一体化接触氧化反应器处理景区生活污水

常州某旅游景区采用一体化生活污水处理装置处理该区生活污水,通过试验确定反应器的最佳工艺参数,研究表明采用接触氧化反应器处理农村污水,在反应器内溶解氧维持在2.0~4.0 mg/L,水力负荷为3.53 m3/(m3.d)的运行条件下,对COD、NH3-N及TN去除率分别达80.82%、69.12%、63.16%,出水可稳定达GB18918-2002《城镇污水处理厂污染物排放标准》一级标准。     

SBBR同步硝化反硝化处理生活污水的影响因素

序批式生物膜反应器SBBR采用塑料鲍尔环填料,在有氧情况下用于处理实际生活污水.该反应器能很好地创造缺氧微环境,载体生物膜具有吸附储碳能力,出现了良好的同步硝化和反硝化现象.反应器中溶解氧浓度在较大的范围内(0.8～4.0 mg·L-1)能有效地实现同步硝化和反硝化.当溶解氧浓度大于4.0 mg·L-1后,TN容积去除率大幅下降,出水TN大幅上升.增加载体生物膜厚度有利于同步硝化和反硝化.进水浓度基本不影响脱氮的效率,但出水TN随进水浓度增加而升高,建议原水浓度高时可增加后续脱氮处理或减少进水量来满足出水要求.优化运行方法和参数后,SBBR连续运行的TN去除率可稳定在74%～82%.     

异养-电极-生物膜联合反应器脱除地下水中硝酸盐的研究

提出了异养 电极 生物膜联合反应器脱除地下水中硝酸盐的工艺 ,该反应器以异养反硝化为主 ,通过电化学段脱除异养段后水中残留的甲醇或硝酸盐、亚硝酸盐氮 .进水中碳氮比 (质量比 )从 2 2— 2 9,都可保证出水中既无亚硝酸盐积累现象 ,也无残留的甲醇 ,但甲醇略为过量时可提高反应器的处理能力 .2 4℃时处理硝酸盐氮浓度 40mg L的进水 ,反应器最大脱硝负荷为 47g (m3 ·h) .     

MBBR处理制药废水的试验研究

采用二级移动床生物膜反应器(MBBR)处理呋喃铵盐制药废水。在填充比为40%,总水力停留时间为32h时,COD的去除率为88.6%,TN的去除率为25.7%,第二级反应器对NH3-N的去除率为56.2%。     

自然水体生物膜对铜(Ⅱ)、镉(Ⅱ)的吸附研究

以董铺水库为水源、天然纯棉绳为人工基质培养生物膜,研究了附着在棉绳表面上的自然水体生物膜吸附Cu和Cd的热力学和动力学特征及pH对吸附性能的影响.通过对实验数据进行非线型拟合,发现生物膜对2种重金属的吸附均符合Freundlich(F)和Langmuir(L)吸附等温式,对2种金属的吸附能力顺序是:Cu＞Cd.生物膜对Cu和Cd的吸附在数小时内可达到平衡,吸附过程符合二级动力学特征.通过调节吸附液的pH值,研究了不同pH对吸附效果的影响.结果表明,随着pH的升高,2种金属的吸附量明显增加.     

Biological pretreatment of Yellow River water

Bio-ceramic filter(BF) and moving-bed biofilm reactor(MBBR) were used for biological pretreatment of Yellow River water in this study. The BF only had slight advantage over MBBR for TOC and ammonia removal. However, like UV254, the average removal rate of THMFP in the BF was much higher than that in the MBBR. UV254 removal did not show obvious correlation with trihalomethane formation potential(THMFP) removal. Hexachlorocyclohexane could be effectively removed in both BF and MBBR. As for diatom and cyanobateria removal the MBBR had better performance than the BF, which was contrary to the average chlorophyll-a(Chl-a) removal rate. The proposal was made in this study that biological flocculation and sedimentation of sloughed biofilm should play a more important role on algae removal in the MBBR than in the BF. The BF and MBBR could effectively remove microcystins. Moreover, MBBR could be a promising technology for biological pretreatment.     

焦化废水中有机物在A1-A2-O系统各段的降解与转化

在厌氧酸化－缺氧－好氧（A1－A2－O）生物膜系统小试装置中处理焦化废水，以探讨有机物在各阶段的降解与转化情况。通过UV吸收光谱及GC／MS分析发现，上海焦化厂废水中的有机组分主要为：甲酚、苯酚、二甲酚等酚类化合物，及以喹啉、吲哚为代表的含氮杂环化合物，约占有机物总量的90％。经A1－A2－O生物膜系统处理后，大部分有毒有害难降解有机物得到了降解和转化。厌氧段中原有物质浓度的增加和新物质的生成，是厌氧酸化使部分有机物降解产生中间产物而造成；缺氧段使大部分有机物被完全降解或转化，还产生一些新的简单有机物，如卤代烃、酯类、醛类等；经好氧段反应后，有机物进一步降解和转化，部分被完全去除，在降解转化过程中又产生了一些中间产物和衍生物，如苯酚、羟基喹啉等。     

悬浮载体生物膜反应器修复受污染河水试验研究

利用自行开发的悬浮载体生物膜反应器 (SCBR)进行了修复受污染河水的试验 ,考察了水力停留时间对CODCr和氨氮去除效果的影响 .试验结果表明 ,在水温为 15～ 2 0℃ ,进水CODCr为 70～ 10 0mg/L ,进水氨氮为 8～ 2 0mg/L的条件下 ,反应器水力停留时间采用 1 0h时 ,SCBR反应器可以有效去除河水中的CODCr和氨氮 ,其中对CODCr的平均去除率可以达到 5 6 9% ,对氨氮的平均去除率可以达到 76 0 % .     

Dairy washwater treatment using a horizontal flow biofilm system

In Ireland, dairy farmyard washwater commonly comprises farmyard run-off and dairy parlour washings. Land-spreading is the most widely used method for treating this wastewater. However, this method can be labour intensive and can cause, in some cases, the degradation of surface and ground waters, mainly due to nitrogen contamination. In this study, a horizontal flow biofilm reactor (HFBR) with step-feed was constructed and tested in the laboratory, to remove organic carbon and nitrogen from a agricultural strength synthetic washwater (SWW). The HFBR had an average top plan surface area (TPSA) of 0.1002 m(2) and consisted of a stack of 45 polystyrene horizontal sheets--15 sheets embedded with 25 mm deep frustums above 30 sheets with 10 mm deep frustums. The frustums acted as miniature reservoirs. The sheets were alternately offset to allow the wastewater to flow horizontally along each sheet and vertically from sheet to sheet down through the reactor. Biofilms developed on the sheets and treated the wastewater. During the 212-d study, the total hydraulic loading rate based on the TPSA of the sheets was 35 l m(-2) d(-1). SWW was pumped for 10 min each hour, in a step feed arrangement at a rate of 23.33 l m(-2) d(-1) on to the top sheet during Phases 1 and 2, and 11.67 l m(-2) d(-1) onto Sheet 16 during Phase 1 (days 1-92) and onto Sheet 30 during Phase 2 (days 93-212). The substrate loading rate during Phases 1 and 2 was 94.8 g total chemical oxygen demand (COD) m(-2) d(-1) and 10.5 g total nitrogen (TN) m(-2) d(-1), based on the TPSA. At steady state in Phase 2, the unit achieved excellent carbon removal of 99.7% 5-day biochemical oxygen demand (BOD(5)) and 96.7% total COD, equivalent to TPSA removal rates of 67.5 g BOD(5)m(-2)d(-1) and 91.7 g COD m(-2) d(-1). The nitrogen removal percentages were 98.3% total ammonium-nitrogen (NH(4)-N(t)) and 72.8% TN, which equated to TPSA removal rates of 4.8 g NH(4)-N(t) m(-2) d(-1) and 7.6g TN m(-2) d(-1). No sloughing of solids or clogging of media occurred during the study. The unit was simple to construct and operate, with little maintenance.     

武汉东湖秋季水体中光合自氧生物膜的生长特性

利用一种自行设计的光合自氧生物膜采样装置,在武汉东湖(重富营养化湖泊)20和100 cm水深处自然培养和收集光合自氧生物膜,研究其生长发育及活性特点.结果表明:富营养化水体中光合自氧生物膜生长经历了潜伏适应期、增长期、脱落期和恢复生长期4个阶段;光合自氧生物膜生物量、胞外多糖含量、COD含量和脱氢酶活性随培养时间延长呈稳定增长趋势;20 cm水深处光合自氧生物膜生长总体上快于100 cm水深处,并且其生物量和活性也较高;光合自氧生物膜的生理特征与一般天然水体中生长的相似,说明重富营养化水体对生物膜的胁迫作用不明显.