UASB反应器处理生活污水的试验研究

采用UASB中试（100m^3／d）对生活污水处理进行了研究。试验结果表明，采用此系统处理生活污水，出水水质良好。COD的去除率在52％-83％，出水的COD值〈100mg／L以下，SS的去除率在95％左右，UASB处理生活污水的最佳停留时间为6h。产气率在0．1m^3／d。不管停留时间在10h、5h，出水的氨氮、乙酸值比进水的高；钙、镁、总氮、总磷、硫酸根和硝酸根离子出水值比进水值低。     

UASB处理硫酸盐有机废水的启动

为了考察上流式厌氧污泥床反应器(UASB)处理含硫酸盐有机废水的特性,采用有效容积为10 L的UASB,研究了启动运行过程中COD和SO2-4降解情况、出水VFA和pH值、产气量及颗粒污泥比产甲烷活性(SMA)变化状况。结果表明,接种厌氧颗粒污泥,保持进水COD为1 500 mg/L,SO2-4浓度为100 mg/L,将HRT由24 h缩短至12 h以提高负荷,经历55 d成功启动了UASB反应器;当HRT为12 h,进水COD和SO2-4负荷为3.0 kg/(m3·d)和0.20 kg/(m3·d),COD和SO2-4的去除率分别达到80%和89%,出水VFA为3 mmol/L,产气量达9.5 L/d,颗粒污泥的SMA为86.4 mL/(g VSS·d)。     

厌氧颗粒污泥膨胀床（EGSB）处理生活污水试验研究

采用厌氧颗粒污泥膨胀床（EGSB）反应器在常温下处理小区生活污水，接种颗粒污泥。试验结果表明：当进水COD 411～560 mg/L，反应器容积负荷可达到3 kg COD/(m³·d)，水力停留时间4 h，上升流速8 m/h，COD去除率可达到85%以上，出水COD为67～88 mg/L。并对EGSB反应器的结构及运行控制参数进行了优化，使其适宜于在常温下处理生活污水及其他低浓度有机废水。     

大型UASB处理阿维菌素废水厌氧污泥颗粒化研究

采用大型UASB反应器处理阿维菌素废水,接种好氧絮状污泥,经过189 d运行,成功实现了厌氧污泥颗粒化.通过调节反应器进水水质控制进水中阿维菌素浓度和长时间培养驯化,阿维菌素对厌氧消化的抑制影响基本消除.UASB反应器进水pH值4～5、COD 8890～12 100 mg/L、容积负荷达到10.5 kg COD/m3·d,COD去除率稳定在85%以上,出水COD为1308～1670 mg/L.     

外循环式UASB反应器处理槟榔废水

在中温（35±2℃）条件下,利用外循环式UASB反应器处理中高有机浓度的槟榔加工废水,并着重探讨了水力停留时间（HRT）对厌氧消化的影响。研究表明,当反应器稳定运行,水力停留时间为1 d,进水COD浓度5 000 mg/L左右,容积负荷在2.53-5.25 kg COD/（m3·d）时,COD去除率在38%以上,出水COD〈3 000 mg/L,平均产气率为0.41 m3/kg COD;若水力停留时间延长至4 d,容积负荷为1.26-1.30 kg COD/（m3·d）,COD去除率可以达到79%,出水COD〈1 200 mg/L,出水可生化性下降,BOD5/COD平均为0.28,实验取得了良好的处理效果,为利用厌氧技术处理槟榔加工废水提供了设计依据。     

厌氧折流板反应器处理生活污水的运行特性

以厌氧消化污泥作为厌氧折流板反应器ABR的接种污泥,研究恒温(35℃)条件下ABR处理生活污水的启动和运行特性。实验结果表明,ABR反应器仅用了39 d就完成初次启动,COD去除率一直稳定在60%左右。在以后运行的5个阶段里,即当水力停留时间为4~10 h,容积负荷为1.17~2.9 kg COD/m3.d,反应器对COD的平均去除率基本稳定在70.49%~80.2%;并且当HRT=7 h,VRL=1.612 kg COD/m3.d时,反应器对COD的去除率平均高达80.2%,平均COD出水低于100 mg/L。在实验过程中(除启动阶段外),反应器出水碱度均远远大于进水碱度,VFA均在1.5 mmol/L以下。     

低温条件下摇动床生物膜反应器处理生活污水的中试研究

采用摇动床生物膜反应器,在中国北方冬春季5～10℃的低温条件下,以城市生活污水处理厂的二级处理出水为水源进行了工作体积4.8 m3的反应器深度处理的中试研究。中试过程以COD、NH4+-N和浊度的去除率为考察指标。实验结果表明:反应器对生活污水深度处理的合适的工艺参数为进水温度10℃,停留时间(HRT)4.8 h,气水比4∶1,曝气量4 m3/h,水流量1.0 m3/h,采用每间隔4 h曝气4 h的间歇式曝气方式;在低温条件下,对污水的COD和NH4+-N的去除率分别为30%和50%,而对浊度的去除率较低。中试表明,摇动床生物膜反应器可应用于中国北方冬春季低温条件下对水中COD和NH4+-N的去除。     

天然色素生产废水的生物处理研究

天然色素生产废水是一种色度大、难处理的高浓度有机废水,为了寻找该废水的有效处理方法,本文作者采用由升流式厌氧污泥床(UASB)、生物接触氧化、混凝吸附组成的废水处理工艺,对该废水进行了处理试验,结果表明,对稀释4倍的原水,当进水COD为14900mg/L左右时,UASB经过36h的水力停留时间,COD的去除率为58.2%～60.2%、出水色度为180～270倍,SS为119～126mg/L,pH值为6.5～6.8;UASB出水经过24h好氧生物接触氧化反应,COD的去除率超过90%,SS<70mg/L;最终经过Ca(ClO)2氧化和煤渣吸附深度处理,脱色可至无色,出水COD为200mg/L以下。UASB生物接触氧化氧化吸附组合处理工艺处理该类天然色素生产废水是可行的。     

兼氧接触氧化与土地渗滤联合处理农村污水的研究

采用兼氧接触氧化与土地渗滤联合处理工艺对农村混合污水进行了试验.结果表明,系统对污染物有良好的去除效果.在进水COD 397～564 mg/L条件下,兼氧接触氧化水力停留时间为24 h时COD去除率大于75%;经过土地渗滤系统处理,在0.02 m3/(m2·d)的水力负荷下,COD去除率大于60%,氨氮、总磷的去除率大于99%.     

颗粒污泥接种UASB反应器处理木糖醇废水试验研究

采用颗粒污泥接种UASB厌氧反应器处理木糖醇生产废水,对废水进行预调配后,由电控柜控制间歇进水.试验结果表明在进水COD为3～5g/L,COD容积负荷在2.70～4.64 kg/(m3·d)的范围时,有机污染物的去除率可稳定地保持在76%～88%,对厌氧出水再进行普通活性污泥法好氧后处理,出水COD可达到100 ms/L以下,稳定地达到国家要求的废水一级排放标准.     

Performance of a submerged membrane bioreactor system for biological nutrient removal.

A pilot submerged membrane bioreactor coupled with biological nutrient removal was used to treat the primary effluent at a municipal wastewater treatment plant. Long-term experiments were conducted by varying hydraulic retention time from 6 to 8 hours and solids retention time from 20 to 50 days, respectively. The performance was assessed by monitoring key wastewater parameters, including chemical oxygen demand (COD), nitrogen, and phosphorus concentration in individual anoxic, anaerobic, aerobic, and membrane separation zones. Results showed that the tested system can consistently achieve COD, nitrogen, and phosphorus removal efficiencies at 80 to 98%, 70 to 93%, and 89 to 98%, respectively. Effluent COD remained low as a result of efficient solid retention, even though there was great variation in influent quality. However, total nitrogen increased proportionally with influent concentration. At a 50-day solids retention time, higher COD and nitrogen oxides specific utilization rates in the anoxic zone resulted in a high production of nitrogen oxides in the subsequent aerobic zone.     

Removal of organic compounds during treating printing and dyeing wastewater of different process units

Wastewater in Shaoxing wastewater treatment plant (SWWTP) is composed of more than 90% dyeing and printing wastewater with high pH and sulfate. Through a combination process of anaerobic acidogenic [hydraulic retention time (HRT) of 15h], aerobic (HRT of 20h) and flocculation-precipitation, the total COD removal efficiency was up to 91%. But COD removal efficiency in anaerobic acidogenic unit was only 4%. As a comparison, the COD removal efficiency was up to 35% in the pilot-scale upflow anaerobic sludge bed (UASB) reactor (HRT of 15h). GC-MS analysis showed that the response abundance of these wastewater samples decreased with their removal of COD. A main component of the raw influent was long-chain n-alkanes. The final effluent of SWWTP had only four types of alkanes. After anaerobic unit at SWWTP, the mass percentage of total alkanes to total organic compounds was slightly decreased while its categories increased. But in the UASB, alkanes categories could be removed by 75%. Caffeine as a chemical marker could be detected only in the effluent of the aerobic process. Quantitative analysis was given. These results demonstrated that GC-MS analysis could provide an insight to the measurement of organic compounds removal.     

UASB-SBR处理涤纶短纤维废水的实验研究

分别采用水解酸化与好氧（SBR）、厌氧（UASB）与好氧（SBR）工艺对涤纶短纤维废水的生物降解性能进行研究。水解酸化与好氧工艺在进水COD为1 900 mg/L的时候,去除率在80%左右。采用UASB-SBR工艺,进水COD为2700 mg/L时,COD去除率可以达到96%,出水COD〈100 mg/L。实验研究表明,涤纶短纤维废水更适合采用UASB-SBR工艺来处理,并且能够取得较好的效果。     

铁炭内电解-厌氧-好氧工艺处理阿维菌素废水的试验研究

血清瓶毒性试验表明 ,AVM对厌氧消化产生强烈的抑制作用。AVM废水经铁炭内电解预处理后 ,COD和AVM的去除率分别达到 19.5 %和 6 8.5 % ,可大大降低废水的毒性。预处理出水再经UASB +生物接触氧化反应器进一步处理 ,当生化系统进水COD为 6 0 0 0— 6 5 0 0mg/L时 ,出水COD为 2 5 0— 2 80mg/L ,总COD去除率达到 95 .6 % ,出水达到生物制药行业排放标准     

Coagulation and precipitation as post-treatment of anaerobically treated primary municipal wastewater.

The main objective of this study was to investigate the feasibility of coagulation as a post-treatment method of anaerobically treated primary municipal wastewater. Both mesophilic and ambient (20 degrees C) temperature conditions were investigated in a laboratory-scale upflow anaerobic sludge bed (UASB) reactor. In addition, optimization of the coagulant, both in terms of type and dose, was performed. Finally, phosphorus removal by means of aluminum and iron coagulation and phosphorus and ammonia nitrogen removal by means of struvite precipitation were studied. Anaerobic treatment of primary effluent at low hydraulic retention times (less than 15 hours) resulted in mean chemical oxygen demand (COD) removals ranging from 50 to 70%, while, based on the filtered treated effluent, the mean removals increased to 65 to 80%. Alum coagulation of the UASB effluent gave suspended solids removals ranging from approximately 35 to 65%. Turbidity removal reached up to 80%. Remaining COD values after coagulation and settling were below 100 mg/L, while remaining total organic carbon (TOC) levels were below 50 mg/L. Filterable COD levels were generally below 60 mg/L, while filterable TOC levels were below 40 mg/L. All coagulants tested, including prepolymerized aluminum and iron coagulants, demonstrated similar efficiency compared with alum for the removal of suspended solids, COD, and TOC. Regarding struvite precipitation, optimal conditions for phosphorus and nitrogen removal were pH 10 and molar ratio of magnesium: ammonia-nitrogen: phosphate-phosphorus close to the stoichiometric ratio (1:1:1). During struvite precipitation, removal of suspended solids reached 40%, while turbidity removal reached values up to 80%. The removal of COD was approximately 30 to 35%; yet, when removal of organic matter was based on the treated filterable COD, the removal increased to approximately 65%. In addition, nitrogen was removed by approximately 70%, while phosphorus removal ranged between approximately 30 and 45% on the basis of the initial phosphorus concentration. Finally, size fractionation of the organic matter (COD) showed that the various treatment methods were capable of removing different fractions of the organic matter.     

Toward a high-rate enhanced biological phosphorus removal process in a membrane-assisted bioreactor.

A membrane enhanced biological phosphorus removal (MEBPR) process was studied to determine the impact of hydraulic retention time (HRT) and solids retention time (SRT) on the removal of chemical oxygen demand (COD), nitrogen, and phosphorus from municipal wastewater. The MEBPR process was capable of delivering complete nitrification independent of the prevailing operating conditions, whereas a significant improvement in COD removal efficiency was observed at longer SRTs. In the absence of carbon-limiting conditions, the MEBPR process was able to achieve low phosphorus concentrations in the effluent at increasingly higher hydraulic loads, with the lowest HRT being 5 hours. The MEBPR process was also able to maintain optimal phosphorus removal when the SRT was increased from 12 to 20 days. However, at higher suspended solids concentrations, a substantial increase was observed in carbon utilization per unit mass of phosphorus removed from the influent. These results offer critical insights to the application of membrane technology for biological nutrient removal systems.     

两级UASB与好氧组合工艺处理城市生活垃圾渗滤液的启动研究

采用两级UASB与好氧组合工艺处理早期城市生活垃圾渗滤液.系统出水按不同比例回流到一级UASB中进行反硝化,同时进行产甲烷反应,有机物在二级UASB中被进一步降解,好氧池完成剩余有机物的去除和氨氮的硝化.启动阶段通过对原渗滤液不同比例的稀释,分5次逐步提高进水浓度,启动结束时完成了对原渗滤液的高效处理.在进水COD浓度从3000 mg/L提高到15000 mg/L,氨氮浓度从250 mg/L提高到1400 mg/L时,最终COD去除率稳定在92%左右,氨氮去除率可达99%以上,一级UASB中反硝化率接近100%,回流比为300%时系统总氮去除率为70%～80%.     

一体化A/O移动床生物膜反应器中DO、TN分布及脱氮效果研究

采用一体化A/O移动床生物膜法工艺，以模拟生活污水研究了该工艺的除碳脱氮效果，并对一体化移动床生物膜反应器的好氧区和缺氧区各纵向断面的COD、DO、NH₃-N、TN、NO^-₃-N和NO^-₂-N进行了检测，通过对缺氧区各断面的DO和TN浓度分布情况，分析了脱氮的产生过程。试验结果表明: 在水力停留时间HRT＝12 h，好氧区DO保持5 mg/L左右，COD进水浓度处于250～400 mg/L时，COD的去除率均在90%以上，且出水COD均在40 mg/L以下；TN进水浓度为20～50 mg/L时，NH₃-N去除率高于90%，其出水浓度可达到5 mg/L以下，脱氮效率也较高，TN去除率可达到65%～85%。COD和NH₃-N的浓度分布状况表明该一体化A/O移动床生物膜反应器的流态趋于全混式。     

Simultaneous nitrification and denitrification with anoxic phosphorus uptake in a membrane bioreactor system.

The performance of an innovative membrane bioreactor (MBR) process using anoxic phosphorus uptake with nitrification and denitrification for the treatment of municipal wastewater with respect to operational performance and effluent quality is addressed in this paper. The system was operated at steady-state conditions with a synthetic acetate-based wastewater at a hydraulic retention time (HRT) of 12 hours and on degritted municipal wastewater at a total system HRT of 6 hours. The MBR system was able to achieve 99% biochemical oxygen demand (BOD), chemical oxygen demand (COD), and ammonia-nitrogen (NH4(+)-N); 98% total Kjeldahl nitrogen (TKN); and 97% phosphorus removal, producing effluent BOD, COD, NH4+-N, TKN, nitrate-nitrogen, nitrite-nitrogen, and phosphate-phosphorus of <3, 14, 0.2, 0.26, 5.8, 0.21, and <0.01 mg/L, respectively, at the 6-hour HRT. The comparison of the synthetic and municipal wastewater run is presented in this paper. Steady-state mass balance on municipal wastewater was performed to reveal some key features of the modified MBR system.