基于玄武岩纤维载体的生物膜法净化污染河道水体

为考察不同水体环境状况下,所构建的基于玄武岩纤维的污染河道水体净化技术的净化效能,通过模拟不同p H、温度及DO的污染河道水体环境,研究了水体中的COD、氨氮及TP指标变化规律,得到所构建的净化技术对COD、氨氮及TP的削减速率。研究结果表明,不同温度环境下COD、氨氮及TP的净化效率会随着时间增加而增强;不同DO环境下COD、氨氮及TP的净化效率随时间增加而增强;不同p H条件下COD净化效率随着时间增加而持续增强,氨氮净化效率随时间增加至某一极值后趋于平稳,而TP的净化效率会随着时间增加表现先升高后降低的趋势。此外,实验期间不同水体环境下COD、氨氮与TP皆在温度20~25℃,p H为7,DO为2~4 mg/L时分别获得93%、90%和36%的最大净化效率;根据实验结果得出的最适宜水体环境为温度20~25℃,p H为7,DO为2~4 mg/L;COD、氨氮及TP削减速率分别为0.63~0.84、3.6×10-3~4.0×10-2和7.1×10-4~2.9×10-3kg/(m3·d)。     

序批式生物膜反应器和序批式反应器处理硝酸盐氮污染河水

在序批式反应器(SBR)中添加ZH组合填料构成序批式生物膜反应器(SBBR),并以SBR为对比,研究了2种工艺对污染河水中硝酸盐氮的去除效果。结果表明,(1)进水硝酸盐氮浓度分别为15、20和30 mg/L时,2种工艺对COD的去除率均大于90%,对COD的去除能力均较强,进水硝酸盐氮的增加对COD的去除效果影响不大;第1个缺氧段是COD的主要去除段,此阶段COD的去除率达到80%以上。(2)随进水硝酸盐氮浓度的增加,SBBR中NO-3-N和TN的去除率分别从99.73%和99.24%降至79.75%和65.56%;SBR中NO-3-N和TN的去除率分别从99.91%和99.51%降至55.57%和41.73%。(3)随进水硝酸盐氮浓度的提高,两反应器内亚硝酸盐氮的积累量增大;进水硝酸盐氮浓度为15、20和30 mg/L时,SBBR中的亚硝酸盐氮最大积累浓度分别为2.90、6.82和10.72 mg/L;SBR中亚硝酸盐氮最大积累浓度分别为4.35、9.47和11.89 mg/L。SBBR中亚硝酸盐氮的积累明显低于SBR。     

不同复合人工湿地对高污染河流有机污染物的去除

为了研究复合人工湿地对高污染河流污水中有机污染物的去除效果及规律,实验构建了不同水力负荷下的潜流+潜流、潜流+表面流、潜流+潜流+表面流、表面流+表面流等人工湿地单元组合成的5个复合人工湿地.连续运行一年以来,各复合人工湿地对BOD5、COD和SS的去除效果分别为91.9％ ～94.7％、69.3％ ～75.8％和92.3％ ～ 93.9％,相对于多级表流湿地,多级潜流湿地更利于有机污染物和悬浮物的去除;BOD5、COD和SS主要在各复合湿地的第一级湿地单元内得到去除;复合人工湿地对COD去除效果秋夏季两季好,春冬两季差;复合人工湿地能有效去除悬浮态BOD5和COD,出水中部分溶解态有机物难以有效降解.     

复合生物滤池处理城市高污染水体

采用中试规模复合生物滤池处理城市高污染水体,考察了滤池的最佳运行参数以及对氮和有机物的去除效果。结果表明:滤池容积负荷宜控制为0.3～0.5 kg COD/(m3.d),水力负荷4.5～5 m3/(m2.d),适宜的通风比为9%,当C/N为5～8时,滤池COD、NH4+-N和TN平均去除率分别为80%、83%和63%,达到高效同步硝化反硝化状态。     

电解法去除重污染河水中的磷

近年来,河流污染严重,严重影响了社会的发展,治理河水污染成为目前急需解决的问题。研究了石墨-铁板电极电解法对城市内河中重污染水体中磷去除的可行性;分析了静置时间、电解时长、初始磷浓度、电压、pH及极板间距对电解法除磷效果的影响,确定了电解法处理重污染水体的最佳运行参数,比较了电解法处理实际河水和模拟河水的TP去除效果。结果表明,重污染河流水体中的磷在较短时间内可以得到去除,在静置时间为3 h,电压为10 V,极板间距为1.5cm,pH保持在中性或弱酸性,电解时长在10~15 min时,TP去除率达到90%以上。同时,在最佳运行条件下,电解法处理实际河水效果较好。     

Laser cleaning of historical limestone buildings in Bordeaux appraisal using cathodoluminescence and electron paramagnetic resonance

BACKGROUND: Most historical buildings in Bordeaux city are made of limestone. This yellowish-white rock is rather porous and highly sensitive to pollution. As a consequence of local weathering conditions, these buildings present a dark appearance due to the development of a superficial dark grey to black crust. METHODS: For the last decade, a campaign has been underway to clean these buildings. Eleven techniques of surface treatment have been used, including laser beam technology. As a contribution to the study of laser beam effects on stone buildings, two analytical methods have been used on clean versus unclean surfaces: Cathodoluminescence (CL) and Electron Paramagnetic Resonance (EPR), in addition to SEM-EDX and XRD. RESULTS: The black crust is composed of different types of particles: carbon porous micro-particles of industrial origin, atmospheric dust due to the erosion of soils and rocks, alumino-silicate particles from urban pollution; all these particles being cemented by gypsum. DISCUSSION: As far as heritage conservation is concerned, the laser surface treatment not only preserves the original patina of the stone, but also leaves surface smoothness unaltered. CONCLUSIONS AND PERSPECTIVES: CL and EPR data confirm that lasers--with highly controlled parameters--only get rid of the black crust and, thus, reveal the underneath layer, the so-called patina. This patina shows no luminescence, whereas the limestone on which it has grown shows a bright orange emission of CL. This indicates CL to be a fast and easy way to provide a high quality control for the restoration of polluted ancient stones.