CN215208983U - Synergistic treatment system for performing nitrogen and phosphorus removal on low C/N sewage by utilizing kitchen waste hydrolysis acidification liquid - Google Patents

Abstract

The utility model relates to the field of kitchen waste recycling and domestic sewage treatment, in particular to a cooperative disposal system for performing nitrogen and phosphorus removal on low C/N sewage by utilizing kitchen waste hydrolysis acidification liquid, which comprises a kitchen waste pretreatment device, a hydrolysis acidification device, a chemical precipitation device, a supernatant drainage system, an AAO system and a secondary sedimentation tank which are sequentially communicated, wherein the hydrolysis acidification device, the chemical precipitation device and the secondary sedimentation tank are respectively communicated with a sludge storage tank, and the AAO system is also communicated with a reservoir; the AAO system is including the anaerobism pond, oxygen deficiency pond and the good oxygen pond that communicate in proper order, and crisscross rivers hole intercommunication about anaerobism pond, oxygen deficiency pond, good oxygen pond take, anaerobism pond and cistern intercommunication, supernatant drainage system with the anaerobism pond intercommunication. The utility model discloses the realization is got rid of the high-efficient immobilization of nitrogen phosphorus in the kitchen garbage carbon source, has effectively reduced nitrogen phosphorus in the denitrification carbon source to shift over to mud with nitrogen phosphorus and can be used as soil amendment.

Description

Synergistic treatment system for performing nitrogen and phosphorus removal on low C/N sewage by utilizing kitchen waste hydrolysis acidification liquid

Technical Field

The utility model relates to a kitchen garbage resourceization and domestic sewage treatment field, concretely relates to utilize kitchen garbage hydrolytic acidification liquid to carry out low CNsewage nitrogen and phosphorus removal's coprocessing system in coordination.

Background

A domestic sewage treatment plant mostly adopts a biological nitrogen and phosphorus removal process, a carbon source is always a control factor of the traditional biological nitrogen and phosphorus removal process, and the carbon source is used as a nutrient substance necessary for the growth of microorganisms and is mainly consumed in the processes of phosphorus release of the microorganisms, denitrification and metabolism of xenobiotics. At present, in domestic sewage treatment plants, the situation that the carbon source of inlet water is seriously insufficient generally exists, the proportion of carbon and nitrogen is seriously disordered, the carbon source is seriously insufficient, the nitrogen and phosphorus removal effect of the operation of a sewage treatment plant system is poor, the carbon source needs to be added, and the adding cost of the carbon source is high.

The kitchen waste leachate contains more organic components, COD is about 20000mg/L, ammonia nitrogen is about 1000mg/L, and total phosphorus is about 50mg/L, and if the kitchen waste leachate is not properly treated and utilized, the kitchen waste leachate can generate pollution such as malodor and the like. The conventional treatment method is a combination of advanced oxidation technology and anaerobic and aerobic biochemical technology, the treatment method is complex in process and high in investment and operation cost, meanwhile, nitrogen and phosphorus in the sewage are reduced, COD is also greatly removed, and the treated wastewater reaches the water quality standard of sewage discharge to urban sewer (DB 31/445-. The effluent of the conventional treatment process still shows serious imbalance of carbon-nitrogen-phosphorus ratio, the carbon source is seriously insufficient, and the operation burden of a sewage plant is increased when the effluent enters the sewage plant.

Therefore, a method is urgently needed to be explored, under the condition that ammonia nitrogen and total phosphorus in the part of wastewater are largely removed, COD in the wastewater is reserved and used as carbon source supplement of a sewage plant, so that the situation that the carbon-nitrogen-phosphorus ratio of incoming water of the sewage plant is seriously disordered and the carbon source is insufficient is improved.

Disclosure of Invention

An object of the utility model is to provide an utilize kitchen garbage hydrolytic acidification liquid to carry out low C/N sewage nitrogen and phosphorus removal's coprocessing system, utilize kitchen garbage as the denitrification carbon source, reduce low C/N sewage treatment cost, accomplish minimizing, resourceization, innocent treatment to kitchen garbage.

The utility model discloses the scheme that the realization purpose adopted is: a co-processing system for performing nitrogen and phosphorus removal on low C/N sewage by utilizing kitchen waste hydrolysis acidification liquid comprises a kitchen waste pretreatment device, a hydrolysis acidification device, a chemical precipitation device, a supernatant drainage system, an AAO system and a secondary sedimentation tank which are sequentially communicated, wherein the hydrolysis acidification device, the chemical precipitation device and the secondary sedimentation tank are respectively communicated with a sludge storage tank, and the AAO system is also communicated with a water storage tank; the AAO system comprises an anaerobic tank, an anoxic tank and an aerobic tank which are sequentially communicated, wherein the anaerobic tank, the anoxic tank and the aerobic tank are communicated by adopting water flow holes which are staggered up and down; the supernatant drainage system is communicated with the anaerobic tank.

Preferably, the kitchen waste pretreatment device is composed of a sorting device and a crushing device.

Preferably, the hydrolysis acidification device comprises a stirring device, an inorganic acid feeding pump, a water replenishing pump, a heating device and a solid-liquid separation device, wherein the heating device is also provided with a temperature control device; the solid-liquid separation device is provided with a slag discharge valve and is communicated with the sludge storage tank through a slag discharge pump; and a water outlet pipe of the hydrolysis acidification device is communicated with the chemical precipitation device.

Preferably, the chemical precipitation device comprises a liquid level meter, a chemical reagent feeding device and a pH monitor, the chemical reagent feeding device comprises a phosphate feeding pump, a magnesium salt feeding pump and an alkali liquor feeding pump, and the phosphate feeding pump, the magnesium salt feeding pump and the alkali liquor feeding pump are sequentially arranged on the water inlet; the water inlet is communicated with the hydrolysis acidification device, and the chemical precipitation device is also provided with a stirring device; the chemical precipitation device bottom still is equipped with the mud valve, through mud pump and storage mud pond intercommunication, the supernatant of chemical precipitation device is carried to the AAO system through supernatant drainage system.

Preferably, an aeration system is arranged in the aerobic tank; the aeration system comprises an aeration head, an air compressor and a gas flow regulating valve, wherein the air compressor is connected with the aeration head through the gas flow regulating valve, and the aeration head is arranged at the bottom of the aerobic tank.

The technical principle of the utility model is that: kitchen garbage is through selecting separately, broken preprocessing device, get into hydrolysis acidification reaction unit, through adjusting solid-to-liquid ratio, kitchen garbage is high temperature, under the acid condition, macromolecule organic matter is the micromolecule organic matter in short time hydrolysis, the micromolecule organic matter is further hydrolyzed into the volatile fatty acid who takes acetic acid as the owner, organic nitrogen and organic phosphorus are hydrolyzed into inorganic nitrogen and inorganic phosphorus and are released in the liquid in the kitchen garbage, through solid-liquid separation, the liquid that contains high concentration nitrogen phosphorus gets into the chemical precipitation device, form struvite sediment and accomplish nitrogen through controlling means in the chemical precipitation device, the degree of depth of phosphorus is got rid of, the volatile fatty acid that acetic acid is the owner has been remain simultaneously, as the denitrification liquid carbon source. Introducing a liquid carbon source into the AAO system through a drainage system, and removing nitrogen and phosphorus in the low C/N sewage by utilizing the carbon source in the liquid through the reflux of the nitrifying liquid. The technology is suitable for the advanced treatment of the sewage with high ammonia nitrogen and low carbon content, does not need an external carbon source, and simultaneously realizes the in-situ co-treatment of the town kitchen waste and the sewage with low C/N.

The utility model has the advantages of it is following and beneficial effect:

(1) the kitchen waste is used as a denitrification carbon source, so that the low C/N sewage treatment cost is reduced;

(2) finishing the reduction, recycling and harmless treatment of the kitchen waste;

(3) the high-efficiency immobilized removal of nitrogen and phosphorus in the kitchen waste carbon source is realized, the nitrogen and phosphorus in the denitrification carbon source are effectively reduced, and the nitrogen and phosphorus are transferred into sludge to be used as a soil conditioner;

(5) the kitchen waste hydrolysis acidification and the low C/N sewage denitrification are synchronously realized, and the treatment cost is greatly saved.

Drawings

Fig. 1 is a schematic structural diagram of embodiment 1 of the present invention.

Reference numerals: 1. a pretreatment device; 1.1, a sorting device; 1.2, a crushing device; 2. a hydrolysis acidification device; 2.1, a heating device; 2.2, a solid-liquid separation device; 2.3, a water replenishing pump; 2.4, adding a pump for inorganic acid; 2.5, a stirring device; 2.6, a slag discharge pump; 2.7, discharging a water pipe; 2.8, a temperature control device; 2.9, a slag discharge valve; 3. a chemical precipitation device; 3.1, a phosphate adding pump; 3.2, adding a magnesium salt pump; 3.3, adding a pump for alkali liquor; 3.4, a stirrer; 3.5, a liquid level meter; 3.6, a sludge discharge pump; 3.7, a water inlet; 3.8, a water outlet; 3.9, a chemical reagent adding device; 4. a supernatant drainage system; 4.1, a drainage pump; 5. a reservoir; 5.1, a raw water pump; 5.2, a sewage inlet; 6. an AAO system; 6.1, an anaerobic tank stirrer; 6.2, an anoxic tank stirrer; 6.3, an air compressor; 6.4, air flow regulating valve; 6.5, an aeration head; 6.6, a water outlet of the aerobic tank; 6.7, an anaerobic tank; 6.8, an anoxic tank; 6.9, an aerobic tank; 7. a secondary sedimentation tank; 7.1, a water outlet of the secondary sedimentation tank; 7.2, a sludge pump; 7.3, a nitrifying liquid reflux pump; 7.4, a water producing pump; 7.5, a sludge reflux system; 7.6, a water inlet of a secondary sedimentation tank; 8. a mud storage pool; 9. a pH monitor; 10. a mud valve; 11. and (4) feeding a material inlet.

Detailed Description

For better understanding of the present invention, the following examples are further illustrative of the present invention, but the present invention is not limited to the following examples.

The embodiment of the utility model provides a related kitchen garbage is mainly for organic garbage such as fruit vegetables and food leftover bits and pieces, melon and fruit peel that abandon in the diet remainder and the family daily life of dining room, restaurant, for the organic garbage that does not contain solid matters such as bold bone, metal, plastics, glass, for expecting in a convenient way the utility model discloses the method is to kitchen garbage's treatment effect, and we take the kitchen garbage of certain colleges and universities dining room in Wuhan City, screen out behind debris such as bone, metal, plastics, glass be used for following embodiment.

Example 1

As shown in figure 1, the utility model provides a pair of utilize kitchen garbage hydrolytic acidification liquid to carry out low C/N sewage nitrogen and phosphorus removal's coprocessing system, including kitchen garbage preprocessing device 1, hydrolytic acidification device 2, chemical precipitation device 3, supernatant drainage system 4, cistern 5, AAO system 6, storage mud pond 8, two heavy ponds 7.

The kitchen waste pretreatment device 1 is communicated with the hydrolysis acidification device 2; the hydrolysis acidification device 2 is provided with a solid-liquid separation device 2.2; a water outlet pipe 2.7 of the hydrolysis acidification device is connected with a water inlet 3.7 of the chemical precipitation device, the supernatant of the chemical precipitation device 3 is connected with an AAO system 6 through a supernatant drainage system 4, and the AAO system 6 is communicated with the secondary sedimentation tank 7; the secondary sedimentation tank 7 is provided with a water outlet 7.1 for discharging the effluent;

the kitchen waste pretreatment device 1 consists of a sorting device 1.1 and a crushing device 1.2 and is used for screening out impurities such as bones, metals, plastics, glass and the like from the kitchen waste and then crushing the kitchen waste into materials with the particle size of less than or equal to 10 mm; the hydrolysis acidification device 2 comprises a water replenishing pump 2.3, a heating device 2.1 and a solid-liquid separation device 2.2.

The water replenishing pump 2.3 is connected with a feed inlet 11 of the hydrolysis acidification device 2, and raw water enters the hydrolysis acidification device 2 through the feed inlet 11 and is used for adjusting the solid-liquid ratio in the hydrolysis acidification device 2. The feed inlet 11 is also provided with an inorganic acid feeding pump 2.4 to ensure the concentration of inorganic acid in the hydrolysis acidification reaction. The hydrolysis-acidification device 2 is provided with an electric heating device 2.1 and a temperature control device 2.8, the electric heating device 2.1 is connected with the hydrolysis-acidification tank body, heat energy generated by electric heating is transferred to the hydrolysis-acidification tank body through the tank body, and the temperature of the hydrolysis-acidification of the kitchen waste is ensured. Be provided with agitating unit 2.5 in the hydrolytic acidification jar, 2 dress bottoms of hydrolytic acidification device are provided with solid-liquid separation device 2.2, and solid-liquid separator is equipped with slag valve 2.9, slag valve 2.9 and storage mud pond 8 intercommunication, and kitchen garbage is under high temperature, acid condition, and macromolecular organic matter is hydrolyzed to the micromolecular organic matter in the short time, and the further hydrolysis of micromolecular organic matter is the volatile fatty acid who uses acetic acid as the owner, and organic nitrogen and organic phosphorus are hydrolyzed to inorganic nitrogen and inorganic phosphorus and are released in the liquid in the kitchen garbage, through solid-liquid separation device 2.2, and solid residue gets into storage mud pond 8 through slag valve 2.9, is provided with slag discharge pump 2.6 between slag valve 2.9 and the storage mud pond 8, and the liquid that contains high concentration nitrogen phosphorus gets into chemical precipitation device 3 through hydrolytic acidification device outlet pipe 2.7.

The chemical precipitation device 3 comprises a chemical reagent adding device 3.9 and a pH monitor 9, the chemical reagent adding device 3.9 is divided into a phosphate adding pump 3.1, a magnesium salt adding pump 3.2 and an alkali liquor adding pump 3.3, the phosphate adding pump 3.1, the magnesium salt adding pump 3.2 and the alkali liquor adding pump 3.3 are sequentially arranged on the water inlet 3.7, and the pH in the chemical precipitation process is ensured by the pH monitor 9; the bottom of the chemical precipitation device 3 is also provided with a sludge discharge valve 10 which is communicated with a sludge storage tank 8 through a sludge discharge pump 3.6; forming struvite sediment in the chemical precipitation reaction process under the control of a stirrer 3.4 of a chemical precipitation device 3 and a chemical reagent adding device 3.9 to complete the deep removal of nitrogen and phosphorus in the kitchen waste hydrolysis acidification liquid, and simultaneously reserving volatile fatty acid mainly comprising acetic acid in the supernatant as a denitrification liquid carbon source; the chemical precipitation device No. 3 comprises a liquid level meter 3.5 for monitoring the water level of the chemical precipitation device 3 in real time, and when the water level reaches a certain height, the supernatant enters an anaerobic pool 6.7 of an AAO system 6 through a supernatant drainage system 4 and a drainage pump 4.1; the drainage pump 4.1 is communicated with a water outlet 3.8 of the chemical precipitation device 3.

The AAO system 6 comprises an anaerobic tank 6.7, an anoxic tank 6.8 and an aerobic tank 6.9 which are sequentially communicated, wherein the anaerobic tank 6.7, the anoxic tank 6.8 and the aerobic tank 6.9 are communicated by water flow holes which are staggered up and down, effluent from the bottom of the anaerobic tank 6.7 enters the anoxic tank 6.8, effluent from the top of the anoxic tank 6.8 enters the aerobic tank 6.9, and a supernatant drainage system drainage pump 4.1 is communicated with the anaerobic tank 6.7; an anaerobic tank stirrer 6.1 is arranged in the anaerobic tank 6.7, and an anoxic tank stirrer 6.2 is arranged in the anoxic tank 6.8 and is used for stirring sludge in the tank; the anaerobic tank 6.7 is communicated with the water storage tank 5, and the nitrifying liquid reflux pump 7.3 is used for refluxing the nitrifying liquid in the aerobic tank 6.9 to the anoxic tank 6.8; the nitrifying liquid is used for removing nitrogen and phosphorus. The aerobic tank 6.9 is provided with an aeration system; the aerobic tank 6.9 is provided with an aeration system, the aeration system is composed of an aeration head 6.5, an air compressor 6.3 and a flow regulating valve 6.4, the air compressor 6.3 is connected with the aeration head 6.5 through the flow regulating valve 6.4, the aeration head 6.5 is arranged at the bottom of the aerobic tank 6.9, and air can be continuously conveyed into the aerobic tank 6.9 through the air compressor 6.3 and the aeration head 6.5 so as to improve the oxygen content in the aerobic tank 6.9.

The water outlet 6.6 of the aerobic tank of the AAO system 6 is connected with the water inlet 7.6 of the secondary sedimentation tank; the secondary sedimentation tank 7 is provided with a water outlet 7.1, and is used for discharging the discharged water through a water producing pump 7.4; a sludge return system 7.5 is arranged between the secondary sedimentation tank 7 and the anaerobic tank 6.7 and is used for returning the sludge in the secondary sedimentation tank 7 to the anaerobic tank 6.7. The sludge in the secondary sedimentation tank 7 is conveyed to a sludge storage tank 8 through a sludge pump 7.2.

In the scheme, the AAO system 6 is a device for a sewage treatment process, can be used for secondary sewage treatment or tertiary sewage treatment, and has good nitrogen and phosphorus removal effects. The reservoir 5 is provided with a low C/N sewage inlet 5.2, low C/N sewage enters the reservoir 5 from the low C/N sewage inlet 5.2, and water in the reservoir 5 is conveyed to the anaerobic tank 6.7 through a raw water pump 5.1.

Example 2

A method for efficient in-situ co-treatment of kitchen waste and domestic sewage comprises the following steps:

the kitchen waste pretreatment device 1 and the water storage tank 5 are respectively filled with kitchen waste and low C/N sewage 1.

2 start-up of the AAO system: inoculating activated sludge and the AAO system 6, and controlling the concentration range of the activated sludge to be 3000-5000 mg/L; adjusting various parameters of the AAO system 6; specifically, firstly, an anaerobic tank stirrer 6.1, an anoxic tank stirrer 6.2, an air compressor 6.3 and an air flow regulating valve 6.4 in the AAO system 6 are started, and the reflux ratio of the nitrifying liquid and the reflux ratio of the sludge are respectively controlled to be about 200% and 100%; the DO concentration of the anaerobic pool 6.7 and the DO concentration of the aerobic pool 6.9 in the AAO system 6 are controlled to be 0.1-0.2mg/L and 2.0-3.0mg/L respectively. Then starting a sludge reflux pump 7.5, and controlling the sludge reflux pump to adjust the sludge reflux ratio according to the MLSS concentration in the AAO system; wherein, the activated sludge can be inoculated with activated sludge of a municipal sewage treatment plant;

3, operating the kitchen waste pretreatment device 1, the hydrolysis acidification device 2 and the chemical precipitation device 3 in series; introducing the supernatant in the chemical precipitation device 3 into an AAO system 6 periodically through a supernatant drainage system 4; in particular, the amount of the solvent to be used,

after the kitchen waste is screened out of impurities such as metal, glass and plastic stools by a sorting device, the kitchen waste is crushed into materials with the thickness less than or equal to 10mm by a crushing device; after being treated by the pretreatment device 1, the kitchen waste is conveyed into a hydrolysis acidification device 2, meanwhile, a water replenishing pump 2.3 is started, raw water enters the hydrolysis acidification device 2 for replenishing water, and the solid-liquid ratio is adjusted to be 1:2-1: 5; simultaneously starting an inorganic acid feeding pump 2.4 to ensure that the concentration of the inorganic acid in the hydrolytic acidification reaction is 0.5-1.5 mol/L; starting a heating device 2.1 of the hydrolysis acidification device 2, wherein the heating device 2.1 is connected with a hydrolysis acidification tank body, and heat energy generated by the heating device 2.1 is transferred into the hydrolysis acidification tank body through the tank body, so that the temperature of hydrolysis acidification of the kitchen waste is ensured to be 90-150 ℃; after hydrolysis acidification is carried out for 2-5h, solid-liquid separation is realized through a solid-liquid separation device 2.2, the solid-liquid separation device 2.2 is provided with a sludge discharge pump 2.9 and a sludge discharge valve 2.6, a water outlet pipe 2.7 of the hydrolysis acidification device 2 is connected with a water inlet 3.7 of a chemical precipitation device 3, the sludge discharge valve 2.6 is communicated with a sludge storage tank 8 through the sludge discharge pump 2.9 and a residue discharge pipe, the large molecular organic matter is hydrolyzed into small molecular organic matter in a short time under the conditions of high temperature and acidity of the kitchen waste, the small molecular organic matter is further hydrolyzed into volatile fatty acid mainly comprising acetic acid, organic nitrogen and organic phosphorus in the kitchen waste are hydrolyzed into inorganic nitrogen and inorganic phosphorus which are released into liquid, and the liquid containing high-concentration nitrogen and phosphorus enters the chemical precipitation device 3 through the water outlet pipe 2.7;

the phosphate adding pump 3.1, the magnesium salt adding pump 3.2 and the alkali liquor adding pump 3.3 of the chemical precipitation device 3 are respectively started, the phosphate adding pump 3.1, the magnesium salt adding pump 3.2 and the alkali liquor adding pump 3.3 are sequentially installed on the water inlet pipe 3.7, the pH in the chemical precipitation process is controlled to be between 8 and 9 through the pH monitor 9, and the phosphorus-nitrogen ratio is controlled to be 1 through the chemical reagent adding device 3.9: 2. magnesium-nitrogen ratio of 1: 1; starting a stirrer for 3.4, stirring at a speed of 100r/min, stirring for 4min, and standing for 3 min; starting a sludge discharge pump 3.6, and discharging residues to a sludge storage tank 8 through a sludge discharge valve 10; and starting a supernatant drainage system 4, and introducing the supernatant into an anaerobic tank 6.7 of the AAO system 6 through a drainage pump 4 by virtue of a water outlet pipe 3.7 of the chemical precipitation device 3.

Example 3

The effective volume of the co-processing system for carrying out nitrogen and phosphorus removal on low C/N sewage by using kitchen waste hydrolysis acidification liquid is 28m³Wherein the capacity of the kitchen waste pretreatment device 1 is 2m³The capacity of the hydrolysis acidification device 2 is 5m³The capacity of the chemical precipitation device 3 is 4m³The capacity of the water storage pool 5 is 6m³AAO System 6 has a capacity of 7m³Comprises an anaerobic tank 6.7, an anoxic tank 6.8 and an aerobic tank 6.9 which are communicated in sequence, wherein the anaerobic tank 6.7, the anoxic tank and the aerobic tank are communicated by adopting water flow holes which are staggered up and down, and the capacity of the anaerobic tank 6.7 is 1m³6.8 capacity of anoxic tank 2m³6.9 of aerobic tank with the capacity of 3m³The capacity of the sludge storage tank 8 is 1m³The capacity of the secondary sedimentation tank 7 is 3m³And the device is made by welding stainless steel plates with the thickness of 8 mm. The specific experimental water is prepared by adopting domestic sewage discharged from a certain university dormitory (the pH is 7.2-8.0, the COD is 200-containing organic silicon 250mg/L, the NH4+ -N is 150-containing organic silicon 200mg/L, the C/N is 1.00-1.67, the sludge inoculated by the AAO system is taken from the activated sludge of a certain sewage treatment plant, the hydraulic retention time is 12h, the kitchen waste is taken from 500kg of kitchen waste of a certain university canteen at regular time every day, and the specific operation process is as follows

1, inoculating activated sludge of an urban sewage treatment plant into an AAO system 6, keeping the sludge concentration of 3000-plus 5000mg/L in an anaerobic tank 6.7, an anoxic tank 6.8 and an aerobic tank 6.9, and introducing sewage discharged by a certain university dormitory and configured into a water storage pool 5 every day; then starting an anaerobic tank stirrer 6.1, an anoxic tank stirrer 6.2 and an air compressor 6.3, and respectively controlling the reflux ratio of the nitrifying liquid and the reflux ratio of the sludge to be about 200% and 100%; 6.7 volume of the anaerobic tank, 6.8 volume of the anoxic tank and 6.9 volume of the aerobic tank are 1:2:3, and the flow rate of inlet water is controlled to be 0.5m³The hydraulic retention time of the AAO system 6 is controlled to be 12 h; the DO concentration of an anaerobic pool 6.7 and an aerobic pool 6.9 in the AAO system 6 are controlled to be 0.1-0.2mg/L and 2.0-3.0mg/L respectively.

2, lifting 500kg of kitchen waste collected in a dining room of a college to a pretreatment device 1, screening out impurities of metal, glass and a plastic stool through a sorting device, crushing the kitchen waste into materials with the size of less than or equal to 10mm through a crushing device, conveying the kitchen waste treated by the pretreatment device 1 into a hydrolysis acidification device 2, starting a water replenishing pump 2.3, feeding raw water into the hydrolysis acidification device 2, replenishing water, and adjusting the solid-liquid ratio to be 1:2-1: 5; simultaneously starting an inorganic acid feeding pump 2.4 to ensure that the concentration of the inorganic acid in the hydrolytic acidification reaction is 0.5-1.5 mol/L; starting a heating device 2.1 of the hydrolysis acidification device 2, wherein the heating device 2.1 is connected with a hydrolysis acidification tank body, and heat energy generated by electric heating is transferred into the hydrolysis acidification tank body through the tank body to ensure that the temperature of hydrolysis acidification of the kitchen waste is 90-150 ℃; after hydrolysis acidification is carried out for 2-5h, solid-liquid separation is realized through a solid-liquid separation device 2.2, the solid-liquid separation device 2.2 is provided with a sludge discharge pump 2.9 and a sludge discharge valve 2.6, a water outlet pipe 2.7 of the hydrolysis acidification device 2 is connected with a water inlet 3.7 of a chemical precipitation device 3, the sludge discharge valve 2.6 is communicated with a sludge storage tank 8 through the sludge discharge pump 2.9 and a residue discharge pipe, the large molecular organic matter is hydrolyzed into small molecular organic matter in a short time under the conditions of high temperature and acidity of the kitchen waste, the small molecular organic matter is further hydrolyzed into volatile fatty acid mainly comprising acetic acid, organic nitrogen and organic phosphorus in the kitchen waste are hydrolyzed into inorganic nitrogen and inorganic phosphorus which are released into liquid, and the liquid containing high-concentration nitrogen and phosphorus enters the chemical precipitation device 3 through the water outlet pipe 2.7; starting a phosphate adding pump 3.1 and a magnesium salt adding pump 3.2 of the chemical precipitation device 3 and an alkali liquor adding pump 3.3, controlling the pH value between 8 and 9 in the chemical precipitation process through a pH monitor 9, and controlling the phosphorus-nitrogen ratio to be 1 through a chemical reagent adding device 3.9: 2. magnesium-nitrogen ratio of 1: 1; starting a stirrer for 3.4, stirring at a speed of 100r/min, stirring for 4min, and standing for 3 min; starting a sludge discharge pump 3.6, and discharging residues to a sludge storage tank 8 through a sludge discharge valve 10; and starting a supernatant drainage system 4, and introducing the supernatant into an anaerobic tank 6.7 of the AAO system 6 through a drainage pump 4 by virtue of a water outlet pipe 3.7 of the chemical precipitation device 3.

3 the effluent of the secondary sedimentation tank 7 after the AAO system 6 treats the sewage discharged and configured in a university dormitory passes through a reflux pump at a certain flow rate (3 m)³D) flows into an anaerobic tank 6.7 to be mixed with the kitchen waste hydrolysis acidification liquid, and the effluent of the other secondary sedimentation tanks 7 passes through a water production pump 7.4 to be completely discharged from the waterDischarging through a port 7.1; when the liquid level in the chemical precipitation device 3 is higher than the designated height, the supernatant drainage system 4 is controlled to be opened through a liquid level meter 3.5, the kitchen waste hydrolysis acidification liquid is introduced into the anaerobic tank to provide a carbon source for the AAO system 6, and the flow is controlled to be 0.1m³H; and mixing and diluting the kitchen waste and the residual sludge fermentation liquor with secondary effluent, wherein C/N of the fermentation mixed liquor is 8-12, and C/P of the fermentation mixed liquor is 30-41. The COD of the effluent of the final secondary sedimentation tank 7 is 32.5-47.6mg/L, TN is 6.8-11.5mg/L, and TP is 0.1-0.7 mg/L. All the above parameters meet the emission requirements.

While the foregoing is directed to the preferred embodiment of the present invention, it will be understood that the invention is not limited thereto, and that various modifications and changes can be made by those skilled in the art without departing from the principles of the invention.

Claims (5)

1. A co-processing system for performing nitrogen and phosphorus removal on low C/N sewage by utilizing kitchen waste hydrolysis acidification liquid is characterized by comprising a kitchen waste pretreatment device (1), a hydrolysis acidification device (2), a chemical precipitation device (3), a supernatant drainage system (4), an AAO system (6) and a secondary sedimentation tank (7) which are sequentially communicated, wherein the hydrolysis acidification device (2), the chemical precipitation device (3) and the secondary sedimentation tank (7) are respectively communicated with a sludge storage tank (8), and the AAO system (6) is also communicated with a water storage tank (5); the AAO system (6) comprises an anaerobic tank (6.7), an anoxic tank (6.8) and an aerobic tank (6.9) which are sequentially communicated, wherein the anaerobic tank (6.7), the anoxic tank (6.8) and the aerobic tank (6.9) are communicated by adopting water flow holes which are staggered up and down, the anaerobic tank is communicated with a reservoir (5), a nitrifying liquid reflux pump (7.3) is arranged between the aerobic tank (6.9) and the anoxic tank (6.8), and the nitrifying liquid reflux pump (7.3) is used for refluxing nitrifying liquid in the aerobic tank (6.9) to the anoxic tank (6.8); the supernatant drainage system (4) is communicated with the anaerobic tank (6.7).

2. The system of claim 1, wherein the system comprises a sewage treatment unit, a sewage treatment unit and a sewage treatment unit, wherein the sewage treatment unit comprises: the kitchen waste pretreatment device (1) is composed of a sorting device (1.1) and a crushing device (1.2).

3. The system of claim 1, wherein the system comprises a sewage treatment unit, a sewage treatment unit and a sewage treatment unit, wherein the sewage treatment unit comprises: the hydrolysis acidification device (2) comprises a stirring device (2.5), an inorganic acid feeding pump (2.4), a water replenishing pump (2.3), a heating device (2.1) and a solid-liquid separation device (2.2), and the heating device (2.1) is also provided with a temperature control device (2.8); the solid-liquid separation device (2.2) is provided with a slag discharge valve (2.9) and is communicated with a sludge storage tank (8) through a slag discharge pump (2.6); and a water outlet pipe (2.7) of the hydrolysis acidification device is communicated with the chemical precipitation device (3).

4. The system of claim 1, wherein the system comprises a sewage treatment unit, a sewage treatment unit and a sewage treatment unit, wherein the sewage treatment unit comprises: the chemical precipitation device (3) comprises a liquid level meter (3.5), a chemical reagent adding device (3.9) and a pH monitor (9), wherein the chemical reagent adding device (3.9) comprises a phosphate adding pump (3.1), a magnesium salt adding pump (3.2) and an alkali liquor adding pump (3.3), and the phosphate adding pump (3.1), the magnesium salt adding pump (3.2) and the alkali liquor adding pump (3.3) are sequentially arranged on a water inlet (3.7); the water inlet (3.7) is communicated with the hydrolysis acidification device (2), and the chemical precipitation device is also provided with a stirring device (3.4); the chemical precipitation device bottom still is equipped with mud valve (10), through mud pump (3.6) and storage mud pond (8) intercommunication, the supernatant of chemical precipitation device (3) is carried to AAO system (6) through supernatant drainage system (4).

5. The system of claim 1, wherein the system comprises a sewage treatment unit, a sewage treatment unit and a sewage treatment unit, wherein the sewage treatment unit comprises: an aeration system is arranged in the aerobic tank (6.9); the aeration system is composed of an aeration head (6.5), an air compressor (6.3) and a gas flow regulating valve (6.4), wherein the air compressor (6.3) is connected with the aeration head (6.5) through the gas flow regulating valve (6.4), and the aeration head (6.5) is arranged at the bottom of the aerobic tank (6.9).

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