib
0.24 + 0.0144
HC1 0.0292 Ib
Material Balance Verification:
PC 3.2461 Ibs Waste
Ash 0.258 Ib Stoch. Air
3.5041 Ibs H?0 Air

3.2461 Ib
1.00 Ib
2.4885 Ibs
0.0156 Ib
3.5041 Ibs
Volume PC Converted to Std Conditions (70°F 14.7 psia)
Product Weight (Ib/min)
CO? 0.7744 x 15.9 x 2000
60
N2 1.9125 x 15." x 2000
60
H?0 0.53 x 15.9 x 2000
60
Air
HC1 0.0292 x 15.9 x 2000
Total Exhaust
Air leak
Heat Balance:
Volume (scfm)
3607.4
13999.9
6035.1
22314.3
163.97
46120.67 scfm
67000 scfm
20879.33 scfm
Heat Input 4100 Btu/lb
Heat losses: (assume 1SOO°F outlet temp rel to 60°F)
Ib/lb waste enthalpy (Btu/lb)
Moisture: 0.53 x 1948.02 = 1032.45 Rtu/lb waste
C02: 0.7744 x 469.1 = 363.27
N2 1.9125 x 464.8 * 888.93
Ash 0.258 x 377.6 = 97.42
HC1 0.0292 x 469.1 = 13.70
Radiation 10% of input = 410.00
Excess Heat: 4100-2805.77
Excess air requirement 1294.23 Btu/1
453.24 Rtu/1
Excess air read, volume: 2.855 x -=-|^
bU
2805.77
= 1295.23 Btu/lb waste
b waste = 2.855 Ib/lb waste
b
9 359 530
- x 2000 *2inT4x "JgT = 20294 scfl
                                                                         218 
-------
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                                                                             C-2(
 II.   Data:  Fuel Analysis

      (Ref: p. 658 19R4 National Waste Processing ASME Conference Proceedings)

    Carbon   -  28.6%
    Moisture -  28.8%
 -   Ash      -  "21.8%
    Sulfur   -   0.1%
    C12      -   0.3%
    HHV as fired - 4600 Btu/lb

    Due to low contents of chlorine and sulfur the entire combustibles are
    assumed to be cellulose type

         Moisture   -  0.288 Ib/lb waste
         Ash        -  0.218 Ib/lb waste
         C6 H10 °5  -  0-494 Ib/lb waste

          C6 H10 °5  + 6n2    ->  6C02  + 5H2°
              162    + 192    ->  264   + 90
                1    •(• 1.185  ->  1.63  + 0.555
As received Ib 0.494 + 0.585 ->  0.805 + 0.274
                   1 Ib 02 requires 4.32 Ib air
                     0.585 x 4.32 = ?.527 Ib air reqd.

Feed  rate :   15.9 tons/hr.
  Stoichiometric air = 2.527 x 15.9 x 2000  = 1339.42 Ib/min
                            60

  One mole of any gas occupies 359ft3 at 14.7 psia and  32°F
    Stoich. air volume:  1339.42
    Total forced draft air = 40,000 scfm
           Excess ai r      = 22,039 scfm
         % excess ai r      = 123%

    Products of Combustion (PC)

Dry ftas   C02:
          N2:
Moisture  H2fl from waste:
          H20 from air:  2.527 x  0.0063
0.0063 Ib H20/lb dry  ai r 0 60% RH -t- 60°DB
          H?0 from combustion:
Mass Balance Verification:
                                             = l7961  scfm
                                             0.805  Ib/lb  waste
                                             1.942  Ib/lb  waste
                                             0.288  Ib/lb  waste
                                             0.016   Ib/lb waste

                                             0.274   Ib/lb waste
                                             3.325   Ib/lb waste
    PC   3.325 Ibs
    Ash  0.218 )b
         3.543 Ibs
                             Waste  1.00  Ib
                       Stoich.  Air  2.527  Ibs
                        H20 Ai r     0.016  1 b
                                    3.543  Ibs
-------
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'
1
Volume PC Converted to Std Conditions

Product Weight (Ib/min)
CO? 0.805 x 15.9 x 2000
60

N? 1.942 x 15.9 x 2000
60

H?0 0.578 x 15.9 x 2000
60
Air

Total Exhaust:
Ai r leak:
Heat Balance:
(70°F, 14.7 psia)
Volume (scfm)
3749.9

14215.8


6581.7
22039.0
46586.4
67000
20414

Heat Input: 4600 Btu/1
Heat Losses: (assume 1800°F outlet temp rel to
Ib/lb waste enthalpy
Moisture: : 0.578 x 1948.02
C02 : 0.895 x 469.1
N? : 1.942 x 464.8
Ash : 0.218 x 377.6
Radiation (10% of input) =

Excess Heat: 4600-2948.55 = 1651.
(Btu/lb)
1125.96 Btu/1
377.63 Btu/1
902.64 Btu/1
82.32 Btu/1
460.00 Btu/1
2948.55 Btu/1











b
60°F)

b waste
b waste
b waste
b waste
b waste
b waste
45 Btu/lb waste
Excess Air Read = 1651.45 Btu/lb waste
1
453.24 (Btu/lb)
= J.b4

Ib/lb w,
 I
 I
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 I
 t
 i .

IL
         Excess  air volume  reqd: 25895  scfm
-------
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I
                                                                             C-22
 III.  Based on  Essex County,  NJ  Data:

         Moisture:       23% by wt.
                                                Btu/lb:  5475
1
p
1



I


.

I



1
1
§>

1
Combustibles: 56% Plastics (PVC
Cellulose
Entire plastics portion is assumed to
the combustibles is assumed to be cell
Comb'ustion Air Requirements:
.
. Oxygen in air is assumed to combine
A. Cellulose waste
C6 H10 05 + 602
162 + 192
1 + 1.185
As received Ib. 0.51 + 0.604
1 Ib 02 • requi res
For each Ib of waste: 0.604 x 4
B . PVC

I ~CH2CH - CH2CH - + n 502 -
L C1 C1 J n
n 125 + n 160 -> n 176 + n
1 + 1.28 -> 1.408 + 0
As received Ib 0.05 + 0.064 -> 0.0704 -t- 0
Ib ai r
Pi nfid f A 1° -- n '''fiR lh 11 p rr
1 b 03
) 5%
51%
be polyvinyl chloride and the rest of
ulose type waste.


with cellulose stoichiometrical ly.

-> 6C02 * 5H20
-> 254 + 90
-> 1.63 + 0.555
-> 0.831 + 0.283
4.32 Ib air
.32 = 2.609 Ib ai r reqd.


> n [4C02 + 2H20 + 2HC1]

36 + n 73
.288 + 0.584
.0144 -t- 0.0292
qd.
, Total theoretical air reqd: 2.609 + 0.2765 = 2.8855 Ib
f
T^
4

Products of Combustion (PC)
Cellulose PVC
Dry Has C02 0.831 + 0.0704
N2 2.8855 - (0.6D4 + 0.064)
Mnicf-iiro 'J^» H f r*nm ui a c •h o


= 0.9014 Ib/lb waste
= 2.2175 Ib/lb waste
= n 11 IK/lh i.iacta
          H20 from air: 2.8855 x 0.0094    = 0.0271 Ib/lb waste
0.0094 Ib H20/lb dry ai r 
-------
1





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.


i


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Feed rate :
Theoretical



One mole of
Theoretical

15.9 tons/hr.
air = 2.8855 x 1.5.9
= 91758.9 -p^ or




x 2000
1529.315 1£
mi n

any gas occupies 359ft^ at 14.7 psia and
air volume: 1529.315 •
Total forced draft ai r = 40,000
Ib „ 359 (460
min *28.84X (460
scfm






32°F
H- 70)
+ 32)

% excess ai r = 40,000 - 20507.23 x 100 = 95%


20507.23

Excess air: 40000 - 20507.


23 = 19492.77 scfm



Volume PC Converted to Std Conditions (70°F 14.7 psia)

Products
C02

N2
H20
Air
HC1




Heat Balance
Heat Input
Heat losses:
Moi sture:
C02:
Ash
HC1

Weight (Ib/min)
0.9014 x 15.9 x 2000
60
2.2175 x 15.9 x 2000
60
0.5545 x 15.9 x 2000
60
19^92.77 scfm
0.0292 x 15.9 x 2000
60

Total Exhaust
Air leak


Volume (scfm)
4199

16232.55
6314
19492.77
163.97

46402.3 SCfm
67000 scfm
20597.7 scfm














: 5475 Btu/lb waste
Ib/lb waste enthalpy
0.5545 x 1948.02
0.9014 x 469.1
2.2175 x 464.8
0.21 x 377.6
0.0292 x 469.1
Radiation loss


(Btu/lb)
= 10R0.18 Btu/lb
= 422.85 Btu/lb
= 1030.69 Btu/lb
79.30 Btu/lb
13.70 Btu/lb
= 547.50 Btu/lb
3174.22 Btu/lb

waste .
waste
waste
waste
waste
waste
waste
f
• „
I
    Excess Heat:   5475-3174.22

Excess air reqd.  volume:
    =  2300.78  Btu/lb  waste

- Btu/lb  waste =  5.076  1b
 Btu/lb
                                                                                       c-2;
                                                                      = 20507.23 scfm
 acta
waste
       = 36077 scfm
                                                                               222<:
-------
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a
                                                                             C-24
 IV.   Data:  Ultimate Analysis of Refuse

      (Ref: p. 228 1984 National Waste Processing ASME Conference Proceedings)
      Calculated from performance test data.

    Carbon       -  0.2472 Ib/lb waste
    Hydrogen     -  0.03484
    Sulfur       -  0.011
    Moisture     -  0.2774
    Nitrogen     -  0.006
    Ash          -  0.21817
    Oxygen       -  0.21529
    Heat Content -  4443 Btu/lb

    Combustion Calculation:

                 C    +    02  -> C02
                12    +    32  -> 44
                 1         2.666  3.666
As received Ib  0.2472     0.6592 0.9064
                0.2472 Ib C requires  0.6592 Ib Oxygen or 2.848 Ib  air

                2M2   +  02  ->  2H20
                 4   +•  32       36
                 1  '     8        9

As received Ib  0.03484  0.279    0.3136
                0.03484 Ib H requires 0.279 Ib  Oxygen or 1.205  Ib  air

                S     +  02  ->  S02
                32      32       64
                 1       1        2
As received Ib  0.011    0.011    0.022
                0.011  Ib  S requires 0.011  Ib 02
                                =  0.0475 Ib air


    Total  02  required  :   0.6592  +  0.279  +  0.011
                       =  0.9492  Ib
     Less  02  in  waste     0.21529  Ib
                       =  0,73391  Ib 02
                       =  3.17 Ib  air

    Required  stoichiometric air  -  3.17 Ib
  Feed rate :   15.9  tons/hr.                 -
  Stoichiometric air =  3.17x15.9  x 2000  x.,4%,,  x 4S  =  22533  scfm
                         ~~60~            "
-------
1
"mi
•
'•

1

1
r



1

1

I


1

Products of Combustion

C02:
S02:
\\2§ from combustion:
H20 from waste:
H?_0 from ai r (Stolen.) :
N2 from waste:
from air:
Vol ume

CO? 0.9064 x 15.9 x 2000
60
SO? 0.022 x 15.9 x 2000
60
H20 0.6208 x 15.9 x 2000
60
N2 2.442 x 15.9 x 2000
60
Air 40,000 - 22532.7

Total Exhaust
Air leak



0,9064 lb/lb waste
0.022 Ib/lb waste
0.3136 lb/lb waste
0.2774 lb/lb waste
0.0298 Ib/lb waste
0.006 lb/lb waste
2.436 lb/lb waste
scfm

4222.3

70.5

7069.0

' 17876.6
17467.3
46705.7
67000
20294
                                                                                   C-25
                                      - -X--
I
Heat Balance

    Heat Input:                           4443  Btu/lb  waste
    Heat losses:   (assume 1800°F  outlet  temp  rel  to 60°F)

               Ib/lb waste  enthalpy  (Btu/lb)
,
1

1
1

i
•
§'•
-

i
•
m
Moisture:
CO?
N2'
Ash
Radiatio

Excess Heat:





CY^~OCC 31 r* ^ o *n 1 1 1
t_XLcbb air rc<-ju I

0.6208 x 1948.02
0.9064 x 469.1
2.442 x 464.8
0.21817 x 377.6
n loss {10% of input)

4443-3296.24 Btu/lb waste

= 1146.76 Btu/lb waste
_,,„<: T* .. 15.9 x 2000
o U
= 607782.36 Rtu/min
rcmcnt. 607782.36 _ f
rement. 453>24 Rtu - 1340..
Ib
= 1209.33 Btu/lb waste
= 425.19 Rtu/lb waste
= 1135.04 Btu/lb waste
82.38 Btu/lb waste
= 444.30 Rtu/lb waste
3296.24 8tu/lh waste






Ih
min
•>*•»,
                            =  17982 scfm
-------
TECHNICAL REPORT DATA
(Please read fnuntctions on the reverse before completing)
1. REPORT NO. 2.
4. TITLE ANDSUBTITLE
Dioxin Analysis of Philadelphia Northwest Incinerator
Summary Report. Volume 2, Appendices A - F
7 AUTHOR(S)
9. PERFORMING ORGANIZATION NAME AND ADDRESS
12. SPONSORING AGENCY NAME AND ADDRESS
US EPA Region 3
841 Chestnut St.
Philadelphia, PA 19107
3. RECIPIENT'S ACCESSION-NO.
MR 6 1 fa 2 0 1 3 /A
5. REPORT DATE
January, 1986
6. PERFORMING ORGANIZATION
8. PERFORMING ORGANIZATION
s

coc
REP
10. PROGRAM ELEMENT NO.
11. CONTRACT/GRANT NO.
13. TYPE OF REPORT AND PERIOD CC
14. SPONSORING AGENCY CODE
15. SUPPLEMENTARY NOTES
 1,6. ABSTRACT

  A study was conducted by US EPA Region 3 to determine the dioxin-related  impact
  of the Philadelphia Northwest Incinerator on public health.  Specifically,  it
  was designed to assess quantitatively the risks to public health resulting  from
  emissions into the ambient air of dioxins as well  as the potential effect of
  deposition of dioxins on the soil in the vicinity of the incinerator.  Volume
  1 is an executive summary of the study findings.  Volume 2 contains contractor
  reports, laboratory analysis results and other documentation.
                                                               ""
17. KEY WORDS AND DOCUMENT ANALYSIS
a DESCRIPTORS
Dioxins
Incinerators
Public health
Air pollution sources
13 DISTRIBUTION STATEMENT
Unlimited
b. IDENTIFIERS/OPEN ENDEDTERMS
Philadelphia
19. SECURITY CLASS (This Report)
N/A
20 SECURITY CLASS (This page)
C. COSATI
Ficld/C
68A
68G
21. NO. OF
212
PAGES
22. PRICE
EPA Form 2220-1 (9-73)
-------
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