-------�
CABLE
DESALINATION OF IRRIGATION RETURN WATERS
CHEMICAL ANALYSIS OF HIGH AND LOW VOLUME FLOWS
Calcium
Magnesium
Sodium
Potassium
Carbonate
Bicarbonate
Sulfate
Chloride
Nitrate
Boron
Iron (total)
pH*
TDS
Low Volume Flows
mq/1
363
178
1380
4.0
0
462
3480
474
83
14
0.03
8.3
6450
High Volume Flows
mq/1
172
91
706
3.
22
437
1520
254
23
6.
0.
8.
3020
8
9
10
6
* pH at time of analysis.
84
-------�
Reverse Osmosis
Unit Description and Pretreatment. The Aerojet-General Reverse
Osmosis (RO) Unit Water Purifier Model 1-560B-1 has a plate and
frame design and contains 600 square feet of membrane. The water
flow schematic is shown in figure 3; the flow through the circular
desalination plates is shown in figure 4.
The pH of the influent was lowered from approximately 7.4 to a range
of 5.5 to 5.8 to control calcium carbonate precipitation and scaling.
A calcium sulfate precipitation inhibitor was also used. Cyanatner
P-35 manufactured by the American Cyanamid Company was used for
this purpose. It was injected at a rate of 3 mg/1.
Membrane Characteristics. Two RO membrane stacks were studied.
The first was a high pressure, low product yield, high salt re-
jection membrane. It was designed to have an applied pressure of
750 p.s.i.g. The second was designed to operate with a lower
applied pressure (350 p.s.i.g.) and higher product yield; but with
lower salt rejection characteristics.
Stack I. As shown in figure 5, the initial stack received an
influent with a varying TDS from June 1967 to January 1968. This
stack was subjected to the operational problems which occur during
the startup of any experimental operation. However, for the
initial 3 months it consistently produced a product containing
under 500 mg/1 of TDS, with an average salt rejection of over
90 percent (figures 6 and 7). A typical analysis for this per-
formance of the unit's influent, product, and brine stream is shown
in table 2. During the unit's operation, the product salinity
fluctuated as the influent salinity varied. This variation is
normal because of the increase in TDS concentration being passed
through the membrance by pore transport. However, the continued
decrease in product quality, as shown by figure 6, was due to
biological fouling and subsequent membrane deterioration.
The flux rate (figure 8) for this stack was as high as 13 gallons
per square foot of membrane per day. This occurred on the first day
of operation. It declined throughout the experimental period with
the exception of October 1967, when a higher than normally applied
pressure was used. The flux rate decrease was caused partially by
the increase in osmotic pressure due to the influent TDS increase.
However, the degree of flux drop that did occur is probable due in
part to another factor. It is speculated that with the high pressure
at which the stack was operated, a separation occurred between the
membrane and the spiral flow baffle (figure 4), thereby decreasing
the exposure time of the water to the membranes and thus resulting
in a lower flux rate. Table 3 summarizes the flux rates and salt
rejection for the operation of Stack I.
85
-------�
FIGURE 3
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FIGURE 5
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-------�
TABLE
REVERSE OSMOSIS
Stack I
Mineral Analysis
Operating Conditions
Date of Sample - July 14, 1967
Operating Pressure, psig - 750
Temperature of Feed Water - 77°F
pH of Feed Water - 5.5
Ion
Ca++
Mg++
Na+
K+
B
S04=
HC03~
Cl"
NO3~
Fe (total)
SiO2
Total Alkalinity
Total Hardness
T.D.S.
pH*
Feed
230
111
862
3.4
8.2
2360
98
314
34
0.02
42
80
1030
4230
6.4
PPM
Product
3.3
1.7
82
0.0
6.1
28
16
94
29
0.02
13
13
15
304
5.4
Brine
347
215
1350
5.1
8.4
3720
140
440
37
0.02
58
136
1750
6400
6.5
* pH of samples at time of analysis,
91
-------�
FIGURE 8
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TABI.E 3
REVERSE OSMOSIS
Stack I
Monthly Averages
Month
June
July
August
September
October
November
December
January
Flux
(qal/ft2/dav)
11.2
10.8
10.3
9.4
10.2
9.4
9.1
8.7
Salt
Rejection
(percent)
92
92
92
89
86
83
82
78
Feed
Salinity
(ppm)
5000
4300
3400
3900
6600
6650
6300
6000
Product
Recovery
(percent)
37
37
37
37
33
36
38
40
93
-------�
Nitrate and boron removal rates are of particular interest. The
nitrate removal rate varied considerably having a range of 0 to 49
percent removal with an average of 27 percent. Boron removed had
a range of 8 to 35 percent removal with an average removal of 21
percent. Both ions were removed at a rate substantially lower than
the general IDS removal rate.
Stack II--Operation and Performance. The second stack was in opera-
tion less than 3 months. Although spared the startup problems the
previous stack experienced, an error in assembly shortened its life
considerably. This stack was operated with the TDS blending system-
previously described. It received a more consistent influent with
a TDS concentration of approximately 3,000 mg/1 (figure 9). The
unit's salt rejection remained constant at 85 percent with a product
TDS between 400 and 600 mg/1 (figure 10). Product flux, however,
as seen in figure 11, varied widely. The variations occurred with
constant operating conditions and were apparently independent of
any exterior operational changes. Upon disassembly of the sitack,
it was found that blockages had occurred in the brine flow paths on
the desalination plates. These blockages, the result of a corroded
aluminum washer, caused an increase in the differential pressure of
from 35 p.s.i.g. to above 95 p.s.i.g. through the stack. This
reduced the effective pressure by 20 percent, which directly influ-
enced the flux rate. It is also postulated that the effective
membrane area of the unit was reduced by bridging of the spiral flow
path with precipitated salt due to the closed brine stream. This
would, as in the case of Stack I, result in a reduced exposure of
the water to the membranes and again a decrease in product flux.
Due to the lower salt rejection design criteria of this stack, its
nitrate and boron removal was essentially zero. All analyses indi-
cated zero nitrate removal and a maximum boron removal of leiss than
0.5 percent. A typical influent, product, and brine stream analysis
for this stack is presented in table 4.
Cost Analysis. The power, chemicals, and supply costs for Sitack II
were summarized in an internal report to Office of Saline Water.
The power and supply costs for operating Stack II totaled $0.42 per
thousand gallons of product produced. A cost breakdown is shown
in table 5.
Electrodialysis
Unit Description and Operation. The electrodialysis unit (ED) was
operated in the summers of 1967 and 1968. A more consistent: opera-
tion was possible in 1968, and this report is concerned primarily
with that run. During this period, it was operated on essentially
the same blended water (figure 7) as the reverse osmosis unit. The
94
-------�
FIGURES 9RIO
FEDERAL WATER POLLUTION CONTROL ADMINISTRATION
IAWWTC - FIREBAUGH, CALIFORNIA
REVERSE OSMOSIS DATA
TOTAL DISSOLVED SOLIDS VERSUS TIME
STACK H
o
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I-
Z Q
LU LJ
ID >
Q
tuuu
3000
S"
f
ART JULY 9
JULY
^^^
^*
AUG
1968
INFLUENT
.
SEPT
OCT
FIGURE 9
PRODUCT
TOTAL DISSOLVED SOLIDS
PPM
l>0 * 00
o o , o o
0 0^0 0
STACK H
\RT JULY 9
v_
JULY
^^^__
AUG
1968
PRODUCT
SEPT
OCT
FIGURE IO
95
-------�
FIGURE II
00 h-
-------�
TABLE 4
REVERSE OSMOSIS
Stack II
Mineral Analysis
Operating Conditions
Date of Sample - August 9, 1968
Operating Pressure, psig - 375
Temperature of Feed Water - 74°P
pH of Feed Water - 5.3
Ion
Ca++
Mg++
Na+
K+
B
SO4=
HCO3~
ci-
N03-
Fe (total)
Si02
Total Alkalinity
Total Hardness
T.D.S.
pH*
Feed
157
85
665
4.3
7.0
1650
55
320
22
0.05
30
46
742
2930
6.8
PPM
Product
2.5
1.2
140
1.0
7.0
6.9
21
196
24
0.02
17
17
11
381
6.8
Brine
331
161
1270
7.
7.
3480
79
400
20
0.
48
65
1490
5900
7.
0
3
04
0
* pH at time of sample analysis,
97
-------�
TABLE 5
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98
-------�
Ionics Electrodialysi's Demineralizer Model 300-B-3 has 150 membrane
pairs and a product capacity of 25 g.p.m. The waste or brine stream
flow rate was varied to inhibit the precipitation of calcium sulfate.
The average rate was 8 g.p.m. for the experimental run. Calcium
carbonate precipitation was prevented by pH control of the brine
stream. A basic flow diagram of the unit is shown in figure 12.
An electro motive force (EMF) of 275 volts was applied across the
stack; current varied with water temperature, membrane conditions,
and influent TDS. The water was passed through the demineralizing
stack once, although the unit had the capability of recycling the
product water.
Performance. The percent TDS removal and effluent TDS concentrations
for the electrodialysis unit are shown in figures 13 and 14. The
apparent variations in TDS removal from 36 percent to less than
20 percent were highly dependent on the physical condition of the
membranes. In general, any sudden improvement in TDS removal was due
to a cleansing of the membranes. Typical substances which fre-
quently accumulated within the stack were precipitated salts, bio-
logical slimes, and suspended solids. The general decline in
efficiency from early August through September is attributed
partially to a 10°C. decline in influent water temperature and
partially to a general metal and/or biological fouling of the
membranes. Both of the above caused an increase in resistance
which lowered the TDS removal capacity of the unit.
Nitrate was removed with an average rate 1.98 times that calculated
for total dissolved solids. This factor compares favorably with
the removal range of values reported by Ionics, Incorporated, which
was 1.47 to 2.47 times the TDS removal (1) .
No significant boron removal was observed at any time, thus ruling
out the use of electrodialysis for reclaiming tile drainage for
direct reuse as irrigation water. A summary of common ion removal
rates is shown in table 6.
Cost Analysis. The cost for the operation of this unit based on
supplies, electrical power consumed, and an average product TDS of
2,300 mg/1 was $0.15 per thousand gallons of water treated. Pro-
rating this figure for a multistack unit and a product quality of
500 mg/1 TDS, the cost is comparable to the RO unit. Table 7 shows
the breakdown of operating costs for the electrodialysis unit.
2 Parenthetical numbers refer to literature cited.
99
-------�
FIGURE 12
liJ
o
CO
CO
31SVM
^~
O ,(£
a:
.di..
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100
-------�
FIGURES I3SI4
FEDERAL WATER POLLUTION CONTROL ADMINISTRATION
IAWWTC - FIREBAUGH, CALIFORNIA
ELECTRODIALYSIS DATA
PER CENT REMOVAL OF TDS VERSUS TIME
JUN
JULY
AUG
SEPT
1968
FIGURE 13
TOTAL DISSOLVED SOLIDS VERSUS TIME
. DISSOLVED SOLIDS- mg/l X I03
ro !>i
in en en
*-. v
^^
^
JUN JULY AUG SEPT
1968
PRODUCT
101
-------�
TABLE 6
ELECTRODIALYSIS DATA
RUN NO. 1
Date of Sample
Brine Stream Dilution gpm
pH of Brine Stream
TDS Removal-percent
Temperature of Influent- °F
Applied E.M.F. -volts
Stack Current-amperes
July 15, 1968
8
5.9
35
75
276
13
Ion
Ca++
Mg++
Na+
K+
B
S04=
HCO3~
Cl"
NO3~
Fe (total)
SiO2
Total Hardness
T.D.S.
pH*
Feed
167
68
625
4.0
6.7
1430
336
167
26
0.00
29
696
3010
8.1
PPM
Product
105
51
515
2.5
6.5
1140
230
157
14
0.02
30
473
2240
7.9
Brine
321
138
1060
7.6
6.7
2580
147
593
54
0.02
29
1370
5240
7.6
* pH at time of analysis.
102
-------�
ELECTRODIALYSIS DATA
Cost Analysis
TABLE 7
Item
Quantity
Used
Per Million Gallons
of Product
Cost
TOTAL
Cost Per
Million Gallons
of Product
Sulfuric Acid 1.04 Tons
Filter Cartridges 100
Electrical Power 4250 KWH
$31.
$ 0.
$ 0.
*
60 /Ton
79 /each
01/KWH
$32.86
$79.00
$42.50
$154.36
*Based on Tankcar lots.
103
-------�
Summary
Desalination of San Joaquin Valley tile drainage water is techni-
cally feasible. The initial reverse osmosis stack was able to
achieve over 90 percent TDS removal; however, nitrate and boron
removals averaged less than 27 percent. The second stack removed
85 percent of the TDS with negligible nitrate and boron removals.
The electrodialysis unit had an average TDS removal of 23 percent
with a maximum of 36 percent. The cost for supplies and power for
reverse osmosis (Stack II) was $0.41 per thousand gallons of
product. The same costs for electrodialysis came to $0.15 per
thousand gallons of product, with a comparable cost to reverse
osmosis for a product of 500 mg/1 TDS.
104
-------�
Papers Cited
(1) Katz, William E., NITRATE REMOVAL BY ELECTRODIALYSIS--A Brief
Review, Ionics, Incorporated, October 25, 1966.
105
-------�
BACTERIAL DEVITRIFICATION OF
AGRICULTURAL TILE DRAINAGE
By
Thomas A. Tamblyn, Perry L. McCarty,
and Percy P. St. Amantl
Introduction
Man cannot continue degrading his environment. When he was a nomad
he did not have to worry about ecology. If he destroyed one area,
all that was necessary was to pick up and move on. As his culture
changed, he was no longer able to simply move away from the messes
he created, so he began sweeping the problem under the carpet. This
process of just covering up the problem has continued to the present
time. The country paid little attention to Teddy Roosevelt when he
told Congress on December 3, 1907, that:
"To waste, to destroy our natural resources, to skin-and
exhaust the land instead of using it so as to increase
its usefulness, will result in undermining in the days
of our children the very prosperity which we ought by
right to hand down to them amplified and developed."
However, for some unexplained reason, there is a change taking place.
The public is demanding a change in philosophy. This report is an
example of what is being done to satisfy this demand. It presents
the results of one of the many studies of advanced waste treatment
that have been undertaken in the past few years. The objectives
of the study were to determine if bacterial denitrification of
agricultural tile drainage was feasible under field conditions,
and if it was, to develop information on process costs.
Process Considerations
Bacterial denitrification is accomplished by both dissimilatory and
assimilatory means. Dissimilatory nitrate reduction is coupled to
energy metabolism. The nitrate ion acts as the terminal hydrogen
acceptor in the energy transport system. When an adequate concen-
tration of a degradable organic material is present, many facul-
tative bacteria are capable of bringing about dissimilatory nitrate
Sanitary Engineer, Federal Water Pollution Control Administration,
Fresno, California; Professor of Environmental Engineering,
Stanford University, Stanford, California; and Director, San
Joaquin Project, Federal Water Pollution Control Administration,
Ada, Oklahoma, respectively.
107
-------�
reduction under anaerobic (or near anaerobic) conditions. Among
these are bacteria in the genera; Pseudomonus, Achromobacter. and
Bacillus. Assimilatory nitrate reduction is accomplished by
reduction of nitrate-nitrogen to the ammonia valence and the sub-
sequent incorporation of' the nitrogen into cellular material (1).
There are differences in the abilities of various bacteria t:o bring
about denitrification (2). Several bacteria can only reduce
nitrate to nitrite, while others can only reduce nitrite to molec-
ular nitrogen, while still others are capable of reducing both
nitrate and nitrite to molecular nitrogen. In addition, the
fraction of the total denitrification process attributable to
either dissimilatory or assimilatory reduction varies for different
organisms. However, these differences are masked and become insig-
nificant when working with mixed cultures, and the general equation
which follows can be formed for the process. McCarty, et al., have
presented the development elsewhere and it will not be given in this
paper (3).
Cm = (1.90 NQ + 1.18 Nx + 0.67 DQ) Cr (1)
Cm = requred concentration of degradable organic material,
mg/1.
NQ = nitrate-nitrogen concentration, mg/1.
N^ = nitrite-nitrogen concentration, mg/1.
Do = dissolved oxygen.
Cr = consumptive ratio.
Cr = actual organic carbon sources requirement
stoichiometric requirement for dissimilatory denitrifi-
cation and deoxygenation.
The consumptive ratio not only varies between organisms, it also
varies with the nature of the organic material being degraded and
possibly with the environment in which the degradation is taking
place (3), (4). Since tile drainage does not contain a significant
concentration of degradable organic material, chemical addition is
required for denitrification. Several organic compounds have been
screened to determine which compound should be used. Methanol was
picked for reasons of economics, a comparatively low consumptive
ratio, ease of handling, etc. (5).
Process Configurations
Once it has been determined that a biological process is technically
feasible, it is necessary to study possible process physical configu-
rations. These studies must be made to determine which is optimum
Parenthetical numbers refer to literature cited.
108
-------�
for the problem at hand. There are three basic sanitary engineering
process configurations which could possibly be used for bacterial
denitrification: anaerobic activated sludge, anaerobic ponds, and
anaerobic filters.
Anaerobic activated sludge for the denitrification of municipal waste
has been studied under both laboratory and field conditions with and
without chemical additions (6, 7). Work is currently underway at
several locations to develop design criteria for this configuration
(8, 9). The anaerobic activated sludge process was not included as
part of the investigation reported on in this paper.
Studies of bacterial denitrification in completely mixed and partial-
ly mixed laboratory scale simulated anaerobic ponds have been made
(4, 5). Because of the long detention times (several days) required
for this process, it has been considered impractical for most situ-
ations. However, because of the low cost of construction and the
availability of land in the San Joaquin Valley, the decision was
made to include anaerobic ponds as part of this investigation.
In the anaerobic filters, the waste is passed through a flooded,
packed column-type reactor (a vessel containing an inactive medium).
A bacterial mass, that is similar to the zoogleal film in a
trickling filter, develops on the media, allowing the use of short
detention times without solids separation and recycle (10). Down-
flow anaerobic filters are and have been operated for bacterial
denitrification with methanol as the electron donor (11, 12).
Upflow anaerobic filters were operated for this investigation in
order to avoid duplication of effort and to fill a gap that existed
in the available information on anaerobic filters.
Experimental Procedures
The primary objective of this study (to determine if bacterial deni-
trification of agricultural tile drainage was feasible under field
conditions) required that the processes be tested under conditions
which duplicated, as nearly as possible, those to be encountered if
a full-scale plant were constructed. As a consequence of this, the
Interagency Agricultural Waste Water Treatment Center was constructed
near Firebaugh, California. It is located in one of the areas of the
San Joaquin Valley where there are existing drainage problems
(figure 1) . The climatic conditions and the quality of available
tile drainage (table 1) were nearly ideal for the investigation.
Anaerobic Ponds
The feasibility of bacterial denitrification in deep ponds under
field conditions was determined in 3-foot (0.9-m) diameter simulated
109
-------�
FIGURE I
EXISTING AND POTENTIAL AGRICULTURAL WASTE WATER DISPOSAL PROBLEM AREAS
SAN JOAOUIN VALLEY-CALIFORNIA
SCALE OF MILES
110
-------�
TABLE 1
CHARACTERISTICS OF TILE DRAINAGE USED AT THE INTERAGENCY
AGRICULTURAL WASTE WATER TREATMENT CENTER
Constituent i Range of Concentrations
. mg/1
Total Dissolved Solids 2500 - ?600
Salts
Sulfate 1500 - 3900
Sodium 620 - 2050
Chloride 310 - 6UO
Calcium l6o - 390
Magnesium 70 - 230
Bicarbonate 280 - 330
Potassium U - 11
Boron U - 15
Nutrients
Nitrogen 5-25
Phosphate 0.13 - 0-33
Pesticides < 0.001
Others
5-Day BOD 1-3
COD 10 - 20
DO 7-9
111
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deep ponds (13). Once the process was shown to be feasible, two
large ponds were constructed as shown schematically in figure 2.
The larger of the two ponds constructed at the Center is 200x50
feet (61 X 15-m) and has a floating cover. The smaller pond is
50x50 feet (15 X 15-m) and is not covered. Both ponds are approxi-
mately 15 feet (4.6-m) deep. To increase the solids retention
time, recycle is necessary. Through the parallel operation of
these two units, it was possible to evaluate the significance of
wind mixing and algal growth on process efficiency.
Anaerobic Filters
Figure 3 is a schematic diagram of the upflow anaerobic filters
used at the Center. Anaerobic filters with 6-foot bed depths which
were 4-, 18-, and 36-inch (10-, 46-, and 91-cm) diameter and 10x10
foot (3-m X 3-m) square have been used at the Center (14). The
lOxlO-foot filter has a false bottom (of the type used in water
treatment rapid sand filters) with an 8-inch (20-cm) plenum. The
primary purpose for building this filter was to investigate the
effect of scale-up on process efficiency due to changes in the
hydraulic regime.
Analytical Techniques and Sample Gathering
The routine analyses used to monitor the operation of the various
units at the Center are summarized below. Most samples were
normally collected between 8:00 and 9:00 a.m., and analyzed imme-
diately. Some samples were taken in the afternoon to gather
information on changes that may have occurred during the peak
photosynthetic period. Diurnal studies were also conducted, as the
need arose.
112
-------�
FIGURE 2
(f)
-------�
FIGURE 3
BIODEGRADABLE ORGANIC
CARBON INJECTION I
WASTE INFLUENT
GAS RELEASED TO ATMOSPHERE
I LI t HI II
TREATED EFFLUENT
MEDIA SUPPORT AND/OR
FLOW DISTRIBUTION SYSTEM
LEGEND
OPTIONAL SAMPLE TAPS
SCHEMATIC DIAGRAM
UPFLOW ANAEROBIC FILTER DENITRIFICATION PROCESS
114
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ROUTINE ANALYSES PERFORMED AT THE
INTERAGENCY AGRICULTURAL WASTE WATER TREATMENT CENTER
Analysis
Nitrate-Nitrogen
Nitrite-Nitrogen
Total Kjeldahl Nitrogen
Ammonia Nitrogen
Organic Nitrogen
Orthophosphate
PH
Alkalinity
Dissolved Oxygen
Suspended Solids
Volatile Suspended Solids
Optical Density
Electrical Conductivity
Algal Cell Counts and
Identifiers
Methanol
Technique
Brucine Method and/or Selective
Ion Electrode
Standard Methods, 12th Edition (15)
Kjeldahl Method
Distillation Method
Kjeldahl Method
Stannous Chloride Modification
Glass Electrode
Standard Methods, 12th Edition
Winkler Method
0.45 u Glass Paper, 103°C.
0.45 u Glass Paper, 600°C.
450 u, 5 cm Cell
Galvanic Cell
Sedgewick-Rafter Cell
Gas Chromatograph, Carbowax Column,
Flame lonization Detector
In addition to chemical analyses, several physical parameters were
monitored. Water temperatures were monitored daily with maximum-
minimum thermometers and periodically with 8-day recording thermo-
graphs. The influent pressure required for an anaerobic filter to
maintain a constant hydraulic detention time was monitored with
varying frequency throughout the study. Flows were calibrated
volumetrically. In addition, tracer studies using the chloride ion
as a tracer were run to determine the actual hydraulic regime of
the different units. Pre- and post-injection density corrections
were made using sodium sulfate. The tracer studies were analyzed
using the volume apportionment technique (16).
Results and Discussion
The initial field studies of bacterial denitrification in simulated
deep ponds indicated that significant denitrification could take
place in ponds with detention times as low as 5 days (13).
Data gathered from the large ponds, which started operation in the
fall of 1968, are summarized in table 2. The covered pond has
consistently outperformed the uncovered one. There are two primary
reasons for this. Large algal populations develop in uncovered
ponds and the resultant high dissolved oxygen concentration inhibits
115
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116
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denitrification. The second reason is that more of the influent
is short-circuited through the uncovered pond because of wind mixing
and temperature variations. The high nitrogen removal efficiencies
recorded for the uncovered pond, when operated with a 10-day detention
time, was probably caused by the formation of a natural partial cover.
The cover was composed of decayed algal and bacterial cells floating
on the surface of the pond. Some type of covering is necessary for
sufficient denitrification to take place. Research is currently
underway to determine if a floating vegetative mat may be used in
place of fabricated pond covers. There have been numerous mechanical
equipment breakdowns associated with these units; therefore, it is,
as yet, impossible to accurately predict the minimum detention time
possible. However, a 10-day detention time with 25 percent recycle
and a pond depth of 15 feet have been shown to be effective for
covered pond summertime operation (table 2) and these criteria were
used for developing process costs.
The data from experiments designed to investigate the significance
of anaerobic filter media size, texture, and sorptive quality are
summarized below (14).
NITROGEN REMOVAL EFFICIENCIES FOR
FILTER DENITRIFICATION UNITS CONTAINING VARIOUS MEDIA
Nitrogen Removal
Efficiency, Percent
Medium
Activated Carbon
Washed Sand
5/16" Coal
5/16" Volcanic Cinders
3/8" Aggregate
5/8" Volcanic Cinders
1" Coal
1" Volcanic Cinders
1" Aggregate
Min.
89
84
80
85
82
87
81
89
89
Max.
99
97
98
98
97
97
98
97
98
Average
96
93
93
94
94
91
93
96
94
Based on the results of an initial feasibility investigation, all
filters operated to generate this data had hydraulic detention
times (based on void volumes) of 2 hours. Medium surface texture,
size, and sorptive quality had no apparent effect on removal
efficiencies. After an extended period of continuous operation,
the bacterial mass within filters containing media with diameters
of less than 1 inch built up to the point where the required influ-
ent pressures (as high as 60 p.s.i.g.) rendered them uneconomical.
117
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The data gathered from the long-term operation of three filters
containing 1-inch-diameter media are summarized in the following
table:
SUMMARY OF LONG-TERM PERFORMANCE
OF FILTERS CONTAINING ONE-INCH-DIAMETER AGGREGATE
Detention Days Percent Nitrogen Required Influent
Time of Removal Pressure, psig
Hrs. Operation Min. Max. Average Min. Max. Average
0.5 275 40 91 68 3.5 11.8 7.2
1.0 240 64 97 88 3.2 9.6 5.4
2.0 244 79 97 91 3.5 9.7 6.2
For about the first 150 days of operation, the required influent
pressure fluctuated within a narrow range. There did not appear to
be any need for backwashing, etc. Since that time, an upward trend
has begun to appear. Investigations are currently underway to deter-
mine the best technique for reducing this pressure.
The temperature of the influent to the units varied from a high of
22° to a low of 10° Centigrade. There were some indications of a
relationship between temperature and nitrogen removal efficiency.
The units that were run with 0.5- and 1-hour detention were less
efficient during the colder part of the year than during the summer
months. This phenomenon did not hold true for the unit operating
at 2 hours. As the temperature of its influent dropped, the length
of the filter bed required for treatment increased. The 6-foot bed
depths used for this investigation and the range of temperatures
encountered were such that the effect was not reflected in the
overall treatment efficiencies of the unit. Process costs for
anaerobic filters were developed assuming a summer detention time
of 1-hour with a 6-foot bed of 1-inch-diameter aggregate.
The average consumptive ratio calculated from the data gathered at
the Center equals 1.47 mg/1 with a standard deviation of + 0.367.
The large standard deviation calculated for the consumptive ratio
is more likely due to inherent difficulties in field studies than
to fluctuations in system requirements. No difference could be
seen between pond and filter methanol requirements. With the
development of an automatic methanol control system, which would
respond to changes in influent and effluent quality, this variation
should be drastically reduced. The methanol requirement for a
typical influent containing 20 mg/1 of nitrate-nitrogen and 8 mg/1
of dissolved oxygen calculated by equation (1) equals 64 mg/1.
118
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As mentioned above, process costs have been estimated using the
operating criteria necessary during the warmer season of the year.
Computer simulation and an extensive water quality monitoring pro-
gram have yielded predictions of the seasonal variations that will
occur in the flow rate and nitrogen content of the waste requiring
treatment (17, 18). These predictions show that 70 percent of the
annual nitrogen load, in pounds per day, will arrive at the treat-
ment plant between April 1 and September 30 (the warmer season).
A bacterial denitrification plant designed to treat this load will
have more than adequate capacity for winter operation.
The estimated costs that have been made to date (December 1969)
indicate that treatment in either anaerobic ponds or filters will
most likely cost between $30 and $60 per million gallons of waste
treated. Plant designs for various influent rates are presently
being made. They will be used to develop equations for the
relationship of plant design capacity to costs per million gallons
of waste treated. From a comparison of the estimated range of
treatment costs and the conclusions of the Bay-Delta Report (19),
it can be said that agricultural tile drainage can be treated and
discharged to the San Francisco Bay System at less cost than that
of any alternative plan.
Conclusion
It has been shown that bacterial denitrification in covered
anaerobic ponds and anaerobic filters are both feasible under field
conditions. Additional work is needed on the actual costs of
treatment using the processes. However, preliminary estimates
indicate that agricultural tile drainage can be treated at a cost
that is substantially below the economic constraint that has been
placed on the system.
119
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Papers Cited
1. Schroeder, E. D., "DISSIMILATORY NITRATE REDUCTION BY MIXED
BACTERIAL POPULATIONS," a thesis submitted in partial fulfill-
ment of the requirements for the degree of Doctor of Philosophy,
Rice University, Austin, Texas (July 1968).
2. Alexander, M., SOIL MICROBIOLOGY, John Wiley, New York (1961).
3. McCarty, P. L., Beck, L. A., and St. Amant, P. P., "BIOLOGICAL
DENITRIFICATION OF WASTE WATERS BY ADDITION OF ORGANIC CARBON,"
24th Annual Purdue Industrial Waste Conference, Purdue
University, Lafayette, Indiana (May 1969).
4. Moore, S. F., "AN INVESTIGATION OF THE EFFECTS OF RESIDENCE
TIME ON ANAEROBIC BACTERIAL DENITRIFICATION," a thesis submitted
in partial fulfillment of the requirements for the degree of
Master of Science, University of California, Davis, California
(1969).
5. McCarty, P. L., "FEASIBILITY OF THE DENITRIFICATION PROCESS FOR
REMOVAL OF NITRATE-NITROGEN FROM AGRICULTURAL DRAINAGE WATERS,"
Appendix, California Department of Water Resources, Bulletin
No. 174-3 (May 1969).
6. Christiansen, C. W., Rex, E. H., Webster, W. M., and Virgil,
F. A., "REDUCTION OF NITRATE-NITROGEN BY MODIFIED ACTIVATED
SLUDGE," U.S. Atomic Energy Commission, TID-7517 (1956).
7. Ludzack, F. J., and Ettinger, M. B., "CONTROLLING OPERATION TO
MINIMIZE ACTIVATED SLUDGE EFFLUENT NITROGEN," Journal Water
Pollution Control Federation, Vol. 34 (1962).
8. Echelberger, W. F., and Tenney, M. W., "WASTE WATER TREATMENT
FOR COMPLETE NUTRIENT REMOVAL," Water and Sewage Works,
Vol. 116, No. 10 (October 1969).
9. Barth, E. F., Brenner, R. C., and Lewis, R. F., "CHEMICAL-
BIOLOGICAL CONTROL OF NITROGEN AND PHOSPHORUS IN WASTE WATER
EFFLUENT," Journal Water Pollution Control Federation, Vol. 40
(1968).
10. Young, J. C., and McCarty, P. L., "THE ANAEROBIC FILTER FOR
WASTE TREATMENT," Proceedings, 22nd Purdue Industrial Waste
Conference (1967).
120
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11. Parkhurst, J. D., Dryden, F. D., McDermott, G. N., and
English, J., "POMONA ACTIVATED CARBON PILOT PLANT," Journal
Water Pollution Control Federation, Vol. 39 (1967).
12. Smith, John; Federal Water Pollution Control Administration,
Robert Taft Center, Cincinnati, Ohio, Personal Communications
(November 10, 1969).
13. Brown, R. L., "FIELD EVALUATION OF ANAEROBIC DENITRIFICATION
IN SIMULATED DEEP PONDS," California Department of Water
Resources, Bulletin No. 174-3 (May 1969).
14. Tamblyn, T. A., and Sword, B. R., "THE ANAEROBIC FILTER FOR
THE DENITRIFICATION OF AGRICULTURAL SUBSURFACE DRAINAGE,"
24th Annual Purdue Industrial Waste Conference, Purdue University,
Lafayette, Indiana (May 1969).
15. "STANDARD METHODS FOR THE EXAMINATION OF WATER AND WASTE WATER,"
American Public Health Association, Inc., New York, New York,
12th Edition (1965).
16. Milbury, W. F., "A DEVELOPMENT AND EVALUATION OF A THEORETICAL
MODEL DESCRIBING THE EFFECTS OF HYDRAULIC REGIME IN CONTINUOUS
MICROBIAL SYSTEMS," a dissertation prepared in partial fulfill-
ment of the requirement for the degree of Doctor of Philosophy,
Northwestern University, Evanston, Illinois (1964).
17. Glandon, L. R., and Beck, L. A., "MONITORING NUTRIENTS AND
PESTICIDES IN SUBSURFACE AGRICULTURAL DRAINAGE," American
Geophysical Union, Fall National Meeting, San Francisco,
California (December 1969).
18. Lindholm, R. R., "SAN JOAQUIN VALLEY DRAINAGE INVESTIGATION-
SAN JOAQUIN MASTER DRAIN," California Department of Water
Resources, Bulletin No. 127, Preliminary Edition (January 1965).
19. "SAN FRANCISCO BAY-DELTA WATER QUALITY PROGRAM," Preliminary
Edition of Final Report by Kaiser Engineers, et al., to the
State of California (December 1968).
121
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ALGAL NUTRIENT RESPONSES
IN AGRICULTURAL WASTE WATER
By
James F. Arthur, Randall L. Brown,
Bruce A. Butterfield, and Joel C. Goldman^-
Introduction
In 1960, the Congress of the United States authorized the Bureau of
Reclamation, under Public Law 86-488, to construct a drainage dis-
posal facility for the Federal San Luis Service Area in the Central
San Joaquin Valley of California. That same year, the California
State Legislature, with voter ratification, passed the California
Water Resources Bond Act, which included a study of agricultural
waste-water drainage facilities in California.
The necessity for such legislation has arisen because of the in-
creasing demand for westside farmland, which though very rich in
nutrients, requires salt leaching to maintain a salt balance.
Unfortunately, the southern portion of the San Joaquin Valley is
almost a closed basin in which there is no natural drainage available
for removal of this waste water. Thus, the California Department
of Water Resources has estimated that by the year 2020, the annual
amount of brackish agricultural waste water requiring disposal will
be about 580,000 acre-feet per year.
The San Joaquin Valley Drainage Investigation (Lindholm, 1965),
which was initiated as a result of the 1960 enactment, concluded
that of several waste-water disposal plans proposed, three were most
likely to prove practical; namely, desalinization, evaporation, or
transportation (removal) of the water from the valley. Further
investigation indicated that the latter method would probably be the
most economical, and that if this method were selected for disposal,
the most convenient transportation route would be by way of a drain
running up the Central Valley through the Delta-San Francisco Bay
System and into the ocean. Unfortunately, this method of disposal
would mean discharging nitrogen into a water system already heavily
taxed with domestic and industrial waste (Beck and St. Amant, 1968;
Stetson and Price, 1968). To find ways of solving the potential
pollution problems that could arise in the Bay, the Interagency
Agricultural Waste Water Treatment Center (IAWWTC) at Firebaugh,
California, was established by a joint task force consisting of the
Research Aquatic Biologist, Federal Water Pollution Control Admin-
istration; Associate Water Quality Biologist, and Assistant Civil
Engineers, California Department of Water Resources, respectively;
Fresno, California.
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Bureau of Reclamation (USER), the California Department of Water
Resources (DWR), and the Federal Water Pollution Control Adminis-
tration (FWPCA), to study the economic and practical feasibility
of biologically removing nitrate-nitrogen from agricultural waste
water (Beck, Oswald, and Goldman, 1969).
After 1-1/2 years of actual prepilot operation, two biological
removal processes, anaerobic bacterial denitrification and algal
nutrient stripping, show the most promise as practical methods of
removing nitrate from eutrophicated waters (Beck and St. Amant,
1968; Beck, Oswald, and Goldman, 1969; St. Amant and McCarty, 1969;
Tamblyn and Sword, 1969). The algal stripping process is the sub-
ject of this paper.
The theory behind the algae stripping method of nitrogen removal is
simple; namely, any nutrient (e.g. nitrogen) required by algae can
be removed from the growth medium by assimilation and subsequent
conversion to cellular material. The algae, along with the: incorpo-
rated nutrient, can then be removed from the medium. Theoretically,
maximum nutrient assimilation by algae will occur if the nutrient
to be removed is the one limiting factor; however, in actual
practice this is often difficult to obtain.
In general, all algae can utilize inorganic nitrogen as either
ammonium salts or nitrates. The reduction process by which inor-
ganic nitrogen is utilized requires energy in the form of light
and is temperature dependent. The basic reaction by which nitrates
are reduced to ammonia generally is thought to occur in four stages
as follows:
nitrate nitrite hyponitrite hydroxylamine
reductase reductase reductase reductase
---- >> HN02 ----- > H2N202 ...... >> NH2OH - ..... -
2 (H) 2 (H) 2 (H) 2 (H)
The end product, ammonia, is then transferred to the amino acid pool
where it can be utilized in the formation of protein. The products
of nitrogen assimilation, which have been determined in Scenedesmus ,
the species studied at the IAWWTC, indicate an immediate increase in
cellular, soluble organic-N; followed by an increase in insioluble-N,
if sufficient carbohydrate is available (Lewin, 1967) .
In addition to seasonal changes in physical factors such as: light and
temperature, changes may occur in the nature and concentration of
nutrient constituents in the growth medium. These nutrient: changes
may limit physiological responses and mask the effects of other
environmental parameters. One such nutrient is phosphorus. It is
124
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one of the major nutrients required for normal algal growth and
normally comprises about 1 percent of the organic material of algae.
Changes in its availability can be brought about by shifts in pH
level, which leads to altering of the rate of phosphate uptake from
the medium, either by a direct effect on permeability of the cell
membrane, or by changing the ionic form of the phosphate, which in
turn can limit nitrate uptake. The latter effect of pH on phosphate
uptake appears to be the case at the IAWWTC, where high alkalinity
levels (300-400 mg/1 CaC03) along with increased pH (due to algal
assimilation of carbon as CO^) results in the precipitation of
phosphate salts. In addition, a reserve of available carbohydrates,
which is dependent upon carbon availability, also plays an impor-
tant role in phosphate uptake, since carbohydrate degredation by
oxidative phosphorylation is needed to provide energy for the
uptake process. Accordingly, when phosphate is deficient in the
growth medium, there is an accumulation of cellular fat, starch,
and wall substance, indicating an interference with nitrogen
metabolism (Lewin, 1967). Fluctuation in the amount of available
phosphorus can, thereby, affect algal growth and nitrate assimi-
lation altering the effect of other parameters being measured.
The availability of trace elements also affects growth and nitrogen
assimilation (Fogg, 1965). For example, as molybdenum becomes
deficient in the medium, the growth rate decreases. A lack of
iron, another essential trace element, leads to a decrease in
chlorophyll level which, in turn, limits the cells' photosynthetic
activity and, thence, its growth. Furthermore, iron (as well as
other metals required for growth) is only slightly soluble in well
oxygenated and/or basic water (Ruttner, 1965), and the availability
of such nutrients to algae in the precipitated form is dubious.
Unfortunately, these are the conditions typically found in high rate
algal ponds, since algae both produce oxygen and use CC>2 in the
photosynthetic process. This utilization of CO by actively growing
algae usually reached a point at which the C0£ revel in the growth
medium is not in equilibrium with the atmosphere, and the pH of
the medium, therefore, will rise. The pH increase, in turn, affects
the solubility and, hence, the availability of other nutrients. A
slowdown of growth results and, thus, the algae in effect limit
their own growth rate. The examples given in this and in the pre-
ceding paragraph are but a few of those which can be cited on how
different nutrient levels can affect algal growth.
The objectives of the IAWWTC are to develop an algal nutrient removal
system that is efficient, dependable, and economical. To accomplish
these goals, we are attempting to: (a) maximize algal nitrogen
assimilation by determining those factors, chemical and physical,
which can be rate-limiting, and (b) determine how to compensate for
fluctuations in those factors. Preliminary studies had indicated
125
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that detention time, depth, and mixing velocities would probably be
the most important parameters affecting the system. However, after
several months of operation, it became apparent that some other
variable was limiting nitrogen assimilation by the algae in the
outdoor growth units. As a result, it was decided to use light
box studies to define optimum algal growth and nitrogen assimilation
parameters before applying them to the outdoor growth units. This
paper presents some of the techniques and results obtained thus
far in the light box and outdoor growth studies.
Methods and Materials
Growth Media. Algal growth studies at the IAWWTC are conducted with
the use of cultures grown indoors in light boxes and in large out-
door growth units in which agricultural tile drainage water serves
as the basic growth medium (Lindholm, 1965). The chemical constit-
uents of this water, which is relatively high in total dissolved
solids (IDS), varies seasonally depending upon the irrigation and
fertilization practices for the particular crop grown.
Nutrient additives used in the light box studies were of analytical
grade. Nitrate-nitrogen (NaNO^) was added, when required, to the
test water to maintain a minimal nitrate-nitrogen concentration of
20.0 mg/1. This concentration is the average predicted for the
San Luis Drainage Area. Carbon additions were made by the injec-
tion of atmospheric air, bottled 4 percent, or 100 percent CC^
(passed through a water scrubber) directly into the flasks; or in
the case of the outdoor growth units, into the intake side of the
mixing pumps.
Growth Unit - Light Box. The light box at Firebaugh consists of
two shelves, 12x3 feet with lighting provided by eight 6-foot,
cool-white, fluorescent lamps placed 15 inches above the surface of
each shelf. Light intensities at the shelf level were approximately
350-400 feet-c. All ballasts were removed from the light fixtures
and placed several feet from the light b"ox to minimize temperature
increases. The studies were conducted with the use of continuous
light (Joint Industry/Government Task Force on Eutrophication, 1969).
Compressed air or bottled C0£ enriched air was passed through a
water scrubber for humidifieation, i.e., to reduce evaporation loss
in the culture containers. The various gas mixtures were distrib-
uted to the flasks through a central manifold system. The gas
pressure to each flask was equalized by placing a short capillary
tube in the air line between the manifold and the flasks.
Although temperature was not controlled to the desired degree
(23 + 1°C.), it remained within the 23 + 5°C range. The lack of
precise control did not appear to have any adverse effect on the algae.
126
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The use of 500 ml aliquots of medium contained in one-liter
Erlenmeyer flasks was found.to give maximum growth rates under
the experimental conditions used at the Agricultural Waste Water
Treatment Center (Brown and Arthur, 1969). Apparently, the
resulting surface to volume ratio allowed optimum CC^ exchange.
Cultures of this volume also permitted adequate subsampling for
chemical and biological analysis.
Outdoor Growth Units. Twenty 8x16x1.2-foot rectangular plywood
fiberglassed units, each having approximately 3,500 1 capacity, were
used for the outdoor growth studies. Two additional units were
used for depth studies, one 18 inches deep and the other 10 inches
deep. Detention time in all units was controlled by adjusting
the flow through rotometers and were calculated using influent flow
rates and pond volumes, not actual hydraulic flows within the units.
Mixing schedules were varied by the use of timers on each of the
mixing pumps.
In addition to the above growth facilities, the Center has one
large (1/4-acre) unit, 200x50 feet, capable of operating at water
depths of from 8 to 36 inches. As with the smaller outdoor units,
detention time and mixing cycles can be varied.
Inoculum. The predominant algal, species used as a test organism at
the Agricultural Waste Water Treatment Center has been the green
algae, Scenedesmus quadricauda, which was originally obtained from
the high-rate algal pond at the University of California's Richmond
Field Station, Richmond, California. This particular species was
chosen because: (a) it has a known high nitrate requirement, (b) it
was available in large quantities, (c) it was relatively easy to
separate, (d) it has been successfully used as a food supplement,
and (e) it occurs naturally in drainage canals near the IAWWTC,
although in relatively low numbers.
Inoculums of Scenedesmus quadricauda used in the light box nutrient
bioassay studies usually were from cultures in the log phase of
growth grown in the outdoor units. The cell density of the inocu-
lated sample was kept at about 2,000 cells/ml to minimize carryover
of nutrients. Although the cultures were neither axenic or even
unialgal, they were predominant (95-100 percent) Scenedesmus and
were acclimatized to the conditions prevailing at the particular time
of the year.
Analyses. Routine analyses of the growth medium used in the light
box and the outdoor growth units included analyses for nitrate,
nitrite, organic nitrogen, orthophosphate, alkalinity, and pH
(American Public Health Assocation, 1965). In addition, when specifi-
cally required, other chemical determinations were made (e.g., iron
127
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determinations, hardness, dissolved oxygen, general trace elements,
etc.).
Many of the conclusions reached in the present study were based on
nitrate uptake by the algae. Daily or semidaily nitrate-nitrogen
analysis was made with a specific ion electrode with random brucine
analyses used to establish a daity standard curve. Numerous com-
parisons of the electrode with the standard brucine method of
nitrate determination indicated that this method was much faster
than the brucine and subject to smaller variations.
Routine analysis of light box samples included suspended and volatile
solids, temperature, absorbence (on a spectrophotometer at: 410 mu),
cell counts, and algal species determinations. In addition to the
above, total light energy, electrical conductivity, IDS, air and
water temperature, wind and precipitation were recorded for the
outdoor growth units. As required, measurements were made of other
factors affecting the operation of algal growth units.
General Procedure. In order to eliminate as many variable's as
possible, a covered storage pond having an 820,000-gallon capacity
was used to provide a constant supply of water for use in the light
box and outdoor growth studies. This large reserve of water allowed
a study period of from 60 to 90 days, without significant changes in
influent quality, as well as making nutrient additions much simpler.
Because of the large fluctuations in nutrient levels betwe-.en studies
(figure 1) an algal nutrient bioassay was conducted in the light box
each time the storage pond was filled to determine the optimum
nutrient level required for maximum growth rate and nitrog;en assimi-
lation. This was normally accomplished by adding varying levels
of different nutrients to the tile drainage in a factorally designed
experiment (e.g., five levels of iron vs. five levels of phosphorus).
A plot of daily nitrate removal from the medium was then used to
determine the effect of the various nutrient additions on nitrate
assimilation. The optimum level of a particular nutrient or
nutrients was then tested to determine if the nitrogen uptake rate
could further be enhanced with the addition of other nutrients.
These tests usually were conducted at three CO? levels (swirled twice
per day, air, and 4 percent CO,,). If a particular nutrient was found
to be limiting nitrogen assimilation, it was added either to the
covered storage pond or to individual growth units.
Results and Discussion
The IAWWTC Site was chosen because: (a) the land was available
through the U.S. Bureau of Reclamation, (b) the tile drainage sump
had a large flow volume, and (c) the water had an average nitrogen
level which was close to the predicted average value for the drainage
128
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FIGURE
N390H1IN 31VM1IN
(I/BUI) sanos Q3Anossia ivioi
129
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area. In table 1 are shown the average predicted monthly flows,
nitrates, phosphates, and total dissolved solids expected in the
San Joaquin Valley agricultural waste-water drain. Note that: the
predicted average nitrate-nitrogen concentration will be about
20 mg/1.
Because of irrigation practices in the area of the IAWWTC over the
last 3 years, the major nutrient constituents have varied considerably
more, see figure 1, than is expected in the overall drain, which draws
from a large and varied service area. As a result, certain algal
growth characteristics were affected by nutrient variation, inasmuch
as the storage pond was filled during different times of the year.
To account for changes in growth patterns resulting from these
changes in water quality, we have been conducting routine algal
nutrient bioassays (in the light box) on our supply water to deter-
mine if any nutrient other than nitrogen is rate-limiting. Unfor-
tunately, the results of these studies have not always been applicable
to the outdoor growth units. For instance, in the light box cultures
there is a very definite year-round 2-4 mg/1 phosphate requirement,
as well as a 2-4 mg/1 iron requirement for part of the year. Figure 2
illustrates the typical relationship between iron and phosphate
additions on algal nitrate assimilation, as determined in the light
box cultures. Accordingly, during one 30-day study in the outdoor
growth units, iron was added to a series of ponds at different
detention times. Ponds receiving iron had total nitrogen removal
efficiencies 20 percent to 30 percent higher than did the ponds with
no iron additions (figure 3a). However, at other times of the year,
the addition of iron had little or no effect on nitrogen removal
(figure 3b), even though it did show up as rate-limiting under light
box conditions.
The same inconsistencies in response have been noted with phosphorus.
The addition of phosphate to the outdoor growth units (figures 4),
though not as well defined as in the light box cultures (figure 2),
clearly demonstrates a need for additional phosphate. During; certain
times of the year, particularly in late spring and early summer when
algal growth rates are maximum (optimum light and temperature), the
pH level is increased to as high as pH 10 and a noticeable precipi-
tation of phosphate salts occurs. In addition, if the level of
either iron or phosphate is increased over the optimum level of
both combined, the level of the other must also be increased. This
is probably the result of co-precipitation at the normal pH (8-10)
and temperature (20-30°C.) ranges of the studies (figure 2).
Temperature also has a significant influence on algal nutrient
response. As ambient temperatures decrease, algal growth rates
also decrease to a level where nutrients are not likely to be limiting
130
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FIGURE 2
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P04-P ADDITION (MG/L)
AVERAGE N03 -N CONCENTRATIONS AFTER 12 DAYS
WITH VARIOUS P04 -P LEVELS AT TWO FE LEVELS
THE EFFECT OF IRON AND PHOSPHATE ADDITIONS ON NITRATE
ASSIMILATION IN THE LIGHT BOX
132
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THE EFFECT OF PHOSPHATE ADDITION ON NITRATE REMOVAL
IN OUTDOOR GROWTH UNITS
134
-------�
(this is not the case with light box cultures). Figure 5 illustrates
the effect of temperature on total nitrogen removal in outdoor growth
units. In this particular study, a submergible heater was placed
in a small growth unit for a 30-day period. Water temperatures in
the unheated pond averaged 16.5°C., while the heated pond averaged
5°C. higher. Nitrogen removal rates were increased by as much as
20 percent in the heated unit over the unheated unit. The data
gathered suggest cause-effect relationship between temperature
and nutrient requirements, most likely due to the effects of temper-
ature on both chemical solubility and biological activity.
Figure 6 illustrates the effect of CC^ addition on algal nitrate
assimilation in the light box. Growth rates, along with corresponding
nitrogen uptake by algae, are greatly increased by the addition of
4 percent CC>2 or atmospheric air. Carbon dioxide performs two basic
functions in algal systems. First, it provides the carbon necessary
for cell synthesis (carbon is often a limiting nutrient in our
water); and, secondly, it maintains the pH at a level at which
nutrient precipitation (e.g., Fe and PO.) is decreased.
The advisability of using CC^ in laboratory studies of algal growth
requirements is often questioned as constituting an unnatural condi-
tion. However, the function of carbon is no different from that of
any other algal nutrient in that it should be in excess (unless it
is specifically being tested) when the effect of any other nutrient
is to be determined. Meyers (Lewin, 1967) states that the investi-
gator faces criticism if he uses 5 percent CC^ for aeration; yet,
if he does not aerate, the CCL concentration may be reduced to a
level below that commonly encountered in natural waters in which
cell concentrations are typically low and CO^ rarely is a limiting
factor. We have found (Brown and Arthur, 1969) that in our water,
when there are high algal concentrations, an external inorganic
carbon source (as CO^) acts primarily to speed up growth, rather
than to change the overall effect of supplemental nutrient addition.
When extra carbon was added as 100 percent CO during this past
summer (1969) to several of the smaller outdoor growth units (figure 7)
and the large, one-quarter acre pond for several hours each day,
there was an immediate increase in nitrate, nitrite, and phosphate
uptake; however, after 10 or 15 days of 100 percent nitrate removal,
an algal die-off occurred in the ponds. Subsequent light box and
growth unit studies have failed to reveal the cause. However,
light box studies conducted immediately after the algal growth pond
die-offs did indicate that neither the 100 percent C02 or the by-
products resulting from C02 addition were toxic. Nor did the die-
offs appear to be the result of nitrogen deficiency, as was first
suspected. Furthermore, a study involving the outdoor growth units
conducted in early fall (1969) showed little effect of C02 on nitrate
135
-------�
FIGURE 5
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FIGURE 7
20-1
/INJECTION OF C02
DAYS OF RUN
EFFECT OF C02 ADDITION ON EFFLUENT NITRATE, NITRITE, AND PHOSPHATE
IN SMALL OUTDOOR GROWTH UNITS
138
-------�
uptake (figure 8), nor were there any subsequent algal die-offs.
Indications are that the dissimilarities noted between the light
box cultures and the growth units with respect to algal nutrient
responses were the result of different seasonal growth rates.
Summary
Studies presently being conducted 'at the IAWWTC to develop practical
biological methods for removing nitrogen from the proposed San Luis
Drain indicate that algal assimilation of nutrients into cellular
material with subsequent removal from the growth medium is a feasible
process. Furthermore, the efficiency of the proposed system is
greatly enhanced if as many variables as possible are optimized,
leaving only nitrogen limiting.
Earlier studies on the effect of such physical variables as deten-
tion time, mixing, and depth indicated that one or more other
factors were affecting algal growth and nitrogen assimilation.
Preliminary light box studies indicated that the variations which
occurred in the levels of nutrients in the source water may have
been responsible for differences in algal response. A review of
chemical data pertaining to the source water over a 3-year period
indicated that large fluctuations in major nutrients and total
dissolved solids did take place.
Laboratory algal nutrient bioassays indicate that orthophosphate
additions of 2.0-3.0 mg/1 P are required the year round to remove
20.0 mg/1 nitrate-nitrogen from the growth medium. This amount
corresponds to the theoretical values predicted from analyses of
the chemical constituents of typical algae. Algae usually contain
10 percent nitrogen, 1 percent phosphorus, and 50 percent carbon.
Iron and carbon (as CO^) also have been found to be limiting algal
growth and nitrogen assimilation during part of the year.
Application of light box results to outdoor growth units have not
always been successful. These differences are thought to be a
function of growth rate. In the light box bioassays, light and
temperature are optimum the year round, while in the outdoor growth
units these parameters vary and as growth rates vary nutrient
requirements vary. It is hoped that in the near future, it will be
possible to quantify these variations and to develop relationships
between them.
139
-------�
FioURE 8
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EFFECT OF VARIOUS LEVELS OF AERATION ON NITROGEN REMOVAL
IN SMALL OUTDOOR GROWTH UNITS
140
-------�
Papers Cited
(1) American Public Health Association, 1965. STANDARD METHODS
FOR THE EXAMINATION OF WATER AND WASTE WATER, 12th Edition,
American Public Health Association, Inc., New York, New York.
(2) Beck, L. A., and St. Amant, P. P., 1968. IS TREATMENT OF
AGRICULTURAL WASTE WATER POSSIBLE? 4th International Water
Quality Symposium, San Francisco, California (August 14, 1968).
(3) Beck, L. A., Oswald, W. J., and Goldman, J. C. 1969. NO,
REMOVAL FROM AGRICULTURAL TILE DRAINAGE BY PHOTOSYNTHETIC
SYSTEMS. Symposium on Sanitary Engineering Research Develop-
ment and Design, Cornell University, Ithaca, New York (1969).
(4) Brown, R. L., and Arthur, J. F., 1969. EFFECT OF SURFACE/
VOLUME RELATIONSHIPS, C02 ADDITION, AERATION, AND MIXING ON
NITRATE UTILIZATION BY SCENEDESMUS CULTURES IN SUBSURFACE
AGRICULTURAL WASTE WATER. Presented at the Eutrophication-
Biostimulation Workshop, Berkeley, California (June 19, 1969).
(5) Fogg, G. E., 1965. ALGAL CULTURES AND PHYTOPLANKTON ECOLOGY,
University of Wisconsin Press, Madison and Milwaukee.
(6) Joint Industry/Government Task Force on Eutrophication, 1969.
Provisional Algal Assay Procedure, unpublished.
(7) Lewin, R. A. (Editor), 1967. PHYSIOLOGY AND BIOCHEMISTRY OF
ALGAE, Academic Press, New York and London.
(8) Lindholm, R. R., 1965. SAN JOAQUIN VALLEY DRAINAGE INVESTI-
GATIONSAN JOAQUIN MASTER DRAIN, Preliminary Edition,
California Department of Water Resources, Bulletin No. 127.
(9) Ruttner, 1965. FUNDAMENTALS OF LIMNOLOGY, 3rd Edition,
University of Toronto Press.
(10) St. Amant, P. P., and McCarty, P. L., 1969. TREATMENT OF HIGH
NITRATE WATERS. Presented at the Annual Conference, American
Water Works Association, San Diego, California (May 1969).
(11) Stetson, C., and Price, E. P., 1968. A DRAINAGE SYSTEM FOR
THE SAN JOAQUIN VALLEY. 4th International Water Quality
Symposium, San Francisco, California (August 14, 1968).
(12) Tamblyn, T. A., and Sword, B. R., 1969. THE ANAEROBIC FILTER
FOR THE DENITRIFICATION OF AGRICULTURAL SUBSURFACE DRAINAGE.
24th Annual Purdue Industrial Waste Conference, Purdue
University, Lafayette, Indiana (May 8, 1969).
141
-------�
THE EFFECTS OF NITROGEN REMOVAL ON
THE ALGAL GROWTH POTENTIAL OF
SAN JOAQUIN VALLEY AGRICULTURAL TILE DRAINAGE EFFLUENTS
By
Randall L. Brown, Richard C. Bain, Jr.,
and Milton G. Tunzi1
Introduction
An integral part of the Firebaugh treatment studies was laboratory
culture experiments to determine the effectiveness of the two
biological processes under investigation, algal stripping and
bacterial denitrification, for removing the algal growth potential
(AGP) of the tile drainage water when added to potential receiving
waters in the Sacramento-San Joaquin Delta. The AGP can be practi-
cally defined as the maximum algal growth (cell numbers, biomass,
etc.) occurring in a water sample in the laboratory when available
nutrients in the sample are the only limiting factors. An additional
objective of these studies was to determine if nitrogen, an essential
algal nutrient, was limiting in the Delta system during all seasons.
Earlier work by the FWPCA (1968) had concluded that nitrogen limited
algal growth only during the spring and summer.
This paper presents some results from these laboratory culture
studies conducted at laboratories in Alameda (FWPCA) and Bryte (DWR),
California during the period January through November 1969. General
procedures for batch assays follow the Provisional Algal Assay Pro-
cedure (1969) with changes in growth being measured by either in
vivo or extractable chlorophyll fluorescence (Bain, 1969). Fluoro-
metry methods were used because of the small subsample volumes
required for chlorophyll measurement and because of their simplicity,
rapidity, and sensitivity.
Methods and Materials
Water. Samples of Delta water were collected near Antioch the day
before an experiment and stored overnight in the dark in plastic
bottles. Treated and untreated tile drainage was also obtained from
the Firebaugh site the same day. Algae were removed from growth
Biologist, California Department of Water Resources, Fresno,
California, and Sanitary Engineer and Aquatic Biologist, Federal
Water Pollution Control Administration, Alameda, California,
respectively.
143
-------�
pond effluent using a flocculent, usually alum or lime. This sepa-
ration process simulated conditions of an operating algae harvesting
plant. All samples from the Firebaugh site were filtered through
Whatman GFA glass filters to remove residual fluorescence. The
Delta samples were unfiltered and thus contained native phytoplankton
which was tested for growth response in the assay. Unfiltered Delta
water, usually containing 1,000-2,000 algal cells per millilLter
(predominantly diatoms), was mixed with various proportions of
treated and untreated agricultural drainage water. Algal counts of
representative flasks were obtained at the termination of an
experiment.
Environmental Conditions. Although both laboratories generally
followed culture procedures outlined in the Provisional Algal Assay
Procedure (1969), there were deviations because of preexisting
facilities and equipment. In each laboratory, growth chambers were
constructed in converted cold storage boxes with temperatures con-
trolled to 20°G.+ 1°C. Lighting was provided by cool-white fluores-
cent bulbs of 350-450 ft-c illumination. At Alameda, light was
directed from beneath the flasks; whereas, at Bryte the bulbs were
above the cultures. Lighting was continuous at both laboratories.
Bryte had reciprocating shakers and both laboratories had the facili-
ties for air mixing; however, only daily swirling was used in these
regrowth studies. Preliminary culture work indicated that swirling
was as effective as either shaking or air mixing. The cultures were
incubated in 500 ml Erlenmeyer flasks filled with 250-300 mis. of
sample. All cultures were grown in triplicate.
Measurement of Response. Both laboratories utilized Turner Model III
fluorometers to measure the in vivo changes in chlorophyll fluores-
cence. Modifications to the fluorometers included a red sensitive
photomultiplier and high sensitivity door (which passes light through
the sample more than once) at Bryte and blue light sources at both
laboratories. A blue primary filter (Corning CS 5-60 with maximum
transmission at 450 mu) and a red secondary filter (Corning CS 2-64,
maximum transmission at 650 mu) were used in the machines. Instru-
ments were nulled against distilled water blanks and subsamples read
using 12x75 mm cuvets. Because of the greater sensitivity of the
instrument at Bryte, samples with off-scale readings were diluted
with distilled water to bring them back to a readable range. As
much as possible all samples were read on the same sensitivity scale.
In vivo fluorometry was used after June 30, 1969. Before this time,
growth was measured by the fluorescence of acetone extracts. In-this
method the water sample was filtered through a Whatman GF/C glass
filter, preserved with magnesium carbonate, frozen, and stored in
darkness. The entire filter (with algae) was then ground in a tissue
grinder with 90 percent acetone. The chlorophyll dissolved in the
144
-------�
90 percent acetone was measured by fluorometry. Chlorophyll "a"
was distinguished from phaeophytin by a second reading after the
addition of HCL.
Although fluorescence was the principal parameter recorded, on
occasion other data were obtained. Nitrate, pH, absorbency at
410 mu, and volatile solids information was obtained during some
runs.
Results
Growth Limiting Nutrient. The primary objective of one series of
experiments was to demonstrate that removal of nitrate from agri-
cultural waste water would reduce its algal growth potential.
Figure 1 shows the results of 10 percent additions of agricultural
drainage water before and after bacterial denitrification processes.
Algal growth in those cultures containing processed water was
almost identical to Delta water controls. In contrast, the addi-
tion of untreated drainage promoted continuous growth much beyond
that of the other samples. Concentrations of NO^-N in these samples
was 17.9, 0.2, and 0.6 mg/1 for the untreated water and for the two
tested bacterial filters, respectively.
Adding nitrogen back to the water from which it has been removed
will result in a medium with an algal growth potential similar to
the original agricultural waste water. Figure 2 illustrates typical
results of nitrogen re-addition to treated waste water. The addition
of 5 percent bacterial filter water had a slight stimulatory effect
on the algal growth potential of the Delta water. A 5 percent addi-
tion of untreated drainage water resulted in a peak fluorescence
value of approximately 200. Additions of 3 or 6 mg/1 nitrogen
(NaNO-j) to the treated water caused the AGP of these samples to
reach peak values similar to that of the untreated water. Untreated
drainage water had a nitrate concentration of approximately 14 mg/1.
Waters with the chemical composition shown in table 1 gave the algal
bioassay results in figures 3 and 4. The treated and untreated agri-
cultural waste water was added to San Joaquin River (Delta) water at
concentrations of 2, 5, and 10 percent by volume.
In figure 3 the AGP's for effluent from the bacterial filter and the
untreated agricultural drain are compared. The AGP's for the combi-
nations of untreated drain water are all significantly higher than
those with effluent from the filter. Using the data from table 1,
the actual increases of inorganic nitrogen (nitrate, nitrite, and
ammonia) range from 0.3 to 1.6 mg/1 with untreated agricultural
tile drainage water addition and from 0.012 to 0.06 mg/1 increase
with bacterial filter effluent. Apparently the addition of more
145
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than 0.8 mg/1 NOo-N (5 percent agricultural drainage water) was
enough to cause the maximum increase in growth because the curves
for 5 and 10 percent drain tile water additions are essentially the
same. The stimulation effect produced by the filter effluent would
probably not normally be noted in the Delta water but in this case
the original Delta water nitrogen levels were so low that addition
caused stimulation of growth.
Figure 4 shows a comparison of the bioassays of effluents from the
untreated drainage and from the algal stripping system. The total
inorganic nitrogen concentration in the algal effluent was higher
than in the bacterial filter effluent, 3.73 mgN/1 compared to
0.62 mgN/1 (table 1).
Table 1 - Chemical Data for Firebaugh Samples
September 29, 1969
Chemical
N03-N
N02-N
NH-N
Total Inorganic N
Organic N
P04-P
Untreated
Agricultural
Tile Drainage
Water
(mg/l)
16.3
0.0
0.0
16.3
0.4
0.1
Treated
Agricultural Tile Drainage
Water
Algal Pond
(mg/l)
3.4
0.2
0.13
3.73
1.19
0.1
Bacterial Filter
(mg/l)
0.3
0.2
0.12
0.62
0.48
0.1
The concentration of nitrogen in the algal pond effluent was about
2-3 times as high as would normally be discharged from the treatment
facilities.
In figure 4, each bioassay curve has the total inorganic nitrogen con-
centration present in the sample yielding the curve. Note the diriect
functional relationship between fluorescence peak and nitrogen concen-
tration.
Comparison of Treatment Methods. The organisms in the two treatment
methods use entirely different pathways for removing nitrogen. There-
fore, there was a possibility that the product waters might have
differing effects on AGP even when their nitrogen contents were
similar in concentration. This possibility was enhanced by the algal
separation process which might remove trace metals or other growth
requirements from solution. Although many assays were conducted, it
was often impossible to obtain process effluents with similar nitrogen
150
-------�
concentrations. Thus it was difficult to show if either system was
more effective in lowering the algal growth potential of the agri-
cultural waste water based on their nitrogen content alone. Gener-
ally, it can be stated that nitrogen removal lowered the AGP,
regardless of what treatment method was used. Two experiments in
which the effluent nitrogen levels were comparable also indicate
that the two systems were similar in their effect on AGP.
The first experiment was conducted on July 25, 1969, using effluent
from an algal pond and a bacterial filter having total nitrogen con-
centrations of about 1.5 mg/1, but with less than 0.5 mg/1 inorganic
nitrogen. Analysis of variance calculations was performed on
differences between initial and maximum fluorescence readings.
Table 2 shows the 95 percent confidence levels obtained by a multiple
range test. The samples connected by underlines are not different
at the 95 percent confidence level. In all instances both pond and
filter effluents showed significantly lower effect than sump water
addition. The pond and filter effluents were the same at 1 and 10
percent additions, but the algae had a greater nutrient removal
effect at 20 percent addition. Based on nitrogen data both efflu-
ents should have had the same effect at all dilutions.
Table 2 - Comparison of Growth Response in San Joaquin
River Water With Percentage Additions Of
Algal Pond, Bacterial Filter, and Untreated
Tile Drain Water
Untreated Treated
Agricultural Agricultural Tile Drain
Percent Addition Tile Drain Water Water
Algal Pond Bacterial Filter
1%
10%
20%
10.8
37.3
34.9
(Fluorescence ttnlts)
1.2
1.2
0.0
1.2
2.4
14.4
Another experiment conducted on September 25, 1969, again using water
from the algal and bacterial filter systems with less than 0.5 mg/1
inorganic tended to confirm the hypothesis that both methods of treat-
ment affected AGP in a similar manner (table 3). Again the difference
between peak and initial fluorescence of the various percentages of
treated water were lower than noted in comparable percentages of
untreated water. In this study algal, and bacterial effluents were
no different in their effect on algal growth at any dilution at the
95 percent confidence level.
151
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Table 3 - Comparisons of Growth Response In
San Joaquin River Water With Percentage
Additions of Algal, Bacterial, and Untreated
Tile Drain Water
September 25, 1969
Untreated Treated
Agricultural Agricultural Tile Drain
Percent Addition Tile Drain Water Water
Algal Pond Bacterial System
1%
10%
20%
4.2
36.2
39.8
(Fluorescence units)
1.3
3.0
1.1
3.0
1.9
1.9
Seasonal Variations in San Joaquin River Water at Antioch., The chlo-
rophyll fluorescence of Antioch water increased from 22.5 fluores-
cence units in mid-June to a peak of 32.5 in late July and gradually
declined to a value of 16.4 by mid-November. Nitrate nitrogen tends
to be lowest in summer and increase in the fall reflecting the
seasonal reductions in algal crop (see table 4).
When Antioch samples are incubated in the laboratory, the chlorophyll
values achieved are similar for all the months tested; see table 4.
Spring and fall samples exhibit growth indicating presence of inor-
ganic nutrients in the Antioch water; summer samples exhibited little
or no growth between initial (field) values and laboratory incubated
values made over a period of 1 week or more. This lack of: additional
yield during summer suggests nutrients were essentially exhausted in
the Delta waters sampled during summer. This finding agrees with
past findings by FWPCA in connection with San Joaquin Master Drain
studies, (Bain, et al., 1968).
152
-------�
Table 4 - Seasonal Chlorophyll and Nitrate Variations
in the San Joaquin River at Antioch Bridge
Chlorophyll Fluorescence
Date
Nov.
Dec.
Jan.
Jan.
Feb.
Mar.
Apr.
June
July
Aug.
Sept
Sept
Oct.
Nov.
Sampled
14,
13,
4,
28,
14,
10,
4,
18,
25,
18,
9,
. 29
20,
17,
1968
1968
1969
1969
1969
1969
1969
1969
1969
1969
1969
, 1969
1969
1969
Initial
(field)
0
1
1
1
0
1
3
22
32
27
24
25
21
16
.3
.6
.0
.2
.9
.4
.3
.5
.5
.6
.6
.4
.6
.4
Peak
(AGP)
27.
34.
30.
82.
54.
36.
12.
30.
32.
28.
26.
28.
28.
25.
7
5
8
6
9
2
1
9
5
0
5
3
2
5
NOo-N
(mg/1)
(initial)
..
.43
.61
.74
.95
.53
.22
.18
.04
.05
.08
--
.09
.22
a Direct readings at 30X scale. Values before June 1969 were
corrected from extracted samples based on sample splits to
determine conversion factor.
Discussion
Algal growth potential tests in two different laboratories indicate
that nitrate-rich agricultural drainage, when mixed with San Joaquin
River Delta water, stimulates algal growth. Seasonal factors do
not alter this finding although in situ algal crop levels vary
seasonally in the Delta. Control samples from the Delta near Antioch
yielded approximately equal chlorophyll peaks in 14 separate AGP
experiments during a 1-year period.
The waters of the Delta near Antioch vary seasonally in nitrate-
nitrogen concentration. Summer nitrate concentrations of 0,05 mg/1
or less, as nitrogen, produced no significant chlorophyll increases
in AGP tests, suggesting nutrient limitations in these waters.
Additions of nitrate-rich tile drainage increased chlorophyll in
all experiments. Additions of nutrient stripped effluents from
different pilot scale treatment facilities at Firebaugh, California,
produced no additional growth except in cases where nutrient removal
efficiencies were known to be low. Selective removal of nitrate-
nitrogen by anaerobic denitrification or removal of nutrients by
algal cells grown in shallow ponds yielded comparable bioassay
results.
153
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The Firebaugh experience suggests that eutrophication due to agri-
cultural waste waters can be controlled by treatment. The experi-
ments do not pretend to forecast receiving water response, but to
promote further evidence concerning the importance of nitrogen
nutrition in controlling western Delta algal populations. The AGP
tests are useful ways to demonstrate tertiary treatment efficiency,
particularly since they measure the effect of treatment on eutroph-
ication symptoms.
154
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Papers Cited
(1) Bain, R. C., 1969. ALGAL GROWTH ASSESSMENTS BY FLUORESCENCE
TECHNIQUES. Proceedings of the Eutrophication-Biostimulation
Workshop, Berkeley, California, June 19-21, 1969.
\
(2) Bain, R. C., et al., 1968. SAN JOAQUIN MASTER DRAIN ON WATER
QUALITY OF THE SAN FRANCISCO BAY AND DELTA, Appendix Part C -
Nutrients and Biological Response. Federal Water Pollution
Control Administration. 116 pp.
(3) JOINT INDUSTRY/GOVERNMENT TASK FORCE ON EUTROPHICATION, 1969,
Provisional Algal Assay Procedure, New York. 62 pp.
155
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HARVESTING OF ALGAE GROWN IN
AGRICULTURAL WASTE WATERS
By
Bruce A. Butterfield and James R. Jones-*-
Introduction
The U.S. Bureau of Reclamation, the Federal Water Pollution Control
Administration, and the California Department of Water Resources
are currently engaged in a joint study near Firebaugh, California,
to determine the feasibility of removing nutrients from subsurface
agricultural waste water in the San Joaquin Valley. Algae harvesting
is being studied for three reasons. One of the processes being
studied is to grow algae, under controlled conditions, which assimi-
lates the unwanted nutrients into cellular material, and then to
harvest the algae from the suspension. Secondly, removal of
naturally occurring algae will be necessary because disposal into
the San Joaquin Delta-San Francisco Bay System is not desired.
And finally, if anaerobic denitrification columns are used to remove
nitrogen, it will be essential to remove algae before the drain
water enters the unit.
This paper is concerned with the algal removal or separation studies
carried on at the Interagency Agricultural Waste Water Treatment
Center (AWWTC). The studies were divided into two phases. One
phase was concerned with the laboratory evaluation of commercially
available flocculating aids. The other phase; with evaluation of
some commercially available separation devices.
Flocculation-Sedimentation Study
Methods and Materials. In the laboratory evaluation of commercially
available flocculating aids, the source of algae-laden water was the
outside growth units of the AWWTC. The algae were grown in saline
water (total dissolved solids has a yearly range from about 2,000 to
over 8,000 mg/1) with some nutrients added to encourage algal growth.
The predominate algae grown were Scenedesmus quadricauda. Concen-
trations ranged from approximately 150 to 400 mg/1 as volatile solids.
A day's sample was collected in a large container and stored in a dark,
cool place. Subsamples were extracted from it throughout the day.
This was done to eliminate daily variations and to allow comparison
between different flocculants.
Assistant Civil Engineer, California Department of Water Resources;
Civil Engineer, U.S. Bureau of Reclamation, Department of the
Interior, respectively; Fresno, California.
157
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In jar tests described below, a total of 56 flocculation aids were
tested alone and in conjunction with these flocculants; aluminum
sulfate, calcium hydroxide and ferric sulfate. The subsamples
with varying flocculation aid concentrations were prepared simul-
taneously and then allowed to settle for 1 hour in a cool, dark
cabinet. The next step was to decant and measure percent light
transmittance of the supernatant. Percent transmittance was scaled
from zero percent (total darkness)' to 100 percent (distilled water)
using a spectrometer at 410 mu. The percent transmittance and
total volatile solids of the uncoagulated sample were also measured.
With these two values, a ratio was developed indicating the amount
of algae removed per sample. The testing of the flocculation aids
was accomplished by optimizing mixing time and rate of mix for the
main flocculants. The criteria were 70 r.p.m. and 3 minutes for
aluminum sulfate and 40 r.p.m. and 8 minutes for calcium hydroxide.
If used alone, they were mixed the same as aluminum sulfate. These
values were obtained using an 800 milliliter sample in a one-liter
beaker mixed by a multimixer with 3-inch by 7/8-inch rectang;ular
paddles.
Discussion
Of the 168 combinations tested, 60 did show some benefit in the
separation process; however, economic evaluation (cost of floccu-
lation aid required) indicated that only the following 24 combi-
nations warrant further investigation:
Flocculation Aid Main Flocculant
1. Dow Chemical Co. PEI 600 aluminum sulfate
2. Dow C-31 none
3. Dow C-31 aluminum sulfate
4. Dow C-32 none
5. Dow C-32 aluminum sulfate
6. Narvan Mines Zeta Floe "0" calcium hydroxide
7. Nalco Nalcolyte 603 aluminum sulfate
8. Nalco Nalcolyte 610 calcium hydroxide
9. Rohm and Haas Primafloc C-3 aluminum sul-fate
10. Rohm and Haas Primafloc C-5 none
11. Rohm and Haas Primafloc C-5 aluminum sulfate
12. Rohm and Haas Primafloc C-7 none
13. Hercules, Inc. Hercofloc 814 aluminum sulfate
14. General Mills, Inc. Genfloc 155 none
15. General Mills, Inc. Genfloc 155 calcium hydroxide
16. General Mills, Inc. Genfloc 156 none
17. General Mills, Inc. Genfloc 156 calcium hydroxide
18. General Mills, Inc. Genfloc 162 none
19. General Mills, Inc. Genfloc 162 calcium hydroxide
158
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Flpcculation Aid
20. American Cyanamid Co. Magnifloc 521-C
21. American Cyanamid Co. Magnifloc 521-C
22. American Cyanamid Co. Magnifloc 820-A
23. American Cyanamid Co. Magnifloc 836-A
24. American Cyanamid Co. Magnifloc 835-A
Main Flocculant
none
aluminum sulfate
calcium hydroxide
calcium hydroxide
calcium hydroxide
The performance of the three main flocculants varies throughout the
year. At certain times, ferric sulfate was tested and found to be
cheaper and perform better than either aluminum sulfate or calcium
hydroxide. At present, they are being monitored on a weekly basis
in order to determine which would be the most economical. Since
iron in the form of ferric chloride (also a flocculant aid) has
been added to the algae growth units as a nutrient, aluminum sulfate
and ferric sulfate have become more effective and calcium hydroxide
less effective.
Carbon has been added to the growth units in the form of carbon di-
oxide and has also affected the efficiency of these three floccu-
lants. Carbon dioxide addition lowers pH, causing ferric and
aluminum compounds to become more effective and calcium hydroxide
less effective. At the AWWTC, a 5.6 pH was found to be optimum,
when ferric and aluminum compounds are used; but this is uneconomical
due to the cost of acid.
Seasonal variations of water quality, temperature, light, etc.,
appear to be influencing factors and must be monitored. A typical
effective series of tests performed in the spring, of aluminum
sulfate, ferric sulfate, and calcium hydroxide is shown on table 1.
Table 1 - Flocculant Effectiveness
(in percent transmittance)
Flocculant
Flocculant Concentration, _mg/l
Ferric Sulfate
Aluminum Sulfate
Calcium Hydroxide
0
63
63
67
3
88
64
66
5
94
65
66
10
94
66
67
20
95
74
70
40
94
93
80
95
The percent transmittance of the original sample was 6 percent and
the volatile solids were about 500 mg/1. The zero concentration
shows the effect of ferric chloride addition to the growth pond;
however, no carbon dioxide was being added then.
159
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Pilot Harvesting Studies
The second phase of separation studies involved the evaluation of
pilot-scale separation devices. The units included flocculation
and settling units, centrifuges, a microscreen, a vacuum filter, a
rapid sand filter, and sand drying beds. It was planned that these
units would give an indication as to how traditional separation
equipment would work on algae-laden water at the AWWTC.
The algal concentration of growth pond effluent varies from 150 mg/1
to 400 mg/1 (0.015 to 0.04 percent by weight). Algae separation is
divided into three stages: concentrating, dewatering and drying.
Concentrating increases the algae solids to l-to-4 percent.
Dewatering increases the solids to 8-to-16 percent. Drying processes
bring the solids to 85-to-92 percent. Destruction of the algae cell
and denaturing of the protein occurs when drying exceeds approxi-
mately 92 percent.
Flocculation and Sedimentation. Algae at Firebaugh can be concen-
trated to about 1 or 2 percent by weight through flocculation and
sedimentation. Settling as a procedure for harvesting of algae is
hindered by the small size of Scenedesmus quadricauda (10-40 micron)
and its specific gravity (approximately 1.006). Auto-flocculation,
the tendency for algae to clump together and settle, occurred
naturally under certain conditions in the rapid growth pond.
A complete self-contained water treatment plant was used for concen-
tration studies. Installed in the settling chamber was a modular
unit of 1-1/2-inch-diameter settling tubes at a five degree incli-
nation to the horizontal. The tubes were installed to reduce the
settling distance of the algae. When the tubes were drained or
backwashed, the algae sludge flowed down and out of. the inclined
tubes.
In general, when transmittance of the settling tank effluent fell
below 90 percent transmittance the unit was backwashed. The amount
of water needed to backwash the tubes was 5-10 percent of the product
water and contained less than 1 percent algae by weight. Aluminum
sulfate was used as a flocculation aid in the unit. With an influent
pH above 9.0 and detention time of 2 hours, 300 to 400 p.p.m. of
aluminum sulfate were needed to remove the suspended algae during
the fall.
Upflow Clarification. One of the concentration devices tested at
the AWWTC was an upflow clarifier. As algae-laden water flows upward,
the cross-sectional area increases and the velocity decreases causing
a settling to take place. At this point, a blanket of floe developed
causing a filtering effect. The sludge or concentrate was drawn off
at this point and clarified liquid was passed off at an upper level.
160
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The operation involved pH adjustment (to approximately 10.8) of the
influent with sodium hydroxide to flocculate the suspended solids.
At times the blanket appeared to plug the unit and stop all flow.
This was followed by a breakup of the blanket and short-circuiting.
The operation removed 90 to 95 percent of the suspended solids in
the 2 to 4 percent solids concentration range.
Centrifugation. Investigations were made into the application of a
solid bowl continuous horizontal centrifuge and a yeast-type nozzle
centrifuge. A self-cleaning centrifuge, similar to the yeast sepa-
rator but with added features, will be tested.
The centrifuges were tested both as algae concentrators and dewaterers.
The dewatering study used algae water concentrated in a sedimentation
unit using aluminum sulfate. A progressing cavity pump or a gravity
feed system was used in all cases to provide a steady, nonpulsing
flow.
The solid bowl centrifuge tested was a 6-inch pilot unit. Variables
included flow rate centrifugal force, and depth of liquid in the
bowl. The bowl depth controlled the sludge consistency from high
flow and wet cake (higher efficiency of algae removal) to low flow
and dryer cake (lower efficiency). In general, algae concentrations
of 3 to 22 percent by weight were achieved, but the efficiency was
usually less than 10 percent. An efficiency of 28 percent was
achieved, but with high flow and wet cake. Whether used for concen-
trating or dewatering, the efficiencies were comparable, but due to
the large volume that will need concentrating, it would not be economi-
cal to use a solid bowl centrifuge except for dewatering. The solid
bowl centrifuge was found to be relatively maintenance-free.
The yeast-type nozzle centrifuge is designed for solid/liquid and
solid/liquid/liquid separation with continuous feed and removal.
Centrifugal force is constant and the solids discharge is controlled
by varying the number and size of nozzles. Maximum flow rate was
1-1/2 g.p.m. With flow rate below 1/2-gallon per minute, no removal
was achieved due to lack of cake buildup in the bowl. As a primary
concentrator this unit obtained removals greater than 80 percent,
but would soon plug with algae and suspended clay material. As a
dewaterer, it would plug sooner with the heavier algal loading.
Screening. A vacuum filter and microscreen are being evaluated.
The vacuum filter has not been tested sufficiently to make any conclu-
sions. In conjunction with this unit, a leaf kit filter was supplied
to help in evaluating the effectiveness of different filter material.
A close-weave monofilament nylon material (120 by 240 threads to the
inch) showed promise in separation and was relatively easy to clean
which is an important factor in economics. Several synthetic felts
gave acceptable results.
161
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An automatic, rotating, drum-type, straining system was tested for
separation of algae. The unit consisted of a self-contained 4-foot-
diameter by 1-foot-wide rotating drum. Screens of 25 micron and
35 micron were supplied with the unit. Algal-laden water entered
the interior of the partially submerged drum and was strained as
the water flowed outward through >the revolving screen. The algae
was caught on the screen and washed off by a row of water jets
located above and outside the drum. It became apparent that the
25 micron screen allowed the smaller algal cells to pass. With the
25 micron screens, the unit removed up to 8 percent of the algae
in a slurry flow of approximately 1 percent of the total influent.
Rapid Sand Filtration. A cross-flow sand filter was evaluated as
a primary algal concentrator. This filter consisted of two sand
beds 3/8 inch thick, 5 inches wide, and 5 feet high. The sand was
contained between two pieces of fine-weave nylon monofilament cloth,
which was supported by 3/8 inch wide plastic spacer strips. The
raw water was pumped up between front and back plastic covers in
the space formed by the plastic spacer strips. It then passed
through the sand bed from both sides toward the center open space
provided by more 3/8-inch spacer strips. The product filled a
column above the filter and overflowed at the top. The water in
the column was used to backflush the filter when the pressure
difference through the sand bed reached a predetermined level. It
became apparent that the sand bed was becoming plugged with algae
as the time between backwashes became shorter. The algae removal
was over 90 percent (without chemical addition) and the solids
content of the sludge, or backwash, was as high as 10 percent.
Future Work
The objective during the next year will be to monitor seasonal vari-
ations that affect the harvesting of algae and to refine operational
procedures. Seasonal monitoring for chemical requirements will be
maintained. Additional seasonal monitoring of the physical charac-
teristics of algae will be maintained to extend the evaluation of
hardware in the dewatering and drying processes. The evaluation of
the microscreen and vacuum filter will be continued to test various
filter materials. A self-cleaning basket centrifuge will also be
evaluated. Future separation work will include flotation studies.
Conclusions
Through laboratory and field testing, it is obvious that effective
concentration can be accomplished using the flocculation-sedimentation
process to remove 90-95 percent of the suspended solids from algae-
laden agricultural waste water. It appears that dewatering and
162
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drying can be accomplished but the efficiencies of the units tested
at AWWTC were low. The need to recirculate the water would increase
the overall cost; however, it is believed better results will be
achieved in larger capacity units.
163
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COMBINED NUTRIENT REMOVAL AND
TRANSPORT SYSTEM FOR TILE DRAINAGE
FROM THE SAN JOAQUIN VALLEY
By
Joel C. Goldman, James F. Arthur,
William J. Oswald, and Louis A. Beck1
Introduction
Current plans call for treatment of agricultural waste water for
nutrient (nitrogen) removal from the proposed San Luis and Master
Drains prior to discharge into the Bay-Delta Area. Of the several
treatment processes currently being investigated, the algae
stripping process was estimated to have required between 6,000 and
12,000 acres of land to accomplish this task. The original proposal
for utilizing the algae process considered only the use of a sepa-
rate treatment facility to be located adjacent to the Drain some-
where along its length. Because every body of water is a potential
algal growth system, this proposal will demonstrate that there are
several alternatives to the original plan, which will greatly reduce
the total cost of treatment and perhaps improve the overall effi-
ciency of nutrient removal.
General Aspects of Proposal
Objective. It is the objective of this report to present alternate
solutions for the treatment of drainage water through the use of
In-Line Treatment. This treatment will utilize components of the
Drain, which were originally designed solely for the transport and
storage of drainage water. Specifically, it will be demonstrated
that with certain modifications, the Drain, itself, can be used as
a partial treatment unit with nutrient removals of up to 40 to 50
percent, and that with similar modifications, the Drain up to
Kesterson, together with the proposed Kesterson storage reservoir,
can accomplish up to 100 percent nutrient removal.
Basic Assumptions. The Drain, as planned, will promote a degree
of algal growth regardless of design and use which will result in
1 Assistant Civil Engineer, California Department of Water Resources,
Fresno, California; Research Aquatic Biologist, Federal Water
Pollution Control Administration, Fresno, California; Professor of
Sanitary Engineering and Public Health, University of California,
Berkeley, California; and Senior Sanitary Engineer, California
Department of Water Resources, Fresno, California, respectively.
165
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incorporation of soluble nutrients into cells and the resultant
reduction of soluble nutrients, which will necessitate some form
of algae separation before terminal discharge into the Bay-Delta
waters.
The San Luis Drain, as it is now proposed, has a surface area of
approximately 770 acres and with the expected flow will have a
mean detention time of 6.3 days. Based on these considerations, it
is highly likely that the Drain will support an undetermined but
possibly significant algal growth at the point of discharge into
the Delta, depending on time of year. This growth will occur natu-
rally due to the high level of nutrients that are present in the
drainage waters, together with the prevailing environmental condi-
tions (sunlight and temperature) that are present in the San Joaquin
Valley from early spring through late fall. Growth may take one or
both of two forms; sessile algae growing on the canal walls in the
photic zone, or suspended algae growing in the photic zone but
uniformly distributed in the cross-section'of the flow.
Unless specifically removed, it is likely that suspended algae will
pass unaltered through any subsequent process, while sessile algae
will break off the walls in clumps, which will then clog any filtra-
tion process.
Since algal growth in the Drain will be unavoidable, maximization of
this growth, followed by complete separation of the algal biomass,
will result in the following benefits:
a. Land requirements for the treatment facility will be
reduced in proportion to the degree of induced algal growth in the
Drain. Thus, the principal cost for treatment will be reduced.
b. The Drain will be put to a dual useconcurrent transport
and treatment of drainage water.
c. The velocity of the Drain is great enough to provide a degree
of turbulence, which will meet part or all of the mixing requirements
necessary to promote the optimum algal growth desired; power require-
ments for this growth will be reduced, thus reflecting still another
cost reduction.
Kesterson Reservoir, as originally envisioned, was to act as a
storage reservoir to hold the first 2 years of drainage flows from
the San Luis Drain (from December 1969 to December 1971), while
the northernmost portion of the Drain from Kesterson to Antioch was
being constructed. With an estimated annual inflow to the San Luis
Drain during these years of approximately 2,500 acre-feet, the
166
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reservoir will store 5,000 acre-feet of water. Based upon a proposed
3-foot depth, the reservoir will initially encompass a land area of
about 1,700 acres. Eventually the land area of the reservoir would
be built up to about 3,000 acres to serve a variety of uses.
At the time the northern section of the Drain is completed and
Kesterson Reservoir is emptied of the 2 years' storage, it is possi-
ble that a substantial growth of algae will have formed in the
reservoir which will further increase the amount of algae to be found
in the Drain. It is not unrealistic to foresee an algal concentration
of up to approximately 100 mg/1 or more in the Drain at Antioch during
the period the reservoir is being emptied. Based upon light consid-
erations only, the depth of the Drain at Antioch will limit the
maximum concentration of algae that can be supported there to
100 mg/1 (see calculations in Appendix).
Current Status of Treatment Processes. Research has been underway
at Firebaugh for over 2 years to determine the feasibility of removing
nitrogen from agricultural drainage water by either algae stripping,
anaerobic denitrification in either deep ponds or filters, or a
combination of both.
The anaerobic filters have demonstrated a high efficiency during
most of the year but appear to be sensitive to temperatures below
12°c. and experience problems of clogging after prolonged operation.
The algae stripping process during the course of the 2 years of re-
search has shown a steady improvement in efficiency, due in part to
algal adaptation, but also due to increased knowledge of the proper-
ties of the process by those conducting the studies. It has also
been shown that over 95 percent of the algal cells can be separated
from the liquid effluent through coagulation with small quantities
of lime or alum, followed by sedimentation.
Thus, both processes appear to be technically feasible, and one can
envision the types of systems in which they would be used. For
example, several candidate systems are shown in figures 1-A, 1-B,
and 1-C. A combined process (figure 1-C) in which algae are grown
and removed prior to column denitrification would give the greatest
factor of safety at approximately the same cost as either of the
two separate processes (figures 1-A and 1-B).
Effect of In-Line Treatment on Overall Cost of Different Proposed
Treatment Processes. Algae Stripping Process--An acceleration of
the treatment process through the provision of a high initial bio-
mass (the algae grown in the Drain) with a reduction in the soluble
nutrient level will decrease costs by:
167
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168
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a. Reducing the land requirements for a treatment plant.
b. Reducing the construction costs of the plant.
c. Reducing power and maintenance costs for a treatment plant.
Anaerobic Denitrification FiltersAs noted previously, it will be
difficult, if not impossible, to eliminate endemic algal growth from
the Drain under existing nutrient and light conditions. Any nitrogen
incorporated into algal cells in transit will be unavailable for
treatment by denitrification, if the cells pass through the filter.
This nitrogen will then be discharged to the Delta and eventually
could be regenerated as soluble nitrogen. If the cells remain in
the filter, then a further problem of filter clogging will arise.
Research currently in progress at Firebaugh to determine what effect
algal-laden water will have on the filters indicates that it adversely
affects filter performance by increasing the concentration of soluble
nitrogen in the filter effluent.
Thus, if algal growth in the Drain could be optimized and the result-
ing algae separated prior to filter treatment, the unit cost of
treatment (which includes separation) could be reduced in the
following ways:
a. The total area requirements for terminal treatment will be
reduced approximately in proportion to the reduction in soluble
nutrients (principally nitrate-nitrogen). The land area required
for separation facilities will be small compared to the reduction
in land area required for the filters.
b. Filter construction costs will similarly be reduced.
c. Methanol costs will be reduced in proportion to the amount
of nitrate-nitrogen removed by In-Line Treatment.
d. Power and maintenance costs will similarly be reduced.
Suggested Modifications to Improve In-Line Treatment
As previously stated, the Drain without modification has the poten-
tial for reducing nitrogen levels by a significant amount. Similarly,
Kesterson Reservoir outflow will increase the algae concentration
in the Drain by as much as 100 mg/1. Therefore, any modification to
the Drain which enhances this efficiency will have significant
economic value, when compared to the original estimate for treating
Drain water solely in a terminal plant. A number of different
alternatives to the original algae stripping proposal thus becomes
apparent. These are as follows:
169
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Enhance Algal Growth in the Drain by Seeding and Nutrient Addition
(If Required). It will be necessary to seed the Drain at Kettleman
City with approximately 50 mg/1 of algae in order to produce
100 mg/1 of algae at Antioch (see Appendix). Work at the Firebaugh
Treatment Center has indicated that the Alamitos Sump water is
deficient in carbon, phosphorus and iron; three nutrients required
to support an algal growth capable of high nitrogen uptake. In
order to promote algal growth at Firebaugh, it has been necessary
to add small quantities of these three ingredients to the sump water.
If a similar nutrient limitation is present in the combined drainage
waters feeding the San Luis Drain, then nutrient addition would be
required along with the initial seeding. However, it should be
pointed out that the Alamitos Sump water is fed by an isolated tile
drainage system. The fact that the San Luis Drain will be fed by
numerous drainage systems in the San Joaquin Valley greatly reduces
the prospect that the composite drainage water will be lacking in
either iron or phosphorus. Carbon is available to the algae only
in the form of carbon dioxide or its derivative, the bicarbonate ion
Work at Firebaugh has indicated that there appears to be a seasonal
change in the CC>2 requirements necessary for high nitrogen conver-
sion into algal cellular material. Thus, it is possible that supple-
mentary C02 will not be required or may be required only during a
portion of the year and during several hours of the day.
Seeding of the Drain could be accomplished by maintaining a growth
pond at Kettleman City which would feed into the Drain. It is
estimated that a 1,000-acre pond will be necessary to produce the
required 50 mg/1 initially in the Drain.
Thus, it would be possible to reduce soluble nitrate-nitrogen levels
at Antioch by up to 40 percent by using the Drain as it is presently
designed with seeding and nutrient additions (if required). Land
requirements and construction costs for a treatment plant would be
similarly reduced by 40 percent.
Keep the Drain Essentially as Proposed bjit Include Kesterson
Reservoir as a Permanent Part of the Flow-Through System. If
Kesterson Reservoir were a permanent part of the Drain System with
a detention time of 10 days at peak flow (at a 3-foot depth), then
it would be possible to produce 100 mg/1 of algae in the reservoir
effluent, thus eliminating the need for initial seeding. Nutrient
addition may be required in accordance with the previous discussion.
As in the first proposal soluble nitrate-nitrogen levels at Antioch
would be reduced 40 to 50 percent with a corresponding savings in
the cost of treatment.
170
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Modify and Use All or Part of the Drain for Partial Treatment.
Assuming nutrients are not limiting, the growth of algae is primarily
dependent on the quantity of available light energy. In an outdoor
system, sunlight is the sole source of this energy. Thus, the
quantity of energy available for the photosynthetic process is
directly proportional to the amount of surface area exposed to
sunlight.
With regard to using the Drain as an algal growth system, any method
that will increase the effective surface area of the Drain will
increase the photosynthetic efficiency and improve the treatment
process.
Several obvious ways to increase this effective surface area
include:
Increase the Surface Area of the DrainIdeally, in order to accel-
erate the growth of algae in the Drain, itself, the entire Drain
should be constructed so as to optimize surface area and minimize
depth. In order for the Drain to act as a sole treatment unit, its
surface area would have to be increased sevenfold over the' current
design. Since no recommendations have been made concerning choice
of nutrient removal process at this time, and because the Drain up
to Dos Palos has already been designed, there does not appear to be
any justification for further consideration of widening the Drain.
Hydraulically Modify the Drain to Create Turbulence--A direct rela-
tionship exists between the degree of turbulence and effective surface
area. By utilizing the flow of the Drain for mixing and hydraulically
modifying the Drain to create turbulence, the overall photosynthetic
efficiency of In-Line treatment can be greatly improved.
Modifications to be considered are:
a. Baffles along the bottom and/or sides to create turbulence
(at the projected velocities).
b. Drop structures strategically along the length of the Drain
(at the projected velocities).
c. Aeration with air (or CC>2 enriched air) to create turbulence;
aeration could be effected as in an aeration tank of an activated
sludge plant. Aeration units could similarly be located strategically
along the length of the Drain.
d. Pumps at intervals along the Drain to promote turbulence.
171
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However, without further investigation, it is difficult, if not impos-
sible, to quantitatively predict what degree of turbulence is required
to produce a desired algal concentration.
Kesterson Reservoir as a Combined Storage Reservoir-Treatment Plant.
Essentially, a major portion of the San Luis drainage flow and the
bulk of the nitrogen load will enter the Drain before Kesterson
Reservoir. Since the land for Kesterson Reservoir (on the order of
3,000 to 6,000 acres) has already been selected as a large part of
the overall drainage system, the concept of converting Kesterson
Reservoir into a combined storage reservoir and treatment plant appears
to be most promising.
By converting the reservoir into an algal growth system with operating
depths varying from 1 foot to 3 feet, the system has the capability for
over 90 percent treatment and still has the flexibility for acting as
an emergency storage reservoir.
Studies at Firebaugh, thus far, indicate that some degree of mixing
is required in algal systems for optimum growth and nutrient removal.
Research to date indicates several hours of mixing per day appears
adequate although research involving shorter mixing periods, which
also appears favorable, is continuing in this area; but, regardless
of the degree of mixing, it will be a consideration in determining
operational costs for a treatment plant.
From the start of this project, mixing was recognized as a major
operational factor in the algae stripping process and, as a result,
several proposals have been brought forth as how to best accomplish
this objective. It has been suggested that pumps might be centralized
in turret fashion to serve several series of ponds to minimize opera-
tional costs or that pumps could be installed in a racetrack-type
pond, such as at Firebaugh. Any treatment plant utilizing these
types of mixing systems will require substantial amounts of power
which will directly affect the total processing costs.
The system proposed for combining the reservoir for storage and
treatment would minimize the power required for mixing by either a
complete gravity or combined initial pumping-gravity flow system.
The land of Kesterson Reservoir embodies a natural slope to the north.
Thus, a minimum amount of cut and fill would be required to produce
a slope of the required degree. Excavated earth could then be effi-
ciently used for side slopes. If necessary, low cost pumping could
be used initially to produce the necessary velocities in the treatment
process.
A design of such a treatment facility, which lends itself very effect-
ively to the dual use proposed, entails a series of equally spaced
172
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channels running longitudinally along the length of the reservoir.
Figure 2 is a sketch of such a proposed plant. The channels would
follow the natural slope and the flow through each channel could
be regulated by individual head gates. Similarly, these gates
could isolate each channel for treatment flexibility and/or
maintenance.
Any desired detention time could be maintained by recirculating a
portion of the effluent. This design will have the following
inherent advantages over a terminal treatment plant as originally
envisioned:
a. Greatly reduces construction costs due to the simplicity
of design.
b. Provides a great degree of flexibility of operation--can
adjust to seasonal variations in flows.
c. Minimizes power requirements by using gravity for a part of
the required mixing.
d. Prevents biomass buildup by eliminating stagnant areas that
are often present in ponds of the Firebaugh design.
e. Allows for cyclic removal, if required.
f. Treatment can still be carried on while the system is being
used as a reservoir.
g. When the Master Drain is put into operation, the reservoir
can be expanded to meet future treatment requirements (see sketch).
The first stage of Kesterson Reservoir has already been designed and
encompasses a series of 12 ponds, each 3 to 4 feet deep. The total
land area involved is in the order of 1,300 acres. There still
remains 3,000 to 4,000 acres of land which can be utilized for the
combined algal growth system and storage reservoir. Figure 3 is a
location map of the proposed Kesterson Reservoir and shows the por-
tion already designed, together with the land area available for
future reservoir use. Figure 4 is a site plan of the system, showing
how an algal system, as envisioned in figure 2, could be incorporated
into the land area reserved for the remainder of the reservoir.
If the size of the reservoir were 4,000 acres, together with the
1,300 acres for the first stage reservoir, then up to 90 percent of
the influent nitrogen from the San Luis Drain waters could be incor-
porated into algal cell material (see Appendix for calculations).
Perhaps the most significant aspect of using Kesterson Reservoir as
173
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FIGURE 2
8
p
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FUTURE EXPANSION
LOW HEAD PUMPING
IF REQUIP.ED-
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WO/WOML
MA7UPAL
KESTERSON
RESERVO I R
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KESTERSON
-SAM LU/S DPA/M
FLOW DIAGRAM
PROPOSED COMBINED RESERVOIR AND ALGAL
STRIPPING PROCESS
NO SCALE
TYPICAL CROSS SECTION
NO SCALE
*
1
N
174
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FIGURE 3
ixmys^s^s^^^
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STATE OF CAt-IFORKIA
THE RESOURCES AGENCY
DEPARTMENT OF WATER RESOURCES
SAN JOAOUIN DISTRICT
LOCATION MAP
KESTERSON RESERVOIR
SAN LUIS DRAIN
175
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AT KESTERSON
176
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a treatment unit is that it has the potential for future conversion
into a stripping plant, if it were necessary to delay installing any
treatment process until some time after construction of the entire
Drain, including the reservoir. No additional land would be required
for such a process, resulting in a very significant savings in cost.
Similarly, the system may be expanded conveniently as the flow in
the Drain increases. Thus, it would be possible to build the treat-
ment plant in stages concurrent with those to increase the storage
capacity of the reservoir.
Combine the Algae Stripping Process and the Anaerobic Filters in
Series. Inasmuch as the studies at Firebaugh indicate that both the
anaerobic filters and the algae, stripping process are technically
feasible, the concept of combining the two systems in a series-type
operation (see figure 1-C) merits intensive investigation. Kesterson
Reservoir, as outlined in the previous section, could serve as the
site for the algae stripping process, followed by algal separation
facilities, and then followed by the anaerobic filters for final
treatment. A significant aspect of this design is that it inher-
ently emodies a substantial factor of safety and insures a polished
drainage water virtually free of nitrogen and other nutrients even
under extreme circumstances.
If a dependable market can be found for the harvested algae., it is
reasonable to assume that a substantial fraction of the cost of the
entire treatment facility can be defrayed. The whole system could
be easily expanded to meet future needs.
Table 1 gives a gross estimate of both land and cost saving;s that
could be achieved by In-Line Treatment. As can be seen from this
table, a savings of approximately $11 to $12 million is possible
when in-line treatment is used for 90 to 100 percent nitrogen
removal as compared to terminal treatment facility as originally
envisioned.
Summary
Work at Firebaugh has demonstrated that it is possible to remove
nitrogen from drainage water by either algae stripping or anaerobic
denitrification.
It has been suggested in this proposal that serious consideration
be given to In-Line Treatment as both an economical and practical
method for nutrient removal.
Because Kesterson Reservoir is an integral part of the proposed
drainage system and contains the required area needed for treatment
by algae stripping, it seems logical to use it as a dual-purpose
treatment and storage reservoir.
178
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Kesterson Reservoir, if modified as suggested, has the potential
to provide nitrogen removals in excess of 90 percent.
The Drain, itself, has the capability for partial treatment. Al-
though it may be impractical to physically modify the dimensions
of the Drain for enhancing algal growth, it is possible to use the
Drain for this purpose by creating turbulence, adding nutrients,
and by seeding.
Work at Firebaugh has demonstrated that it is technically feasible
to remove nitrogen by growing and harvesting algae. However, at
this time, there are many unanswered questions about the process.
Some of the more important problems to be solved include:
a. What are the optimum nutrient conditions required for
maximizing nitrogen removal?
b. What is the optimum detention time?
c. What is the maximum depth under which the process will
work? For design purposes in this report, a depth of 1 foot has
been used, This depth has been found to be adequate for maximum
nitrogen removal at Firebaugh. However, there are some indications
that greater depths will be as efficient. If this holds true, then
this proposal for In-Line Treatment will be conservative in its
estimates of land required.
d. What degree and duration of mixing is required?
The combining of the algae stripping process with the anaerobic
filters in a series operation at Kesterson Reservoir would insure
an efficient system under the most extreme circumstances and would
provide the maximum operational flexibility.
It appears from this brief preliminary analysis of the situation that
the use of In-Line Treatment can reduce treatment costs considerably.
Recommendations
Based on the analysis contained herein, it is strongly recommended that
a more comprehensive analysis of the use of In-Line Treatment be made
in the near future. This analysis should include actual design of an
In-Line Treatment unit with estimates of construction costs of In-Line
Treatment, estimated operational costs, and, inasmuch as algal treat-
ment is dependent on defraying the overall cost through economic
recovery of the value of algae, further detailed investigation for
finding an economic market for the algae byproduct.
179
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APPENDIX
A. Detention Time in San Luis Drain
Characteristics of Drain
Length
Segment (miles)
Kettleman City 12
to Highway 198
Highway 198 15
to Jameson Ave.
Jameson Avenue 7
to Lassen Ave.
Lassen Avenue 17
to Tranquillity
Tranquillity 62**
to Kesterson
Russell to 10
Ness Avenue
Kesterson to 75
Antioeh
Plow Bottom
Capacity Width Depth
(cfs) (ft) (ft)
100 6.0 5-5
150 7.0 6.4
200 7.0 7.3
300 8.0 8.0
300 8.0 8.0
300 8.0 5.8
450 10 9.7
Cross*
Sectional Volume1
Area
(ft2) ft3xlO
78.4 4.97
106.1 8.42'
131.2 4.87
160.0 14.4
160.0 43.9
96.9 5.06
237*** 93.2
Deten-
tion
Time
( days )
0.577
0.650
0.281
0.556
1.695
0.195
2.410
TOTAL DETENTION TIME = 6.364
* All side slopes 1.5:1
** Russell to Ness Avenue is included in the Tranquillity to Kesterson segment,
*** Not available if treatment is carried out at Kesterson.
B. Maximum Algal Growth Possible in Drain Under Natural Conditions
The San Luis Drain has a surface area of 770 acres and a mean deten-
tion time of 6.3 days. If 1 mg/1 of algae were initially presented
in the Drain, and assuming an average of four cell doublings during
transit to the Delta, then 16 mg/1 of algae would be present at
discharge. However, consideration must be made of the fact that if
even 2 mg/1 of algae were present initially and the same number of
doublings occurred, then the Drain would contain 32 mg/1 of algae.
One more doubling would bring the level of algae to 64 mg/1.
180
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Therefore, it is almost impossible to predict the amount of algae
which the Drain will contain both initially and at discharge into
the Delta. It should be recognized, however, that the Drain does
have the potential for supporting a relatively high concentration
of algae and that consideration of this fact should enter the
design of any nutrient removal process.
C. Amount of Nitrogen Removed From Drainage Water By Naturally
Occurring Algae
Assumptions
a. Algae concentration at discharge = 16 to 65 mg/1. (Estimate)
b. Nitrogen content of algal cells = 8-10 percent (use 8 percent)
c. Total nitrogen concentration in drainage water = 20-25 mg/1
(use 25 mg/1).
d. Therefore,
amount of nitrogen removed from drainage water and converted
into algal cell material is:
16 mg/1 x 0.08 = 1.28 mg/1 (minimum estimate)
64 mg/1 x 0.08 = 5.12 mg/1 (maximum estimate)
or approximately:
JL-28 x 10° = 5 percent (minimum estimate)
5.12 x 100 _ on , . ,
c - 20 percent (maximum estimate)
of the incoming nitrogen will be removed.
D. Amount of Algae Theoretically Possible in Outflow From Kesterson
Reservoir
Assumptions
a. Maximum flow in San Luis Drain = 290 MGD
b. Surface area of Kesterson Reservoir = 3,000 acres
c. Depth of reservoir = 3 feet (normal operating depth).
181
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Detention Time = 3,000 x 43.560 x 3 x 7.48 = 10 Days
290 x 10&
Assume that in April and September conditions are critical
Average solar energy during these months = 8 x 10° K
cal/acre/day.
Total energy/reservoir/day = 3,000 x 8 x 106 =
24 x 109 K cal.
Assume that photosynthetic efficiency in converting solar energy
to algal biomass = 3 percent
Algae contain 6 K cal/gram (average value)
Therefore, amount of algae produced per day in pond equals
24 x 109 x 3 x 10-2 = ?
Average algal concentration in outflow from Kesterson
Reservoir =
_ 12 x 1010 ms £. 100 n
290 x 106 x 3.79
Based upon calculations in part F of the Appendix, the Drain at
Antioch has the capability for supporting approximately 100 mg/1 of
algae based upon light limitations only. Therefore, it is possible
that 100 mg/1 of algae leaving Kesterson Reservoir will still be
present at Antioch, the point of discharge to the Delta.
E. Nitrogen Conversion To Algal Cells in Kesterson Reservoir When
Used as a Treatment Unit
a. Nitrogen removal in First-Stage Storage Reservoir
Area = 1,300 acres
Depth = 3 feet
Flow Rate = 290 MGD
Detention Time = 1.300 x 43.560 x 3 x 7.48 _ 4>3 d
290 x 106
Same assumptions for solar energy conversion into algal bio-
mass as in Part D.
182
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Therefore, amount of algae produced per day in pond equals:
(1.3 x 103) (8 x 106) (3 x 10"2) = 5.2 x 107 grams
6
Average algal concentration in outflow from First-Stage
Reservoir equals
5.2 x 1010 mg = 47 mg/1
290 x 10° x 3.79
b. Nitrogen Conversion to Algal Cells in Combined Treatment Plant-
Storage Reservoir
Area = 4,000 acres
Depth = 1 foot
Flow Rate = 290 MGD
Detention Time = 4,000 x 43,560 x 1 x 7.48 _ ^5 D g
290 x 106
Total energy/reservoir/day = 4,000 x 8 x 106 = 32 x 109 K Cal
Assume that photosynthetic efficiency in converting solar
energy to algal biomass = 5 percent (5 percent could be obtained
due to excellent hydraulic design of reservoir and greater depth).
Amount of algae produced per day in pond equals
32 x 109 x 5 x 10"2 = 26.7 x 107 grams
6
Average algal concentration in outflow from Treatment Plant =
26.7 x 1010 mg = 243 mg/1
290 x 106 x 3.79
Total algae produced in Kesterson Reservoir = 243 + 47 =
290 mg/1
Assume: Nitrogen content of algal cells = 8 percent.
Influent nitrogen content = 25 mg/1.
Thus,
Total Nitrogen in Algal Cells = 290 x .08 10Q =
25
93 percent
183
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F. Algal Growth Required For 90 Percent Nitrogen Removal
Algal cell material has an energy content of 6 K cal/gram or
6 x 454 = 2,724 K cal/lb. (dry weight) See attached Character-
istics of the San Luis Drain (page 180).
Sunlight Energy Input:
To compute solar energy flux (S) input to surface of Drain
(Assume critical conditions in April and September); there-
fore,
Daily Energy Input (S) = 2 x 102 cal/cm2/day
and, energy to 1 acre = 2 x 102 x 4,025 x 107 x 10"3
K cal/cal = 8 x 106 K cal/acre/day
Necessary Energy Output - Entire Drain
450 sec. ft. = 290 million gallons per day
Nitrogen content of drainage water = 25 mg/liter (maximum)
Assume 90 percent removal; therefore, there will be 22.5 mg/
liter in algal cells.
Algal biomass to be produced at 50 percent protein =
50/6.25 = 8 percent N, therefore, biomass to be produced
= 22.5/.08 = 280 mg/liter.
Therefore, final algal concentration should be 280 mg/liter,
and the corresponding required biomass production per day is
280 x 8.34 x 290 = 675,000 Ibs. per day.
G. What Can Be Done To Grow Algae in The Drain
In order to use the Drain most strategically as a growth unit, it
will be necessary to seed the Drain with a concentration of algae
sufficient to give complete light absorption initially and to permit
as many doublings as possible to occur during transit. With good
mixing, doubling will start at once and may continue up to a concen-
tration permitting 1/3 d light transmission.
In this case the Drain would be initially seeded with a concentration
proportional to the mean depth at Kettleman which is 3.77 ft.
184
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d = 3.77 x 30.48 = 115 cm
Using the Beer-Lambert equation for concentration as a function of
depth, the concentration of algae at Kettleman should be:
c -
C - 115 x 15 x 10-3 - 52
and at the end of the 6.3-day transit the concentration would be
d = 6.15 x 30.48 = 188 cm (Depth at Antioch)
Cc = 188 x 1.5 x 10-3 x 3 = 100 mg/liter
Antioch concentration will be light limited at 100 mg/liter and
to attain any further increment shallow ponding would be required.
The increment of 48 mg/liter between Kettleman and Antioch would
constitute fixation of 48 x 290 x 8.34 x 2,724 =
310 x 10 K cal of solar energy in the form of algae or
310 x 106 = 40.4 x 104 K cal/acre/day
7.67 x 102
The mean conversion efficiency would be
40.4 x 104
8 x 106
x 100 = 5.06 percent. 5.06 percent conversion
efficiency is higher than the anticipated efficiency of 3.5 per-
cent in the originally planned 5,800 acres of 12-inch-deep ponds.
However, a 5.06 percent conversion efficiency may be possible
because of the greater depth and light absorption and the excel-
lent mixing provided in the Drain if it has a velocity of 2 feet
per second. The 767-acre Drain, itself, thus would be equivalent
to roughly 1,000 acres of regular growth ponds at Antioch.
H. How Could the Drain Be Best Used to Accomplish the Above?
The strategy would be as follows:
Grow algae at Kettleman City and seed the Drain with about
52 mg per liter dry weight basis.
Required acreage at Kettleman City about 1,000
Acreage equivalent of Drain 1,QQQ
Total land in seeding and conveyance 2,000
Balance of land required at north end
5,800 - 2,000 = 3,800 acres
185
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As one may see, a substantial savings in total land as well as a
savings in expensive "north end" land could result from this scheme.
Inasmuch as land in the vicinity of Kesterson is probably much less
expensive than land in the vicinity of Antioch, and because there is
to be a pond there anyway, it might be worthwhile to consider opera-
ting a major growth and harvesting facility at Kesterson. This could
possibly reduce the land requirement in the vicinity of Antioch to
about 1,500 acres, or less.
186
A U S GOVERNMENT PRINTING OFFICE 1970 O4O4-220
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