前置A2NSBR系统硝化和反硝化除磷的特性

以处理实际低C/N生活污水的前置A2NSBR系统为研究对象,考察系统内生物膜的硝化特性和活性污泥的反硝化除磷特性.试验研究了有机物和NO2^--N浓度对生物膜硝化性能的影响,以及不同电子受体浓度对反硝化吸磷速率的影响.结果测得硝化速率为11.3mgNH4^+-N/(L·h),在填充率40%的条件下容积负荷为0.27kgNH4+-N/(m3·d),有机物的存在会对硝化有抑制,但是系统表现出了良好的抗有机负荷冲击能力,硝化速率为9.72mg NH4^+-N/(L·h).NO2^--N处理对AOB活性几乎无影响,对NOB活性抑制作用明显,当NO2^--N浓度为400mg/L时,NOB活性仅为1.63%,几乎接近完全被抑制.根据本次不同电子受体条件下除磷批次试验的结果,好氧吸磷速率为17.62mg P/(g VSS·h),以NO3--N为电子受体的缺氧吸磷速率是12.94mg P/(g VSS·h),从而可知缺氧聚磷菌占总聚磷菌的比例大约是73.4%,其中在NO2^--N浓度为30mg/L出现吸磷抑制,当NO2^--N和NO3^--N共存时,NO2--N在初始浓度为15mg/L便出现吸磷抑制.

前置A_2NSBR工艺系统的启动特性研究

以实际低C/N生活污水(C/N为3.85)为研究对象,重点研究了按照厌氧/缺氧/硝化时序运行的新型前置A_2NSBR工艺系统的启动特性.结果表明,采用除磷A_2SBR和硝化N-SBR先单独启动后耦合运行的方式能够实现快速启动,系统在N-SBR中维持稳定的硝化,在A2SBR中实现了以NO_3^-N为电子受体的反硝化除磷,系统连续运行45d后达到稳定,各项出水指标COD、NH_4^+-N、TN、TP平均值分别为33.82mg/L、0.85mg/L、13.56mg/L,、0.3mg/L,相应的去除率分别为84.31%、98.41%、76.81%、93.87%,各项出水指标达到国家《城镇污水处理厂污染物排放标准GB 18918-2002》中的一级A标准.FISH实验表明,PAOs成为A_2SBR系统中的优势菌群,占全菌比例上升到14.77%.

A_2N工艺的固有弊端分析及其对策研究

基于反硝化除磷理论开发的A2N双污泥工艺已经成为国内外污水生物处理领域的研究重点,介绍了A2N双污泥反硝化除磷工艺的原理及其发展,深入分析了该工艺的固有弊端,综述了国内外学者针对A2N工艺的弊端所提出的对策和改进工艺,并对其进行评价,指出了当前研究中存在的主要问题,提出了今后的研究方向。

Optimization of denitrifying phosphorus removal in a predenitrification anaerobic/anoxic/post-aeration+nitrification sequence batch reactor(pre-A_(2)NSBR)system:Nitrate recycling,carbon/nitrogen ratio and carbon source type

Because the efficiency of biological nutrient removal is always limited by the deficient carbon source for the low carbon/nitrogen(C/N)ratio in real domestic sewage,the denitrifying phosphorus removal(DNPR)was developed as a simple and efficient method to remove nitrogen and phosphorous.In addition,this method has the advantage of saving aeration energy while reducing the sludge production.In this context,a pre-denitrification anaerobic/anoxic/post-aeration+nitrification sequence batch reactor(pre-A_(2)NSBR)system,which could also reduce high ammonia effluent concentration in the traditional two-sludge DNPR process,is proposed in this work.The pre-A_(2)NSBR process was mainly composed of a DNPR SBR and a nitrifying SBR,operating as alternating anaerobic/anoxic/post-aeration+nitrification sequence.Herein,the long-term performance of different nitrate recycling ratios(0-300%)and C/N ratios(2.5-8.8),carbon source type,and functional microbial community were studied.The results showed that the removal efficiency of total inorganic nitrogen(TIN,including NH4^(+)-N,NO_(2)^(-)-N,and NO_(3)^(-)-N)gradually increased with the nitrate recycling ratios,and the system reached the highest DNPR efficiency of 94.45% at the nitrate recycling ratio of 300%.The optimum C/N ratio was around 3.9-7.3 with a nitrogen and phosphorus removal efficiency of 80.15%and 93.57%,respectively.The acetate was proved to be a high-quality carbon source for DNPR process.The results of fluorescence in situ hybridization(FISH)analysis indicated that nitrifiers and phosphorus accumulating organisms(PAOs)were accumulated with a proportion of 19.41%and 26.48%,respectively.

双污泥SBR工艺反硝化除磷脱氮特性及影响因素

以生活污水为处理对象,研究了双污泥A2NSBR工艺反硝化除磷脱氮特性,重点考察了进水C/P和C/N及HRT的影响作用;同时基于DO、ORP和pH的典型变化规律,验证它们作为反硝化除磷过程控制参数的可行性.结果表明,在本试验条件下,P的去除率随着进水C/P的升高整体呈现上升趋势.当进水C/P≥19.39左右时,系统可维持优良的除磷效果;而当进水C/P降至15.36以下时,系统除磷效果呈恶化趋势.另一方面,A2NSBR在低C/N条件下仍可获得相对良好的除磷率,但易导致反硝化脱氮率的下降.C/N的升高增加了聚磷菌厌氧阶段合成PHB的量,继而提高最终的脱氮和除磷效果;但C/N过高将使厌氧段未反应完全的过剩碳源滞留到缺氧段,优先支持反硝化异养菌(ordinary heterotrophic organisms,OHOs)的反硝化反应而减少了缺氧阶段DNPAOs可利用的电子受体数,致使缺氧除磷效果恶化.此外,A2NSBR拥有2套完全独立的SBR,较利于建立以DO、ORP和pH为参数的过程控制体系.

反硝化除磷脱氮理论及工艺研究进展

介绍了反硝化除磷脱氮的理论,并重点对几种比较典型的反硝化除磷脱氮工艺进行评述。

反硝化除磷理论与工艺研究进展

简单介绍了反硝化除磷的相关理论及工艺研究进展,针对反硝化除磷"两类菌属学说"和"一类菌属学说",单污泥工艺BCFS和双污泥工艺A2N工艺及A2NSBR工艺分别进行了具体阐述,并总结归纳了反硝化除磷工艺的优点,指出其具有广阔发展前景。