CN102001791A - Urban sewage strengthening treatment method in cold area based on multi-point feed water adjustment - Google Patents

Urban sewage strengthening treatment method in cold area based on multi-point feed water adjustment Download PDF

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CN102001791A
CN102001791A CN 201010557069 CN201010557069A CN102001791A CN 102001791 A CN102001791 A CN 102001791A CN 201010557069 CN201010557069 CN 201010557069 CN 201010557069 A CN201010557069 A CN 201010557069A CN 102001791 A CN102001791 A CN 102001791A
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pond
detention time
hydraulic detention
water outlet
aerobic
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CN102001791B (en
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赫俊国
韩宝平
刘剑
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Harbin Institute of Technology
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Harbin Institute of Technology
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Abstract

The invention discloses an urban sewage strengthening treatment method in a cold area based on multi-point feed water adjustment, which relates to an urban sewage strengthening treatment method and solves the problems of incapability of synchronous and efficient denitrogenation and dephosphorization, poor treatment effect, high running cost and unsuitability for treating urban sewage in the cold area in the traditional technology of treating the urban sewage. The method comprises the following steps of: firstly, primary precipitation of sewage: dividing effluent of a primary settling tank into two parts or three parts through a distribution well for distribution; and secondly, synchronously introducing the effluent mixing liquid of an anaerobic tank and an anoxic tank 1 and the reflowing sludge at the head end of an aerobic tank into the aerobic tank, introducing the effluent of the aerobic tank into an anoxic tank 2, introducing the effluent of the anoxic tank 2 into a secondary settling tank through water drop, discharging a supernatant as treated purified water, reflowing a part of sludge at the lower layer, and discharging the rest as the remaining sludge. The invention can synchronously carry out efficient denitrogenation and dephosphorization, has favorable treatment effect and low running cost and is suitable for treating the urban sewage in the cold area.

Description

A kind of Municipal Wastewater in Cold Region enhanced processing method based on the multipoint water feeding regulation and control
Technical field
The present invention relates to a kind of sewage in urban area treatment process.
Background technology
At present, biological activity mud method is mainly adopted in municipal sewage treatment, and biological activity mud method has a variety of treatment process, and the processing method that often has has, common aeration, A-B method, A/O technology, A 2/ O denitrification dephosphorization technique, oxidation ditch process etc.A 2/ O technology as the simplest synchronous denitrogen dephosphorus technology in system, and is widely used in the domestic and international municipal effluent biological carbon and phosphorous removal sewage work with advantages such as its effect stability, wide adaptabilities.
But this technology coexists as anaerobism, anoxic and aerobic three kinds of different envrionment conditions alternate runs and different types of microorganism species such as polyP bacteria, denitrifying bacteria, nitrifier in the same sludge system, cause two big contradictions, on the one hand, nitrifier, the different mud age of denitrifying bacteria and polyP bacteria and carbon source battle, the nitrate that carries in the returned sluge has also suppressed the release of phosphorus under the anaerobic condition simultaneously, this mutual restriction effect of result, cause the denitrogenation dephosphorizing efficient of this technology to be difficult to further improve, finally cause the contradiction of denitrogenation and dephosphorization opposition; On the other hand, nitrobacteria belongs to aerobic bacteria, is back to the oxygen-starved area through nitrification liquid, its activity is suppressed, the denitrifying bacterium environmental optima is an anaerobic environment, and the process aerobic zone can influence the activity of denitrifying bacterium, takes the photograph the phosphorus bacterium and under anaerobic releases phosphorus, aerobic condition is inhaled phosphorus, but pass through the oxygen-starved area nonsensical to dephosphorization, phosphorus bacterium performance is taken the photograph in influence, and three kinds of bacteriums have the suitableeest separately dissolved oxygen, all can suppress bacterial activity through other zones, influence the denitrogenation dephosphorizing effect.In addition,, be back to the oxygen-starved area by nitrification liquid and carry out denitrification, not only limit the clearance of TN (total nitrogen content), and increased the power working cost because anaerobic/anoxic/aerobic layout forms.
In addition, north cold area municipal effluent temperature is low, cause the interior microorganism active of Sewage treatment systems poor, the denitrogenation dephosphorizing effect is undesirable, therefore how to study a kind of Municipal Wastewater in Cold Region synchronous denitrification dephosphorizing treatment process, overcome the contradiction between the denitrogenation dephosphorizing removal, make cold district sewage reach denitrogenation dephosphorizing and steady running efficiently simultaneously, this is present problem demanding prompt solution.
Summary of the invention
The present invention seeks to for solve the technology that adopts existing Treating Municipal Sewage exist can't synchronous high-efficiency denitrogenation dephosphorizing, poor processing effect, working cost high and be not suitable for the problem of Treatment of Municipal Wastewater in Cold Region, and a kind of Municipal Wastewater in Cold Region enhanced processing method that provides based on the multipoint water feeding regulation and control.
Municipal Wastewater in Cold Region enhanced processing method based on the multipoint water feeding regulation and control carries out according to the following steps: one, sewage is carried out preliminary sedimentation, hydraulic detention time is 0.5~1.0h, by distributing well preliminary sedimentation tank water outlet separated into two parts or three parts is distributed then; Two, anaerobic pond and anoxic pond 1 go out water mixed liquid and 30%~50% Aerobic Pond head end returned sluge enters Aerobic Pond simultaneously, hydraulic detention time is 4.0~6.0h, the Aerobic Pond water outlet enters anoxic pond 2, hydraulic detention time is 0.5~1.0h, anoxic pond 2 water outlets enter through drop carries out mud-water separation in the second pond, hydraulic detention time is 2.0~3.0h, dissolved oxygen concentration is 1.3~1.7mg/L, supernatant liquor is as the discharge of handling of purifying waste water, the part mud of lower floor is refluxed, and all the other are as excess sludge discharge;
Wherein preliminary sedimentation tank water outlet separated into two parts distributes (two portions are 100% altogether) in the step 1, promptly (Aerobic Pond water outlet COD is 80~150mg/L) under the competent condition of carbon source, 20%~50% preliminary sedimentation tank water outlet and anaerobism returned sluge enter anaerobic pond simultaneously, hydraulic detention time is 1.0~1.5h, the nitrification liquid that 50%~80% preliminary sedimentation tank water outlet and 100%~300% Aerobic Pond reflux enters anoxic pond 1 simultaneously, and hydraulic detention time is 1.0~1.5h;
The preliminary sedimentation tank water outlet is divided into three parts and distributes (three parts are 100% altogether) in the step 1, promptly (Aerobic Pond water outlet COD is 40~80mg/L) under the insufficient condition of carbon source, 20%~50% preliminary sedimentation tank water outlet and anaerobism returned sluge enter anaerobic pond simultaneously, hydraulic detention time is 1.0~1.5h, the nitrification liquid that 30%~50% preliminary sedimentation tank water outlet and 100%~300% Aerobic Pond reflux enters anoxic pond 1 simultaneously, hydraulic detention time is 1.0~1.5h, 20%~30% preliminary sedimentation tank water outlet and Aerobic Pond go out water mixed liquid and enter anoxic pond 2 jointly, and hydraulic detention time is 0.5~1.0h;
In the step 2 part mud of lower floor being refluxed, is 5%~30% to be back to anaerobic pond, and 30%~50% is back to the Aerobic Pond head end.
Advantage of the present invention: 1, sewage is assigned to anaerobic pond and anoxic pond 1 with certain proportion, increased the residence time of sewage in anaerobic pond and anoxic pond 1, if the residence time of technology is designed routinely, then can reduce the volume of anaerobic pond and anoxic pond 1, save construction cost;
2, sewage is assigned to anaerobic pond and anoxic pond 1 with certain proportion, efficiently solves carbon source contradiction in the common process, make the anaerobism section release carbon source abundance in phosphorus process and the anoxic section denitrification process, improve the denitrogenation dephosphorizing effect; The mud that is back to anaerobic pond reflux to adopt 5%~30% than low reflux ratio, can reach the purpose of dephosphorization; The mud that is back to the Aerobic Pond head end refluxes and adopts 30%~50%, and nitrification liquid refluxes and adopts 100%~300%, can reach good denitrogenation;
3, sewage is assigned to anaerobic pond and anoxic pond 1 with certain proportion, efficiently solves the contradiction of sludge age in the common process, can be fit to the different mud age of denitrogenation and dephosphorization, improve the denitrogenation dephosphorizing effect by the water distribution ratio control;
4, increased the return-flow system that is back to the Aerobic Pond head end from second pond mud, reduced the residence time of nitrobacteria under the low dissolved axygen environment, make nitrobacteria promptly be back to Aerobic Pond without anaerobism and anoxic process, guaranteed the aerobic condition of nitrobacteria, cultivated the obligate nitrobacteria, keep the high-effect of nitrobacteria, improved the nitrification effect of Aerobic Pond;
5, behind Aerobic Pond, establish an anoxic pond 2, can further carry out denitrification, solved the problem of utilizing nitrification liquid backflow carrying out denitrification restricted T N clearance, reduce nitrate concentration, improve the TN clearance;
6, establish an anoxic pond 2 behind Aerobic Pond, reduce nitrate concentration, the nitrate that the backflow of minimizing anaerobic sludge is carried improves the removal effect of phosphorus to the influence of anaerobic phosphorus release;
7, behind Aerobic Pond, establish an anoxic pond 2, further carry out denitrification, can reduce the nitrification liquid reflux ratio of Aerobic Pond, can guarantee denitrogenation, can reduce the power working cost again to anoxic pond 1;
8, set up filler in anoxic pond, fixedly denitrifying bacterium makes denitrifying bacterium be in anoxia condition, is not subjected to the influence of dissolved oxygen, can increase denitrifying bacterium quantity and denitrification effect;
9, set up filler at Aerobic Pond, be used for fixing microorganism, form the compound worker's technology of microbial film-active sludge, biomass in the increase system improves the denitrogenation dephosphorizing effect;
10, establish the partition wall classification in the Aerobic Pond, the perforate of neighboring walls subtend makes it to form the plug-flow processing form, makes the mixed solution uniform mixing that fluctuates up and down, increases treatment effect.
11, present method adopts reinforcing mass transfer, adds the built-up type fibrous packing, increases and throw measures such as the mud backflow reinforcement biological treatment of second pond to the Aerobic Pond head end, effectively improve the Municipal Wastewater in Cold Region treatment effect, steady running, the problem of solution low-temperature sewage synchronous denitrification dephosphorizing weak effect.
Description of drawings
Fig. 1 is based on the technological principle synoptic diagram of the intensive treatment of the Municipal Wastewater in Cold Region of multipoint water feeding regulation and control in the embodiment one.
Embodiment
Technical solution of the present invention is not limited to following cited embodiment, also comprises the arbitrary combination between each embodiment.
Embodiment one: in conjunction with shown in Figure 1, present embodiment is carried out according to the following steps based on the Municipal Wastewater in Cold Region enhanced processing method of multipoint water feeding regulation and control: one, sewage is carried out preliminary sedimentation, hydraulic detention time is 0.5~1.0h, by distributing well preliminary sedimentation tank water outlet separated into two parts or three parts is distributed then; Two, anaerobic pond and anoxic pond 1 go out water mixed liquid and 30%~50% Aerobic Pond head end returned sluge enters Aerobic Pond simultaneously, hydraulic detention time is 4.0~6.0h, the Aerobic Pond water outlet enters anoxic pond 2, hydraulic detention time is 0.5~1.0h, anoxic pond 2 water outlets enter through drop carries out mud-water separation in the second pond, hydraulic detention time is 2.0~3.0h, dissolved oxygen concentration is 1.3~1.7mg/L, supernatant liquor is as the discharge of handling of purifying waste water, the part mud of lower floor is refluxed, and all the other are as excess sludge discharge;
Wherein preliminary sedimentation tank water outlet separated into two parts distributes (two portions are 100% altogether) in the step 1, promptly (Aerobic Pond water outlet COD is 80~150mg/L) under the competent condition of carbon source, 20%~50% preliminary sedimentation tank water outlet and anaerobism returned sluge enter anaerobic pond simultaneously, hydraulic detention time is 1.0~1.5h, the nitrification liquid that 50%~80% preliminary sedimentation tank water outlet and 100%~300% Aerobic Pond reflux enters anoxic pond 1 simultaneously, and hydraulic detention time is 1.0~1.5h;
The preliminary sedimentation tank water outlet is divided into three parts and distributes (three parts are 100% altogether) in the step 1, promptly (Aerobic Pond water outlet COD is 40~80mg/L) under the insufficient condition of carbon source, 20%~50% preliminary sedimentation tank water outlet and anaerobism returned sluge enter anaerobic pond simultaneously, hydraulic detention time is 1.0~1.5h, the nitrification liquid that 30%~50% preliminary sedimentation tank water outlet and 100%~300% Aerobic Pond reflux enters anoxic pond 1 simultaneously, hydraulic detention time is 1.0~1.5h, 20%~30% preliminary sedimentation tank water outlet and Aerobic Pond go out water mixed liquid and enter anoxic pond 2 jointly, and hydraulic detention time is 0.5~1.0h;
In the step 2 part mud of lower floor being refluxed, is 5%~30% to be back to anaerobic pond, and 30%~50% is back to the Aerobic Pond head end.
Carrying out preliminary sedimentation in the present embodiment step 1 is in order to remove large granular impurity.
Preliminary sedimentation tank water outlet separated into two parts or three parts are distributed in the present embodiment step 1, it is to carry out anaerobic phosphorus release that preliminary sedimentation tank water outlet and anaerobism returned sluge enter anaerobic pond simultaneously, it is to become nitrogen to discharge the nitrate denitrification that the preliminary sedimentation tank water outlet enters anoxic pond 1 simultaneously with the nitrification liquid that Aerobic Pond refluxes, preliminary sedimentation tank water outlet and Aerobic Pond go out water mixed liquid and enter anoxic pond 2 jointly, can make anoxic pond 2 have sufficient nutritive substance further to carry out denitrification.
Dissolved oxygen concentration is 1.3~1.7mg/L in the present embodiment step 2, can prevent anaerobic phosphorus release.
The BOD sludge loading is 0.1~0.2kgBOD5/kgMLSS.d in the present embodiment.
Adopt multiple spot cycle control mode in the present embodiment, the nitrification liquid that promptly removes the Aerobic Pond backflow enters anoxic pond 1, second pond mud is except that some is back to anaerobic pond, some is back to the Aerobic Pond head end, wherein the second pond mud that is back to anaerobism and Aerobic Pond head end can adopt same set of reflux, enter two return lines, promptly amount to two cover return-flow systems, three cover backflow pipelines.
Present embodiment is process object with the municipal effluent, mainly removes organism, nitrogen and phosphorus.
Embodiment two: what present embodiment and embodiment one were different is that sewage carries out preliminary sedimentation in the step 1, and hydraulic detention time is 0.6~0.9h.Other step and parameter are identical with embodiment one.
Embodiment three: what present embodiment and embodiment one were different is that sewage carries out preliminary sedimentation in the step 1, and hydraulic detention time is 0.8h.Other step and parameter are identical with embodiment one.
Embodiment four: present embodiment is different with one of embodiment one to three be in the step 2 anaerobic pond and anoxic pond 1 go out water mixed liquid and 35%~45% Aerobic Pond head end returned sluge enters Aerobic Pond simultaneously, hydraulic detention time is 4.5~5.5h, the Aerobic Pond water outlet enters anoxic pond 2, hydraulic detention time is 0.6~0.9h, anoxic pond 2 water outlets enter through drop carries out mud-water separation in the second pond, hydraulic detention time is 2.2~2.8h, and guarantor's dissolved oxygen is 1.4~1.6mg/L.Other step and parameter are identical with one of embodiment one to three.
Embodiment five: present embodiment is different with one of embodiment one to three be in the step 2 anaerobic pond and anoxic pond 1 go out water mixed liquid and 40% Aerobic Pond head end returned sluge enters Aerobic Pond simultaneously, hydraulic detention time is 5.0h, the Aerobic Pond water outlet enters anoxic pond 2, hydraulic detention time is 0.8h, anoxic pond 2 water outlets enter through drop carries out mud-water separation in the second pond, hydraulic detention time is 2.5h, and guarantor's dissolved oxygen is 1.5mg/L.Other step and parameter are identical with one of embodiment one to three.
Embodiment six: present embodiment is different with one of embodiment one to five is that anoxic pond 1 and anoxic pond 2 are set up the built-up type fibrous packing in the step 2, form by soft fiber bundle, high molecular polymerization plastics ring plate and axial cord, the carrier profile is circular, outside diameter is 80mm, thick 3mm.Other step and parameter are identical with one of embodiment one to five.
Set up filler in the present embodiment, fixedly denitrifying bacterium makes denitrifying bacterium be in anoxia condition, is not subjected to the influence of dissolved oxygen, can increase denitrifying bacterium quantity and nitrification effect.
Embodiment seven: what present embodiment was different with one of embodiment one to six is to increase throwing built-up type fibrous packing at Aerobic Pond in the step 2, form by soft fiber bundle, high molecular polymerization plastics ring plate and axial cord, the carrier profile is circular, and outside diameter is 80mm, thick 3mm.Its step and parameter are identical with one of embodiment one to six.
Set up filler in the present embodiment, but fixation of microbe forms microbial film-active sludge recombining process, the denitrogenation dephosphorizing effect of consolidation system.
Embodiment eight: what present embodiment was different with one of embodiment one to seven is that anaerobic pond adopts the stirring of alr mode mixing under water in the step 2; Anoxic pond 1 and anoxic pond 2 adopt and stir under water and weak aeration mode; Aerobic Pond is provided with aerating apparatus, and Aerobic Pond establishes the partition wall classification, makes it to form the plug-flow processing form, makes the mixed solution uniform mixing that fluctuates up and down.Its step and parameter are identical with one of embodiment one to seven.
Present embodiment makes sewage be in turbulent motion in total system in order to the mass transfer process of enhanced sewage, control Re 〉=1200, or adopt whipping appts, control power of agitator 〉=0.5W/m 3

Claims (8)

1. Municipal Wastewater in Cold Region enhanced processing method based on multipoint water feeding regulation and control, it is characterized in that carrying out according to the following steps: one, sewage is carried out preliminary sedimentation based on the Municipal Wastewater in Cold Region enhanced processing method of multipoint water feeding regulation and control, hydraulic detention time is 0.5~1.0h, by distributing well preliminary sedimentation tank water outlet separated into two parts or three parts is distributed then; Two, anaerobic pond and anoxic pond (1) go out water mixed liquid and 30%~50% Aerobic Pond head end returned sluge enters Aerobic Pond simultaneously, hydraulic detention time is 4.0~6.0h, the Aerobic Pond water outlet enters anoxic pond (2), hydraulic detention time is 0.5~1.0h, anoxic pond (2) water outlet enters through drop carries out mud-water separation in the second pond, hydraulic detention time is 2.0~3.0h, dissolved oxygen concentration is 1.3~1.7mg/L, supernatant liquor is as the discharge of handling of purifying waste water, the part mud of lower floor is refluxed, and all the other are as excess sludge discharge;
Wherein preliminary sedimentation tank water outlet separated into two parts distributes (two portions are 100% altogether) in the step 1, promptly under the competent condition of carbon source, COD is at 80~150mg/L in the Aerobic Pond water outlet, 20%~50% preliminary sedimentation tank water outlet and anaerobism returned sluge enter anaerobic pond simultaneously, hydraulic detention time is 1.0~1.5h, the nitrification liquid that 50%~80% preliminary sedimentation tank water outlet and 100%~300% Aerobic Pond reflux enters anoxic pond (1) simultaneously, and hydraulic detention time is 1.0~1.5h;
The preliminary sedimentation tank water outlet is divided into three parts and distributes (three parts are 100% altogether) in the step 1, promptly under the insufficient condition of carbon source, COD is at 40~80mg/L in the Aerobic Pond water outlet, 20%~50% preliminary sedimentation tank water outlet and anaerobism returned sluge enter anaerobic pond simultaneously, hydraulic detention time is 1.0~1.5h, the nitrification liquid that 30%~50% preliminary sedimentation tank water outlet and 100%~300% Aerobic Pond reflux enters anoxic pond (1) simultaneously, hydraulic detention time is 1.0~1.5h, 20%~30% preliminary sedimentation tank water outlet and Aerobic Pond go out water mixed liquid and enter anoxic pond (2) jointly, and hydraulic detention time is 0.5~1.0h;
In the step 2 part mud of lower floor being refluxed, is 5%~30% to be back to anaerobic pond, and 30%~50% is back to the Aerobic Pond head end.
2. a kind of Municipal Wastewater in Cold Region enhanced processing method based on the multipoint water feeding regulation and control according to claim 1 is characterized in that sewage carries out preliminary sedimentation in the step 1, and hydraulic detention time is 0.6~0.9h.
3. a kind of Municipal Wastewater in Cold Region enhanced processing method based on the multipoint water feeding regulation and control according to claim 1 is characterized in that sewage carries out preliminary sedimentation in the step 1, and hydraulic detention time is 0.8h.
4. according to claim 1,2 or 3 described a kind of Municipal Wastewater in Cold Region enhanced processing methods based on the multipoint water feeding regulation and control, it is characterized in that anaerobic pond and anoxic pond (1) in the step 2 go out water mixed liquid and 35%~45% Aerobic Pond head end returned sluge enters Aerobic Pond simultaneously, hydraulic detention time is 4.5~5.5h, the Aerobic Pond water outlet enters anoxic pond (2), hydraulic detention time is 0.6~0.9h, anoxic pond (2) water outlet enters through drop carries out mud-water separation in the second pond, hydraulic detention time is 22~2.8h, and guarantor's dissolved oxygen is 1.4~1.6mg/L.
5. according to claim 1,2 or 3 described a kind of Municipal Wastewater in Cold Region enhanced processing methods based on the multipoint water feeding regulation and control, it is characterized in that anaerobic pond and anoxic pond (1) in the step 2 go out water mixed liquid and 40% Aerobic Pond head end returned sluge enters Aerobic Pond simultaneously, hydraulic detention time is 5.0h, the Aerobic Pond water outlet enters anoxic pond (2), hydraulic detention time is 0.8h, anoxic pond (2) water outlet enters through drop carries out mud-water separation in the second pond, hydraulic detention time is 2.5h, and guarantor's dissolved oxygen is 1.5mg/L.
6. a kind of Municipal Wastewater in Cold Region enhanced processing method according to claim 5 based on the multipoint water feeding regulation and control, it is characterized in that anoxic pond in the step 2 (1) and anoxic pond (2) set up the built-up type fibrous packing, form by soft fiber bundle, high molecular polymerization plastics ring plate and axial cord, the carrier profile is circular, outside diameter is 80mm, thick 3mm.
7. a kind of Municipal Wastewater in Cold Region enhanced processing method according to claim 6 based on the multipoint water feeding regulation and control, it is characterized in that increasing throwing built-up type fibrous packing at Aerobic Pond in the step 2, form by soft fiber bundle, high molecular polymerization plastics ring plate and axial cord, the carrier profile is circular, outside diameter is 80mm, thick 3mm.
8. a kind of Municipal Wastewater in Cold Region enhanced processing method based on the multipoint water feeding regulation and control according to claim 7 is characterized in that anaerobic pond adopts the stirring of alr mode mixing under water in the step 2; Anoxic pond (1) and anoxic pond (2) adopt and stir under water and weak aeration mode; Aerobic Pond is provided with aerating apparatus, and Aerobic Pond establishes the partition wall classification, makes it to form the plug-flow processing form, makes the mixed solution uniform mixing that fluctuates up and down.
CN2010105570696A 2010-11-24 2010-11-24 Urban sewage strengthening treatment method in cold area based on multi-point feed water adjustment Expired - Fee Related CN102001791B (en)

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Cited By (5)

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Publication number Priority date Publication date Assignee Title
CN102557342A (en) * 2011-12-28 2012-07-11 广州市市政工程设计研究院 Process and device for treating sewage through denitrification and dephosphorization by anaerobic-anoxic-oxic-anoxic (AAOA) plus membrane bioreactor (MBR) process
CN103253768A (en) * 2013-04-11 2013-08-21 李思敏 Multi-point water feeding town sewage treatment system and treatment method thereof
CN105084672A (en) * 2015-08-22 2015-11-25 哈尔滨金大环境工程有限公司 Sectional-water-inlet A/O (anoxic/oxic) composite sewage treatment plant and sewage treatment method
CN106315969A (en) * 2015-06-25 2017-01-11 麦王环境技术股份有限公司 Integrated wastewater treatment equipment of IBR (integral biological reactor) and treatment process
CN111217447A (en) * 2019-11-29 2020-06-02 段林卓 Process and device for treating sewage of outdoor flush toilet in alpine region

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CN101012093A (en) * 2007-01-22 2007-08-08 华中科技大学 Integral synchronous denitrification dephosphorizing bioreactor
CN101041533A (en) * 2007-02-28 2007-09-26 沈阳化工学院 Denitrogenation dephosphorizing technique for integral sewage treatment
CN101811801A (en) * 2010-04-02 2010-08-25 江苏江华水处理设备有限公司 Direct-flow biological nitrogen removal sewage treatment method

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* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN101012093A (en) * 2007-01-22 2007-08-08 华中科技大学 Integral synchronous denitrification dephosphorizing bioreactor
CN101041533A (en) * 2007-02-28 2007-09-26 沈阳化工学院 Denitrogenation dephosphorizing technique for integral sewage treatment
CN101811801A (en) * 2010-04-02 2010-08-25 江苏江华水处理设备有限公司 Direct-flow biological nitrogen removal sewage treatment method

Cited By (7)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN102557342A (en) * 2011-12-28 2012-07-11 广州市市政工程设计研究院 Process and device for treating sewage through denitrification and dephosphorization by anaerobic-anoxic-oxic-anoxic (AAOA) plus membrane bioreactor (MBR) process
CN103253768A (en) * 2013-04-11 2013-08-21 李思敏 Multi-point water feeding town sewage treatment system and treatment method thereof
CN106315969A (en) * 2015-06-25 2017-01-11 麦王环境技术股份有限公司 Integrated wastewater treatment equipment of IBR (integral biological reactor) and treatment process
CN105084672A (en) * 2015-08-22 2015-11-25 哈尔滨金大环境工程有限公司 Sectional-water-inlet A/O (anoxic/oxic) composite sewage treatment plant and sewage treatment method
CN105084672B (en) * 2015-08-22 2017-09-22 哈尔滨金大环境工程有限公司 Subsection water inflow A/O composite sewage treatment equipments and sewage water treatment method
CN111217447A (en) * 2019-11-29 2020-06-02 段林卓 Process and device for treating sewage of outdoor flush toilet in alpine region
CN111217447B (en) * 2019-11-29 2022-06-03 段林卓 Process and device for treating sewage of outdoor flush toilet in alpine region

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