 |
Claims  |
|
|
What is claimed is:
1. A process for waste water purification in a system utilizing an
activated sludge process to reduce sludge bluking, said process having an
aeration tank, having a volume, from which treated waste water is
continuously discharged, said process comprising the steps of:
identifying an oxygen related constituent of interest in the waste water in
the aeration tank, which constituent has a concentration which is known to
change in a characteristic manner during a cycle of the intermittently fed
activated sludge process;
said oxygen related constituent being dissolved oxygen in the waste water
in the aeration tank;
establishing a control value of said concentration of said dissolved oxygen
in the waste water being treated in the aeration tank, said value being
indicative for a requested purification stage of the treated waste water;
measuring said concentration of said dissolved oxygen in the waste water in
the aeration tank;
comparing the measure concentration of said dissolved oxygen in the waste
water in the aeration tank against the established control value; and
intermittently introducing, in a cycle of from about one half hour to two
hours, batches of waste water, having a volume, to be treated into the
aeration tank only when said measured concentration of said dissolved
oxygen in the waste water in the aeration tank equals said established
control values wherein the intermittent introduction of batches of waste
water to be treated occurs for a period of each cycle, of about one half
hour to about two hours, of waste water purification as a function of the
measured concentration and said determinable period of each cycle for
introducing a batch of waste water is substantially shorter than its
corresponding cycle of from about one half hours to two hours;
the volume of the batches of waste water being introduced into the aeration
tank in each said cycle being in a range of from about 5% to about 30% of
the volume of the aeration tank, whereby sludge bulking is reduced.
2. The process for waste water purification according to claim 1 wherein
said measurement of said concentration of said constitunnt of interest is
utilized as an alarm release when severe deviation occurs between said
measurement and the experienced ordinary variation of said concentration
immediately after said introduction of untreated waste water into the
aeration tank.
3. The process for waste water purification according to claim 1 wherein
said control value identifies an upper value of dissolved oxygen
concentration, and wherein said untreated waste water is introduced into
the aeration tank in a batch-wise technique when said oxygen concentration
equals said control value.
4. The process for waste water purification according to claim 3 wherein
said control value, identified as an upper value of dissolved oxygen
concentration, is selected to be between about 5% to about 90% oxygen
saturation in the aeration tank.
5. The process for waste water purification according to claim 3 including
the steps of: establishing a curve reflective of dissolved oxygen
concentration relative to an introduced volume of untreated waste water in
the aeration tank; establishing the dissolved oxygen concentration value
of the treated water in the aeration tank; comparing the established
oxygen concentration value against the curve; and providing alarm means
responsive to a resultant value from the step of comparing the established
oxygen concentration values against the curve when said resultant value
exceeds a predetermined maximum value.
6. The process for waste water purification according to claim 1 wherein
the waste water introduced into the aeration tank has unfavorable
Carbon:Nitrogen:Phosphor source ratios.
7. The process for waste water purification according to claim 1 wherein
the waste water introduced into the aeration tank is obtained from the
food processing industry, breweries and/or effluents from biogas reactors.
8. The process for waste water purification according to claim 1 wherein
said determinable period comprises about 0.5 minutes to about 3 minutes.
9. A process for waste water purification in a system employing an
activated sludge process to reduce sludge bulking, said process having an
aeration tank, from which tank treated waste water is continuously
discharged, comprising the steps of:
feeding intermittently, in a cycle of from about one half hour to two
hours, batches of waste water to be treated into the aeration tank which
has a given volume;
each of said batches being fed for an interval of less than about five
minutes; and
monitoring a measurable parameter of dissolved oxygen in the aeration tank
indicative for the bacterial activity in the aeration tank, such that when
said parameter indicates a drop of said activity below a specified value,
a waste water inlet to the aeration tank is opened for the batch feeding
of the waste water to be treated into the aeration tank from which treated
waste water is continuously discharged;
the volume of the batches of waste water being introduced into the aeration
tank in each said cycle, of from about one half hour to two hours, being
in a range of from about 5% to about 30% of the volume of the aeration
tank, whereby sludge bulking is reduced.
10. The process for waste water purification according to claim 9 wherein
the bacterial activity is monitored by measuring the dissolved oxygen
concentration in the aeration tank, which dissolved oxygen concentration
is an indication of the bacterial activity therein.
11. The process for waste water purification according to claim 10 wherein
the waste water is fed into the aeration tank when the oxygen
concentration in the aeration tank equals a specified value of between
about 5% and about 90% of oxygen saturation.
12. The process for waste water purification according to claim 11
including the steps of: establishing a curve reflective of dissolved
oxygen concentration relative to an introduced volume of water to be
treated in the aeration tank; measuring the dissolved oxygen concentration
value of the water in the aeration tank; comparing the measured dissolved
oxygen concentration value against the curve; and providing alarm means
responsive to a resulting value from the step of comparing the measured
dissolved oxygen concentration value against the curve, when said
resulting value exceeds a predetermined maximum value.
13. The process for waste water purification according to claim 9 wherein
the waste water to be treated has an unfvvorable Carbon:Nitrogen:Phosphor
source ratio.
14. The process for waste water purification according to claim 9 wherein a
source of the waste water to be treated introduced into the aeration tank
comes from at least one of the members of the group consisting of a food
processing process, a brewery process, and a effluent from biogas
reactors.
15. The process for waste water purification according to claim 9 wherein
the continuously discharged treated waste water is conveyed downstream to
secondary sedimentation tanks.
16. A process for waste water purification in a system utilizing an
activated sludge process to reduce sludge bulking, said process having an
aeration tank from which treated waste water is continuously discharged,
said process comprising the steps of:
identifying an oxygen related constituent of interest comprising dissolved
oxygen in the waste water in the aeration tank, which constituent has a
concentration which is known to change in a characteristic manner during a
cycle of the intermittently fed activated sludge process;
establishing a control value of said concentration of said constituent of
interest in the waste water being treated in the aeration tank, said value
being indicative for a requested purification stage of the treated waste
water;
measuring said concentration of said constituent of interest;
comparing the measured concentration of said constituent of interest
against the established control value; and
intermittently introducing batches of waste water to be treated, for
between about one half minute to about two minutes, in a cycle of from
about one half hour to two hours, into the aeration tank only when said
measured concentration of said constituent of interest equals said
established control values wherein the intermittent introduction of
batches of waste water to be treated represent a feed volume per cycle of
up to approximately 30% of the aeration tank's volume, whereby sludge
bulking is reduced.
17. The process for waste water purification according to claim 16 wherein
the feed volume of the waste water to be treated per cycle is between
about 10 to 20% of the aeration tank's volume.
18. A process for waste water purification in a system utilizing an
activated sludge process to reduce sludge bulking, said process having an
aeration tank, having a volume from which treated waste water is
continuously discharged, said process comprising the steps of:
establishing a control value for dissolved oxygen in the waste water being
treated in the aeration tank, said value being indicative for a requested
purification stage of the treated waste water;
measuring dissolved oxygen in the aeration tank;
comparing the measured concentration of said dissolved oxygen against the
established control value; and
intermittently introducing at from about one half hour to two hours,
batches of waste water, having a volume, to be treated into the aeration
tank only when said measured value of dissolved oxygen equals said
established control values wherein the intermittent introduction of
batches of waste water to be treated occurs for a period, of about 0.5
minutes to about 3 minutes of each cycle, of about one half hour to about
two hours, of waste water purification as a function of the measured
concentration and said period of each cycle;
the volume of the batches of waste water being introduced into the aeration
tank in each said cycle being in a range of from about 5% to about 30% of
the volume of the aeration tank, whereby sludge bulking is reduced. |
|
 |
|
 |
Claims |
|
|
|
Description |
|
|
BACKGROUND OF THE INVENTION
1. Field of the Invention
The invention relates to a process for waste water purification employing
the activated sludge process with a ventilated activation tank from which
treated waste water is continuously discharged.
2. Description of the Prior Art
It is a customary and generally-recognized rule of the art that the
continuous, but usually not constant, flow rate of the waste water which
is introduced into the biological stage of a waste water treatment plant
is not manipulated. The result is a continuous charging of the aeration
tanks, and within limits which are set, for example, on top by the
separation duct and/or rainwater overflow, the flow rate of the waste
water into the aeration tanks is a direct function of the inflow rate. In
the case of domestic or urban waste water, this results in the known daily
cycle of flow rate and pollution load expressed as COD (=chemical oxygen
demand) or BOD.sub.5 (=biochemical oxygen demand after 5 days)
concentration.
These daily cycles (or weekly cycles) of waste water load are generally
reflected in fluctuations of treatment efficiency, that is, they lead to
fluctuations of the COD and BOD.sub.5 concentration in the effluent, which
is also clearly reflected in the permissible COD discharge values in
accordance with waste water discharge laws. Accordingly, for example, the
permissible COD maximum is twice the standard value (=operational
average).
This shows that, so far, it has clearly not been possible to achieve
constant purification performance within relatively narrow limits.
Therefore, it seems desirable to develop a process which achieves a
uniform discharge and guarantees a more effective protection of the water
resources.
An additional problem in waste water treatment technology employing the
activated sludge process is the uncontrolled formation of bulking sludge
which is difficult to eliminate, especially with unfavorable C:N:P ratios
(ratio of Carbon:Nitrogen:Phosphor source).
Even in the very earliest publications concerning the activated sludge
process, it is considered advantageous to introduce the waste water
alternately into two or more aeration tanks, so that there is a batch-wise
operation for each individual tank (J. Soc. Chem. Ind. 33 (1914) 112).
This method of operation has recently been propagated once again as the
sequential batch reactor process (J. Water Pollution Control Fed. 51
(1980) 2747). A variant of the process is the continuously-fed activation
tank with intermittent aeration and emptying (Publ. Health Eng. 8 (1980)
20; J. Water Pollution Control Fed. 56 (1984) 1160). Particular advantages
of the last-named process are good eIimination rates when the waste water
concentration and quantities fluctuate widely, and high dentrification
rates.
According to another aerobic waste water purification method, such as in
Austrian Pat. No. 32 18 33, the waste water is treated in batches under
increased air pressure in activated sludge tanks with a sudden pressure
release after the completion of the biological treatment, by means of
which a certain sludge densification is achieved.
In laboratory tests with mixed pure bacterial cultures, Van den Eynde, et
al. (European J. Appl. Microbiol. Biotechnol. 15 (1982) 246) achieved an
elimination of the filamentous bulking sludge bacteria by the desired
flocculants by means of intermittent substrate supply. However, the
transition from laboratory findings with pure cultures to industrial waste
water purification is not without its difficulties.
OBJECT OF THE INVENTION
It is therefore an object of the invention to develop a process by means of
which, even with waste waters with unfavorable C:N:P ratios, the tendency
to the formation of bulking sludge is suppressed, an a uniform treatment
efficiency is achieved within narrowly defined limits independent of daily
and weekly fluctuations of the waste matter content of the water.
SUMMARY OF THE INVENTION
The process developed by the present invention is characterized by the fact
that the waste water is fed into the aeration tank in batches by opening
the waste water inlet to the tank is opened briefly for the batch-wise
feed of waste water when the bacterial activity in the tank drops below a
specified level. More specifically, the invention provides a process for
waste water purification in a system utilizing an activated sludge process
with an aeration tank from which treated waste water is continuously
discharged while the batch-wise feed is controlled by a measurable
concentration value of a particular constituent of interest in the waste
water in the aeration tank indicating a special decrease in the bacterial
activity. This constituent of interest has a concentration which is known
to change in a characteristic manner during a cycle of the intermittently
fed activated sludge process being reflective of the bacterial activity
within the aeration tank. A (first) value establishing an accepted
parameter for the concentration of the constituent of interest in the
continuously discharged treated water is established being characteristic
for a special level of decreased bacterial activity set as a limit for the
treatment cycle. The concentration of the constituent of interest within
the waste water contained in the aeration tank is measured, and that
measured concentration is compared against the established parameter.
Finally, waste water is introduced into the aeration tank when the
measured concentration of the constituent of interest equals the accepted
(first) control value.
In some tests, namely with the conventional, continuous treatment of waste
water in aeration tanks with an unfavorable C:N:P ratio, it was observed
that the bulking sludge formation which occurs can be completely
eliminated by a batch-wise dosing of the waste water feed. This was not
possible with continuous feed of the same waste water to the aeration
tanks, and increase in the C:N:P ratios in the bulking sludge forming
waste water as generally recommended.
The batch-wise dosing is conducted so that the incoming waste water flow is
interrupted for a certain period of time by an apparatus which functions
as a valve. At the end of the treatment cycle or dosing cycle adjusted to
the admitted limit of bacterial activity decrease, the valve, which can
also be designed as an adjustable gate, is opened for a brief period of
time and a batch of fresh waste water is admitted to the aeration tank.
The next dosing cycle begins with the renewed interruption of the waste
water inflow. Typical period lengths of the dosing cycle, for example, are
30 to 60 minutes. The average hydraulic load and the sludge reflux ratio
with batch-wise dosing are the same as with the ordinary continuous
charging of the aeration tank.
The periodicity of this recommended intermittent feed of waste water to the
activated sludge tanks, especially with waste waters which tend to a
severe formation of bulking sludge, can initially be set as desired, but
it must, in each case, be adjusted to the current purification conditions.
It has also been determined that the process can be optimized by means of
an automatic regulatory system, which specifically measures the oxygen
concentration in the aeration tank as an indicator for the bacterial
activity to control the inlet.
BRIEF DESCRIPTION OF THE DRAWINGS
The above, as well as other features and advantages of the present
invention, can be more clearly appreciated through consideration of the
detailed description of the invention in conjunction with the several
drawings, in which:
FIG. 1 is a schematical sectional elevational view of a grit chamber
demonstrating the adjustable weir in closed position;
FIG. 2 is a schematical sectional elevational view of a grit chamber
demonstrating the adjustable weir in opened position;
FIG. 3 is a graph illustrating an oxygen curve from an aeration tank during
one cycle of intermittent waste water supply;
FIG. 4 is a control flow diagram for a batch-wise dosing process according
to the teachings of the present invention;
FIG. 5 illustrates a sludge volume index of aeration tanks with continuous
feed of waste water which produces bulking sludge;
FIG. 6 shows a sludge volume index of aeration tanks with batch-wise or
continuous supply of waste water which produces bulking sludge; and
FIG. 7 shows a schematic diagram of an activated sludge plant regulated by
the teachings of the present invention.
DESCRIPTION OF THE PREFERRED EMBODIMENT
Both the process and apparatus of this invention can be generally
appreciated through an initial consideration of FIGS. 1, 2 and 7. In FIG.
1, there is shown a grit chamber, or device in which waste water to be
treated in an aeration tank is initially held. The chamber 11 includes a
waste water inlet means 1 and an adjustable weir or valve means 2, by
which waste water from the chamber 11 can be discharged therefrom for
treatment in an aeration tank. As schematically represented in FIG. 7, an
aeration tank 13 is fed through a batch-wise process with waste water from
the grit chamber or pre-sedimentation tank 11 via an element 2 which
provides a valve-like function. As will be explained hereinafter, this
valve-like function can be effected through a weir means which is
hydraulically, pneumatically or otherwise remotely actuated through the
control steps of this invention. The discharge of treated waste water from
the aeration tank 13 is effected through a throttle means 4 which controls
the discharge rate from the aeration tank 13 into a secondary
sedimentation tank 5, from which it is finally discharged via line 6. The
operation of the valve element 2 is governed by a regulatory control
mechanism through the sensor means 7. The output of this sensor means 7 is
conveyed to a control means 8, and the process of this invention can be
effected according to the flow diagram illustrated in FIG. 4.
The process is based on the time course of bacterial activity (respiration
rate) in an activated sludge tank subjected to a batch-wise feed of waste
water, specifically as it is reflected in the changes of the oxygen
concentration in the activated sludge tank throughout the dosing cycle,
for example, as illustrated in FIG. 3.
If, at the end of a treatment or dosing cycle (e.g., with 120 seconds of
feed per hour), fresh waste water (e.g., anaerobically treated sulfite,
evaporator condensate from the pulp and paper industry) flows into the
aeration tank, the concentration of the oxygen dissolved in it drops
within a few minutes to a very low value near the limits of detection, in
spite of continued and constant aeration. Depending on the concentration
and volume of waste water added, some time passes, for example, 20 to 40
minutes, after the oxygen minimum is reached, until the dissolved oxygen
again reaches values which would prevail with a continuous influx of waste
water.
These periodic fluctuations of the oxygen concentration are now used by the
invention to regulate the intermittent addition of waste water in a simple
manner. For this purpose, the oxygen concentration is measured
continuously, preferably in the lower region of the aeration tank, by
means of an appropriate oxygen probe which is connected to a measurement
transformer. Such oxygen detecting devices are commercially available and
can be obtained from, for example, SYLAND, of Heppenheim, Federal Republic
of Germany. These deviees are apt to supply signals for controlling valves
when predetermined values of oxygen concentration are reached.
Preferably, the measurement is compared by means of a microprocessor with
the (first) adjusted value W.sub.1 as specified above used to control the
ordinary pulsed inflow operation of the installation and additionally with
a second value W.sub.2 used to release an alarm in the case of
purification failure. At oxygen concentrations below the first command
value, for example 3-4 mg O.sub.2 /l, the inlet to the aeration tank
remains closed, and waste water is dammed up in the grit chamber or
intermediate holding tank. When the first oxygen command value is
exceeded, the inlet is opened for a preset time interval, preferably by
means of a timer, for example, for three minutes (as in FIG. 4).
At the same time, the microprocessor switches over to the second oxygen
command value, for example, 0.5 mg/l. If the measurements do not drop
below this second control value, for example, within five minutes after
the opening of the inlet, then there is either a malfunction of the
activated sludge or a dosing error, which trips an alarm signal. For
example, 15 minutes after the opening of the inlet, the timer switches
back to the first command value, and the regulation circuit is again in
the starting status. As shown in FIG. 4, stable discharge values can be
achieved independent of the waste content of the water and the
temperature. According to experience so far, the residual COD in the
discharge is somewhat lower (5-10%) than with continuous feeding of the
aeration tank. In addition, a greater aeration efficiency is achieved at
oxygen concentrations below the second cnntrol value. This results in a
certain reduction of the specific energy requirement for aeration.
A further (lower) command value can also be used to trip switching
processes, for example, to terminate the waste water influx into the
aeration tank.
In the case of more severe daily and/or weekly fluctuations of the
hydraulic load (Q), it is recommended that the hydraulic load of the
aeration tank be made more uniform by the installation of a make-up tank
or holding tank.
Analogous to the regulation of waste water dosing by means of the oxygen
concentration described above, any other hydrochemical or
physical-chemical parameters (pH, rH, pCO.sub.2, concentration of acetate,
methanol, etc.) which change to a sufficient extent and in a
characteristic manner during a dosing cycle can be used as a control
parameter.
The cycle time or indicator values and the feed quantity per cycle are
governed by the pollutant concentration in the waste water to be treated,
the specified volume load or sludge loading of the aeration tank, and the
desired effluent quality, and have to be adjusted according to the actual
requirements.
Generally, the fee volume per cycle is between 5% and 30%, specifically in
the vicinity of between 10% and 20% of the volume of the aeration tank.
But with low-load operation (at 0.2 kg COD/kg dry substance .multidot.d),
it can be less than 5%.
The appropriate cycle time is determined as a function of the biological
activity of the sludge and can be determined empirically. In general, it
is in the vicinity of 0.5 to 2 hours for treatment of moderately polluted
waste water requiring nitrification.
The threshold values for the waste water admission (W.sub.1) and the alarm
trip (W.sub.2) are also determined empirically. W.sub.1 is at low-load
operation, for example, and purification with nitrification in the
vicinity of the oxygen saturation value of the curve (see FIG. 3) for the
oxygen concentration in the aeration tank, i.e , in the range of 4-5 mg
O.sub.2 /l, while W.sub.1 at high-load operation and/or pre-sedimentation
operation can be set at approximately 2 mg O.sub.2 /l or even less than
that.
In relation to the oxygen saturation of the treated water, W.sub.1 can
specifically be between 5% and 90%, generally between 50% and 80%.
The alarm-trip threshold of W.sub.2 is also taken in reference to
continuous recordings of the oxygen concentration. It is above the
(highest) oxygen minimum of the curve (see FIG. 3). W.sub.2 is
specifically adapted to the slope of the oxygen curve typical for the
purification process after the termination of the waste water admission.
If the oxygen measurement has not dropped below a specified value within
the shortest possible length of time of a maximum 10 minutes (specifically
2 to 5 minutes), the alarm is tripped. This specified value is clearly
above the typical value for the selected alarm time, specifically 0.5 to 2
mg/l above it.
If the composition and quantity of the waste water being treated are
largely constant, the treatment or dosing cycle can be adjusted on the
basis of optimized historic values, either by an electrical timer or by
timed electrical relays. In this case, the dosing cycle has a constant
period length.
The simplest arrangement of the batch-wise admission of waste water to an
aeration tank is that, behind the grit chamber, there is an adjustable
gate, whose operation is governed electromechanically, as shown in FIGS. 1
and 2. This apparatus is suitable above all for plants with a waste water
inflow through inlet flow means 1 which is largely uniform.
In Phase I of the dosing cycle, the gate or valve means 2 is perpendicular
and blocks the waste water flow from the aerated or not aerated grit
chamber 11 into the aeration tank.
In Phase II, by means of an electrical pulse, the locking mechanism of the
adjustable gate 2 is opened. It swings down, and the dammed-up waste water
flows rapidly into the aeration tank.
In Phase III, the adjustable gate 2 is brought back to the vertical
position by means of a drive motor.
The length of time when the waste water may inflow through the inflow means
1 may be the time when the adjustable gate 2 is open, and additionally,
the time when the adjustable gate 2 is being brought back to a vertical
position to cut off flow to the aeration tank. As can be seen above, this
period of time would be the sum of the time of Phase II and the time of
Phase III. As indicated infra, Phase II may have a time of 3 minutes and
Phase III may have a time of 2 minutes. Therefore, if the time of Phase II
and the time of Phase 3 are added, these two phases together will equal 5
minutes, which time is the time during which waste water may flow into the
aeration tank.
The same purpose as an adjustable gate can be performed by an
electromechanically-operated slide valve, which periodically opens and
closes the discharge from the grit chamber via a channel or a tube, in
response to the control signals from one of the regulatory circuits
described by the invention. The sludge is removed via a line 3.
If, with a hydraulic retention time of the waste water of four hours and a
sludge reflux ratio of, for example, 500% per day, the length of the
dosing cycle is set at one hour, for example (Phase I: 55 minutes, Phase
II: 3 minutes Phase III: 2 minutes), then after the dosing, in the
aeration tank there is a fluid volume increase by 20%, or a
correspondingly increased fill level. But to obtain a discharge into the
secondary sedimentation tank which is as uniform as possbble, in spite of
such a fluctuation in the level, the contents of the tank do not flow over
an overflow edge into the collecting channel, but flow against a
resistance of sufficient magnitude, for example, through crown-shaped
relatively narrow pipes placed in the wall of the tank (for example, free
width of 3-4 cm) into the collection channel, and from there into the
final sedimentation tank.
In plants without a grit chamber, it is necessary to install a reservoir,
the volume of which is, for example, 10% to 20% of the volume of the
aeration tank. This continuously-fed, aerated or not aerated chamber is
generally emptied by means of a slide or valve mechanism 2, as illustrated
in FIG. 1. Only with constant waste water composition and flow rates can
an automatic drainage of the reservoir be carried out by an overflow
mechanism.
As illustrated in FIG. 7, the aeration tank 13 is fed intermittently with
waste water from the primary sedimentation tank 11 via an element 2 with a
valve function, while the discharge is continuous via a throttle 4 into a
secondary sedimentation tank 5 with a discharge 6. The operation of the
valve element 2 is governed by a regulatory mechanism through the probe or
sensor means 7. The output of the probe 7 is conveyed to a program control
means 8, and operates in the manner illustrated in the flow diagram of
FIG. 4.
Embodiment:
In the purification of anaerobically treated sulfite evaporator condensate
cellulose manufacture (COD approximately 10 kg m.sup.-3) from biogas
reactors (Aivasidis and Wandrey, Umschau Wissenschaftmagazine 84 (1984)
15), after dilution to 1:15, a COD purification degree of 90.+-.3% was
achieved. The aeration time was 24 hours, the oxygen concentration in the
aeration tank 4.0.+-.0.3 mg/l, the sludge reflux ratio approximately 750%
d.sup.-1 and the sludge load (B.sub.TS)0.3-0.4 kg COD per kg dry weight.of
activated sludge. The temperature was 22.degree..+-.2.degree. C. The
treatment was seriously hindered after a few days by the massive formation
of bulking sludge (SVI (sludge volume index) more than 1000 ml g.sup.-1).
By increasing the original C:N:P ratio (100:5:1), as recommended to combat
bulking sludge (Kapp, DFG Research Report KR 624/1, Institut fur
Siedlungswasserbau, Wassergute und Abfallwirtschaft, Universitat Stuttgart
(1980)), the sludge volume index can, of course, be reduced to as low as
400 ml g.sup.-1 (FIG. 5), but yet a satisfactoy sedimentation action
cannot be achieved.
The dosing cycles were set with a timer to 30 to 120 sec h.sup.-1, without
changing the total throughput from what is was during continuous
operation, which was maintained in a reference tank. As shown in FIG. 6,
the batch-wise dosing of the waste water not modified by the addition of
nutrients resulted in an acceptable sedimentation action. The efficiency
(90.+-.3%) in relation to COD elimination did not decrease. On the
contrary, on the basis of the average of the measurements conducted so
far, it increased by approximately 5%.
These results demonstrate the effectiveness of the batchwise addition of
waste water to combat the formation of bulking sludge and to improve the
efficiency of aerobic waste water treatment.
The preferred area of application for the batch-wise dosing of waste water
is in industrial waste water treatment plants in which operation is--as
known--disrupted by the formation of bulking sludge, such as in the
treatment of waste waters from the food processing industry.
What has been described is a unique process and apparatus whereby waste
water can be treated in a batch-wise process in an aeration tank from
which tank treated waste water is continuously discharged. The batch-wise
or dosed introduction of untreated waste water into the aeration tank is
controlled by a measurement of a constituent of interest in the waste
water held in the aeration tank.
The invention as described hereinabove in the context of a prefered
embodiment is not to be taken as limited to all of the provided details
thereof, since modifications and variations thereof may be made without
departing from the spirit and scope of the invention.
* * * * *
|
|
|
|
|
|
|
Description |
|
