CN111847798A - Leachate treatment system and method suitable for waste incineration power plant - Google Patents

Leachate treatment system and method suitable for waste incineration power plant Download PDF

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CN111847798A
CN111847798A CN202010760310.9A CN202010760310A CN111847798A CN 111847798 A CN111847798 A CN 111847798A CN 202010760310 A CN202010760310 A CN 202010760310A CN 111847798 A CN111847798 A CN 111847798A
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tank
effluent
treatment
enters
waste incineration
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郭智
刘杰
刘健平
王元月
史振宇
张欣
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CECEP Engineering Technology Research Institute Co Ltd
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    • C02TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
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    • C02FTREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
    • C02F1/00Treatment of water, waste water, or sewage
    • C02F1/28Treatment of water, waste water, or sewage by sorption
    • C02F1/281Treatment of water, waste water, or sewage by sorption using inorganic sorbents
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    • C02F1/30Treatment of water, waste water, or sewage by irradiation
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    • C02F1/00Treatment of water, waste water, or sewage
    • C02F1/52Treatment of water, waste water, or sewage by flocculation or precipitation of suspended impurities
    • C02F1/5236Treatment of water, waste water, or sewage by flocculation or precipitation of suspended impurities using inorganic agents
    • C02F1/5245Treatment of water, waste water, or sewage by flocculation or precipitation of suspended impurities using inorganic agents using basic salts, e.g. of aluminium and iron
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    • C02F1/00Treatment of water, waste water, or sewage
    • C02F1/52Treatment of water, waste water, or sewage by flocculation or precipitation of suspended impurities
    • C02F1/54Treatment of water, waste water, or sewage by flocculation or precipitation of suspended impurities using organic material
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    • C02F1/00Treatment of water, waste water, or sewage
    • C02F1/58Treatment of water, waste water, or sewage by removing specified dissolved compounds
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    • C02F2103/06Contaminated groundwater or leachate
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    • C02FTREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
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    • C02F2301/08Multistage treatments, e.g. repetition of the same process step under different conditions
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    • C02F3/00Biological treatment of water, waste water, or sewage
    • C02F3/02Aerobic processes
    • C02F3/12Activated sludge processes
    • C02F3/1236Particular type of activated sludge installations
    • C02F3/1268Membrane bioreactor systems
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    • C02FTREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
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    • C02F3/28Anaerobic digestion processes
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    • C02F7/00Aeration of stretches of water

Abstract

The invention relates to the technical field of sewage treatment, in particular to a percolate treatment system and method suitable for a waste incineration power plant. The percolate treatment system suitable for the waste incineration power plant comprises an adjusting tank, a hydrolysis acidification tank, a UASB anaerobic reaction tank, an air floatation tank, a sedimentation tank, an analytic deamination tower, an A/O reaction tank, an MBR membrane tank, electron beam irradiation equipment, a coagulation tank, an aeration biological filter and an activated carbon filter which are sequentially connected along the water flow direction. The leachate treatment system suitable for the waste incineration power plant can ensure that the quality of the leachate generated by the waste incineration plant after treatment reaches the emission limit standard of the domestic waste landfill control standard (GB16889 + 2008), and has the advantages of good treatment effect, low cost, stable operation and generation of concentrated phase liquid after no film, so the leachate treatment system has better application and popularization prospects, and can be used for stable production, cost reduction, efficiency improvement, driving protection and navigation of the waste incineration plant.

Description

Leachate treatment system and method suitable for waste incineration power plant
Technical Field
The invention relates to the technical field of sewage treatment, in particular to a percolate treatment system and method suitable for a waste incineration power plant.
Background
The garbage percolate is organic polluted waste water which has complex water quality components, high pollutant concentration, large water quantity and water quality fluctuation and is difficult to treat, and the main source of the garbage percolate is the sanitary landfill and incineration treatment process of municipal domestic garbage. The characteristics of leachate pollutants generated in refuse landfills and incineration plants are different: the leachate generated by the landfill site is generally lower in B/C ratio and higher in ammonia nitrogen concentration (for middle and old aged landfill sites), while the leachate stock solution of an incineration plant is fresh, higher in COD (chemical oxygen demand) and better in B/C ratio. Because the leachate of the incineration plant contains a large amount of macromolecular organic matters which are difficult to degrade, and has high total nitrogen concentration and high toxicity, the landfill leachate can not reach the increasingly strict discharge requirement by using the traditional biochemical process or independently depending on a certain technology to process the landfill leachate. Therefore, it is urgently needed to develop an economic and reasonable technically feasible combined treatment process, efficiently treat the landfill leachate generated in the operation process of the incineration plant up to the standard, and provide stable production, cost reduction, efficiency improvement and driving protection for the incineration plant.
Chinese patent CN110028210A discloses a process for treating landfill leachate based on UASB technology. The leachate enters a UASB anaerobic reactor after being pretreated, and a heating system is arranged in the UASB reactor, so that the automatic heating in the anaerobic reaction process can be realized. And enabling the effluent of the UASB to enter a two-stage A/O biochemical reaction tank. And the effluent of the two-stage A/O enters an ultrafiltration system, a nanofiltration system and a reverse osmosis system to enable the effluent to reach the discharge standard or be recycled. The method is a more conventional combined treatment process for the percolate, and mainly has the problem that concentrated phase liquid after the membrane is difficult to treat.
Chinese patent CN110577333A discloses a new technology for treating leachate. The landfill leachate enters a denitrification and secondary nitrification process after being pretreated and treated by a UASB reactor, and is subsequently treated by an ultrafiltration, DTRO and RO membrane process, so that produced water is recycled. The invention increases the low-pressure reverse osmosis after the high-pressure reverse osmosis, improves the water quality of the reverse osmosis outlet water, but can not properly treat the concentrated solution after the membrane generated by the reverse osmosis unit.
Chinese patent CN110510825A discloses a zero-concentrated-solution landfill leachate treatment method and system. The method mainly removes suspended matters, heavy metals and partial organic matters in water by adding alkali for coagulating sedimentation, simultaneously increases the pH value of the water to more than 10, and then converts ammonia nitrogen in the water into ammonium sulfate by a membrane deamination technology, reduces the concentration of the ammonia nitrogen in the water, and improves the C/N ratio of the effluent. The biochemical process adopts multistage AO + MBR to reduce the concentration of organic matters, ammonia nitrogen and total nitrogen in water, and the tail end uses countercurrent adsorption and dynamic filtration technology to ensure that the effluent reaches the standard and is discharged, and has the characteristics of no generation of concentrated solution, good treatment effect and lower treatment cost. However, the pretreatment process of the method at the front end of the membrane deamination is incomplete, so that the degassing membrane is easily polluted and blocked, the membrane is frequently cleaned, and the stable operation of the system is influenced. The ammonium sulphate solution produced in the deamination stage is of low concentration (not commercially valuable) and requires the additional use of an evaporator to concentrate and crystallize the solution to obtain ammonium sulphate solids, which undoubtedly increases the overall operating costs. The tail end adopts an adsorption and filtration mode to remove the residual pollutants in the water, on one hand, as the pollutant concentration of the MBR effluent is still high, the adsorbent is easy to adsorb and saturate, the adsorbent needs to be frequently regenerated by reforming, and the abraded adsorbent is supplemented and replaced; on the other hand, the filter tank is easy to harden, needs frequent air-water backwashing, and is not easy to replace filter materials. After the costs of adsorbent reforming regeneration, filter material replacement, etc. are distributed, the actual treatment cost will rise.
Disclosure of Invention
Aiming at the defects of the prior art, the invention provides a percolate treatment system and method suitable for a waste incineration power plant, which can ensure that the quality of treated percolate generated by a waste incineration plant reaches the emission limit standard of the control standard of a domestic waste landfill (GB16889 + 2008), and has the advantages of good treatment effect, lower cost, stable operation and generation of concentrated phase liquid without a film, thereby having better application and popularization prospects and being capable of realizing stable operation, cost reduction and efficiency improvement of the waste incineration plant and driving protection.
In order to achieve the purpose, the invention adopts the following technical scheme:
the utility model provides a filtration liquid processing system suitable for msw incineration power plant, includes equalizing basin, hydrolysis-acidification pool, UASB anaerobic reaction jar, air supporting pond, sedimentation tank, analysis deamination tower, AO reaction tank, MBR membrane cisterna, electron beam irradiation equipment, coagulating basin, bological aerated filter and active carbon filtering pond that connect gradually along the rivers direction.
Preferably, among the above-mentioned leachate treatment system who is applicable to the msw incineration power plant, still include sludge dewatering device, UASB anaerobic reaction tank's sludge outlet, the dross export in air supporting pond, the sludge outlet of sedimentation tank, the sludge outlet in A/O reaction tank, the sludge outlet in MBR membrane cisterna, the sludge outlet in coagulation basin all with sludge dewatering device connects.
Preferably, among the above-mentioned leachate treatment system who is applicable to the msw incineration power plant, still include the heat exchanger, the play water of sedimentation tank passes through earlier the heat exchanger is connected to again analysis deamination tower, the play water of the bottom of analysis deamination tower passes through earlier the heat exchanger is connected to again the A/O reaction tank.
Preferably, among the above-mentioned leachate treatment system who is applicable to the msw incineration power plant, the lower part of analysis deamination tower is equipped with steam inlet, the steam inlet of analysis deamination tower is connected with the waste heat steam supply pipe of msw incineration plant.
Preferably, in the leachate treatment system suitable for the waste incineration power plant, a dephlegmator is arranged at the top of the desorption deamination tower, and a gas outlet at the top of the desorption deamination tower is connected to an inlet of the dephlegmator.
Preferably, among the above-mentioned leachate treatment system who is applicable to the msw incineration power plant, the MBR membrane cisterna is external MBR membrane cisterna, be provided with curtain formula MBR membrane module in the external MBR membrane cisterna.
The invention also provides a method for treating the percolate by adopting the percolate treatment system suitable for the waste incineration power plant, which sequentially comprises the following steps of:
(1) the percolate enters a regulating tank to regulate the water quantity and the water quality;
(2) the effluent of the regulating reservoir enters a hydrolysis acidification tank for hydrolysis acidification treatment, and macromolecular organic matters are decomposed into micromolecular organic matters;
(3) the effluent of the hydrolysis acidification tank enters a UASB anaerobic reaction tank for anaerobic treatment;
(4) the effluent of the UASB anaerobic reaction tank enters an air floatation tank for air floatation treatment to remove part of suspended matters and surfactants;
(5) the effluent of the air floatation tank enters a sedimentation tank;
(6) the effluent of the sedimentation tank enters an analytic deamination tower to remove ammonia nitrogen;
(7) the effluent of the resolving deamination tower enters an A/O reaction tank for biochemical treatment;
(8) the effluent of the A/O reaction tank enters an MBR membrane tank for treatment;
(9) the effluent of the MBR membrane tank enters electron beam irradiation equipment for electron beam irradiation treatment;
(10) the effluent of the electron beam irradiation equipment enters a coagulation tank for coagulation treatment;
(11) the effluent of the coagulation tank enters an aeration biological filter for treatment;
(12) and the effluent of the biological aerated filter enters an activated carbon adsorption tank, and is subjected to adsorption treatment by activated carbon in the activated carbon adsorption tank and then is discharged after reaching the standard.
Preferably, in the above method, in the step (7), a steam inlet of the desorption deamination tower is connected to a waste heat steam supply pipeline of a waste incineration plant, and low-temperature and low-pressure steam generated by a waste incineration waste heat boiler is used for negative pressure desorption deamination.
Preferably, in the above method, in the step (10), in the electron beam irradiation device, the energy of electrons accelerated by an accelerator is 0.5 to 5.0MeV, and the irradiation dose is 2 to 15 kGy.
The invention has the following beneficial effects:
(1) the treatment system and the method provided by the invention are utilized to treat the leachate of the waste incineration plant, no membrane concentrated phase liquid is generated, the problem of treatment of the membrane concentrated phase liquid in the existing leachate treatment process is solved, and the treatment system and the treatment method have the advantages of stable operation and guaranteed quality of produced water;
(2) the invention utilizes low-temperature low-pressure steam of the waste incineration plant to carry out negative pressure desorption deamination, has high deamination efficiency and high speed, and can effectively reduce energy consumption and treatment cost. Meanwhile, compared with the traditional ammonia stripping method and ammonia evaporation method, on one hand, alkali is not needed to be added to adjust the pH value in the resolving deamination process, the medicament usage amount and the sludge generation amount are reduced, and the treatment cost of a deamination unit is further reduced; on the other hand, the concentration of the separated ammonia gas is higher, the ammonia water is easy to collect and prepare, the ammonia water can be further used for a flue gas denitration unit of a burning plant, and the treatment cost of the percolate and the overall operation cost of a waste burning plant can be effectively reduced. The C/N ratio of the leachate can be obviously improved by deamination, favorable conditions are created for the subsequent biochemical process, and the hydraulic retention time and aeration energy consumption in the biochemical process section are reduced, so that the treatment cost is reduced.
(3) The strong oxidant is generated by the action of electron beams and water molecules, the refractory organic matters of the leachate are damaged, the B/C ratio in tail water is effectively improved, the advanced treatment efficiency is improved, and the method has the advantages of no secondary pollution and high treatment speed.
Drawings
Figure 1 shows a schematic view of a percolate treatment system according to the invention, suitable for use in a waste incineration power plant.
Detailed Description
For the convenience of understanding, the leachate treatment system and method suitable for a waste incineration power plant according to the present invention will be further described with reference to the drawings and examples, but the scope of the present invention is not limited thereto.
Fig. 1 shows a schematic view of a percolate treatment system according to the invention, suitable for use in a waste incineration power plant, comprising in succession:
(1) a regulating pool: the leachate enters an adjusting tank to adjust the water quantity and the water quality, so that the fluctuation of the production quantity and the water quality of the leachate caused by seasonal changes is reduced, and the balance and the stability of the water quantity and the water quality of a leachate treatment facility are ensured;
(2) a hydrolysis acidification pool: the effluent of the regulating reservoir enters a hydrolysis acidification pool, and the long-chain high molecular polymer in the water is destroyed and degraded in the hydrolysis acidification pool, so that the B/C ratio in the water is improved. After hydrolysis and acidification, the pH value of water is reduced to about 5, and the pH value is adjusted to 6.5-7.0 by using sodium carbonate so as to meet the condition of methanation in the UASB anaerobic reaction tank;
(3) UASB anaerobic reaction jar: the effluent of the hydrolysis acidification tank enters a UASB anaerobic reaction tank to remove most organic matters in the water;
(4) an air floatation tank: and (3) enabling the effluent of the UASB anaerobic reaction tank to enter an air floatation tank, removing a surfactant, floating oil and part of suspended matters which may exist in the effluent, and simultaneously realizing foam separation. The gas-water ratio is controlled to be 10: 1-30: 1, and the ascending flow rate is controlled to be 1.2-3 m/h;
(5) a sedimentation tank: the effluent of the air floatation tank enters a sedimentation tank for solid-liquid separation, so that the SS content in the supernatant is reduced;
(6) resolving the deamination tower: the supernatant of the sedimentation tank exchanges heat with the effluent of the desorption deamination tower in a condenser, and then the temperature of the supernatant is increased and the supernatant enters the desorption deamination tower. The method is characterized in that low-temperature and low-pressure steam (the temperature is 100-130 ℃, the pressure is 0.3-0.5 MPa) generated by a waste incineration plant is utilized, under the condition of negative pressure (0.04-0.08 MPa), alkali is not needed to be added for adjusting the pH value of water, most ammonia nitrogen in the water is removed, the C/N ratio is increased to 6-9: 1, and the subsequent biochemical process is facilitated. The water after deamination and the inlet water of the desorption deamination tower enter a subsequent biochemical unit after heat exchange and temperature reduction in a condenser. Ammonia-containing steam discharged from the top of the desorption and deamination tower is condensed in a partial condenser at the top of the tower to generate ammonia water, and the ammonia water with the concentration of 8-16% is prepared by controlling the reflux amount of the ammonia water and the temperature of the partial condenser at the top of the tower and is used for a flue gas denitration unit of an incineration plant;
for the analytic deamination tower used in the embodiment of the present invention, reference is made to chinese published patent application No. CN110304779A, published in 2019, No. 07, No. 19, in 2019, No. 10, No. 08, which is entitled "a method and a treatment system for materializing deamination of anaerobic effluent of landfill leachate", and the applicant: zhongxiao engineering and technology research institute, ltd. For the sake of brevity, this is incorporated herein by reference, and all technical disclosure of the above-mentioned applications should be considered as part of the technical disclosure of the present application.
(7) A/O + MBR biochemical treatment unit: the effluent of the resolving deamination tower enters an A/O + MBR biochemical treatment unit. The sludge concentration in the A/O reaction tank is 4-6 g/L, the anoxic zone mainly carries out denitrification on nitrate in water, the dissolved oxygen in the anoxic zone is controlled to be 0.2-0.5 mg/L, the aerobic zone removes organic matters in the water and carries out nitration reaction, and the dissolved oxygen in the aerobic zone is controlled to be 3-5 mg/L. The MBR membrane tank is externally arranged, a curtain type MBR ultrafiltration membrane is arranged in the membrane tank, and the membrane flux is 0.1-0.2 m3/(m2·d);
(8) An electron beam irradiation unit: and (3) enabling effluent of the AO + MBR biochemical treatment unit to enter electron beam irradiation equipment, performing electron beam irradiation treatment to generate a large amount of strong oxidant, removing part of COD, most of chroma and peculiar smell in water, and destroying/modifying part of macromolecular organic matters. Selecting an intermediate energy section (0.5-5.0 MeV) by an irradiation source accelerator of the electron beam irradiation equipment, wherein the irradiation dose is 2-15 kGy;
(9) a coagulation tank: and (3) enabling the effluent of the electron beam irradiation equipment to enter a coagulation tank, and adding a certain amount of coagulant to realize solid-liquid separation in the coagulation tank so as to remove suspended matters and partial COD in water. The coagulant is one or more of polymeric ferric sulfate, polymeric aluminum chloride and polyacrylamide, and the adding amount is 0.1-2 g/L;
(10) and (3) aerating the biological filter: the effluent of the coagulation tank enters an aeration biological filter for advanced treatment, and the hydraulic load is 0.3-0.5 m3/(m2·h);
(11) An activated carbon adsorption tank: and (4) the effluent of the biological aerated filter enters an activated carbon adsorption tank, and is subjected to activated carbon adsorption treatment and then is discharged after reaching the standard.
Further, sludge and scum produced by the UASB anaerobic tank, the sedimentation tank, the AO + MBR unit, the coagulation tank and the air flotation tank are collected and dehydrated to the water content of below 60 percent, and then are put into an incinerator of a waste incineration power plant for incineration treatment.
Example 1
The basic water quality of the percolate of a certain garbage incineration plant in Hebei is as follows: the pH value is 6.6-6.8; the COD concentration is 55000-75000 mg/L; the ammonia nitrogen concentration is 660-750 mg/L; the total nitrogen concentration is about 1000-1280 mg/L. The leachate treatment system is utilized to treat leachate, and the specific method comprises the following steps:
1. the percolate enters a regulating tank to regulate the water quantity and the water quality;
2. the effluent of the regulating tank enters a hydrolysis acidification tank, after hydrolysis acidification, the pH value of the water is reduced to 5.3, and the pH value is regulated to 6.9-7.2 by using sodium carbonate so as to meet the condition of methanation produced in the UASB anaerobic reaction tank;
3. the effluent of the hydrolysis acidification tank enters a UASB anaerobic reaction tank to remove most organic matters in the water. The pH value of the effluent is 7.8-8.0, the COD concentration is 9000-10400 mg/L, the ammonia nitrogen concentration is 2350-2700 mg/L, and the SS is 11-14 g/L;
4. the effluent of the UASB anaerobic reaction tank enters an air floatation tank, the air-water ratio is controlled at 20:1, and the ascending flow rate is controlled at 2.2 m/h;
5. the effluent of the air floatation tank enters a sedimentation tank;
6. and after the effluent of the sedimentation tank exchanges heat with the effluent of the desorption deamination tower, the temperature is raised to 45 ℃, and the effluent enters the desorption deamination tower. The low-temperature and low-pressure steam (the temperature is 100-135 ℃, the pressure is 0.3-0.6 MPa) generated by a waste incineration plant is used for providing heat, and deamination is carried out under the conditions that the pressure is 0.068MPa and the water temperature is 78 ℃. The ammonia nitrogen concentration of the water after deamination is reduced to be less than 750mg/L, and the ammonia nitrogen is subjected to heat exchange with inlet water of an analytic deamination tower and is cooled to about 34 ℃, and the ammonia nitrogen enters a subsequent biochemical unit. Condensing ammonia-containing steam discharged from the top of the resolving deamination tower in a partial condenser at the tower top to prepare ammonia water with the concentration of 12%;
7. the effluent of the resolving deamination tower enters an A/O + MBR biochemical treatment unit. The sludge concentration in the A/O reaction tank is 4.5g/L, the dissolved oxygen in the anoxic zone is controlled to be 0.3-0.4 mg/L, and the dissolved oxygen in the aerobic zone is controlled to be 4.2-4.6 mg/L. The membrane flux of the MBR membrane tank is 0.2m3/(m2D), effluent COD is 550-610 mg/L, ammonia nitrogen concentration is 25-40 mg/L, total nitrogen concentration is 65-75 mg/L, total phosphorus is 1-2 mg/L, and pH is 6.6-6.8;
8. and the effluent of the A/O + MBR biochemical unit enters electron beam irradiation equipment. An irradiation source accelerator of the electron beam irradiation equipment is an intermediate energy section (0.5-5.0 MeV), and the irradiation dose is controlled to be 8.7 kGy;
9. feeding the effluent of the electron beam irradiation equipment into a coagulation tank, and sequentially adding polymeric ferric sulfate and polyacrylamide in the amount of 1g/L and 1.5mg/L respectively;
10. the supernatant of the coagulation tank enters an aeration biological filter tank, and the hydraulic load of the filter tank is 0.4m3/(m2·h);
11. The effluent of the aeration biological filter enters an activated carbon adsorption tank, and the final effluent quality has the following main indexes: the pH value is about 7, the COD concentration is 40-48 mg/L, the BOD concentration is 8-12 mg/L, the ammonia nitrogen concentration is 3-6 mg/L, the total nitrogen concentration is about 12-17 mg/L, the total phosphorus concentration is about 0.5-0.9 mg/L, the SS is 16-22 mg/L, and the chromaticity is 20-25, and all the emission limit value standards in the table 3 of the control standard for domestic waste landfill (GB 16889) are met.
In addition, sludge and scum produced by the UASB anaerobic tank, the sedimentation tank, the AO + MBR unit, the coagulation tank and the air flotation tank are collected and dehydrated to the water content of below 60 percent, and then are put into an incinerator for incineration treatment.
Example 2
The basic water quality of the percolate of a certain waste incineration plant in Anhui province is as follows: the pH value is 6.1-6.5; the COD concentration is 50000-65000 mg/L; the ammonia nitrogen concentration is 480-630 mg/L; the total nitrogen concentration is about 910-1200 mg/L.
The leachate was treated as in example 1, with the difference that:
the pH value of the effluent of the adjusting tank is reduced to 5.4, and the pH value is adjusted to 6.8-7.0 by using sodium carbonate;
the air-water ratio of the air floatation tank is controlled at 16:1, and the ascending flow rate is controlled at 3 m/h;
the effluent of the sedimentation tank is subjected to heat exchange with the effluent of the desorption deamination tower, the temperature is raised to 42 ℃, and the effluent enters the desorption deamination tower;
providing heat by using low-temperature and low-pressure steam (the temperature is 100-110 ℃, and the pressure is 0.3-0.4 MPa) generated by a waste incineration plant, and carrying out deamination under the conditions that the pressure is 0.07MPa and the water temperature is 78 ℃;
the sludge concentration in the A/O system is 4.6g/L, the dissolved oxygen in the anoxic zone is controlled to be 0.25-0.35 mg/L, and the dissolved oxygen in the aerobic zone is controlled to be 3.8-4.4 mg/L; the membrane flux of the MBR membrane tank is 0.18m3/(m2·d);
The irradiation dose of the electron beam is controlled to be 9 kGy;
adding polymeric ferric sulfate and polyacrylamide into the coagulation tank, wherein the adding amount is 1.6g/L and 2mg/L respectively;
the hydraulic load in the aeration biological filter is 0.44m3/(m2·h)。
After the leachate is treated, the final effluent quality has the following main indexes: the pH value is about 7.0, the COD concentration is 42-50 mg/L, the BOD concentration is 7.2-14 mg/L, the ammonia nitrogen concentration is 3-6 mg/L, the total nitrogen concentration is 14-17 mg/L, the total phosphorus concentration is 0.5-0.9 mg/L, the SS is 10-20 mg/L, and the chroma is 17-24, and all meet the emission limit standard in table 3 of the control standard of a domestic garbage landfill (GB 16889-2008).
Comparative example 1
Compared with example 1, the difference is only that: the effluent of the UASB anaerobic reaction tank directly enters an analytic deamination tower. The concentration of SS in water is higher, so that the deamination unit is blocked and sludge is deposited after running for a period of time, the treatment effect is reduced, water inlet needs to be stopped, and water scale and sludge in the device are removed.
Comparative example 2
Compared with example 1, the difference is only that: the effluent of the electron beam irradiation equipment directly enters the biological aerated filter. Because the pretreatment is not performed by coagulation, the treatment load of the rear-end biological aerated filter and the activated carbon adsorption tank is increased, the retention time of water in the biological aerated filter and the activated carbon adsorption tank is prolonged, and the regeneration time interval of activated carbon in the activated carbon adsorption tank is shortened.
Although the invention has been described in detail hereinabove by way of general description, specific embodiments and experiments, it will be apparent to those skilled in the art that many modifications and improvements can be made thereto based on the invention. Accordingly, such modifications and improvements are intended to be within the scope of the invention as claimed.

Claims (9)

1. The utility model provides a filtration liquid processing system suitable for msw incineration power plant which characterized in that, includes equalizing basin, hydrolysis-acidification pool, UASB anaerobic reaction jar, air supporting pond, sedimentation tank, analysis deamination tower, AO reaction tank, MBR membrane tank, electron beam irradiation equipment, thoughtlessly congeals pond, biological aerated filter and active carbon filtering pond that connect gradually along the rivers direction.
2. The leachate treatment system suitable for a waste incineration power plant of claim 1, further comprising a sludge dewatering device, wherein the sludge outlet of the UASB anaerobic reaction tank, the scum outlet of the air flotation tank, the sludge outlet of the sedimentation tank, the sludge outlet of the A/O reaction tank, the sludge outlet of the MBR membrane tank, and the sludge outlet of the coagulation tank are connected with the sludge dewatering device.
3. The leachate treatment system suitable for a msw incineration power plant of claim 1, further comprising a heat exchanger, wherein the effluent of the settling tank passes through the heat exchanger before being connected to the desorption deamination tower, and the bottom effluent of the desorption deamination tower passes through the heat exchanger before being connected to the A/O reaction tank.
4. The leachate treatment system suitable for a waste incineration power plant of claim 1, wherein the lower part of the desorption deamination tower is provided with a steam inlet, and the steam inlet of the desorption deamination tower is connected with a residual heat steam supply pipeline of the waste incineration plant.
5. The leachate treatment system suitable for a waste incineration power plant of claim 1, wherein a dephlegmator is disposed at the top of the desorption deamination tower, and a top gas outlet of the desorption deamination tower is connected to an inlet of the dephlegmator.
6. The leachate treatment system suitable for a waste incineration power plant of claim 1, wherein the MBR membrane tank is an external MBR membrane tank, and curtain MBR membrane modules are arranged in the external MBR membrane tank.
7. A method for leachate treatment with a leachate treatment system suitable for a waste incineration power plant according to any of claims 1 to 6, comprising the following steps in sequence:
(1) the percolate enters a regulating tank to regulate the water quantity and the water quality;
(2) the effluent of the regulating reservoir enters a hydrolysis acidification tank for hydrolysis acidification treatment, and macromolecular organic matters are decomposed into micromolecular organic matters;
(3) the effluent of the hydrolysis acidification tank enters a UASB anaerobic reaction tank for anaerobic treatment;
(4) the effluent of the UASB anaerobic reaction tank enters an air floatation tank for air floatation treatment to remove part of suspended matters and surfactants;
(5) the effluent of the air floatation tank enters a sedimentation tank;
(6) the effluent of the sedimentation tank enters an analytic deamination tower to remove ammonia nitrogen;
(7) the effluent of the resolving deamination tower enters an A/O reaction tank for biochemical treatment;
(8) the effluent of the A/O reaction tank enters an MBR membrane tank for treatment;
(9) the effluent of the MBR membrane tank enters electron beam irradiation equipment for electron beam irradiation treatment;
(10) the effluent of the electron beam irradiation equipment enters a coagulation tank for coagulation treatment;
(11) the effluent of the coagulation tank enters an aeration biological filter for treatment;
(12) and the effluent of the biological aerated filter enters an activated carbon adsorption tank, and is subjected to adsorption treatment by activated carbon in the activated carbon adsorption tank and then is discharged after reaching the standard.
8. The method of claim 7, wherein in the step (7), the steam inlet of the desorption deamination tower is connected with a waste heat steam supply pipeline of a waste incineration plant, and low-temperature and low-pressure steam generated by a waste incineration waste heat boiler is used for carrying out negative pressure desorption deamination.
9. The method according to claim 7 or 8, wherein in the step (10), in the electron beam irradiation apparatus, the energy of the electrons accelerated by the accelerator is 0.5 to 5.0MeV, and the irradiation dose is 2 to 15 kGy.
CN202010760310.9A 2020-07-31 2020-07-31 Leachate treatment system and method suitable for waste incineration power plant Pending CN111847798A (en)

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