发酵液作为EBPR碳源的动力学模拟

发酵液是一种优质的碳源,能够提高生物除磷系统(EBPR)的除磷效果.采用基于碳源代谢的修正ASM2模型,能够较好地模拟发酵液作为EBPR碳源的动力学变化规律.发酵液作为EBPR唯一碳源时,系统中的异养菌不仅不对聚磷菌(PAO)的生长构成竞争关系,反而促进PAO的生长.发酵液作为实际污水的补充碳源时,优化了污水中的碳源组成,创造了有利于聚磷菌生长的环境,使EBPR中聚磷菌达到微生物总量的40%以上,比实际污水作为碳源的EBPR中的PAO含量提高了3.3倍.     

基于废陶瓷的多孔陶瓷研制及其对Ni2+的吸附性能

通过SEM、XRD、FT-IR表征及多孔陶瓷对废水中镍的去除能力,确定多孔陶瓷的制备条件:原料中田菁粉掺杂质量分数为4%,焙烧温度为800℃.SEM和孔结构表征说明,焙烧使多孔陶瓷形貌、结构发生变化;随着焙烧温度的升高,多孔陶瓷的比表面积和孔容呈现降低的趋势,而孔径呈现增大的趋势;EDS分析能表明,原废瓷粉和多孔陶瓷的主要元素组成均为Si、Al、O.SEM、XRD和FT-IR分析表明,多孔陶瓷吸附前后结构稳定.吸附Ni2+的系列实验表明,多孔陶瓷用量为10 g·L-1,吸附时间为60 min,进水pH值为6.32,进水Ni2+浓度在100 mg.L-1以内.在此条件下废水的Ni2+去除率可达89.7%,多孔陶瓷对废水中镍有较好的去除效果.以制备的多孔陶瓷处理含镍废水,考察多孔陶瓷对废水中Ni2+的吸附动力学和吸附等温线,结果表明,多孔陶瓷对Ni2+的吸附过程符合准二阶动力学模型(R2=0.999 9),Qe为9.09 mg·g-1;吸附过程可用Freundlich方程和Langmuir方程来描述,温度由20℃升高至40℃,最大吸附量Qm由14.49 mg·g-1上升至15.38 mg·g-1.     

有机蒙脱石负载纳米铁去除溶液中四溴双酚A的研究

研究了改性蒙脱石负载纳米铁材料(NZVI-CMT)在甲醇-水体系中对四溴双酚A(TBBPA)的去除作用,并确定了反应温度、TBBPA初始浓度以及材料投加量等因素对去除效果的影响.结果表明,在25℃条件下,0.02 g NZVI-CMT对初始浓度为10 mg·L-1TBBPA溶液的去除率可达97.5%,而且NZVI-CMT对TBBPA的去除率明显高于两种单一材料即纳米零价铁(NZVI)及有机蒙脱石(CMT)的去除率(18.3%、67.3%),同时也大于两者之和(85.6%).利用NZVI-CMT对TBBPA进行重复去除实验时,前3次的去除率均可达到90%以上.通过检测降解产物并分析材料对TBBPA去除过程的特性,发现NZVI-CMT对TBBPA的去除以吸附为主,并伴有少量还原脱溴反应发生,而且较高的反应温度对降解反应有利.     

四氯乙烯和铬复合污染地下水的有机凹凸棒土吸附性能研究

研究了有机凹凸棒土对人工模拟地下水中PCE和Cr6+两者复合污染的吸附行为。分别探讨了振荡吸附时间、凹土投加量、pH值对添加了重金属Cr6+前后凹土吸附PCE效果的影响;通过凹土对PCE的吸附等温线,讨论其吸附的内在机理。结果表明:有机凹土对TCE的吸附10min内达到平衡,吸附率达63.5%,而铬离子存在时吸附率下降至38.2%;当凹土加入量为15.38g/L时,吸附率可达62.8%,铬离子存在时,达到饱和所需的凹土量增加。PCE单组分在有机凹土上的吸附符合langmuir等温式。PCE和Cr(Ⅵ)经复合之后,PCE的吸附效果有所下降,吸附过程采用langmuir及freundlich等温式拟合均不够准确。     

改性凹凸棒土吸附地下水中硝基苯的实验研究

从凹凸棒土(以下简称凹土)的有机改性入手,研究凹土的十六烷基三甲基溴化铵(CTAB)、十八烷基三甲基氯化铵(OTAC)改性及吸附模拟硝基苯(nitrobenzene,NB)污染地下水的影响因素及性能。结果表明:采用超声改性法制得的CTAB、OTAC改性凹土对地下水中NB具有较强的吸附能力,每100g凹土改性剂最佳用量为30 mmol。在NB浓度为20mg/L、投加量为4%、吸附时间30 min的条件下,NB吸附去除率分别达45.68%、55.40%;改性凹土的静态吸附行为符合Langmuir吸附等温方程。     

活性炭吸附法处理冶金废水的工程设计模型

以博哈特(Bohart)和亚当斯(Adams)方程为推导依据,结合连续进水活性炭模型实验,证明了活性炭吸附法处理冶金废水的可行性,且得出了活性炭吸附高度、工作周期、污染物去除率等重要设计参数之间的关系,为活性炭的工程设计提出了一套有效的参考计算方法和设计程序。     

Using lysosomal membrane stability of haemocytes in Ruditapes philippinarum as a biomarker of cellular stress to assess contamination by caffeine, ibuprofen, carbamazepine and novobiocin

Although pharmaceuticals have been detected in the environment only in the range from ng/L to g/L, it has been demonstrated that they can adversely affect the health status of aquatic organisms. Lysosomal membrane stability (LMS) has previously been applied as an indicator of cellular well-being to determine health status in bivalve mussels. The objective of this study is to evaluate LMS in Ruditapes philippinarum haemolymph using the neutral red retention assay (NRRA). Clams were exposed in laboratory conditions to caffeine (0.1, 5, 15, 50 μg/L), ibuprofen (0.1, 5, 10, 50 μg/L), carbamazepine and novobiocin (both at 0.1, 1, 10, 50 μg/L) for 35 days. Results show a dose-dependent effect of the pharmaceuticals. The neutral red retention time measured at the end of the bioassay was significantly reduced by 50% after exposure to environmental concentrations (p < 0.05) (caffeine = 15 μg/L; ibuprofen = 10 μg/L; carbamazepine = 1 μg/L and novobiocin = 1 μg/L), compared to controls. Clams exposed to these pharmaceuticals were considered to present a diminished health status (retention time < 45 min), significantly worse than controls (96 min) (p < 0.05). The predicted no environmental effect concentration (PNEC) results showed that these pharmaceuticals are very toxic at the environmental concentrations tested. Measurement of the alteration of LMS has been found to be a sensitive technique that enables evaluation of the health status of clams after exposure to pharmaceuticals under laboratory conditions, thus representing a robust Tier-1 screening biomarker.     

用于城市生活垃圾好氧堆肥的滚筒式生物反应器研制

针对城市生活垃圾研制了一种用于好氧发酵的滚筒式生物反应器。滚筒式生物反应器的设计主要包括主体结构设计,支承装置的设计计算,传动装置的功率选用,进、出料装置的功能研究等。为保证滚筒式反应器发挥最大功用,在滚筒内壁增设抄板并设计了抄板的结构形式、布置情况及安装位置,用以延长生活垃圾在滚筒内的停留时间,使好氧发酵更为充分。     

复合膜生物反应器处理环氧氯丙烷废水

实验利用复合膜生物反应器处理以甘油为原料制备环氧氯丙烷产生的废水,考察了不同进水COD、水力停留时间以及盐度对处理能力的影响,并进行盐度冲击实验。生物处理后出水进行了深度处理的研究。结果表明:进水COD对处理能力影响较小;适当延长水力停留时间能优化出水水质;废水盐度高于22g/L时会对微生物产生抑制作用;深度处理能进一步降低出水COD;微生物通过一定时间的驯化期能适应并处理高盐度废水。     

Iron and lead ion adsorption by microbial flocculants in synthetic wastewater and their related carbonate formation

Although microbial treatments of heavy metal ions in wastewater have been studied, the removal of these metals through incorporation into carbonate minerals has rarely been reported. To investigate the removal of Fe^3＋ and Pb^2＋, two representative metals in wastewater, through the precipitation of carbonate minerals by a microbial flocculant （MBF） produced by Bacillus mucilaginosus. MBF was added to synthetic wastewater containing different Fe^3＋ and Pb^2＋ concentrations, and the extent of flocculation was analyzed. CO2 was bubbled into the mixture of MBF and Fe^3＋/Pb^2＋ to initiate the reaction. The solid substrates were analyzed via X-ray diffraction, transmission electron microscopy and energy dispersive spectroscopy. The results showed that the removal efficiency decreased and the MBF adsorption capacity for metals increased with increasing heavy metal concentration. In the system containing MBF, metals （Fe^3＋ and Pb^2＋）, and CO2, the concentrated metals adsorbed onto the MBF combined with the dissolved CO2, resulting in oversaturation of metal carbonate minerals to form iron carbonate and lead carbonates. These results may be used in designing a method in which microbes can be utilized to combine CO2 with wastewater heavy metals to form carbonates, with the aim of mitigating environmental problems.