聚合铝铁对A2/O系统 EPS及生物絮凝性能的影响

通过向实验室构建的A2/O模型好氧池末端投加聚合铝铁(PAFC)来强化系统的生物除磷,使得出水总磷达到《城市污水处理厂污染物排放标准GB 18918-2002》中的一级A标准,并重点分析投加的PAFC对A2/O系统中活性污泥胞外聚合物(EPS)和活性污泥生物絮凝性能的影响.结果表明,随着PAFC投药量的增加,A2/O系统活性污泥EPS总量变化不大,但EPS组分中蛋白/多糖含量的比值逐渐降低,由投药前的3.30降低至投药后的2.30;EPS中金属离子含量逐渐增加,在厌氧-缺氧-好氧的运行周期内,各处理单元污泥的EPS中金属铝离子含量增加.投加PAFC后,活性污泥颗粒变大,二沉池出水的Zeta电位明显降低,由投药前-15.83 mV降低至-21.20 mV,污泥产量增加.因此,适量投加PAFC后,生物絮凝性能得到改善,出水中悬浊颗粒减少,出水水质变好.     

水源更换对给水管网水质的影响研究

为了研究水源更换对给水管网水质的影响,对北方A市水源更换过程中管网水质理化指标进行了监测分析.通过33 h的监测发现,由于水源水质不同造成管网水质化学不稳定,管网水水质部分指标发生了明显的下降,pH从7.54降到7.18,碱度从188　mg·L^-1降到117 　mg·L^-1,氯化物从310 　mg·L^-1降到132 　mg·L^-1（以Cl^-计）,电导率从0.176　S·m^-1降到0.087 　S·m^-1,钙离子和镁离子略有下降分别为15 　mg·L^-1和11 　mg·L^-1,这些都是由于滦河水质与黄河水质不同造成的;余氯在换水过程中发生了较复杂的变化,主要是由于水源更换造成耗氯量增加以及夜间用水量少造成管网水输配时间长引起的;pH、碱度、余氯的变化使得管网水中铁的含量增加,最高达到0.4 　mg·L^-1,超出饮用水标准规定的0.3 　mg·L^-1.通过分析水源更换过程中水质的变化,提出了控制管网水质稳定的方法主要有提高pH、增加碱度、投加缓蚀剂和严格保证出厂水及管网水水质指标特别是余氯等.     

铁氧化物改性黏土对Cr(Ⅵ)的吸附性能研究

利用铁氧化物对黏土进行了包覆改性,采用静态吸附法对该改性黏土吸附Cr(Ⅵ)的特性进行了研究,并考虑了反应时间、pH、浓度、温度对吸附的影响。实验结果表明,整个吸附过程基本在3h内完成;改性黏土对Cr(Ⅵ)的吸附量随溶液初始pH的增大而明显减小;随着溶液初始浓度和温度的增大而增大。同时,在初始pH为3.0的条件下,研究了改性黏土吸附Cr(Ⅵ)的动力学和热力学特性,结果表明,改性黏土对Cr(Ⅵ)吸附能较好地符合准二级动力学方程和Langmuir等温式。由Langmuir等温式得出,在293K、初始pH为3.0条件下的单层饱和吸附量为12.91 mg•g-1。确定了改性黏土吸附Cr(Ⅵ)的热力学参数,表明该吸附过程是一个吸热的自发过程。与原土的对比实验表明,改性黏土对Cr(Ⅵ)的吸附能力大大增强。     

纳米铁强化的混凝-沉淀-过滤工艺对典型印染废水中有机物去除

以东江流域某典型印染企业尾水为研究对象,将混凝剂与少量的纳米铁进行复合投加,再结合多介质过滤器对印染尾水进行深度处理实验研究.结果表明,新型混凝剂HPAC-9对极性有机物具有较强的去除能力,但对非极性或弱极性有机物去除效果不很理想.通过将纳米铁与HPAC-9复合投加并结合多介质过滤工艺,对印染企业尾水中的有机污染物进行...     

己内酰胺生产废水的铁碳微电解深度处理与机理研究

采用铁碳微电解方法对己内酰胺生产废水进行深度处理,探讨了pH值、停留时间、铁碳质量比对处理效果的影响。在pH为4、停留时间为120 min、铁碳质量比为4的最佳处理条件下,COD去除率可达57.8%,色度去除率可达68.4%。微电解对己内酰胺废水的作用主要通过铁的絮凝作用,处理过程中的酸性条件、微电解的氧化还原和电场作用,从而提高其去除效率。     

Preparation and coagulation efficiency of polyaluminium ferric silicate chloride composite coagulant from wastewater of high-purity graphite production

The aim of the present work was to produce a polyaluminium ferric silicate chloride (PAFSiC) coagulant from acidic and alkaline wastewater of purifying graphite by roasting, and subsequently to evaluate coagulation efficiency of the reagent by treating surface water from the Yellow River as well as municipal wastewater in comparison with the conventional coagulant polyaluminium chloride (PAC). The PAFSiC coagulant was prepared by co-polymerization. The effects of (Al+Fe)/Si molar ratio, OH/(Al+Fe) molar ratio (i.e., value), coagulant dosage and pH value of test suspension on the coagulation behavior of FAFSiC and the stability of the PAFSiC were also examined. Results showed that PAFSiC performed more efficiently than PAC in removing turbidity, chemical oxygen demand (COD), and total phosphate (TP). The PAFSiC with a value of 2.0 and (Al+Fe)/Si ratio of 5 (PAFSiC 2.0/5) showed excellent coagulation effect for both turbidity and COD, while PAFSiC 1.0/5 was the best for TP. The optimum coagulation pH range of PAFSiC 2.0/5 was 5.0–9.0, slightly wider than that of PAC (6.0–8.0). The process can be easily incorporated into high-purity graphite production plants, thereby reducing wastewater pollution and producing a valuable coagulant.     

Roles of manganese oxides in degradation of phenol under UV-Vis irradiation: Adsorption, oxidation, and photocatalysis

The effect of crystal structure on photocatalytic activities of manganese oxides and underlying reaction mechanism were investigated.     

La-Co-Fe-Cu/HZSM-5在尾气碳颗粒燃烧中的催化性能

采用柠檬酸络合低温浸渍法制备分子筛负载钙钛矿型复合氧化物催化剂。采用XRD、SEM和H2-TPR等手段对催化剂性能进行表征,并在微型固定床反应器中对催化剂进行活性评价。结果表明,在钙钛矿型复合氧化物中进行B位离子掺杂,可以改善催化活性,碳颗粒燃烧温度降低。在20%LaCoO3/HZSM-5催化剂中用铁离子部分取代钴离子可以改善碳颗粒的燃烧性能,取代量增加碳颗粒燃烧温度降低,但是生成CO2的选择性也降低,以20%LaCo0.2Fe0.8O3/HZSM-5为催化剂,Tig、Tm和Tf分别为256℃、399℃和403℃,但生成CO2的选择性只有72.5%。在20%LaCo1-xFexO3/HZSM-5中的钙钛矿型复合氧化物B位离子中加入铜离子后,在碳颗粒燃烧反应中生成CO2的选择性得到明显改善,Sco2提高10个单位以上。以20%LaCo0.2Fe0.6Cu0.2O3/HZSM-5为催化剂,在碳颗粒燃烧反应中生成CO2的选择性可以达到94.7%,Tig、Tm和Tf分别为242℃、427℃和445℃。     

吸附树脂负载铁酞菁催化降解硝基苯的研究

在可见光照射下,采用吸附树脂负载铁酞菁催化过氧化氢降解硝基苯.考察了光照、催化剂投加量、双氧水投加量、温度及pH值等因素对催化效果的影响.结果表明,在功率为50W卤钨灯照射下,硝基苯溶液初始质量浓度为200 mg/L,初始pH值为3,催化剂投加量为1.5 g/L,双氧水投加量为1.0 mL/L,温度为35℃下反应10h,硝基苯去除率可达到79.9％.     

Debromination of decabromodiphenyl ether by organo-montmorillonite-supported nanoscale zero-valent iron：Preparation, characterization and influence factors

An organo-montmorillonite-supported nanoscale zero-valent iron material(M-NZVI) was synthesized to degrade decabromodiphenyl ether(BDE-209). The results showed that nanoscale zero-valent iron had good dispersion on organo-montmorillonite and was present as a core-shell structure with a particle size range of nanoscale iron between 30–90 nm, characterized by XRD, SEM, TEM, XRF, ICP-AES, and XPS. The results of the degradation of BDE-209 by M-NZVI showed that the efficiency of M-NZVI in removing BDE-209 was much higher than that of NZVI. The efficiency of M-NZVI in removing BDE-209 decreased as the pH and the initial dissolved oxygen content of the reaction solution increased, but increased as the proportion of water in the reaction solution increased.