1. Bulking Control Jae K. (Jim) Park, Professor
Dept. of Civil and Environmental Engineering
University of Wisconsin-Madison

2. Activated Sludge Separation Problems (1)
Dispersed growth
Cause: Microorganisms do not form but are dispersed, forming only small clumps or single cells.
Effect: Turbid effluent. No zone settling of sludge.
Slime (jelly) viscous bulking; or non-filamentous bulking
Cause: Microorganisms are present in large amounts of exocellular slime. In severe cases, slime imparts a jelly-like consistency to the activated sludge.
Effect: Reduced settling and compaction rates. Virtually no solids separation in severe cases resulting in overflow of sludge blanket from secondary clarifier. In less severe cases a viscous foam often is present.
Bulking
Cause: Filamentous organisms extend from flocs into the bulk solution and interfere with compaction and settling of activated sludge.
Effect: High SVI - very clear supernatant. Low RAS and WAS solids concentration. In severe cases, overflow of sludge blanket occurs. Solids handling processes become hydraulically overloaded.

3. Settling Problem in Activated Sludge Processes

4. Activated Sludge Separation Problems (2)
Pin floc or pinpoint floc
Cause: Small, compact, weak, roughly spherical flocs are formed, the larger of which settle rapidly. Smaller aggregates settle slowly.
Effect: Low SVI - a cloudy, turbid effluent
Blanket rising
Cause: Denitrification in secondary clarifier releases poorly soluble N2 gas which attaches to activated sludge flocs and floats them to the secondary clarifier surface.
Effect: A scum of activated sludge forms on surface of secondary clarifier.
Foaming/scum formation
Cause: Caused by non-degradable surfactants and by the presence of Nocardia spp. and sometimes by presence of Microthrix parvicellar.
Effect: Foams float large amounts of activated sludge solids to surface of treatment units. Nocardia and Microthrix foams are persistent and difficult to break mechanically. Foams accumulate and can putrefy. Solids can overflow into secondary effluent or overflow tank free-board on to walkways.

6. Floc Formers

7. Foaming
Nocardia spp.

8. Ideal, Non-Bulking Activated Sludge Floc
Filamentous organisms and floc forming organisms in balance
Strong, large floc
Filaments do not interfere
Clear supernatant
Low SVI
Filamentous
backbone
Filamentous Bulking Activated Sludge Floc
Filamentous organisms predominant
Strong, large floc
Filaments interfere with settling, compaction
Clear supernatant
High SVI
Pin Point Floc
Low filamentous organisms
Weak, small floc
Turbid supernatant
High SVI

10. Young Sludge White foam
The floc is barely forming and does not settle. A large amount of floc particles are left in the supernatant. Fluffy floc that is left behind in the supernatant is called straggler floc.

12. A Typical Sludge Old Sludge
A typical activated sludge system with a mixed liquor suspended solids (MLSS) color that would be described as light brown or "coffee with cream".
The MLSS color is dark brown, the foam also has a darker color.

13. Too much treatment time in an activated sludge system can cause an old sludge condition. This is sometimes called over-aeration. Over-aeration causes the floc to be very compact and dense. It settles quickly and leaves very small floc particles, called pin-floc, in the supernatant. Some of the floc particles are so light that they float to the surface and spread out in the clarifier. This condition is called ashing.

14. Over Aeration
Pin Point Floc (in a Clarifier)
Surface ashing

15. Denitrification Good settling sludge Sludge blanket rising
2NO e- + 12H+ → N2  + 6H2O
Good settling sludge
Sludge blanket rising N2
Activated sludge

16. Filamentous Organism Types
Between 25~30 types observed
Approx. 10~12 types commonly seen
Indicative of causative conditions
Grow as filaments (trichomes) rather than individual cells or cell aggregates (flocs)
A necessary and beneficial component of the activated sludge floc community
Beneficial effects: enhance floc structure and produce low substrate residuals
Detrimental effects: pin floc, bulking, foaming
Factors affecting filamentous organism growth
Sludge age, DO, waste characteristics, reactor configuration (or waste feeding regime), and presence of initial unaerated zones

17. Causes of Bulking (1) DO concentration
Four filamentous bacteria proliferate with low DO.
At low to moderate sludge age: type 1701, S. natans and Haliscomenobacter hydrossis
At high sludge age: Microthrix parvicella
All of these microorganisms usually respond well to increases in dissolved oxygen.
Nutrient deficiency
Type 021N, Thiothrix spp., type 0041 and type 0675 grow with nitrogen and/or phosphorus deficiencies. Biological slime often accumulates as well with the growth of these microorganisms. Adding ammonia or phosphoric acid to the aeration tank is usually required to control these microorganisms.

18. Sphaerotilus natans, 1000x
Microthrix parvicella, 1000x
Haliscomenobacter hydrossis, 1000x

19. Type 021N, 1000x
Thiothrix II, 1000x
Thiothrix I, 1000x

20. Causes of Bulking (2) Low pH
Fungi can proliferate under low pH conditions. The condition is most often found when the influent pH is low. However, it may also be observed in nitrifying systems or oxygen-activated sludge systems where the natural alkalinity of the wastewater is low. Elimination of the low influent pH or addition of alkalinity to the system is required to subdue the fungi.
Sulfide
Thiothrix spp., type 021N, Beggiatoa spp. and type 0914 can all oxidize sulfide to elemental sulfur and incorporate the sulfur into the cell. The sulfur can be seen in the cell when observed under a microscope. The sulfide's source must be eliminated or the sulfide "tied up" chemically.

21. Causes of Bulking (3) Readily metabolized food
Some organisms grow well on easily broken-down, soluble materials. Sugars and short carbon-chain materials are examples. These organisms are S. natans, type 021N, Thiothrix spp., H. hydrossis, Nostocoida limicola and type Reducing the sludge age and installing a selector often help to control N. limicola and type1851.
Slowly metabolized food
Types 0041, 0092, and 0675 and M. parvicella are able to grow on slowly broken-down foods and are prevalent in systems that biologically remove nitrogen and phosphorus. Their growth is also augmented by the use of complete mixing in the aeration tank. Control is attained by reducing the sludge age, using plug-flow if possible, and maintaining a uniform DO. Anoxic selectors do not help because some of these microorganisms may be able to denitrify.

22. Not a filamentous organism
Nostocoida limicola, 1000x
Nitrosomonas, 1000x
Not a filamentous organism
Nocardia, 1000x

23. Causes of Bulking (4) Reactor configuration
At short to moderate sludge age, properly designed selectors (aerobic, anoxic, and anaerobic) can control the following organisms:
Type 021N, Thiothrix spp., S. natans, type 1701, H. Hydrossis, and Nocardia
Unaerated zones
At long sludge age (e.g., nitrifying BNR plants), the presence of unaerated zones allows the growth of the following organisms that are not controlled by any type of selector:
M. parvicella, type 0092, type 0041, and type 0675
Nature of substrate
Soluble and readily biodegradable vs particulate and slowly biodegradable
Organisms preferring soluble readily biodegradable substrates:
S. natans, type 021N, Thiothrix spp., H. hydrossis, N. limicola, and type 1851

24. Control of Bulking (1) Low DO aerobic zone growers
Features: readily biodegradable substrate
low DO
low moderate sludge age
Organisms: S. natans, type 1701, H. hydrossis
Control: aerobic, anoxic, or anaerobic selectors
Mixotrophic aerobic zone growers
moderate to high sludge age
sulfide oxidized to stored sulfur
rapid nutrient uptake rates under nutrient deficiency
Organisms: Type 021N, Thiothrix
nutrient addition
eliminate sulfide

25. Control of Bulking (2)
Other aerobic zone growers
Features: readily biodegradable substrate
moderate to high sludge age
Organisms: Type 1851, N. limicola
Control: aerobic, anoxic, or anaerobic selectors
Aerobic, anoxic, and anaerobic zone growers
Features: grow in aerobic, anoxic, or anaerobic (BioP) systems
high sludge age
grow on hydrolysis products of particulate (?)
Organisms: Type 0041, type 0675, type 0092, M. parvicella
Control: ?
Because a wide variety of causes for filamentous organism growth exist, a wide range of control measures are required.

26. Mechanisms of Filamentous Organism Bulking (1)
1. Surface to volume ratio
Filamentous organisms
Floc formers (FF)
Unfavorable conditions
Substrate (low)
DO (low)
Nutrient deficiency
More frequently found in
CSTR
PFR
Low substrate gradient due to dilution after instantaneous mixing
High substrate
gradient due to less dilution
CSTR: continuously-stirred tank reactor
Prone to bulking
PFR: plug flow reactor

27. Mechanisms of Filamentous Organism Bulking (2)
2. Kinetic hypothesis
Floc formers (FF)
Bulking
Filamentous organism (FO)
µm Ks
FO low low
FF high high
Low substrate S
Failed to explain microbial population dynamics with temporal and spatial substrate transients

28. Mechanisms of Filamentous Organism Bulking (3)
3. Accumulation-regeneration hypothesis FF FO
Capable of rapidly accumulating and storing substrate when exposed to a high substrate concentration compared with filamentous organisms
When high substrate gradient exists, i.e., PFR, FO cannot compete; thus, no bulking
PFR: high substrate gradient
CSTR: low substrate gradient

29. Methods of Creating Substrate Gradient
Temporal
Batch operated
Example: sequencing batch reactor (SBR)
Spatial
Plug flow reactor (PFR)
Example: conventional activated sludge process
Selector (a separate reactor ahead of the aeration basin) (see the detail later)
Example: biological nutrient removal processes

30. Changes in Soluble COD and Respiration Rate over Time
PFR (batch operated): rapid COD uptake due to limited food available
CSTR: slow COD uptake due to unlimited supply of food

31. Mechanisms of Filamentous Organism Bulking (4)
4. Starvation resistance hypothesis
Slow growing FO with high starvation resistance
Fast growing FF with moderate starvation resistance (low DO)
Fast growing FO with limited starvation resistance
Fast growing FF with moderate starvation resistance (high DO)
Fast growing FF with high DO
At low DO,
Fast growing FO
wins
Fast growing FF with low DO
Slow growing FO
wins S S*
S**

32. Physical Characteristics of FF and FO
Characteristics FF FO Max. substrate uptake rate High Low Max. specific growth rate High Low Endogenous decay rate Low High Decrease in µ from low S conc. Significant Moderate Resistance to starvation Low High Decrease in µ from low DO Significant Moderate Organic sorbability in excess S High Low Denitrification capability Yes No Luxury uptake of P Yes No

33. DO
SVI
Bulking
Bulking

34. Design DO and Substrate Utilization Rate
At higher q, more
DO needed
A typical municipal WWTP

35. Selectors
Microorganisms with rapid sol. COD uptake/storage sequestrate substrate in selector and use it to survive in aeration basin (starvation phase)
Microorganisms require energy to take up and store sol. COD in selector. Energy is obtained from
Oxidation of COD using O2: Aerobic selector
Oxidation of ammonia to NO3-: Anoxic selector
Hydrolysis of stored poly-P to PO43-: Anaerobic selector
Aerobic: kinetic only
Anoxic: kinetic + ability to denitrify
Anaerobic: kinetic + ability to store polyphosphate

36. Selector Types Selectors Secondary Aeration clarifier basin Effluent
Influent
RAS
WAS
Influent
Secondary
clarifier
Aeration
basin
Effluent
Selectors

37. Comparison of Biological Selectors (1)
Aerobic
Advantages
Simple process, no additional internal recycle streams other than RAS
Relies on basin geometry, not nitrification
Disadvantages
Does not reduce O2 requirements
Requires more complex aeration system design to meet maximum O2 uptake rate in the initial high F/M zone
May require patent fee if operated within a certain range of DO conditions

38. Comparison of Biological Selectors (2)
Anoxic
Advantages
Tends to buffer nitrification (recovers approx. 3.5 lb alkalinity as CaCO3 per lb of NO3--N denitrified)
Lowers O2 demand in a nitrification process (recovers approx lb O2 per lb of NO3- reduced)
The initial high F/M region occurs in the anoxic zone with the high O2 demand met by NO3- instead of O2
Disadvantages
Cannot be used with a process that does not nitrify
Uses an additional recycle stream
Requires care in design and operation to minimize the introduction of O2 in the anoxic zone. Poor system design could induce low DO bulking

39. Comparison of Biological Selectors (3)
Anaerobic
Advantages
Simple design, no internal recycle other than RAS
The simplest of selector systems to operate
Can be used for biological phosphorus removal
Disadvantages
A patented process and require a licensing fee
Does not reduce O2 requirements
May not be compatible with long SRTs
Requires care in design and operation to minimize the introduction of NO3- and O2 in the anaerobic zone. Poor system design could induce low DO bulking

40. Design Parameters
Parameter Recommended value Source
Initial substrate concentration > 80 mg COD/L Lee et al. (1982)
Initial F/M 20~25 g COD/g MLVSS·day Lee et al. (1982)
8~12 g COD/g MLVSS·day Jenkins (1988)
Initial floc loading 50~150 g COD/g MLSS Eikelboom (1977&82)
No significance Lee et al. (1982)
Fractional substrate removal 50~70% Eikelboom (1977&82)
in all selectors (soluble and 80% Chudoba et al. (1987)
degradable)
Soluble substrate leaving selector 60 mg COD/L Jenkins (1988)
Substrate gradient between first 25 mg/L Chudoba et al. (1973)
selector and main aeration basin
Aeration basin dispersion number < 0.2 Tomlinson (1979)
Number of compartments 1~5 van Niekerk (1986)
Hydraulic retention time 12~25 min van Niekerk (1986) 5~20 min Casey et al. (1975)

41. Initial Substrate Concentration
Design Guideline (1)
Initial Substrate Concentration 80
Initial substrate concentration: > 80 mg COD/L (Lee et al., 1982)

42. Design Guideline (2) Initial F/M (COD)
Initial F/M: 20~25 g COD/g MLVSS·day (Lee et al., 1982)

43. Soluble COD Leaving Selector
Design Guideline (3)
Soluble COD Leaving Selector 60
Soluble COD leaving selector: < 60 mg/L (Jenkins, 1988)

44. Control of Activated Sludge Bulking Using Substrate Gradients
Temporal - intermittently fed A.S., e.g., SBR
Spatial
Dispersion number (D/uL): < 0.1
or # of CSTR in series: > 6
Floc loading (F/L): 50~150 g COD/g MLSS
PFR:
CSTR:

45. Estimation of # of CSTRs in Series and Dispersion Number, D/uL
Levenspiel, O. (1972). Chemical Reaction Engineering, 2nd Ed., pp

47. Dispersion Model u L
D = D = 0

48. Example (1) Determine dispersion number and # of CSTRs in series.
Time, t (min)
Tracer conc., C (g/L) 5 10 15 20 25 30 35 3 4 2 1

49. Example (2)

50. Relationship between Sludge Settleability and Dispersion Number
Dispersion number (D/uL): < 0.1

51. # of CSTR in series: > 6
Relationship between Sludge Settleability and Number of Equivalent Tanks
# of CSTR in series: > 6 6

52. Bulking Control - Summary
1. Change of the mixing configuration in the aeration basin (low dispersion number) 2. Selector installation - promotes growth of floc- forming bacteria 3. Chlorine injection (hydrogen peroxide also an option) 4. Increase in the aeration basin DO - low DO bulking 5. Nutrient addition - nutrient deficiency bulking

53. Bulking Control by Chlorination
Dose based on g Cl2/kg MLVSS/day (lb Cl2/1000 lb/day)
Low dose: 2~3 g Cl2/kg MLVSS/day
Moderate dose: 5~6 g Cl2/kg MLVSS/day
High dose: 10~12 g Cl2/kg MLVSS/day
Dose controlled by monitoring trend in SVI and microscopic examination.
Dose point selected to achieve adequate dosing frequency of 3 time/day or more.
Excellent mixing at dose point required to avoid turbidity formation.
Cl2
Cl2
Secondary
clarifier
Aeration basin
Cl2
RAS
WAS
Most common

54. Aerobic Selector Design
Staged reactor with F/M gradient. First stage loading important to control viscous bulking. (F/M)I = 8~12 g COD/g MLVSS·day
SOUR 50~60 mg O2/g MLSS·hr, but only 15~25% of substrate oxidized. DO 1~2 mg/L.
Selector HRT often 10~20 min for municipal wastewater
Three to four compartments (1/1/1/2 or 1/1/2)
F/M=12 kg COD/kg MLSS·hr
F/M=6 kg COD/kg MLSS·hr
F/M=3 kg COD/kg MLSS·hr
Wastewater
RAS

55. Anoxic Selector Design
Reactor staging not necessary. F/M gradient less than aerobic selector (6/3/1.5 g COD/g MLSS·day)
Provide mixers rather than aeration. About 8 g NO3--N req./g COD oxidized (5 g NO3--N req./g BOD oxidized).
NO3- supplied by RAS and mixed liquor recycle
Rapid denitrification rates (5~10 mg NO3--N/g MLSS·hr at 20°C).
Anoxic zone HRT often about 1 hr for municipal wastewaters. Three compartments (1/1/2)
Anoxic selector
Secondary
clarifier
Aeration basin
Internal recycle
RAS
WAS

56. Anaerobic Selector Design
Design concepts similar to anoxic selector, except internal recycle.
HRT typically 0.75 to 2 hrs.
Three compartments (1/1/2)
(F/M)i = < 6 g COD/g MLSS·day
Design criteria still evolving.
Anaerobic selector
Secondary
clarifier
Aeration basin
RAS
WAS

57. Selector Configuration at City of Hamilton, OH
Original system T3
Modification to selector (HRT: 4 min.)
Modification of T2A to selector (HRT: 7 min.)
HRT: 8~12 min

58. SVI Change over Time, City of Hamilton, OH
T3: Better settling (low SVI) due to selectors
T2A & T2B: After selector installation, decreased SVI

59. Operational Data, City of Albany, GA Wastewater Treatment Plant
SVI drop after chlorination
Stable effluent SS and BOD

60. SVI drop after anoxic selector installation
Effect of Anoxic Stage on the Settleability of Activated Sludge in a Completely-Mixed Plant
SVI drop after anoxic selector installation

61. Upper Occoquan Sewage Authority
Historically plagued by M. parvicella
Mechanical surface aerators
Denitrification expensive
Aerobic selector

62. Performance Data

63. Tri-City, Oregon Historically poor plant stability
Low alkalinity water
Anoxic selector
Mixed liquor recycle
Baffle
Primary effluent To
secondary
clarifiers
RAS
Submerged
mixer
Anoxic
selector

64. Performance Data SVI, mL/g 300 Plug flow anoxic Plug flow anoxic
Step feed
Step feed
Plug flow
anoxic
Aeration
of selector
200
SVI, mL/g
100
1986
1987
1988

65. Fayetteville, Arkansas
Effluent phosphorus requirement
Readily biodegradable wastewater
Anaerobic selector
Surface
mechanical
aerator
Submerged
mixer
Anaerobic
selector
Aeration
basin
Primary
effluent To
secondary
clarifiers
RAS

66. Anoxic Selector Design (1)
1. Determine COD uptake rate, denitrification rates, and nitrate requirements from a pilot study 2. Measure influent (primary effluent) and secondary effluent (or recycle) CODs to determine degradable substrate (CODinf - CODeff). 3. Determine flow rates, recycle rates, and recycle concentrations to be used for design. 4. Assume 50~80% of the biodegradable COD must be removed in the selectors or that the soluble COD in the selector effluent must be reduced to 60 mg/L. 5. From the above information, determine the required HRT of the selector which in turn can be used to determine the selector volume from the flow and recycle flow. 6. Compartmentalize (determine the number of selectors) to provide either a high soluble substrate concentration or a high F/M in the initial compartment.

67. Anoxic Selector Design (2)
Design conditions Flow rate, Q = 8 mgd Recycle, R = 0.5Q = 4 mgd Required selector soluble effluent COD = 60 mg/L Total COD of primary sedimentation tank effluent, CODinf = 250 mg/L Soluble COD of primary sed. tank effluent, sol. CODinf = 150 mg/L Nitrate requirements = 8 (typically 6~10) mg sol. COD removed/mg NO3--N (note that complete denitrification is not the goal in bulking control but merely uptake of COD.) Denitrification rate = 4 mg NO3--N/g VSS·hr MLSS in recycle = 7,000 mg/L MLVSS = 0.75 MLSS in recycle; thus, Xr = 5,250 mg/L NO3- in recycle = 15 mg N/L Substrate uptake in full-scale plant = 65 mg COD/g VSS·hr Substrate uptake in pilot-scale batch reactor = 140 mg COD/g VSS·hr Substrate uptake in pilot-scale anoxic reactor = 120 mg COD/g VSS·hr

68. Anoxic Selector Design (3)
Selectors
Effluent
Aeration tank
Secondary
clarifier
Q = 8 mgd
CODinf=250 mg/L
Sol. CODinf=150 mg/L
R = 4 mgd
Xr=5,250 mg/L
NO3-=150 mg N/L
Sol. CODr=50 mg/L
Determination of degradable COD influent to the selector after dilution with recycle
Biodegradable sol. CODinf = = 100 mg/L
Mass balance: Q·Cinf + 0.5Q·Crec = 1.5 Q·Cmix (conc. in the selector)
Thus, 8 mgd × 100 mg/L × 8 mgd × 0 mg/L = 1.5 × 8 mgd × Cmix
Cmix = 66.7 mg/L readily biodegradable COD
Assuming 65% of this must be removed in the selector, 43 mg/L must be removed.

69. Anoxic Selector Design (4)
Determination of degradable COD influent to the selector after dilution with recycle - continued
Alternatively, using the criterion of 60 mg/L sol. COD in the selector effluent,
8 mgd × 150 mg/L × 8 mgd × 50 mg/L = 1.5 × 8 mgd × Cmix
Cmix=117 mg/L total sol. COD
Amount to be removed to attain a residual of 60 mg/L sol. COD would be: 117 mg/L - 60 mg/L = 57 mg/L
This criterion of 60 mg/L seems over conservative for this case since 50 mg/L of this is not readily biodegradable.
Determination of selector biomass
Q·Xinf Q·Xr = 1.5 Q·Xmix
8 mgd × 0 mg/L × 8 mgd × 5,250 mg/L = 1.5 × 8 mgd × Xmix
Xmix = 1,750 mg VSS/L

70. Anoxic Selector Design (5)
Check whether there is sufficient nitrate in recycle
Q·Ninf Q·Nr = 1.5 Q·Nmix
8 mgd × 0 mg/L × 8 mgd × 15 mg/L = 1.5 × 8 mgd × Xmix
Nmix = 5 mg NO3--N/L available
NO3--N req. = 43 mg/L COD removed  8 mg COD/mg NO3--N
= 5.3 mg NO3--N/L
Thus, 0.3 mg/L NO3--N is needed.
Potential remedies
1. Recycle more RAS.
2. Recycle directly from end of nitrification tank.
3. Remove less substrate in the selector and check whether acceptable.
4. Add additional nitrate to the selector.
For simplicity, option 4 will be chosen.
Calculate HRT in the selector
Denitrification limited:

71. Anoxic Selector Design (6)
Calculate HRT in the selector - continued
Need to remove 5.3 mg NO3--N/L; thus,
HRT = 5.3 mg NO3--N/L  7 mg NO3--N/L·hr = hr = 46 min
Substrate limited:
Need to remove 43 mg COD/L; thus,
HRT = 43 mg COD/L  210 mg COD/L·hr = 0.20 hr = 12 min
Since the time required for denitrification is greater than for substrate removal, the necessary HRT is controlled by denitrification.
Determine total selector volume
V = (Q+Qr) × t = 1.5 × 8 mgd × hr × 1day  24 hr
= Mgal = × 106 gal × 1 ft3/7.48 gal = 50,602 ft3

72. Anoxic Selector Design (7)
Check initial substrate concentration
Assuming three equally-sized completely-mixed compartments
each of 1/3 × 46 min = 15.3 min = 1.06 × 10-2 day
Thus, COD removed = 1.79 mg NO3--N/L × 8 mg COD/mg NO3--N
= 14.3 mg/L
Therefore, the concentration of sol. COD will be = mg COD/L. This is greater than the recommended 80 mg COD/L; thus, three compartments may be sufficient. This check is based on the assumption that principles important to design of aerobic selector should also be applied to anoxic selectors.
Jenkins (1988): 8~12 mg COD/g MLVSS·day; thus, acceptable.

73. References
Eikelboom, D. H. and H. J. J. van Buijsen, Microscopic Sludge Investigation, Manual, TNO Res. Inst. for Env. Hygiene, Delft, The Netherlands, Hegg, B.A., K.L. Rakness and J.R. Schultz, Evaluation of Operations and Maintenance Factors Limiting Municipal Wastewater Treatment Plant Performance, paper presented at 41st annual meeting of the RMWPCA, Albuquerque, NM, Jenkins, D., M.G. Richard and G.T. Daigger, Manual on the Causes and Control of Activated-Sludge Bulking and Foaming, Lewis Publishers, Ann Arbor, 193 p., U.S. General Accounting Office, Report to the Administrator, Environmental Protection Agency, Wastewater Dischargers Are Not Complying with EPA Pollution Control Permits, GAO/RCED-84-53, 61 p., 1983.