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SECTION 12
COMBINED SYSTEM AND COMPARISON
OF PROCESSES
COMBINED SYSTEM OF TERTIARY TREATMENT
In addition to the investigations of individual technological processes
described in previous sections, a combined treatment system was examined in
order to check the combined operation of selected tertiary processes at the
pilot plant. This system included the processes that were both effective
and technically and economically feasible, and on the other hand, those that
complemented each other for high quality of final effluent.
These combined processes were studied in two periods (figure 5-15). The
first period, September to October 1976, involved the system comprised of
contact coagulation, filtration, adsorption, and ozone oxidation (figure
5-13). The second period, February to March 1977, was intended to check the
effectiveness of adsorption on a wastewater coagulated dose of 100 mg/1 of
alum (instead of 250 mg/1 and without NaOCl). The ozone oxidation was
omitted in the second period.
The effectiveness of individual processes of the combined system has
been presented in previous sections: section 7, table 7-11, coagulation and
filtration; section 8, table 8-10, figures 8-36 and 8-37, adsorption; and
section 9, tables 9-16 and 9-17, oxidation with ozone.
The average effectiveness of the combined system in the first period is
summarized in tables 12-1 and 12-2. COD removal in the whole system equaled
95 percent. Total removal of nonionic detergents in the whole system was
76 percent.
Percentage removal of color was determined spectrophotometrically in
particular processes:
Contact coagulation 46%
Contact coagulation with
oxidation with NaOCl and
filtration 96%
Adsorption 80%
The adsorption effluent was completely colorless.
Among the other parameters, permanganate COD concentration decreased
from 24 mg of 02/1 in biological effluent to approximately 1.2 mg of 02/1 in
431
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adsorption effluent. It changed slightly during ozonation. B005 decreased
from 3.3 mg of 02/1 after coagulation and filtration to approximately 2.0 mg
of 02/1 in effluent from the adsorption process. Anionic detergents were
removed to traces. As is clear from these results, the quality of the
treated effluent wastewater is very high and meets, for pollutants analyzed,
class I water purity standards (appendix C). Ozone oxidation is in this
case superfluous. As a result, in the recommended system this process has
been omitted.
COMPARISON OF PROCESSES
Feasibility analysis and choice of processes for practical application
should be based on a comparison of their technological effectiveness and on
capital and operating costs. Partly because of the rather small scale of
the pilot plant, and mainly because of difficulties in comparing prices of
materials and structures in Polish and U.S. currency, capital and operating
costs have not been included here. Instead, the values of the main indi-
vidual factors that influence the operating costs have been given.
The effectiveness of individual processes applied after biological
treatment based on pilot plant data is summarized in table 12-3.
The consumption of chemicals, materials, and water as well as the
percentage of wasted volume is presented in table 12-4.
The wastewater pumping head, which influences the cost of energy, and
the major energy used for purposes other than pumping are shown in table
12-5.
It is clear from the data summarized in table 12-5 that the greatest
chemical consumption occurs in the case of coagulation; however, activated
carbon is the most costly material. The greatest energy consumption occurs
in the hyperfiltration process, as a result of very high wastewater pumping
head. The energy consumption in ozone oxidation is also considerable. In
regard to water consumption for the needs of the process, the greatest
consumption occurs in ion exchange for regeneration of resins. It reaches
15 percent of total flow capacity. This amount is then discharged to the
sewerage system as concentrated spent regenerant and washings. With hyper-
filtration the nonusable concentrate (up to 10 percent) is treatable by
conventional treatment techniques [80]. Large volumes of sludge that need
to be dewatered occur in the coagulation process. The cost of further
treatment of concentrates and sludge is an additional important and often
decisive factor in the choice of particular processes for practical appli-
cation.
432
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Table 12-1. Average effectiveness of the combined system for COD
Kind of sample Concentration
mg02/l
Biologically 100
Contact coagulation 40
effluent
After filtration and
preliminary oxidation 30
with NaOCl
After adsorption 6
After ozonation 5
Removal in Cumulative
unit processes, % removal, %
v
60 60
25 70
80 94
16 95
Table 12-2. Average effectiveness of the combined
system for nonionic detergents
Kind of sample
Biologically treated
After contact coagulation
preliminary oxidation,
and filtration
After adsorption
After ozonation
Concentration
mg/1
10
»
5.6
3.7
2.4
Removal in
unit processes, 5
44
44
34
35
Cumulative
£ removal , '.
44
44
63
76
433
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Table 12-3. Effectiveness of individual processes
applied after biological treatment
Process
Filtration
(plain)
Coagulation
Adsorption
after AS+F
after AS+C
+F
Oxidation by
ozone
Ion exchange
Hyperfiltration
Removal , %
COD Detergents3 Col or Others
av. 30 35 up to 45 Susp. solids
below 10 mg/1
BOD5: 30 to 75
av. 70 av. 44 av. 96
20 to 50 41 to 48b 30 to 50
TOC: 56 to 73
*
av. 80 31 to 41 av. 80
av. 32 av. 35e av. 67
up to 46 up to 58 74 to 87
93 99 99 Conductivity:
97 to 89
Nonionic detergents.
Anionic detergents.
GContact coagulation with oxidation and filtration.
After activated sludge, coagulation, and filtration.
eln ozonation after adsorption.
434
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Table 12-4. Consumption of chemicals and materials
and volume of water wasted
Process
Oxidation
Ion exchange
Hyperfiltration
Consumption of chemicals
and materials per 1 m3
of treated wastewater
15 g of NaOCl
50 g of ozone
2.5 g of NaCl
1.7 g of HC1
1 g of resin
10 g of alum
1 g of polyelectrolyte
(for prefiltration)
Water consumption
or wasted volume
in % of treated
wastewater
Filtration
Adsorption
Coagulation
0
100 g of act. carbon
250 g of alum
100 g of HC1
5
2 to 3
7 to 10
(sludge)
0
10 to 15
(spent
regenerant)
< 10
(rejected
concentrate)
435
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Table 12-5. Energy consumption and wastewater pumping head
Process
Filtration
Adsorption
Coagulation
Oxidation
Ion exchange
Hyperfiltration
Energy consumption
other than pumping
kWh per 1 m3
Small
Small
Small
1.2
Small
Considerable for
Wastewater pumping
head, in
4
4
6
4
4
250
pretreatment for spiral
wound membrane, small for
tubular membrane [78]
436
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33. Koziorowski, B. "Industrial wastewater treatment (Oczyszczanie sciekow
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43. Debowski, Z. , and K. Holowiecki. "Analysis of errors made during meas-
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440
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57.
58.
59.
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61.
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63.
64.
65.
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67.
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syntetycznych substancji powierzchniowo czynnych w wodzie metoda kolory-
metryczna z kwasem fosforowolframowym," 1974 (section 11).
Netzer, A., S. Beszedits, P. Wilkinson, and H.K. Miyamoto. "Treatment of
dye wastes by ozonation." Wastewater Technology Centre, Canaca Centre
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Water and Wastewater Treatment Research, Canada Centre for Inland Waters,
Burlington, Canada (section 11).
Zenz, D., and M.J. Weingarden. "Ozonation of microstrained secondary
effluent." Metropolitan Sanitary District of Greater Chicago, Research
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REFERENCES (continued)
68. Bishop, D.F., T. P. O'Farrell, J. Stanberg, and J. Porter. "Advanced
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70. "Wastewater ammonia removal by ion exchange." Water Pollution Control
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71. Robinson, D.J., H. E. Weisberg, G.J. Chase, K.R. Libby, Jr., and J.L.
Capper. "An ion exchange process for recovery of chromate from pigment
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72. Maggiolo, A., and J. H. Sayles. "Application of exchange resins for
treatment of textile dye wastes." EPA-660/2-75-016, June 1975 (section
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442
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APPENDIX A
ANALYTICAL PROCEDURE FOR SELECTED CONSTITUENTS
DETERMINATION OF NONIONIC POLYETHOXYLIC SYNTHETIC SURFACE-ACTIVE AGENTS
BY COLORIMETRIC METHOD WITH PHOSPHOTUNGSTIC ACID
Principle
Nonionic polyethoxylic surface-active agents are precipitated in
the form of a complex compound with phosphotungstic acid and barium
chloride or potassium chloride. The tungsten, making up this compound
in a solution of concentrated sulfuric acid, forms with hydroquinone, a
red-brown coloring. The intensity of color is measured spectrophotomet-
rically at 500 nm.
Procedure
Measure off into a centrifugal test tube 10 ml of sample, or 10 ml
of the sample condensed or diluted to such a volume that the nonionic
surface-active substance content is 0.02 to 0.25 mg. Add two drops of
hydrochloric acid solution 1 + 1.
Combine 1 ml of barium chloride solution, or 1 ml of potassium
chloride in the case where more than 200 mg/1 of sulfates appear, and 1
ml of phosphotungstic acid solution. Place the sample in boiling water
and heat for 15 min. Spin off the sediment in a centrifugal machine for
15 min at a speed of 2,500 to 3,000 r/min. Carefully decant the
liquid from above the sediment; add 10 ml of hot distilled water; mix
thoroughly; and spin off the sediment again. Repeat the spinning twice.
Decant, and add 3 ml of sulfuric acid. Mix, and after the sediment has
totally dissolved, add 1 ml of hydroquinone. Mix. Fill a sample to 10
ml with sulfuric acid, and mix; after 15 min, measure the absorption,
providing a light path of 1 cm.
DETERMINATION OF PERMANGANATE COD
Principle
A sample of water or sewage is treated with an excess of potassium
permanganate solution in an acidified medium at the temperature of
boiling water bath. The amount of the oxidant consumed is then estimated
by the titrimetric method. The result is calculated from the net
equivalence of KMn04 consumed and is expressed as milligrams of oxygen
per liter of the sample.
443
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Procedure
The container with analyzed water or sewage is well shaken and the
exact volume of TOO ml of the sample is transferred to a conical flask. For
highly contaminated samples, a smaller volume is measured and made up to 100
ml with distilled water. Then, 5 ml of H2S04 (1:2) and 20 ml of 0.01 N
KMn04 are added and the flask is immersed in boiling water bath for 30 min.
After removing the flask from the water bath, 20 ml of 0,01 N oxalic acid is
added and the solution is titrated with 0.01 N KMn04 until the first perma-
nent slight pink color appears.
Calculation:
mg/1 0 =
(a-b) * F x 80
V
where: a - volume (in ml) of 0.01 N KMnO, required for titration;
b = volume (in ml) of 0.01 N KMnO, consumed for the blank
titration of distilled water required for dilution of
sample;
F = calculation factor for conversion of volume of the
KMnO, solution used in titration into exactly 0.01 N
standard solution; and
V = volume (in ml) of analyzed sample.
DETERMINATION OF ALUMINUM ANALYSIS
The aluminum content was determined spectrophotometrically using the
solubility of the aluminum complex with 8-hydroxichinoline in chloroform.
To 50 ml of filtered wastewater were added 10 ml of CH3C1, 10 ml of 5 per-
cent solution of 8-hydroxichinoline, and 10 ml of 10 percent ammonium ace-
tate. The sample was precipitated for several minutes. Next it was left
for separation of the layers. The chloroform layer was separated. Extrac-
tion was carried out another two times using 10 ml of chloroform each time.
The chloroform extract was collected and the extinction determined. The
aluminum concentrations were read off from the standard curve.
When iron in the wastewater was an obstacle to determination, the
sample was acidified and oxidized, and ammonium was added. The arising iron
compound was extracted several times with isoamyl alcohol. After the iron
ions in the sample had been removed, the aluminum was determined according
to the method described previously. The method of determining aluminum was
checked by using weight determination with the same reagent (8-hydroxi-
chinoline).
444
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APPENDIX B
METHOD OF DETERMINING FINAD INDEX
DETERMINATION OF PHENOL NUMBER
Principle of Determination
In an alkaline medium (pH about 10.0) and in the presence of potassium
ferrocyanide, phenol with p-aminoantipyrine forms an indophenol dye, soluble
in chloroform, colored greenish-yellow to orange.
Procedure
Increasing doses of carbon are added to 0.1 mg/1 of phenol solution,
amounting to from 2 to 50 mg/1.
After 3 h of contact time, 5 ml of the buffer solution (20 percent
NH4C1 in a 25 percent ammonium hydroxide solution) and, after mixing, 3 ml
of 8 percent potassium ferrocyanide are added to 500 ml of the filtrate.
After 3 min, 15 ml of chloroform are added and the sample is extracted.
The extraction is repeated with a second dose of chloroform and the combined
extracts are filled up with chloroform in the cylinder to the volume of 25
ml. The measurement is made using the spectrophotometer at 460 nm. The
result is read from the standard curve previously prepared [1],
Calculation
A Freundlich isotherm is plotted on double log-log paper:
!og ~~~ = f * log c
where: x = the amount of adsorbed phenol (mg/1),
m = carbon amount (g), and
C = final phenol concentration (mg/1).
The phenol index is read from the diagram by extrapolating the straight line
to its intersection with the parallel one to the axis of ordinates at the
point log 0.01. The obtained value from - corresponds to the diminution
of the phenol solution concentration from 0.1 to 0.01 mg/1. Then:
445
-------�
m =
x
0.1-0.01 = 0.09
y id
The phenol index =
0.09
y
g of carbon.
DETERMINATION OF IODINE NUMBER
Principle of Determination
The iodine amount not bound by the carbon is determined volumetrically
by means of sodium thiosulphate.
Procedure
To 20 ml of 0.2 N iodine solution is added 0.2 g of carbon. Then the
solution is mixed for 4 min and filtered through a soft paper filter. The
volumetric determination of the residual iodine amount is performed using
0.1 N sodium thiosulfate solution. Simultaneously, a blank test (without
carbon) is carried out. This makes it possible to determine the residual
iodine amount in the solution after adsorption on the filter [2].
DETERMINATION OF INDOLE NUMBER
Principle of Determination
Indole, together with sodium nitrite and sulfuric acid, forms a red-
colored nitrozoindole, extracted by means of isoamyl alcohol and determined
spectrophotometrically at 500 nm.
Procedure
An increasing carbon dosage from 2 to 20 mg/1 is added to 1 1 of the
indole solution at the concentration 0.6 mg/1. After 30 min of mixing the
sample, 0.5 ml of 1 percent NaN02 and 2 ml of concentrated H2S04 are added
to 100 ml of the filtrate. After 2 h the arising color is extracted with 25
ml of isoamyl alcohol, and the sample is determined at 500 nm. The obtained
result is read from the standard curve previously prepared [3].
Calculation
The Freundlich isotherm is plotted, and from the diagram the value
y is read from — , corresponding to C = 0.1 where x = 0.5 and m = the
m
indole index, and the indole index =
DETERMINATION OF PHENAZONE NUMBER
Principle of Determination
0.5
g of carbon.
Antipyrine (phenazone) treated with iodine forms iodoantipyrine, sol-
446
-------�
uble in chloroform. The nonbonded iodine amount is determined by means of
sodium thiosulfate.
Procedure
Approximately 0.3 g of carbon is added to 50 ml of 0.4 percent phena-
zone solution and then mixed for 20 min. Afterwards, the solution is fil-
tered through a hard filter, with the first 15 ml of the filtrate rejected.
To 25 ml of the filtrate are added 2 g of sodium acetate and 30 ml of
0.1 N iodine solution. The whole sample is then left for 20 min; then the
precipitate is dissolved in 100 ml of chloroform, and volumetric determina
tion by means of 0.1 N sodium thiosulfate (NA2S203) is made. The blank
sample (without carbon) was dealt with in the same way [2, 4].
Calculation
°'94 (7f"n
The phenazone index =
P
where: p = carbon amount in g,
N = amount of 0.1 N sodium thiosulphate (NA^O ) solution in
ml necessary for the volumetric determination of the tested
sample, and
n = amount of the 0.1 N sodium thiosulphate (Na2S 0 ) solution
necessary for the volumetric determination of the blank
sample.
DETERMINATION OF DETERGENT NUMBER
Principle of Determination
Anionic detergents, including LSS, form with methylene blue a complex
organic compound of a blue color, soluble in chloroform. The color inten-
sity is measured spectrophotometrically at 652 nm and compared with the
standard curve.
Procedure
Carbon doses increasing from 5 to 50 mg/1 are added to 1 1 of the LSS
solution of a concentration of 0.25 mg/1. After 60 min of continuous con-
tact, the LSS amount in the filtrate is determined. The 100-ml sample is
alkalized in the presence of phenophtalein by means of 1 N of NaOH solution
and afterwards acidified with sulfuric acid. Then it is transferred to a
separator, and 10 ml of chloroform and 25 ml of methylene blue are added.
(Thirty ml of 0.1 percent solution are added to 500 ml of water; then 6.8 ml
447
-------�
of the concentrated sulfuric acid (H2S04) and 50 g of NaH2P04*H20 are added.
After it completely dissolves, the sample is filled with distilled water to
1 I-)
The whole sample is extracted vigorously for 30 s and left for separa-
tion. The chloroform layer is transferred to another separator, and the
extraction procedure is repeated twice more using 10 ml of chloroform.
In the second separator, 50 ml of rinsing solution is added to the
combined extracts (6.8 ml of the concentrated sulfuric acid and 50 g of
NaH2P04-H20 are added to 500 ml of distilled water, and after the sample has
been dissolved, it is filled up to the volume 1 1) and vigorously shaken.
After settling, the chloroform layer is poured out into a 50-ml flask. The
rinsing is repeated twice with the addition of 10 ml of chloroform. The
chloroform extracts combined are filled to 50 ml with chloroform. The ad-
sorption is determined at 652 nm [5].
Calculation
The Freundlich isotherm, log
m
- log C, is plotted
x
corresponding
and determined from the diagram, the value from
to C = 0.025, where x = 0.225 and m = detergent index. The detergent
0.225
index - —
y
g of carbon.
References
1. Water Institute Management, "Analytical procedure for determination
of pollutants in surface water and wastewaters (Przepisy analytyczne
oznaczania zanieczyszczen w wodach powierzchniowych i sciekach)." IGW,
Warszawa, 1972.
2. Gomella, C. "Criteria for selecting activated carbons for treatment
of waters (Criteres de choix d'un charbon actif pour le traitement des
eau).11 Techniques Municipales Veau, 383, Octobre 1970.
3. White D., and G. A. Vaughan. "The determination of indole in tar
fractions." The Analyst, 997, 597, 1957.
4. Bauer, K. H. "Analysis of organic compounds (Analiza zwiazkdw organ-
icznych)," PWT, Warszawa, 1957.
5. Standard Method for the Examination of Water and Wastewater, 13th
Edition, APHA AWWA WPCF, 1971.
448
-------�
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APPENDIX C
DECREE OF THE MINISTRY COUNCIL (extract)
dated: November 29, 1975
On the water classification and conditions which should be
fulfilled by wastewaters discharged to receiving waters.
In Poland three classes of purity have been laid down for inland surface
waters:
1. The first class includes those waters which are intended for:
a. drinking water supply,
b. supply to an industrial plant requiring water of drinking water
quality,
c. breeding of fish of the salmon type.
2. The second class includes waters which are intended for:
a. breeding of fish, with the exception of the salmon type,
b. water supply for domestic livestock,
c. organized bathing facilities,
d. recreational purposes and water sports.
3. The third class includes waters intended for:
a. supply to an industrial plant, except for those industries requir-
ing water of drinking water quality,
b. irrigation of agricultural land and greenhouses.
2. Table 1 of the decree defines the size of admissible pollutants of
inland surface waters in individual classes of purity.
3. a. The pollutants contained in an average hour-long outflow of waste-
water fed into inland surface waters cannot:
1. cause an excess of admissible pollutants in the receiver in
relation to the normal water flow in the place where the
wastewater is fed in or in relation to the active volume of
standing water,
2. contain solid waste or settlable suspended solids which have
been left for 2 hours in an amount greater than 0.5
cm3/dm3, or dangerous substances (DDT and PCB).
450
-------�
If the maximum hour-long outflow of wastewater exceeds by at least
twofold the average hour-long of wastewater, the maximum outflow
is taken as the basis for determining the conditions which the
wastewater should fulfill.
The long term low-average flow of the receiving stream at the
point of discharge has been adopted as the design flow to use in
determining permissible waste loading.
451
-------�
Table C-1
Permissible pollutant concentration for surface waters
Parameters
1
Oxygen dissolved
BOD5
Permanganate COD
COD
Saprobity
Chloride
Sulfate
Hardness
Residue total
filterable
Residue total
nonfilterable
Temperature
Odor
Color
pH value
Nitrogen (ammonia)
Nitronen ("nitrate)
Units
2
mg 02/dm3
mg 02/dm3
mg 02/dm3
mg 02/dm3
mg Cl/dm3
mg S04/dm3
meg/dm3
mg/dm3
mg/dm3
°C
mg Pt/dm3
PH
mg NNH /dm3
ma N.,« /dm3
Pur
I
3
> 6
< 4
<10
<40
oligo to-
betamezo
<250
<150
<7
<500
<20
<22
<3R
n
6.5-
8.0
<1.0
<1.5
i t y c 1
II
4
> 5
< 8
<20
<60
betamezo
to-alpha-
mezo
<300
<200
£H
<1000
<30
<26
natural
a t u r
6.5-
9.0
<3.0
<7.0
ass
III
5
> 4
<12
<30
<100
alpha-
mezo
<400
<250
<14
<1200
<50
<26
specific
a 1
6.0-
9.0
<6.0
<15.0
452
-------�
Table C-l (con.)
Permissible pollutant concentration for surface waters
Parameters
1
Nitrogen (organic)
Total iron
Manganese
Phosphate
Rhodanate
Cyanides (without
complex cyanide)
Complex cyanides
Volatile phenols
Detergents
Oils
Ether ic extract
Lead
Mercury
Copper
Zinc
Cadmium
Chromium +3
Chromium +6
Units
2
mg N /dm3
a org
mg Fe/dm3
mg Mn/dm3
mg P04/dm3
mg CNS/dm3
mg CN/dm3
mg Me/CN(x)
/dm3
mg/dm3
mg/dm3
mg/dm3
mg/dm3
mg Pb/dm3
mg Hg/dm3
mg Cu/dm<
mg Zn/dm3
mg Cd/dm3
mg Cr/dm3
mg Cr/dm3
Purity c
I II
3 4
< 1 . 0 <2 . 0
£1.0 £1.5
<0.1 <0.3
£0.2 £0.5
£0.02 £0.5
£0.01 £0.02
<1.0 <2.0
£0.005 £0.02
<1.0 <2.0
_
£5.0 £15.0
£0.1 £0.1
£0.001 £0.005
<0.01 <0.1
<0.01 <0.1
<0.005 <0.003
<0.5 <0.5
<0.05 £0.1
lass
III
5
£10.0
£ 2.0
£ 0.8
£ 1.0
£ 1.0
£0.05
£ 3.0
£0.05
£ 3.0
-
£40.0
£ 0.1
£0.01
£ 0.2
£ 0.2
£ 0.1
£0.5
£0.1
453
-------�
Table C-l (con.)
Permissible pollutant concentration for surface waters
Parameters
1
Nickel
Sum of heavy
metals
Silver
Vanadi urn
Boron
Arsenic
Chlorine, total
residual
Fluorine
Sulfide
Acrilonitrile
Caprolactam
Units Purity class
I II III
2 345
mg Ni/dm3 1^-0 £1.0 £l-0
mg/dm3 £5.0 <\$.Q £40.0
mg Ag/dm3 £0.01 £0.01 £0.01
mg V/dm3 £l . 0 £l . 0 <1 . 0
mg B/dm3 £1.0 £l . 0 £1.0
mg As/dm3 £0.05 0.05 0.2
mg Cl2/dm3 - -
mg F/dm3 £1.5 £1.5 £2.0
mg S/dm3 - - 0.1
mg/dm33 £2.0 £2.0 £2.0
mg/dm3 £1.0 1^-0 £l . 0
Coli index
Panthogenic
bacteria
Fish bioassay
24 h
>0.01
undetectable undetect- undetect-
able able
positive-water should not cause
death of fish in the course of
24 h
454
-------�
GLOSSARY
abrasion number of activated carbon: Coefficient expressed
n
">
j°" lst°*hte™: Q««>t1ty of adsorbed substance per unit of adsorbent
related to the concentration of adsorbate at equilibrium.
n
Cbeennscorched^t°«,aohA 1" ?er™^> rewlnlnfl after the carbon has
oeen scorched at 850° C in relation to carbon weight.
bed porosity: Relation of volume of all free spaces to total carbon volume.
carrier: Chromatographic column filling and chromatographic plate covering.
chromatogram: In column chromatography-the sorbent column after expansion
?^arated substances; in thin-layer chromatography-
'
substances
W1'th clear
wastewater in
of separated
to carry out
coagulation:
A physicochemical process consisting of the removal of pollut
8 Wa of fl°"" and sedimentation of
that are difficult to
by the number of milliliters of waste-
°f
column chromatography: Analytical technique consisting of the separation of
components of a mixture on chromatographic column filling. P f
455
-------�
GLOSSARY (continued)
contact coagulation: Method of coagulation whereby a coagulant salt is
added to the wastewater influent to the upflow gravel-sand filtration
bed; coagulation occurs in the filtration bed.
content of substances dissolved in hydrochloric acid: Mass of ^residue,
in percentages, obtained after the carbon has been boiled in hydro
chloric acid in relation to carbon weight.
content of substances soluble in water: Mass of dry residue. In
ages, obtained after the carbon has been boiled in 200 ml of
water, in relation to carbon weight.
conventional coagulation in a reactor with suspended floes: A method of
coagulation whereby wastewater with coagulant added flows through a
layer of suspended floes, in which the coagulation process occurs.
developing the chromatogram: Filtration through the column with a band of
pure solvent previously adsorbed on it or with an admixture of strongly
surface-active substance.
dye capacity of resins: Amount in milligrams of dye absorbed on 1 ml of
resin in defined reaction conditions.
dynamic activity: Adsorptive capacity expressed by time lapse of Protective
activity of the activated carbon layer from the moment adsorption
begins up to the moment traces of vapors and gases appear behind the
carbon layer,
eluation: Gradual dissolution of separated substances in a column or on a
thin-layer plate with water or other suitably chosen solvents.
eluent- In thin-layer and column chromatography, the fluid used to wash out
the substance from the column or from the thin-layer plate.
exchange capacity for wastewater: Alkalinity of wastewater expressed in
milligrams of CAC03 in relation to 1 1-
exchange capacity of resin: Maximum number of ions, in milligram-
equivalents, which can be linked by 1 ml of resin,
extraction: Individual operation used to separate fluid or solid mixtures;
the component from the extracted phase is transformed into a solvent.
FINAD: Index defining adsorptive properties with regard to five pollutant
parameters: phenol, iodine, indole, phenazone, and detergents.
granulation: Measurements of grains (particles) of carbon, given in milli-
meters .
456
-------�
GLOSSARY (continued)
hydraulic loading BV/h: Bed loading per hour.
o
macropores: Pores with radii of about 10,000 A.
mechanical endurance: Fraction of activated carbon, in percentages, not
subject to disintegration in a ball mill.
methylene number: Number of milliliters of 0.15 percent methylene blue
decolorized by 0.2 grams of activated carbon.
o
micropores: Pores with radii of about 10 A.
milligram number: Number of milligrams of activated carbon necessary for
decolorizing 200 ml of standard solution of molasses.
ozone dose mg/1: Amount of ozone fed into 1 1 of wastewater.
porometric determination of pore size: Method of determining capillary
o
volume at radii less than 100 A.
porosity of activated carbon: Carbon property of having pores, i.e., open
or closed spaces and channels of different diameters.
porozimetric determination of pore size: Method of determining capillary
o
volume at radii in the range of 75,000 to 100 A.
regeneration capacity: Relation, in percentages, of the amount of activated
carbon obtained as a result of regeneration to the amount of carbon
before regeneration.
regeneration of ion-exchange resins: Transforming the exhausted ion-
exchange resin again into a chloride or hydrogen form.
subgrain: The grain which remains after sifting, although the dimension of
this grain is smaller than that of the sieve openings.
thermal regeneration: Regeneration consisting of the burning of pollutants
at a temperature of about 800° C in the presence of or without steam.
tar and oil substance content in carbon: A test consisting in boiling down
activated carbon in 10 percent solution of sodium hydroxide and ascer-
taining whether the filtrate is colorless.
thin-layer chromatography: Analytical technique consisting in the sepa-
ration of components of a mixture on a chromatographic plate; the
migrational center of separated substances is constituted by a suitably
prepared plate covered with a thin layer of sorbent.
457
-------�
GLOSSARY (continued)
total capacity of resins: Number of milligram-equivalents (meq) of ions
removed by a volume of resin (ml).
total surface area activated carbon: Total surface area corresponding to a
unit of activated carbon mass, measured by the BET method.
volatile substance content in carbon: Number of volatile parts in the
carbon, expressed in percentages, in relation to carbon weight.
water absorptivity: Pore volume accessible for water expressed in grams of
water per 1 g of carbon.
458
-------�
TECHNICAL REPORT DATA
(Please read Inductions on the reverse before completing)
— . — IT B(=f
2.
3. RECIPIENT'S ACCESSION NO.
5 REPORT DATE
March 1978
6. PERFORMING ORGANIZATION CODE
8. PERFORMING ORGANIZATION REPORT NO.
10. PROGRAM ELEMENT NU.
1BB610
11. CONTRACT/GRANT NO
Public Law 480, SFC
055323
13 TYPE OF REPORT AND PERIOD COVERED
Final; 6/72-6/77
14. SPONSORING AGENCY CODE
EPA/600/13
REPORT NO.
EPA-600/2-7 8-072 , .
4. TITLE AND SUBTITLE RemOval of Color, Detergents, and
Other Refractory Substances from Textile Wastewater
J
|7~."AUTHOR(S)
Jerzy Kurbiel
9 PERFORMING ORGANIZATION NAME AND ADDRESS
Polish Institute of Meteorology and Water
Management
Cracow Division
Cracow, Poland
12. SPONSORING AGENCY NAME AND ADDRESS
EPA Office of Research and Development
Industrial Environmental Research Laboratory
Research Triangle Park, NC 27711 .
15.SUPPLEMENTARY NOTES !ERL.RTP project officer is Max Samfield, Mail Drop 62, 919,
541-2547.
1*. ABSTRACT The reoort gives results of laboratory and pilot scale research to deter-
Stth NaOCl and followed by adsorption on activated carbon as the final step.
DESCRIPTORS
i - —
Pollution Sludge
Textile Industry Filtration
Waste Water Coagulation
Decoloring Adsorption
Detergents Activated Carbon
Refractory Materials Ozonization
Ton Exchange Resins
13. DISTRIBUTION STATEMENT
Unlimited
^—^^^—
EPA Form 2220-1 (9-73)
—^-»^
KEY WORDS AND DOCUMENT ANALYSIS
b.lDENTIFIERS/OPEN ENDED TERMS
Pollution Control
Stationary Sources
Biological Treatment
Hyperfiltration
19. SECURITY CLASS (ThisReport)
Unclassified
20. SECURITY CLASS (Thispage)
Unclassified
COSATI Field/Group
13B OTA
11E 07D
13H
11K
11G
14B
22. PRICE
459
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