化肥厂含氮废水的生物硝化处理试验

用维纶软性纤维作填料，进行了生物膜法三级硝化处理化肥厂含氮废水的试验，ＴＫＮ的去除负荷最高可达０．３７７ｋｇ／ｍ＾３．ｄ，总硝化率可达９３％。三级硝化后，出水中Ｕｒｅａ－Ｎ〈３ｍｇ／Ｌ、ＮＨ３－Ｎ〈１７ｍｇ／Ｌ。若投加痕量Ｍｇ＾２（５０μｇ／Ｌ）可以促进尿素的水解 。     

炼油废水生物脱氮中间试验

对炼油废水中氮氮的生物降解用两种工艺进行了中间试验。试验结果表明,正常工艺条件下,Ｏ／Ｏ工艺处理后出水中ＮＨ３－Ｎ〈２５ｍｇ／Ｌ,ＣＯＤ〈４０ｍｇ／Ｌ,油〈５ｍｇ／Ｌ;Ａ／Ｏ工艺处理后出水中ＮＨ３－Ｎ〈２０ｍｇ／Ｌ,ＣＯＤ〈５０ｍｇ／Ｌ,油〈５ｍｇ／Ｌ,ＮＯ＾３－Ｎ〈１０ｍｇ／Ｌ。     

MBR系统好氧反硝化效果及好氧反硝化菌的鉴定

采用间歇曝气法对MBR系统好氧反硝化菌进行了培养和富集,考察了系统的好氧反硝化效果及其影响因素,并对好氧反硝化菌进行了分离和鉴定。实验结果表明:在DO为2.0~3.0 mg/L、m(C)∶m(N)为8∶1的条件下,MBR系统好氧反硝化效果较好,COD、氨氮、TN的去除率分别达到90%,90%,62%左右;从系统活性污泥中得到11株好氧反硝化性能较好的好氧反硝化菌,它们属于变形菌门,分别属于不动杆菌属、丛毛单胞菌属、气单胞菌属、假单胞菌属和噬氢菌属。     

厌氧／好氧生物脱氮—絮凝法处理焦化废水

采用厌氧／好氧生物脱氮－絮凝法处理焦化废水，出水中ＮＨ３－Ｎ〈１５ｍｇ／Ｌ，ＣＯＤ为９６－１５８ｍｇ／Ｌ。利用甲醇残液及其他有机废水作为外加碳源，可以达到以废治废的目的。     

间歇式活性污泥反应器内短程同步硝化反硝化的研究

以絮状活性污泥为种泥，以模拟城市生活污水为处理废水，在间歇式活性污泥反应器（SBR）内进行污泥的驯化和培养，通过控制运行条件在SBR内成功实现了NO2-N的积累和短程同步硝化反硝化。实验结果表明，NO2-N积累阶段，控制温度（31±1）℃、曝气量40～45L／h、污泥泥龄9—15d，SBR内NO2-N积累率可达95％-96％。培养成熟的好氧颗粒污泥平均粒径为3—5mm，用其进行短程同步硝化反硝化实验，一个反应周期5h结束后SBR出水的COD，NO2-N，TN去除率分别达92％，95％，85％。     

Cd2+对好氧颗粒污泥同步硝化反硝化过程的影响

研究了SBR中不同质量浓度的Cd2+对好氧颗粒污泥同步硝化反硝化过程的影响。实验结果表明:低ρ(Cd2+)(0.1 mg/L)可促进硝化反应的进行,而高ρ(Cd2+)(大于3.0 mg/L)会对硝化反应产生抑制作用;Cd2+的加入导致反硝化速率降低,且对同步硝化反硝化脱氮效率产生一定抑制作用;另外低ρ(Cd2+)还可促进COD的去除,但Cd2+的加入导致TN去除率下降。     

Cr（Ⅵ）对活性污泥系统反硝化过程的影响

采用反硝化反应器,研究了Cr（Ⅵ）对活性污泥系统反硝化过程的影响。在进水Cr（Ⅵ）投加量2.5 mg/L条件下,活性污泥反硝化过程中COD和硝酸盐氮的去除率受到的影响较小,而在10.0 mg/L条件下受到的影响较大,COD和硝酸盐氮的去除率分别从最初的97.1%和99.0%降至70.6%和24.7%。在停止投加Cr（Ⅵ）后的恢复期内,反硝化系统可以逐渐恢复对COD和硝酸盐氮的去除,亚硝酸盐氮仍会有积累,但随着时间的延长可恢复至初始状态。硝酸盐氮还原为亚硝酸盐氮的过程比亚硝酸盐氮的还原过程更易受到Cr（Ⅵ）的影响。     

废水生化处理营养盐投加方式的探讨

改进废水生物处理营养盐投加方式，即以二沉池出水ＮＨ３－Ｎ和ＰＯ４＾３－的浓度来控制营养盐的投加量。该法不仅可避免营养盐投加过量或不足，提高ＣＯＤ的去除率，而且可大大减少营养盐耗量。     

DO对同步硝化反硝化协同除磷的影响

采用序批式活性污泥反应器(SBR)处理模拟城市污水,在厌氧--好氧运行方式下,考察了DO对同步硝化反硝化协同除磷效果的影响.结果表明,DO的变化对该系统中有机物的去除影响不显著,当DO为1.5～2.0 mg/L时,TN及TP去除率均能达到90%以上,并可以应用pH曲线拐点来判断系统硝化过程是否完成.     

厌氧／好氧生物脱氮－絮凝法处理焦化废水

采用厌氧／好氧生物脱氨－絮凝法处理焦化废水，出水中ＮＨ＿３－Ｎ＜１５ｍｇ／Ｌ，ＣＯＤ为９６－１５８ｍｇ／Ｌ。利用甲醇残液及其他有机废水作为外加碳源，可以达到以废治废的目的。     

A/O生物膜法处理乳液聚合ABS树脂生产废水

采用混凝—A/O生物膜法处理乳液聚合ABS树脂生产废水,确定了混凝预处理工序PAC和PAM的投加量,考察了混合液回流比(R)和A/O段总水力停留时间(HRT)对废水中COD,NH_4~+-N,SS,TN等污染物去除效果的影响。实验结果表明,在HRT为18～24 h、R为2～3的工艺条件下,A/O生物膜法好氧段发生了同步硝化反硝化反应,废水经处理后,出水COD小于60.0 mg/L,ρ(NH_4~+-N)小于5.0 mg/L,TN小于15.0 mg/L,达到了GB 31570—2015《石油炼制工业污染物排放标准》的要求。     

高氨氮化工废水MBBR—AMBBR—MBBR组合工艺处理

采用移动床生物膜反应器（MBBR）—厌氧移动床生物膜反应器（AMBBR）—MBBR组合工艺处理高氨氮化工废水。反应器采用几何构型优化、比表面积大的新型YD-25生物载体和DNF-203硝化细菌,实现了同步硝化和反硝化,强化了脱氮能力。采用投加菌种和排泥的方式,经27 d的驯化培养即完成了反应器的挂膜启动。试验结果表明：最佳操作条件为HRT 8 d、MBBR中DO 3 mg/L、进水pH 8.0;在进水COD 2 840~7 437 mg/L、ρ（氨氮）92~179 mg/L、TN 148~258 mg/L、pH 6~8的条件下,出水指标均值为COD 352 mg/L、ρ（氨氮）21.2 mg/L、TN 36 mg/L、pH 7.4,满足排放要求。     

In situ nitrogen removal from leachate by bioreactor landfill with limited aeration

The feasibility of simultaneous nitrification and denitrification in a bioreactor landfill with limited aeration was assessed. Three column reactors, simulating bioreactor landfill operations under anaerobic condition (as reference), intermittent forced aeration and enhanced natural aeration were hence established, where aerated columns passed through two phases, i.e., fresh landfill and well-decomposed landfill. The experimental results show that limited aeration decreased nitrogen loadings of leachate distinctly in the fresh landfill. In the well-decomposed landfill, the NH(4)(+)-N of the input leachate could be nitrified completely in the aerated landfill columns. The nitrifying loadings of the column cross section reached 7.9 g N/m(2)d and 16.9 g N/m(2)d in the simulated landfill columns of intermittent forced aeration and enhanced natural aeration, respectively. The denitrification was influenced by oxygen distribution in the landfill column. Intermittent existence of oxygen in the landfill with the intermittent forced aeration was favorable to denitrify the NO(2)(-)-N and NO(3)(-)-N, indicated by the high denitrification efficiency (>99%) under the condition of BOD(5)/TN of more than 5.4 in leachate; locally persistent existence of oxygen in the landfill with enhanced natural aeration could limit the denitrification, indicated by relatively low denitrification efficiency of about 75% even when the BOD(5)/TN in leachate had an average of 7.1.     

循环式复合水解酸化—CASS—絮凝沉淀组合工艺处理化工园区废水

采用循环式复合水解酸化—CASS—絮凝沉淀组合工艺处理江苏省某化工园区污水厂的实际废水(COD260~815 mg/L、ρ(氨氮)19.15~40.41 mg/L、TN 22.51~50.66 mg/L、TP 0.79~3.21 mg/L),考察了污染物浓度的沿程变化,评价了各工段对主要污染物的去除效果。实验结果表明,组合工艺对废水有着较好的处理效果,平均COD、氨氮、TN、TP的去除率分别高达83.29%、95.34%、61.29%、82.70%,平均出水COD、ρ(氨氮)、TN、TP分别为56.2,1.27,14.34,0.33 mg/L,出水水质接近GB 18918—2002《城镇污水处理厂污染物排放标准》的一级A标准。     

用移动床生物膜反应器处理石化废水

采用悬浮填料移动床生物膜反应器处理石化废水,在水力停留时间大于6h、反应器填料投加率为50％的条件下,出水COD、NH3－N、SS、浊度等均达到国家排放标准,在水力停留时间大于8h时,能达到良好的硝化效果。     

In situ ammonia removal in bioreactor landfill leachate

Although bioreactor landfills have many advantages associated with them, challenges remain, including the persistence of NH(3)-N in the leachate. Because NH(3)-N is both persistent and toxic, it will likely influence when the landfill is biologically stable and when post-closure monitoring may end. An in situ nitrogen removal technique would be advantageous. Recent studies have shown the efficacy of such processes; however, they are lacking the data required to enable adequate implementation at field-scale bioreactor landfills. Research was conducted to evaluate the kinetics of in situ ammonia removal in both acclimated and unacclimated wastes to aid in developing guidance for field-scale implementation. Results demonstrate that in situ nitrification is feasible in an aerated solid waste environment and that the potential for simultaneous nitrification and denitrification (even under low biodegradable C:N conditions) in field-scale bioreactor landfills is significant due to the presence of both aerobic and anoxic areas. All rate data fit well to Monod kinetics, with specific rates of removal of 0.196 and 0.117 mgN/day-g dry waste and half-saturation constants of 59.6 and 147 mgN/L for acclimated and unacclimated wastes, respectively. Although specific rates of ammonia removal in the unacclimated waste are lower than in the acclimated waste, a relatively quick start-up of ammonia removal was observed in the unacclimated waste. Using the removal rate expressions developed will allow for estimation of the treatment times and volumes necessary to remove NH(3)-N from recirculated landfill leachate.     

Monitoring operational and leachate characteristics of an aerobic simulated landfill bioreactor

Long-term biodegradation of MSW in an aerobic landfill bioreactor was monitored as a function of time during 510 days of operation. Operational characteristics such as air importation, temperature and leachate recirculation were monitored. The oxygen utilization rates and biodegradation of organic matter rates showed that aerobic biodegradation was feasible and appropriate to proceed in aerobic landfill bioreactor. Leachate analyses showed that the aerobic bioreactor could remove above 90% of chemical oxygen demand (COD) and close to 100% of biochemical oxygen demand (BOD5) from leachate. Ammonium (NH4+), nitrate (NO3-) and sulphate (SO4(2-)) concentrations of leachate samples were regularly measured. Results suggest that nitrification and denitrification occurred simultaneously, and the increase in nitrate did not reach the levels predicted stoichiometrically, suggesting that other processes were occurring. Leachate recirculation reduced the concentrations of heavy metals because of the effect of the high pH of the leachate, causing heavy metals to be retained by processes such as sorption on MSW, carbonate precipitation, and hydroxide precipitation. Furthermore, the compost derived from the aerobic biodegradation of the organic matter of MSW may be considered as soil improvement in the agricultural plant production. Bio-essays indicated that the ecotoxicity of leachate from the aerobic bioreactor was not toxic at the end of the experiment. Finally, after 510 days of degradation, waste settlement reached 26% mainly due to the compost of the organic matter.     

Landfill leachate treatment using sub-surface flow constructed wetland by Cyperus haspan

Performance evaluation of pilot scale sub-surface constructed wetlands was carried out in treating leachate from Pulau Burung Sanitary Landfill (PBSL). The constructed wetland was planted with Cyperus haspan with sand and gravel used as substrate media. The experiment was operated for three weeks retention time and during the experimentation, the influent and effluent samples were tested for its pH, turbidity, color, total suspended solid (TSS), chemical oxygen demand (COD), biochemical oxygen demand (BOD(5)), ammonia nitrogen (NH(3)-N), Total phosphorus (TP), total nitrogen (TN) and also for heavy metals such as iron (Fe), magnesium (Mg), manganese (Mn) and zinc (Zn) concentrations. The results showed that the constructed wetlands with C. haspan were capable of removing 7.2-12.4% of pH, 39.3-86.6% of turbidity, 63.5-86.6% of color, 59.7-98.8% of TSS, 39.2-91.8% of COD, 60.8-78.7% of BOD(5), 29.8-53.8% of NH(3)-N, 59.8-99.7% of TP, 33.8-67.0% of TN, 34.9-59.0% of Fe, 29.0-75.0% of Mg, 51.2-70.5% of Mn, and 75.9-89.4% of Zn. The significance of removal was manifested in the quality of the effluent obtained at the end of the study. High removal efficiencies in the study proved that leachate could be treated effectively using subsurface constructed wetlands with C. haspan plant.     

Simultaneous removal of COD and ammonium from landfill leachate using an anaerobic-aerobic moving-bed biofilm reactor system

The performance of a moving-bed biofilm reactor (MBBR) system with an anaerobic-aerobic arrangement was investigated to treat landfill leachate for simultaneous removal of COD and ammonium. It was found that the anaerobic MBBR played a major role in COD removal due to methanogenesis, and the aerobic MBBR acted as COD-polishing and ammonium removal step. The contribution of the anaerobic MBBR to total COD removal efficiency reached 91% at an organic loading rate (OLR) of 4.08 kgCOD/(m3d), and gradually decreased to 86% when feed OLR was increased to 15.70 kgCOD/(m3d). Because of the complementary function of the aerobic reactor, the total COD removal efficiency of the system had a slight decrease from 94% to 92% even though the feed OLR was increased from 4.08 to 15.70 kgCOD/(m3d). Hydraulic retention time (HRT) had a significant effect on NH+4-N removal; more than 97% of the total NH+4-N removal efficiency could be achieved when the HRT of the aerobic MBBR was more than 1.25 days. The anaerobic-aerobic system had a strong tolerance to shock loading. A decrease in COD removal efficiency of only 7% was observed when the OLR was increased by four times and shock duration was 24 h, and the system could recover the original removal efficiency in 3 days. The average sludge yield of the anaerobic reactor was estimated to be 0.0538 gVSS/gCOD rem.