硫自养反硝化饮用水脱氮：悬浮填料与硫源作用效果评估

针对饮用水硝酸盐污染和固定床硫自养反硝化脱氮负荷低等问题,开展流化床型硫自养反硝化脱氮研究,探究聚乙烯醇-海藻酸钠-活性炭悬浮填料对硫自养反硝化的影响,并对比了不同硫源(升华硫、硫代硫酸钠和生物硫)对反硝化效果的影响.结果表明,悬浮填料可显著提升反硝化脱氮效果,升华硫与硫代硫酸钠效果优于生物硫.在最佳条件下,TN去除率可稳定保持在98.49%,TN脱氮负荷达2.84 g·L^-1·d^-1.机理分析表明,悬浮填料中海藻酸钠可作为异养反硝化的有机碳源,实现自养与异养反硝化相结合,减少了副产物NO₂^-和SO₄^2-的生成,并提供碱度,保持体系pH的稳定.加入悬浮填料后,反硝化微生物生长得到促进,优势菌属为Thauera(兼性自养反硝化菌)和Brachymonas(异养反硝化菌).     

温度分化对APBR反应器性能及产甲烷菌群落的影响

为了研究温度分化对固定床厌氧反应器(anaerobic packed bed reactor,APBR)牛粪发酵处理效果及产甲烷菌群落的影响,反应器发酵温度从室温(22℃±1℃)阶梯式分化到低温(15℃±1℃)、中温(37℃±1℃)和高温(55℃±1℃).温度变化的过程中,温度越高COD(chemical oxygen demand)去除率和日总产气量越高,分化后COD去除率分别为25%、45%、60%,相应的日产气量为2.3、4.0、8.5 L·d-1,但是甲烷含量基本保持不变(~60%);温度突然变化造成挥发性脂肪酸含量骤然增加,并处于波动状态.16S r RNA基因克隆文库法分析表明,室温时包含广古菌门中的常见重要产甲烷菌MBT(甲烷杆菌目)、Mst(甲烷鬃菌科)、Msc(甲烷八叠球菌科)和MMB(甲烷微菌目),以及嗜热菌,也有少部分泉古生菌门,发酵温度分化后,产甲烷菌多样性减少,中温条件下产甲烷菌种类相对较少.定量PCR表明Mst、MMB和Msc总基因浓度都有所减少,并且温度越高减少越多,各菌数量相对比例变化较大,但Mst仍为优势产甲烷菌.     

多级微氧生物流化床预处理高浓度丙烯酸废水

采用多级微氧生物流化床反应器预处理高浓度丙烯酸废水,考察了进水负荷的影响,并对丙烯酸的降解产物进行了分析.结果表明,反应器在水力停留时间为12 h,水温25℃,进水丙烯酸为3 000～9 000 mg.L-1,丙烯酸容积负荷为6.0～18.0kg.(m3.d)-1的条件下,对丙烯酸去除率在95%以上,COD去除率为15%～30%,出水中丙烯酸浓度<150 mg.L-1.丙烯酸降解的主要中间产物为乙酸和丙酸,平均每1.00 mol的丙烯酸可转化成0.22 mol乙酸和0.36 mol丙酸.多级微氧生物流化床可实现丙烯酸废水的高负荷预处理.     

丛枝菌根强化型生态浮床处理煤化工模拟含盐废水

针对缺乏经济有效的中低盐废水脱盐技术问题,本试验利用丛枝菌根(AM)真菌增强植物抗盐胁迫能力,搭建AM强化型生态浮床,既探索新的中低盐废水处理技术,又解决普通浮床植物耐盐胁迫能力差、除盐效率低的问题.结果表明,AM真菌(Glomus etunicatum)与浮床植物美人蕉(Canna indica L.)建立了良好的共生关系,且侵染不受盐胁迫的影响.接种AM真菌提高了生态浮床处理含盐废水的能力,21 d内TDS、COD、TN和TP的去除率分别达到了36. 1%、74. 4%、57. 6%和59. 1%,比未接种AM真菌的普通生态浮床分别提高了79. 2%、36. 4%、32. 7%和37. 6%.从具体盐离子来看,21 d内水体中Na、K、Ca和Mg离子的去除率分别达到了34. 4%、61. 3%、57. 4%和51. 9%,相比未接种AM真菌的普通生态浮床分别提高了11. 4%、37. 1%、18. 3%和24. 6%.从植物对盐的吸收来看,AM的存在促进了美人蕉对Na离子的吸收和向地上部的转移,这可能是AM强化型生态浮床功能得到提升的主要原因之一.本研究表明AM真菌可增强生态浮床修复水体污染的能力,提高脱盐效率.     

Energy recovery from solid waste fuels using advanced gasification technology

Since the mid-1980s, TPS Termiska Processer AB has been working on the development of an atmospheric-pressure gasification process. A major aim at the start of this work was the generation of fuel gas from indigenous fuels to Sweden (i.e. biomass). As the economic climate changed and awareness of the damage to the environment caused by the use of fossil fuels in power generation equipment increased, the aim of the development work at TPS was changed to applying the process to heat and power generation from feedstocks such as biomass and solid wastes. Compared with modern waste incineration with heat recovery, the gasification process will permit an increase in electricity output of up to 50%. The gasification process being developed is based on an atmospheric-pressure circulating fluidised bed gasifier coupled to a tar-cracking vessel. The gas produced from this process is then cooled and cleaned in conventional equipment. The energy-rich gas produced is clean enough to be fired in a gas boiler (and, in the longer term, in an engine or gas turbine) without requiring extensive flue gas cleaning, as is normally required in conventional waste incineration plants. Producing clean fuel gas in this manner, which facilitates the use of efficient gas-fired boilers, means that overall plant electrical efficiencies of close to 30% can be achieved. TPS has performed a considerable amount of pilot plant testing on waste fuels in their gasification/gas cleaning pilot plant in Sweden. Two gasifiers of TPS design have been in operation in Grève-in-Chianti, Italy since 1992. This plant processes 200 tonnes of RDF (refuse-derived fuel) per day. It is planned that the complete TPS gasification process (including the complete fuel gas cleaning system) be demonstrated in several gas turbine-based biomass-fuelled power generating plants in different parts of the world. It is the aim of TPS to prove, at commercial scale, the technical feasibility and economic advantages of the gasification process when it is applied to solid waste fuels. This aim shall be achieved, in the short-term, by employing the cold clean product gas in a gas boiler and, in the longer-term, by firing the gas in engines and gas turbines. A study for a 90 MWth waste-fuelled co-generation plant in Sweden has shown that, already today, gasification of solid waste can compete economically with conventional incineration technologies.     

生物流化床处理生活污水的动力学研究

本研究采用颗粒活性炭（Granule Activated Carbon,GAC）为填料,考察了生物流化床（Biological fluidized Bed,BFB）处理生活污水的动力学.研究结果表明,GAC-BFB内生物膜的表现产率YoA为2.3057gVSS/gCOD,微生物细胞衰减常数Kd为0.3056d-1;基质降解动力学中米氏常数Ks为0.2182mg/L,反应速率常数K为13.09 mg/（l·h）.GAC-BFB的微生物生长动力学拟合方程为1/θc=2.3057q-0.3056,R2=0.9549; GAC-BFB的基质降解动力学拟合方程为1/U =0.2182＊1/S ＋0.0764,R2 =0.9972,该微生物生长动力学拟合方程及基质降解动力学拟合方程能较好的反映GAC-BFB系统的出水水质状况,本研究所获得的动力学关系和动力学参数可作为GAC-BFB系统的设计依据.     

超重力-O_3-Fenton氧化法深度处理彩涂废水

在旋转填充床(RPB)中,采用O3-Fenton氧化法深度处理实际彩涂废水。实验结果表明:在反应温度为25℃、气体流量为150 L/h、液体流量为30 L/h、初始p H为7、反应时间为5.0 min、Fe2+浓度为0.10 mmol/L、H2O2浓度为1.0 mmol/L、RPB转速为1 000 r/min的条件下,彩涂废水的COD去除率达到99.7%,比非超重力O3-Fenton体系的处理效果高出60.0百分点。表明超重力技术对O3-Fenton氧化法深度处理彩涂废水具有良好的强化效果。     

微囊化生物流化床降解对氯甲苯的性能优化

在生物流化床中接入微囊化菌株ycsd01,形成微囊化生物流化床。分别考察装液量、水力停留时间(HRT)、微胶囊接种量、对氯甲苯初始浓度、降解温度和降解pH值对流化床降解对氯甲苯的影响,用响应面法进一步获得了微囊化生物流化床处理对氯甲苯的最佳工艺条件。含菌微胶囊降解对氯甲苯的适宜条件为:装液量为10 L,HRT为72 h,微胶囊接种量为10%~15%,对氯甲苯初始浓度为120 mg/L,降解温度为30~35℃,降解pH值为7.0。响应面优化所得的最佳工艺条件为:pH=7.1,对氯甲苯初始浓度120.36 mg/L和微胶囊接种量11.24%,预测对氯甲苯的降解率达85.32%。     

焚烧烟气中二噁英类控制技术研究进展

焚烧烟气中二噁英是制约垃圾焚烧技术发展的关键性问题。文章描述了烟气中二噁英的形态分布,并综述了烟气中二噁英控制技术的研究进展,指出了有待进一步研究的问题;重点阐述了活性炭吸附技术,比较了传统的利用活性碳吸附技术的净化工艺与双层滤料颗粒床+活性炭+布袋除尘脱酸除二噁英一体化新工艺。