Pilot-scale Study of River Sewage Treatment by Aerobic-anaerobic
Reactor
Zhu Haiyan
Department of Chemical Engineering, Inner Mongolia Vocational College of Chemical Engineering,
Huhhot, Inner Mongolia, 010010
Keywords: River Sewage, Kaldnes Carriers, Fixed-bed Bioreactor, Sludge Reduction.
Abstract: The work conducted a pilot-scale study of sewage treatment of a certain river in the Yuquan District of
Huhhot by aerobic-anaerobic fixed-bed bioreactor constructed by Kaldnes carriers. After the reactor started
off to work, the biological film on the stuffing increased the thickness to about 1 mm a week later. It is
shown from the results after a continuous operation of 30 d that the ammonia nitrogen will become 5-10
mg/L when the water ingress COD is 60-150 mg/L and will get lower than 2 mg/L when the effluent COD
is under 40 mg/L. If the concentration of effluent suspended solid without precipitation is below 10 mg/L
and the chroma is inferior to 1,00 after the device is of stable operation, it can be indicated that the reactor is
effective for the removal of organic matter, ammonia nitrogen and chroma. The pilot-scale experiment in
the work verifies the feasibility and advantages of river sewage treatment in use of this reactor, which
proposes the new concepts and methods for the river sewage treatment.
1 INTRODUCTION
At present, the seven largest rivers of China are all
facing pollution of different degrees. Especially in
the 138 urban rivers, the vast majority that flow
through the prosperous areas are polluted in varying
levels, among which 38% are under the national
surface water quality standard V grade. Thus, it
clearly reflects based on the facts above that China is
now suffering severe water pollution and obvious
deterioration trend. Currently, there are mainly three
kinds of river sewage control technologies already in
use or tested both at home and abroad: physical,
chemical and biological methods. But the chemical
methods are not applicable here due to the large
amount of waste water and relatively low pollutant
concentration. With regard to river purifying
technology, so far in China, only physical methods,
such as water dilution and desilting, have been put
into realistic application. However, physical
methods are always palliatives that treat the
symptom but not the underlying problems.
Biological methods are the mostly studied by the
reasons that the organic matter, nitrogen and
phosphorus can be effectively dislodged from the
waste water by this method. Thereinto, most of the
research aims at the biofilm technology, but the
disadvantage is that the excess sludge produced in
the process of waste water treatment is easy to cause
secondary pollution. In particular, the excess sludge
will increase the sediment quantity. Prolonged
pollutants degradation is bound to exert a potential
adverse effect on the function of rivers. In order to
remove pollutant and reduce sludge, it is effective to
add stuffing into the aeration tank, or enhance the
biomass and the residence time of microorganism.
One of the most common biofilm technologies is the
Moving Bed Biofilm Reactor (MBBR). Kaldnes
stuffing is added to the aeration tank and anaerobic
tank so as to enhance the biomass and reduce the
sludge. On account that the carrier, having a cutting
effect on bubble, is added to the reactor, the aeration
rate will be inferior to that by the conventional
biological methods. For this reason, it can finally
increase the unit concentration of microorganism
and decrease the construction and operation costs.
MBBR has been widely adopted in the upgrading
and rebuilding of sewage treatment plants in Europe.
While in China, the method is only experimented in
the Lucun Wastewater Treatment Plant in Wuxi and
has achieved satisfactory results.
With the accretion of population, the Heihe
River in the Yuquan district of Huhhot suffers
severe contamination. Most parts of the river are
classified under V grade or worse than V grade 1,
with the pollution characteristics as synthetic
organic pollution. Ammonia nitrogen and total
phosphorus are the main pollutants, and the
214
214
Haiyan Z.
Pilot-scale Study of River Sewage Treatment by Aerobic-anaerobic Reactor.
DOI: 10.5220/0006022502140217
In Proceedings of the Information Science and Management Engineering III (ISME 2015), pages 214-217
ISBN: 978-989-758-163-2
Copyright
c
2015 by SCITEPRESS – Science and Technology Publications, Lda. All rights reserved
domestic runoff is the primary pollution source,
followed by industrial waste, poultry and stock farm,
farmland and surface runoffs. The research utilized
aerobic-anaerobic biointerval moving bed reactor
(hereafter referred to as reactor) to dispose the
sewage. In this way, it is conducive to maintaining
microorganism inside the reactor in high
concentration and enhance the unit processing load.
There is no need of nitrification liquid reflux to cut
down energy consumption. Moreover, the diverse
aerobic and anaerobic environment inside the reactor
can reduce the productivity of excess sludge in the
process of sewage treatment. Thus, the goal can be
achieved that the excess sludge is decreased or even
eliminated at the same time of treating the waste
water. This reactor adopts the Kaldnes carrier that is
extensively used in the market. The Kaldnes carrier
is known for the characteristics of large specific
surface area, big quantity of biofilm formation and
fast biofilm forming speed.
In order to further explore the effects and
feasibility of the reactor on removing the organism
and nitrogen in the water courses of Huhhot, the
pilot-scale test was carried on to study the process of
river sewage treatment. This, as a result,
accumulated abundant engineering data for the
popularization and application of this technology.
2 TEST MATERIAL AND
METHOD
2.1 The Water Samples Were Collected
in the River near Yuquan District
in Huhhot.
The quality of waste water was tested with pH
between 7.0 and 8.2, ammonia nitrogen between 5
and 10 mg/L, TP between 0.2 and 1 mg/L, COD
between 60 and 150 mg/L and chroma between 200
and 500. The water temperature during this period
was between 18 and 24.
2.2 Testing Apparatus and Process
Flows
The pilot plant and process flows in the sewage
treatment are shown as follows. The pilot plant has a
height of 1.2 m (effective height of 1m), width of
0.33 m and length of 3 m. Interrupted by the
clapboard, the plant can be divided into nine zones.
The volume of the whole reactor is 1 m3. Inside the
reactor, there is 65% of Kaldnes stuffing, with a
diameter of 2 cm, thickness of 1 cm and specific
surface area of 450 m2/m3, placed in the reactor.
The void fraction of the reactor is 95%. Through
placing perforated aerator pipe at different positions
inside the reactor, the aerobic zone and anaerobic
zone are alternatively formed. The gas water ratio is
kept within 15:1 and the residence time of waste
water in the reactor is 10 h. By this method, the
sewage is pumped into the reactor from the river
with no need for primary settling tank or regulating
reservoir. Besides, the waste water can directly be
drained after reactor processing with no use for
secondary settling tank and can flow in the way of
baffling in the reactor. The amount of daily water
treatment reaches 2.4 tons.
2.3 Test Methods and Plant Operating
Conditions
Before the test, the activated sludge by filter
pressing should be collected from the nearby sewage
treatment plant and inoculated to the reactor in the
front. The inoculum concentration should be
controlled within the range between 10% and 15%
of the reactor volume. At the back of the reactor,
two aerobic zones should inoculate microorganisms
domesticated in the lab to remove the nitrogen-
containing compounds. Such microbial populations
contain quite a few nitrifying and denitrifying
bacteria, by which they can effectively remove the
nitrogen-containing compounds. Then the inoculated
reactor begins to input water continuously. After a
week, the microorganisms inside gradually adapt to
the characteristics of river sewage. The biofilm on
the carrier has a thickness of 1 mm and is khaki in
color. Owing to the aeration that makes the Kaldnes
stuffing keep tumbling, the internal biofilm of
Kaldnes stuffing at the aerobic zone gains a higher
thickness than the external surfaces. While in that
the Kaldnes stuffing at the anaerobic zone stays
static, the sludge stacks between the inner side and
outer side interspaces and is black in color. When
the reactor can outlet water stably, it is time for data
detection. Samples should be collected in both the
entrance and exit of reactor. During this period, the
test mainly explored the effects of reactor under a
certain residence time on the removal of organism,
ammonia nitrogen, SS, turbidity and phosphorus as
well as the variations of dissolved oxygen (DO)
inside. Based on a series of laboratory research on
the residence time for river sewage of different
concentrations, the pilot-scale test controls the time
within 10 h.
2.4 Analysis Methods
The test adopted the analysis methods including
potassium dichromate method for COD
Pilot-scale Study of River Sewage Treatment by Aerobic-anaerobic Reactor
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measurement, Nessler's reagent colorimetric method
for chroma measurement, ammonium molybdate
spectrophotometric method for determination of
ammonia nitrogen content and laws of weight for
determination of suspended sludge (SS) and the
concentration variations of microorganisms on the
stuffing. Portable dissolved oxygen instrument
(Hash DO6+) was used to test the concentration of
dissolved oxygen (DO) at different positions of the
reactor.
3 RESULTS AND DISCUSSION
3.1 Removal Efficiency of Reactor on
the Organism
After a week or so, the reactor can perform stably
after some debugging. With a continuous operation
for 30 days, the reactor is able to effectively remove
the organism from the waste water. Even if the
concentration of organic pollutants fluctuates wildly,
the exit COD of reactor can still keep stable, all
under 40 mg/L. This reflects that the reactor can
steadily wipe out the organic pollutants from the
river sewage. The main reason lies in the biofilm
suspended on the Kaldnes carrier that enhances the
monolithic microorganism concentration. By
weighing the microorganism on the stuffing after
elution, the concentration can reach 6 to 8 g/L,
which is conspicuously higher than that with the
conventional activated sludge method.
3.2 Removal Efficiency of Reactor on
the Ammonia Nitrogen
It is shown that the concentration of ammonia
nitrogen is approximately 8 to 10 mg/L from the
variation of ammonia and nitrogen in the entrance
and exit of the reactor. This indicates that the river is
suffering very serious pollution and eutrophication.
After treating the waste water through the reactor,
the concentration of ammonia nitrogen in the exit
becomes lower than 2 mg/L and the plant keeps a
stable performance in removing the ammonia
nitrogen. The reactor constructed in this research
contains a repeated alternation from being aerobic to
being microaerobic, then to being anaerobic. On this
account, the nitrate and nitrite produced at the
aerobic zone can be used for denitrification at the
next anaerobic zone. In this case, there is no need of
nitrification liquid reflux to accomplish
denitrification, which is quite helpful to save energy.
Compared with the A20 technology frequently used
in the urban sewage treatment plants at present, this
reactor makes it easier to operate and saves the
transportation expenses since nitrification liquid
reflux is no longer required.
3.3 Variation of Phosphorus in the
Reactor
The removal efficiency on phosphorus is not
apparent because the excess sludge production is not
sufficient in the operation process. But the
concentration of phosphorus is rather low in the
river, basically around 0.8 mg/L. After being treated
by the reactor, the phosphorus concentration in the
exit can reach 0.5 mg/L or so. With regard to other
water courses, if the phosphorus content is pretty
high in the river, then there is a need to add medical
flocculation precipitation at the exit of the reactor to
wipe out the phosphate so as to reach the discharge
standard.
3.4 Removal Efficiency of Reactor on
SS
It can be seen from the SS variations at the entrance
and exit of the reactor that the SS of water inflow is
about 30 to 60 mg/L while the SS of the exit is lower
than 10 mg/L with mean of 5 mg/L. This reveals that
the reactor has a very good effect on sludge
reduction. The main reason lies that the porous
Kaldnes stuffing placed in the reactor can effectively
intercept the SS at the anaerobic zone. Then the
intercepted SS can resolve at the anaerobic zone and
the organism released can be used as the carbon
source of denitrification. Studies have shown that
the aerobic, microaerobic and anaerobic alternative
environment in the reactor is prone to separate the
anabolism from catabolism of microorganisms and
drop down the productivity of sludge. Therefore, it
is believed that the environment which is
collectively aerobic, microaerobic and anaerobic can
reduce the SS in its favor, especially conducive to
the sewage treatment in the heavily polluted rivers.
In addition, after analyzing the concentration of
dissolved oxygen (DO) at different positions by
means of DO instrument, it can also be discovered
that the DO concentration at the aerobic zone is 3 to
4 mg/L and goes up as the travel distance increases
while the DO concentration at the anaerobic zone is
only 0-0.5 mg/L. This result can explain that the
alternation phenomenon of being aerobic and
anaerobic happens at the direction of reactor
horizontal flow.
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3.5 Removal Effect of Reactor on
Chroma
The original chroma of the river is dark and
seriously polluted. Seen from the appearance, the
water is almost black with peculiar smell. The
chroma of sewage tested is between 200 and 500.
And after being treated through the reactor, the
muddy water gets transparent with the chroma
reduced to 50 to 100. This manifests that the reactor
is able to steadily and efficiently clear the pollutant
and chroma in the sewage.
4 CONCLUSIONS
(1) It can be concluded that the aerobic-anaerobic
repeatedly alternative moving bed biofilm reactor
(abbreviated as the reactor) is able to treat the river
sewage effectively according to the results gained
from the continuous sewage treatment after the
stable operation of the reactor in 30 days. When
water inflow is between 60 and 150 mg/L and the
hydraulic retention time is 10 h, the exit COD can be
maintained at about 40 mg/L.
(2) This technology has a certain resistance to
COD impact and a strong adaptability to the
concentration variations of organism in the waste
water. Thus, there is no need of regulating reservoir
and secondary settling tank. The exit SS is inferior
to 10 mg/L.
(3) The resistance to COD impact is displayed in
this technology. The Kaldnes stuffing inside the
reactor enhances the concentration of
microorganisms to the twice of biomass with the
normal activated sludge method. Moreover, the
plug-flow reactor is conducive to blending the
sewage and microorganism so that the reactor shows
a stronger adaptability.
This reactor can form an aerobic and anaerobic
environment in the flow direction. This environment
can effectively remove the ammonia nitrogen in the
waste water. When the concentration of ammonia
nitrogen at the entrance reaches 8 to 10 mg/L, the
concentration of ammonia nitrogen at the exit will
drop down to less than 2 mg/L. After the reactor
performs steadily, the SS of the water outlet keeps
below 10 mg/L with a mean concentration of 5
mg/L. This reflects that the coefficient of sludge
production in the reactor is pretty low, so no
secondary settling tank is needed for sewage
treatment. Such is also regarded as one of the
remarkable advantages of this technology.
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