CN111003891A - Bioreactor for treating garbage transfer station pressed leachate - Google Patents

Abstract

The invention discloses a bioreactor for treating leachate of a garbage transfer station, which belongs to the technical field of auxiliary equipment for garbage treatment and has the technical key points that: according to the treatment process of the leachate, the bioreactor body comprises a biological flocculation tank, an A-section sedimentation tank, an EMR reaction tank group and a B-section sedimentation tank which are sequentially communicated; a water inlet is arranged on the biological flocculation tank; the section A sedimentation tank is communicated with the biological flocculation tank; the EMR reaction tank group comprises a biological selection tank, an amplification reaction tank and a depth reaction tank which are sequentially communicated, wherein the biological selection tank is communicated with the section A sedimentation tank at one side far away from the amplification reaction tank, and a water outlet is formed in the section A sedimentation tank; the section B sedimentation tank is communicated with the deep reaction tank; meanwhile, a water outlet is arranged on the B section sedimentation tank; a plurality of aeration devices are arranged in the biological flocculation tank and the EMR reaction tank group. The invention can effectively reduce the COD content and the ammonia nitrogen content in water, reduce the occurrence of the phenomenon of the overflow of malodorous gas in the pipeline and improve the protection of the comprehensive environment of the garbage transfer station.

Description

Bioreactor for treating garbage transfer station pressed leachate

Technical Field

The invention belongs to the technical field of auxiliary equipment for garbage treatment, and particularly relates to a bioreactor for treating leachate of a garbage transfer station.

Background

At present, domestic medium and small sized garbage transfer stations and mobile dynamic-leaching garbage stations/boxes generate leachate (leachate, compressed liquid/leachate/sewage), ground washing water and container washing water which are usually and directly discharged into municipal pipe networks in cities and towns, Chemical Oxygen Demand (COD) in the leachate is usually more than 8000mg/L, the content of wastewater particulate matters (SS) in the leachate is usually more than 2000mg/L, and a large amount of floaters, vegetable roots and particulate matters cause municipal pipe networks to be blocked. The content of animal and vegetable oil in the wastewater is usually more than 1000 mg/L, and the animal and vegetable oil is adhered to the surface of the particulate matter, so that the adhesive force of the particulate matter is enhanced, and the blockage of a municipal pipe network is aggravated. Meanwhile, after the pipeline is blocked by the sewage, the garbage in the pipeline is rotten to generate toxic components, and foul gas is emitted outwards from the pipeline well along the pipeline. In addition, animal and vegetable oil and harmful gas such as methane are accumulated in the pipeline, so that the hidden danger of explosion or explosion caused by open fire can be caused.

The medium-pressure leaching liquid of the existing garbage transfer station has the following processing difficulties: the fibrous particles are piled up to block pipelines and high-content animal and vegetable oil, and simultaneously, the COD content and the ammonia nitrogen content in the leachate are too high. However, as for the current leaching solution pressing treatment method of the garbage transfer station, as shown in fig. 1, the leaching solution pressing treatment device of the garbage transfer station mainly comprises: the device comprises a collecting tank, an adjusting tank, an oil-water residue separator, an air floatation tank, a sedimentation tank, a sludge concentration tank for collecting sewage and a clean water tank for collecting clean water which are sequentially communicated.

However, the effect of reducing the COD content and the ammonia nitrogen content in water in the leaching solution pressing treatment mode of the waste transfer station is poor, so a new technical scheme needs to be provided to solve the above problems.

Disclosure of Invention

Aiming at the defects in the prior art, the invention aims to provide the bioreactor for treating the leachate of the garbage transfer station, which can effectively reduce the COD content and the ammonia nitrogen content in water, reduce the occurrence of the phenomenon of the overflow of malodorous gas in a pipeline and improve the protection of the comprehensive environment of the garbage transfer station.

In order to achieve the purpose, the invention provides the following technical scheme: the utility model provides a bioreactor for handling rubbish transfer station presses leachate, is including installing in rubbish transfer station and being arranged in reducing the bioreactor body of pressing COD in the leachate, according to the processing procedure of pressing the leachate, the bioreactor body is including biological flocculation basin, A section sedimentation tank, at least one EMR reaction tank group, the B section sedimentation tank that communicate according to order in proper order.

A large amount of activated sludge for flocculation adsorption is arranged in the biological flocculation tank, and a water inlet is formed in the upper end of the biological flocculation tank;

the A-section sedimentation tank is used for separating mud and water; the A section sedimentation tank with biological flocculation basin intercommunication is equipped with a plurality of baffles one between A section sedimentation tank and biological flocculation basin, is equipped with a plurality of confessions between two adjacent baffles one of keeping away from biological flocculation basin bottom the water in the biological flocculation basin flows into breach one in the A section sedimentation tank.

The EMR reaction pond group is including the biological selection pond, the amplification reaction pond and the degree of depth reaction pond that communicate each other in proper order, the biological selection pond keep away from the one side of amplification reaction pond with A section sedimentation tank intercommunication, A section sedimentation tank is equipped with the outlet that supplies upper liquid in the A section sedimentation tank to flow in the amplification reaction pond on the bottom of the pool one side of keeping away from A section sedimentation tank.

The B section sedimentation tank is used for separating mud and water and discharging clean water; the section B sedimentation tank is communicated with the deep reaction tank, a plurality of second baffles are arranged between the section B sedimentation tank and the deep reaction tank, and a plurality of second gaps for water in the deep reaction tank to flow into the section B sedimentation tank are arranged between two adjacent second baffles far away from the bottom of the deep reaction tank; meanwhile, the upper end of the B section sedimentation tank is provided with a water outlet.

And a plurality of aeration devices are arranged in the biological flocculation tank and the EMR reaction tank group.

Through adopting above-mentioned technical scheme, the pressure leachate in the rubbish transfer station is through the processing back of earlier stage (promptly through oil water residue separator, air supporting pond processing), and the fibrous particulate matter in the pressure leachate can obtain effectual the getting rid of, has reduced the problem of blockking up sewer pipe. Then the pretreated leachate enters a biological flocculation tank from a water inlet, the inflow water and the sludge are subjected to flocculation adsorption by activated sludge in the sewage (namely organic particulate matter colloid is captured by a large amount of flocculation-type bacteria in zoogloea) under the stirring action of an aeration device, and at the moment, soluble organic matters in the sewage are selectively adsorbed and utilized by biological cell membranes of the objects, so that the COD content of the sewage is greatly reduced. And the activated sludge with saturated adsorption automatically flows into the A-section sedimentation tank for solid-liquid separation. The upper liquid in the A-section sedimentation tank flows into the biological selection tank, and under the action of the activated sludge added by artificial assistance, the selective switch is used for aeration so as to select 'high-efficiency COD degradation bacteria' (namely EM bacteria) with short generation period and high metabolism speed. Then the 'high-efficiency COD-degrading bacteria' enter an amplification reaction tank along with sewage, and are subjected to amplification culture under the action of an aeration device. And then the bacteria capable of efficiently degrading COD enter the deep reaction tank along with sewage to further degrade residual organic matters in the sewage, and finally the sewage is discharged into a B-section sedimentation tank for mud-water separation, the upper-layer liquid in the B-section sedimentation tank can be discharged into a municipal pipe network through a water outlet, and the discharged upper-layer liquid reaches the discharge standard of the municipal pipe network. Therefore, the bioreactor can effectively reduce the COD content and the ammonia nitrogen content in water, reduce the occurrence of the phenomenon of the overflow of malodorous gas in a pipeline, and improve the protection of the comprehensive environment of the garbage transfer station.

The invention is further configured to: the B section sedimentation tank bottom is equipped with the blow off pipe that is used for the mud retrieval and utilization, be equipped with the dredge pump on the blow off pipe, the other end of blow off pipe stretches into in the biological flocculation pond, and one of blow off pipe near biological flocculation pond is served and is equipped with the blowdown valve.

Through adopting above-mentioned technical scheme, with the mud (activated sludge) of B section sedimentation tank bottom via the blow off pipe discharge carry out the mud retrieval and utilization in the biological flocculation basin to practiced thrift the resource, improved the comprehensive utilization to activated sludge.

The invention is further configured to: the sewage draining pipe is provided with a branch pipe, the other end of the branch pipe extends into the biological selection tank, and the branch pipe is provided with a branch valve.

Through adopting above-mentioned technical scheme, arrange into the biological selection pond with the mud (activated sludge) of B section sedimentation tank bottom via branch pipe part in, replace artifical increase activated sludge in the biological selection pond, not only increased the comprehensive utilization ratio to activated sludge in the B section sedimentation tank, reduced the cost of labor moreover, efficiency is higher, operates convenience more simultaneously and laborsaving.

The invention is further configured to: the section A sedimentation tank bottom is equipped with the sludge pipe, and the other end of sludge pipe is equipped with in the sludge impoundment, be equipped with sludge pump and mud valve on the sludge pipe, the other end of sludge impoundment has mud pressure filter through the elevator pump intercommunication.

By adopting the technical scheme, the sludge at the bottom of the section A sedimentation tank is basically sludge which is saturated in adsorption, and the sludge is saturated in adsorption, so that the sludge is no longer activated sludge, and the sludge in the section A sedimentation tank only needs to be discharged periodically and is subjected to post-treatment in a sludge filter press.

The invention is further configured to: the EMR reaction pool group is formed by sequentially connecting a biological selection pool, an amplification reaction pool and a depth reaction pool in series; wherein, the biological selection pool: an amplification reaction tank: the volume ratio of the deep treatment tank is 1 (2-50) to 20-1000.

By adopting the technical scheme, only three pools, namely the biological selection pool, the amplification reaction pool and the deep reaction pool, can be used for efficiently removing soluble organic matters in the pressing and leaching solution, and the treatment efficiency is high.

The invention is further configured to: the two groups of EMR reaction cell groups are connected in parallel and are communicated.

Through adopting above-mentioned technical scheme, adopt two sets of parallel arrangement, and the ERM reaction tank that connects in parallel the setting each other, two sets of ERM reaction tanks can carry out sewage treatment in step this moment, have improved efficiency greatly.

The invention is further configured to: a plurality of biological ropes are hung in the deep reaction tank at intervals, a plurality of biological filler devices are fixed on the biological ropes at intervals, and the biological filler devices are immersed in the water body of the deep reaction tank.

By adopting the technical scheme, microorganisms can be attached to the cavity of the biological filler device due to the existence of the biological rope and the biological filler device, so that the impact load resistance of the system is improved.

The invention is further configured to: the reflux ratio of the sludge amount refluxed to the biological flocculation tank in the B section sedimentation tank to the water inflow amount of the biological flocculation tank is 20-200%.

Through adopting above-mentioned technical scheme, the reflux ratio = B section sedimentation tank backward flow to the sludge volume of biological flocculation pond/the inflow of biological flocculation pond, through the reasonable proportion of informing the sludge volume of B section sedimentation tank backward flow to biological flocculation pond and the inflow of biological flocculation pond, can increase from the efficiency of flocculation between the sludge volume of B section sedimentation tank backward flow and the inflow of biological flocculation pond, improve the content of the quantity organic matter of flocculation and precipitation.

The invention is further configured to: each biological rope is perpendicular to the flowing direction of the water body, and the biological filling devices on two adjacent biological ropes are arranged in a staggered mode.

Through adopting above-mentioned technical scheme, biological rope perpendicular to water flow's direction sets up, and biological rope and the biofilm carrier device that is located on the biological rope play certain effect of blockking and postponing this moment, can make the microorganism in the water body can be as long as possible stay in degree of depth reaction tank from this, has further promoted the treatment effeciency of organic matter in the sewage.

The invention is further configured to: the baffle I close to the lower part of the notch I is integrally connected with an L-shaped partition plate I, and a first channel for allowing fluid in the biological flocculation tank to flow into the section A and settle out is formed between every two adjacent L-shaped partition plates I.

And a second L-shaped partition plate is integrally connected on the second baffle plate close to the lower part of the second notch, and a second channel for allowing the fluid in the deep reaction tank to flow into the B-section sedimentation tank is formed between the two adjacent L-shaped partition plates.

Through adopting above-mentioned technical scheme, the existence of L type baffle one and L type baffle two plays directional water conservancy diversion effect to a certain extent, reduces sewage and flows backward to sewage treatment's efficiency and quality have been improved.

In conclusion, the invention has the following beneficial effects:

1. the invention can effectively reduce the COD content and the ammonia nitrogen content in water, reduce the occurrence of the phenomenon of the overflow of malodorous gas in the pipeline and improve the protection of the comprehensive environment of the garbage transfer station;

2. optimally, due to the existence of the biological rope and the biological filler device, microorganisms can be attached to the cavity of the biological filler device, so that the impact load resistance of the system is improved;

3. optimized, the biological rope is perpendicular to the flowing direction of the water body, and the biological rope and the biological filler device positioned on the biological rope play a certain role in blocking and delaying, so that microorganisms in the water body can stay in the deep reaction tank as long as possible, and the treatment efficiency of organic matters in sewage is further promoted.

Drawings

FIG. 1 is a process flow diagram of a conventional leachate treatment apparatus of a waste transfer station;

FIG. 2 is a schematic diagram of a bioreactor for treating leachate from a waste transfer station;

FIG. 3 is a flow chart of the treatment process of example 1 in a bioreactor for treating a landfill leachate;

FIG. 4 is a flow chart of the treatment process of example 2 in a bioreactor for treating the leachate of a waste transfer station.

Description of the drawings: 1. a bioreactor body; 2. a biological flocculation tank; 3. a section A of a sedimentation tank; 4. a set of EMR reaction cells; 41. a biological selection pool; 42. an amplification reaction tank; 43. a deep reaction tank; 5. a B section of sedimentation tank; 6. a water inlet; 7. a first baffle plate; 8. a first gap is formed; 9. a water outlet; 10. a second baffle plate; 11. a second gap; 12. a water outlet; 13. an aeration device; 14. a blow-off pipe; 15. a sludge pump; 16. a blowdown valve; 17. a branch pipe; 18. a bypass valve; 19. a sludge pipe; 20. a sludge tank; 21. a sludge valve; 22. a sludge filter press; 23. a biological rope; 24. a biological filler means; 26. an L-shaped partition plate I; 27. a first channel; 28. an L-shaped clapboard II; 29. and a second channel.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

Example 1: a bioreactor for treating the leachate of a garbage transfer station comprises a bioreactor body 1 which is arranged in the garbage transfer station and is used for reducing COD in the leachate and is used for treating the leachate after pretreatment, and the bioreactor body 1 is arranged between an intermediate tank and a sedimentation tank as shown in figure 2. Therefore, according to sewage treatment's order, rubbish transfer station presses leachate treatment device includes in proper order: an oil-water residue separator, an air floatation tank, an intermediate tank, a bioreactor body 1, a sedimentation tank, a sludge concentration tank for collecting sewage and a clean water tank for collecting clean water. The water collecting tank and the adjusting tank are arranged outside the whole sewage treatment body, the water collecting tank and the adjusting tank are arranged under the ground in the garbage transfer station, the horizontal heights of the water collecting tank and the adjusting tank are low, so that sewage in the garbage station can automatically flow into the water collecting tank, and the water collecting tank is mainly used for collecting the sewage. And finally, after COD content of the clean water in the clean water tank is qualified through COD online detection, the clean water can be directly discharged to a municipal pipe network.

The oil-water residue separator is preferably a kitchen oil-water residue separation device with the authorization notice number of CN102616952B, and is characterized in that the device consists of a water inlet chamber, a water inlet liquid level control chamber, a three-phase separation chamber, a water outlet liquid level control chamber, a water outlet chamber, an oil storage chamber and a dissolved air pump which are arranged in a body, wherein a filter residue frame is arranged in the water inlet chamber; a dissolved air contactor, an oil collecting and discharging cover and a water outlet ring pipe are arranged in the three-phase separation chamber, and a slag collecting hopper is arranged at the lower part of the three-phase separation chamber; the water inlet liquid level control chamber is connected with the dissolved air contactor through a water inlet mixing pipe; the effluent liquid level control chamber is communicated with the effluent chamber through an effluent overflow weir; the outlet of the dissolved air pump is communicated with the water inlet mixing pipe through a dissolved air pipe, and the inlet of the dissolved air pump is connected with the water outlet chamber through a pipeline; the oil collecting and discharging cover is communicated with the oil storage chamber through an oil discharging hole.

The air floatation tank is preferably a micro-nano bubble generator with the authorization notice number of CN207981053U, and is characterized in that the bubble generator consists of a dissolved air tank, an air pump and a circulating water pump, wherein the upper part of the dissolved air tank is a dissolved air area provided with an atomizing water distribution nozzle, an air valve core and a packing layer, and the lower part of the dissolved air tank is a water storage area provided with a water inlet pipe, a floating ball liquid level control valve, a micro-nano bubble outlet and a circulating water outlet; the air pump and the circulating water pump are provided with electric cabinets to adjust the air inlet pressure and the circulating time of bubble water so as to generate micro-nano bubbles with different particle sizes and uniformity.

Firstly, garbage leachate in the garbage transfer station and flushing liquid for flushing the ground of the garbage transfer station are collected in a water collecting tank through self-flowing; then the sewage is lifted to a regulating tank by a submersible sewage pump to carry out homogenization and equalization (the homogenization and equalization is beneficial to the next treatment) on the sewage so as to improve the impact load resistance of the whole sewage treatment device; and then the sewage enters an oil-water residue separator to carry out three-phase separation on the sewage, wherein a light oil residue mixture is discharged from the top, heavy particulate matters are deposited at the bottom of the reaction tank and discharged into a sludge tank 20 through an air stripping pipeline, in addition, relatively clean water bodies are automatically discharged into an air flotation tank and are connected into the air flotation tank to carry out air flotation reaction so as to remove most of oil substances and particulate matters in the sewage, and air flotation effluent can be automatically discharged into a middle tank to carry out homogenization and equalization again.

Then the water in the intermediate tank flows into the bioreactor body 1 to further absorb water-soluble organic matters, thereby effectively reducing the COD content of the water. And then the sewage treated by the bioreactor body 1 is discharged into a clear water tank through a water outlet 12, and the detected COD content is qualified and then can be discharged into a municipal pipe network.

As shown in figure 2, according to the treatment process of the leachate, the bioreactor body 1 comprises a biological flocculation tank 2, an A-section sedimentation tank 3, an EMR reaction tank group 4 and a B-section sedimentation tank 5 which are sequentially communicated. Wherein, the EMR reaction pool 4 is composed of a biological selection pool 41, an amplification reaction pool 42 and a depth reaction pool 43 which are communicated with each other in sequence.

The biological flocculation tank 2 is used for flocculating and adsorbing organic matter particle colloid; a large amount of activated sludge for flocculation adsorption is arranged in the biological flocculation tank 2, and a water inlet 6 is arranged at the upper end of the biological flocculation tank 2.

The A-section sedimentation tank 3 is used for separating mud and water; a section sedimentation tank 3 and biological flocculation pond 2 intercommunication are equipped with a plurality of baffles 7 between A section sedimentation tank 3 and biological flocculation pond 2, are equipped with a plurality of water that supply in the biological flocculation pond 2 and flow into breach 8 in the A section sedimentation tank 3 between two adjacent baffles 7 of keeping away from biological flocculation pond 2 bottom.

As shown in figure 2, in order to achieve the effect of directional diversion to a certain extent and reduce the backflow of sewage into the A-section sedimentation tank 3, an L-shaped partition plate 26 is integrally connected to the two baffle plates 7 close to the lower part of the notch I8, and a channel I27 is formed between the two adjacent L-shaped partition plates 26 arranged up and down. The first channel 27 only has the function of allowing the fluid in the biological flocculation tank 2 to flow into the A-section sediment, and the reverse flow of the sewage is limited to a certain extent under the action of the first L-shaped partition plate 26, so that the efficiency and the quality of sewage treatment are improved.

Meanwhile, as shown in fig. 2, a sludge pipe 19 is installed at the bottom of the section a sedimentation tank 3, the other end of the sludge pipe 19 is provided with a sludge tank 20 for collecting sludge, a sludge pump 15 and a sludge valve 21 are also installed on the sludge pipe 19, and the sludge valve 21 is preferably a ball valve. The other end of the sludge tank 20 is connected to a sludge filter press 22 via a lift pump, and the sludge filter press 22 is preferably a DY belt press filter (manufactured by Wuxinghanhao mechanical factory, Huzhou). The sludge deposited at the bottom of the A-stage sedimentation tank 3 can be subjected to sludge concentration in the sludge tank 20, and the sludge subjected to concentration and dewatering is guided into the sludge filter press 22 through the lifting pump and is subjected to filter pressing under the action of external force to form a sludge block with the water content of less than 20 percent (weight).

A biological selection tank 41 for screening out high-efficiency COD degrading bacteria; the biological selection tank 41 is communicated with the section A sedimentation tank 3 at one side far away from the amplification reaction tank 42, and a water outlet 9 for the upper layer liquid in the section A sedimentation tank 3 to flow into the amplification reaction tank 42 is arranged at one side of the bottom of the section A sedimentation tank 3 far away from the section A sedimentation tank 3.

The amplification reaction tank 42 is used for the amplification culture of the high-efficiency COD degrading bacteria; the amplification reaction tank 42 is connected with the biological selection tank 41 through a perforated wall. Meanwhile, a partition plate is vertically installed at the upper end of the amplification reaction chamber 42, the lower end of the partition plate is inserted into the amplification reaction chamber 42, and the height of the partition plate is one half of the amplification reaction chamber 42.

The deep reaction tank 43 is mainly used for further degrading organic matters remained in the sewage; the deep reaction chamber 43 is connected to the amplification reaction chamber 42 through a perforated wall. A plurality of PVC biological ropes 23 are hung in the deep reaction tank 43 at intervals, a plurality of biological filler devices 24 are fixed on the biological ropes 23 at intervals, and the biological filler devices 24 are immersed in the water body of the deep reaction tank 43. The biological filler device 24 is made of PVC material and has a plurality of cavities (not shown in the figure) on the surface, and the cavities (which are micro-hole structures) can be attached by microorganisms (EM bacteria), so that the contact area between the microorganisms and organic matters in the sewage is increased.

The volume ratio of the biological selection tank 41, the amplification reaction tank 42 and the advanced treatment tank 43 is 1 (2-50) to (20-1000). One alternative embodiment is as follows, the volume ratio of the biological selection tank 41 to the amplification reaction tank 42 to the deep treatment tank 43 is 1: 25: 620. as shown in fig. 2, in order to further prolong the residence time of the EM bacteria in the deep reaction tank 43, each of the biological ropes 23 is arranged perpendicular to the direction of the water body flow, and the biological filler devices 24 on two adjacent biological ropes 23 are arranged in a staggered manner, so that a good blocking effect is achieved, the residence time of the EM bacteria in the deep reaction tank 43 is prolonged, and the capability of the deep reaction tank 43 in treating and degrading organic matters is greatly improved.

The B section sedimentation tank 5 is used for separating mud and water and discharging clean water; the section B sedimentation tank 5 is communicated with the deep reaction tank 43, a plurality of baffle plates II 10 are arranged between the section B sedimentation tank 5 and the deep reaction tank 43, and a plurality of gaps II 11 for water in the deep reaction tank 43 to flow into the section B sedimentation tank 5 are arranged between two adjacent baffle plates II 10 far away from the bottom of the deep reaction tank 43; meanwhile, the upper end of the B section sedimentation tank 5 is provided with a water outlet 12.

As shown in FIG. 2, in order to perform a directional diversion function to a certain extent and reduce the backflow of sewage into the deep reaction tank 43, two L-shaped partition plates 28 are integrally connected to the two baffle plates 10 close to the lower part of the second notch 11, and a second channel 29 is formed between the two L-shaped partition plates 28 which are vertically arranged. The second channel 29 has the function of only allowing the fluid in the deep reaction tank 43 to flow into the B-section sedimentation tank 5.

Meanwhile, a sewage discharge pipe 14 for recycling sludge is arranged at the bottom of the B-section sedimentation tank 5, as shown in fig. 2, a sewage discharge pump (not marked in the figure) is arranged on the sewage discharge pipe 14, the other end of the sewage discharge pipe 14 extends into the biological flocculation tank 2, a sewage discharge valve 16 is arranged at one end of the sewage discharge pipe 14 close to the biological flocculation tank 2, and the sewage discharge valve 16 is preferably a ball valve. Meanwhile, the reflux ratio of the sludge amount refluxed to the biological flocculation tank in the B section sedimentation tank to the water inflow amount of the biological flocculation tank is 20-200%. In an optional embodiment, the reflux ratio of the sludge amount refluxed to the biological flocculation tank from the B-section sedimentation tank to the water inflow of the biological flocculation tank is 50%.

As shown in figure 2, in order to further increase the comprehensive utilization rate of the activated sludge in the B-section sedimentation tank 5, a branch pipe 17 is arranged on the sewage discharge pipe 14, the other end of the branch pipe 17 extends into the biological selection tank 41, a branch valve 18 is arranged on the branch pipe 17, and the branch valve 18 is preferably a ball valve. At the moment, the effluent of the A section sedimentation tank 3 is discharged into the biological selection tank 41 in a self-flowing manner and is fully mixed with the sludge which flows back from the B section sedimentation tank 5. Therefore, under the action of the aeration device 13, a nutrient-rich environment is provided for the microorganisms (EM bacteria) in the biological selection tank 41, and at the moment, "high-efficiency COD degrading bacteria" with short generation period and high metabolism speed can rapidly propagate in the biological selection tank 41. When the sludge in the biological selection tank 41 is expanded, the biological selection tank 41 provides an artificial mode to close the aeration device 13, the aeration is stopped, and the biological selection tank 41 is converted into an anoxic tank for use. When the sludge expansion does not occur, the biological selection tank 41 can be used for manually selecting normal aeration to provide a positive environment for the microorganisms and accelerate the metabolism of the microorganisms.

As shown in fig. 2, a plurality of aeration devices 13 are installed in the bioflocculation tank 2, the biological selection tank 41, the amplification reaction tank 42 and the deep reaction tank 43, aeration heads of the aeration devices 13 are respectively installed at the bottoms of the bioflocculation tank 2, the biological selection tank 41, the amplification reaction tank 42 and the deep reaction tank 43, air supply devices (circulation pumps and blowers) (not shown in the figure) of the aeration devices 13 are respectively installed outside the bioflocculation tank 2, the biological selection tank 41, the amplification reaction tank 42 and the deep reaction tank 43, air pumps are connected with the corresponding aeration heads by PVC plastic hoses, and the aeration devices 13 are preferably FLD type butterfly jet aerators (environmental protection equipment ltd, Shandong Fred, Ltd.). The FLD type butterfly jet aerator is mainly composed of an outer cavity, an inner cavity, an outer nozzle, an inner nozzle, an air inlet and a liquid inlet. The inner cavity and the outer cavity are cavities formed by the involutory bonding of an upper disc-shaped shell and a lower disc-shaped shell, the inner cavity and the outer cavity are coaxially sleeved, the liquid inlet and the air inlet are respectively connected with the inner cavity and the outer cavity along the axis direction, and the inner nozzle and the outer nozzle are respectively and concentrically and uniformly distributed along the circumferential surfaces of the inner cavity and the outer cavity. The inner cavity is a working medium cavity, and the outer cavity is an injection medium cavity.

As shown in figures 2 and 3, the sewage in the intermediate tank is discharged into the biological flocculation tank 2, and a large amount of water-soluble organic matters in the sewage are absorbed under the action of activated sludge, so that the COD content of the water body is effectively reduced. Then the sewage enters the A-section sedimentation tank 3 for solid-liquid separation, the upper liquid in the A-section sedimentation tank 3 flows into the biological selection tank 41, and under the action of the activated sludge added by artificial assistance, the selective switch aeration is carried out, so that the 'high-efficiency COD degradation bacteria' (namely EM bacteria) with short generation period and high metabolism speed is selected.

Then the "high efficiency COD degrading bacteria" enters the amplification reaction tank 42 along with the sewage, and the "high efficiency COD degrading bacteria" is subjected to amplification culture under the action of the aeration device 13. And then the bacteria for efficient COD degradation enter the deep reaction tank 43 along with the sewage to further degrade organic matters remaining in the sewage, and finally the sewage is discharged into the B-section sedimentation tank 5 for mud-water separation, the upper-layer liquid in the B-section sedimentation tank 5 can be discharged into the municipal pipe network after being discharged into the clean water tank through the water outlet 12, and the discharged upper-layer liquid reaches the discharge standard of the municipal pipe network.

Example 2: a bioreactor for treating a garbage transfer station leachate, which is different from the bioreactor of example 1 in that: as shown in FIG. 4, there are two sets of the above-mentioned EMR reaction cell groups 4, and the two sets of EMR reaction cell groups 4 are arranged in parallel in a conductive manner.

The specific embodiments are only for explaining the present invention, and the present invention is not limited thereto, and those skilled in the art can make modifications without inventive contribution to the present embodiments as needed after reading the present specification, but all of them are protected by patent law within the scope of the claims of the present invention.

Claims (10)

1. A bioreactor for treating the leachate of a waste transfer station comprises a bioreactor body (1) which is arranged in the waste transfer station and is used for reducing COD in the leachate, and is characterized in that according to the treatment process of the leachate, the bioreactor body (1) comprises a biological flocculation tank (2), an A-section sedimentation tank (3), at least one EMR reaction tank group (4) and a B-section sedimentation tank (5) which are sequentially communicated;

a large amount of activated sludge for flocculation adsorption is arranged in the biological flocculation tank (2), and a water inlet (6) is arranged at the upper end of the biological flocculation tank (2);

the A-section sedimentation tank (3) is used for separating mud and water; the section A sedimentation tank (3) is communicated with the biological flocculation tank (2), a plurality of first baffles (7) are arranged between the section A sedimentation tank (3) and the biological flocculation tank (2), and a plurality of first gaps (8) for water in the biological flocculation tank (2) to flow into the section A sedimentation tank (3) are arranged between two adjacent first baffles (7) far away from the bottom of the biological flocculation tank (2);

the EMR reaction tank group (4) comprises a biological selection tank (41), an amplification reaction tank (42) and a depth reaction tank (43) which are sequentially communicated with one another, wherein the biological selection tank (41) is communicated with the section A sedimentation tank (3) on one side far away from the amplification reaction tank (42), and a water outlet (9) for allowing upper-layer liquid in the section A sedimentation tank (3) to flow into the amplification reaction tank (42) is formed in one side, far away from the bottom of the section A sedimentation tank (3), of the section A sedimentation tank (3);

the B section sedimentation tank (5) is used for separating mud and water and discharging clean water; the section B sedimentation tank (5) is communicated with the deep reaction tank (43), a plurality of second baffles (10) are arranged between the section B sedimentation tank (5) and the deep reaction tank (43), and a plurality of second gaps (11) for water in the deep reaction tank (43) to flow into the section B sedimentation tank (5) are arranged between two adjacent second baffles (10) far away from the bottom of the deep reaction tank (43); meanwhile, the upper end of the B section sedimentation tank (5) is provided with a water outlet (12);

a plurality of aeration devices (13) are arranged in the biological flocculation tank (2) and the EMR reaction tank group (4).

2. The bioreactor for treating the leachate of the garbage transfer station according to claim 1, wherein a drain pipe (14) for recycling sludge is arranged at the bottom of the B-section sedimentation tank (5), a drain pump is arranged on the drain pipe (14), the other end of the drain pipe (14) extends into the biological flocculation tank (2), and a drain valve (16) is arranged at one end of the drain pipe (14) close to the biological flocculation tank (2).

3. The bioreactor for treating the leachate of the garbage transfer station as claimed in claim 2, wherein a branch pipe (17) is provided on the sewage discharge pipe (14), the other end of the branch pipe (17) extends into the biological selection tank (41), and a branch valve (18) is provided on the branch pipe (17).

4. The bioreactor for treating the leachate of the garbage transfer station according to claim 1, wherein a sludge pipe (19) is arranged at the bottom of the A-section sedimentation tank (3), the other end of the sludge pipe (19) is arranged in a sludge tank (20), a sludge pump (15) and a sludge valve (21) are arranged on the sludge pipe (19), and the other end of the sludge tank (20) is communicated with a sludge filter press (22) through a lifting pump.

5. The bioreactor for treating the garbage transfer station leachate according to claim 1, wherein the EMR reaction pool group (4) is composed of a biological selection pool (41), an amplification reaction pool (42) and a deep reaction pool (43) which are connected in series in sequence; wherein the biological selection cell (41): an amplification reaction cell (42): the volume ratio of the deep treatment tank (43) is 1 (2-50) to (20-1000).

6. The bioreactor for treating the garbage transfer station leachate according to claim 5, wherein there are two groups of EMR reaction groups (4), and the two groups of EMR reaction groups (4) are connected in parallel.

7. The bioreactor for treating the garbage transfer station leachate according to claim 5, wherein a plurality of biological ropes (23) are hung at intervals in the deep reaction tank (43), a plurality of biological filling devices (24) are fixed on the biological ropes (23) at intervals, and the biological filling devices (24) are immersed in the water body of the deep reaction tank (43).

8. The bioreactor for treating the leachate of the garbage transfer station according to claim 1, wherein the reflux ratio of the amount of the sludge refluxed to the biological flocculation tank (2) in the B-stage sedimentation tank (5) to the amount of the water fed into the biological flocculation tank (2) is 20-200%.

9. The bioreactor for treating the leachate at the garbage transfer station as recited in claim 5, wherein each bio-rope (23) is arranged perpendicular to the flowing direction of the water body, and the bio-packing devices (24) on two adjacent bio-ropes (23) are arranged in a staggered manner.

10. The bioreactor for treating the garbage transfer station leachate according to the claim 1, characterized in that a first L-shaped baffle plate (26) is integrally connected to the first baffle plate (7) close to the lower part of the first notch (8), and a first channel (27) for allowing the fluid in the biological flocculation tank (2) to flow into the A-section sediment is formed between the two adjacent first L-shaped baffle plates (26);

and a second L-shaped partition plate (28) is integrally connected to the second baffle plate (10) close to the lower part of the second notch (11), and a second channel (29) for allowing the fluid in the deep reaction tank (43) to flow into the section B sedimentation tank (5) is formed between every two adjacent second L-shaped partition plates (28).

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