水解酸化-好氧工艺处理感光材料有机废水研究

感光材料有机生产废水含有多种合成有机物，其BOD5／CODer比值为0．46～0．48，可生化性良好，经水解酸化处理后该废水的BOD5／CODcr的比值可提高至0．54～056，平均增加了17％左右。水解酸化－好氧串联工艺对该废水总的处理效果表明：在废水CODer进水浓度2000～2500mg／L范围内，CODer总去除率可达95％左右，BOD5总去除率可达97％左右；水解酸化后好氧生化系统的动力学半速度常数Ks＝103mg／L，最大比降解速度K＝5．0／日。     

UAMR中温处理高浓度啤酒废水研究

研究了上流厌氧复合反应器（ＵＡＭＲ）中温处理高浓度啤酒废水的工况，并对反应器运行性能的影响因素进行了分析。试验结果表明，在３５℃时，当进水有机容积负荷为８～１２ｋｇＣＯＤ／ｍ＾３·ｄ，水力停留时间ＨＲＴ〉０．４ｄ时，ＣＯＤ去除率可达到８０％以上，沼气ＣＨ４含量为７０．３％，反应器平均生物积累产率为０．０５０４ｋｇｖｓｓ／ｋｇＣＯＤ。     

燃煤锅炉除尘脱硫废水处理与循环利用技术

介绍了采用沉灰、沉渣中和、微滤三池毗连的废水处理方法及板式微孔过滤新技术，实现燃煤锅炉除尘脱硫废水封闭循环利用。     

铁蓝—活性炭生物膜法处理彩色胶片水洗废水的研究

定影漂白废话水用铁蓝法预处理，结果表明，以硫酸亚铁为沉淀剂，投加量为铁氰化物理论值的１．３倍，ＣＮ去除率为９８％，反应生成的普鲁士蓝纯度较高，可供综合利用，铁蓝法除ＣＮ后的出水与显影冲洗废水混合，再经生炭生物膜法处理，ＣＯＤｃｒ去除率为８０％；     

废水处理方案选择专家系统的设计

介绍了一种用于选择工业废水工艺流程方案的专家系统的设计。该系统采用框架式结构对知识进行描述，用指标函数方程进行各种费用的计算比较，最终得出最佳处理工艺流程方案。     

我国红树林净化污水研究进展

红树林具有净化污水的潜能,我国在20世纪80年代中期开始以污染生态学为理论依据进行红树林净化污水的研究.国内红树林净化污水研究主要包括两方面内容,一是研究污水排放对红树林的影响,包括重金属污水、含油废水、生活污水等不同类型污水排放对红树林生长、生理生态、红树林沉积物、林区藻类等的影响;二是研究红树林净化污水的效能,包括红树林累积、吸收和对污水中污染物的净化能力、净化效果的研究.主要从以上两个方面,综述了国内红树林净化污水的研究进展,以期为红树林净化污水的进一步研究和应用提供参考.     

提高氧化沟法城市污水处理系统除磷效果探讨

根据厦门市集美污水处理厂的实际生产情况,通过对除磷原理的分析,从溶解氧、泥龄、回流及进水方式3个方面出发,在实际生产中进行调控测算,从而找出提高污水处理系统除磷效果的有效方法。     

厌氧--好氧--硅藻土处理屠宰废水工程实例

采用厌氧—好氧—硅藻土法处理屠宰废水 ,经过一段时间运行表明 ,处理效果稳定 ,进水CODcrll0 0 0mg/L左右 ,出水在 12 0mg/L以下。本文总结了设计施工过程中一些经验教训     

A／O工艺处理石油化工废水试验研究

本文介绍了采用Ａ／Ｏ新工艺组合处理高浓度的炼油、化工混合废水中试情况，试验结果表明；Ａ／Ｏ新工艺组合具有抗冲击性能好，产泥量少，在一定条件下，出水各项指标达标排放，还就填料选择、含氮化合物的消化反应、污泥生物相和各池工艺参数相互关系进行了讨论。     

Utilization of Bagasse Energy in Thailand

Bagasse, a biomass fuel, is the waste generated by the sugar-making process from sugar cane. Sugar making is one of the most important agricultural-produce processing industries for developing countries in Southeast Asia, Latin America and Africa. As sugar producing plants need electric power and process steam, co-generation using bagasse as an alternate fuel for petroleum has been in use for some time. Thailand recently became one of the largest sugar exporters by enlarging plant capacities and improving equipment, thus reducing its production cost. In addition, the Thai government promotes power generation using bagasse as a means to combat global warming by raising the purchase price of the surplus power. The industry is in the process of further raising the plant capacity, and improving the power-generating efficiency. This will enable a plant to generate more electric power than its in-plant need so that the surplus power can be sold to the commercial grid. It also plans to become a local power supplier during off-season of sugar making by adding a condensing turbine generator. A typical Thai sugar plant of the latest design generates steam of 4Mpa at the bagasse boiler outlet with the temperature of 400°C at 84% boiler efficiency. With the bagasse LHV of 7,540 kJ/kg and that of fuel oil 41, 840 kJ/kg, and taking 90%as oil-burning boiler efficiency, 5.95 kg of bagasse would replace 1 kg of oil. The Kyoto Mechanism defines CO₂ generation by fuel oil as 2.65 kg per liter. Using 0.85for the specific gravity of fuel oil, the amount of CO₂ generation will be 3.12 kg-CO₂/kg. Therefore, CO₂reduction per ton of bagasse in terms of fuel oil will be: 3.12/5.95 =0.524 kg-CO₂/kg-bagasse. As 1 kg of bagasse generates 2 kg of steam, the CO₂reduction of a 100t/h steam boiler will be112,660 ton/year for an annual operation of4,300 hours, as follows. 0.524 × 100/2 = 26.2 t-CO₂/h, 26.2 × 4,300 =112,660 t-CO₂/year. This revised version was published online in August 2006 with corrections to the Cover Date.