铁盐絮体预负载-超滤除锑(V)效能研究

采用"铁盐絮体预负载-超滤"耦合工艺,有效提高了水中金属锑的去除效果,缓解超滤污染.结果表明,当水样p H<7时,锑(V)的去除效率高达98%以上,且出水锑(V)浓度远低于5μg/L;腐殖酸去除效果在不同化学条件下均能保持95%以上.铁盐絮体预负载层能作为超滤膜的屏障,减少了超滤膜接触污染物几率,当水样p H=6时,不可逆污染的相对值最低为0.015.     

复合式动态膜生物反应器处理印染废水效能及膜污染控制

分别采用动态膜生物反应器(DMBR)与复合式动态膜生物反应器(HDMBR)处理印染废水,研究投加悬浮填料前后对污染物去除和膜污染控制影响。投加和未投加悬浮填料的反应器分别标为反应器A和B。结果表明,A反应器对色度、浊度、NH4+-N、TN、TP、COD、UV254平均去除率依次为86.39%、96.00%、90.13%、85.84%、89.63%、95.75%和88.24%,分别比B反应器提高了6.15%、2.24%、8.33%、5.99%、5.56%、1.79%和6.39%。对两反应器污泥混合液进行变性梯度凝胶电泳分离可知,水解酸化池与好氧池内既有相同的微生物种属,也有其特有的种属,而A反应器中各微生物优势地位均比B反应器明显。A反应器中混合液的EPS浓度增加量、LB-EPS积累量、污泥粒径小于10 μm所占比例、膜通量降低幅度均小于B反应器,LB-EPS积累量是影响污泥混合液中Zeta电位、污泥粘度变化的主要原因。膜表面滤饼层的红外图谱与三维荧光图谱解析,验证了蛋白质和多糖是膜表面污染物的主要成分。A反应器中悬浮填料为微生物提供载体,增强了微生物降解能力,能提高对污染物的去除率,同时也延缓了膜污染。     

氧化石墨烯-多壁碳纳米管低压膜抗污染性能研究

为提高碳纳米材料低压膜污染的可恢复性和强化其灭菌效果,本研究将氧化石墨烯(Graphene oxide,GO)与聚乙二醇(Polyethylene glycol,PEG)非共价改性后的多壁碳纳米管(Multi-walled carbon nanotube,MWCNT)以两种结构形式(共混式/嵌入式)负载到0.45 μm聚醚砜片式膜表面,制备了共混式/嵌入式GO-MWCNT低压膜.进而研究了GO-MWCNT不同结构形式对处理典型污染物(牛血清蛋白、腐殖酸、海藻酸钠)过程中膜污染情况的影响.实验结果显示,MWCNT中GO的添加,可使碳纳米材料膜孔径分布更集中,纯水通量在2.011 L·m^-2·h^-1·kPa^-1以上,属于低压膜的运行范围.在处理小尺寸牛血清蛋白的膜滤过程中,采用共混结构(M系列)的GO-MWCNT膜,缓解污染效果优于顶层嵌入结构(I系列);在处理较大尺寸的腐殖酸、海藻酸钠的膜滤过程中,采用顶层嵌入结构(I系列)的GO-MWCNT膜,缓解污染效果优于共混结构(M系列).GO的添加使得碳纳米材料低压膜的抗蛋白质黏附性能得到有效提高,在保证膜表面粗糙度不会大幅度提高的前提下,添加0.2 mg GO的抗蛋白黏附效果优于添加0.5 mg GO.共混式/嵌入式GO-MWCNT膜均可以充分发挥GO边缘切割杀菌作用,GO投加量与灭菌性能呈正相关.其中,共混结构(M系列)的GO-MWCNT膜灭菌效果优于顶层嵌入结构(I系列).     

平板膜-生物反应器净化微污染水源水的研究

利用平板膜-生物反应器恒流运行处理微污染水源水,考察通量为18、25及30 L/m2·h时其运行特性及有机物和氨氮的去除效果.结果表明:3个工况对COD的去除率分别为78.7%、76.9%和80.4%,出水COD低于15 mg/L;3个工况对NH4 -N的去除率分别为90.4%、87.4%和92.8%,出水NH4 -N低于0.5 mg/L;3个工况对UV254的去除率分别为27.5%、28.2%和48.1%.胞外聚合物(EPS)的研究结果表明,其与膜污染之间并没有显著关系,运行通量的选择是影响膜污染和操作运行的一个重要原因.     

Physicochemical and thermal characterization of nonedible oilseed residual waste as sustainable solid biofuel

The present study aims to investigate the potential of nonedible oilseed Jatropha (Jatropha curcas) and Karanja (Pongamia pinnata) defatted residual biomasses (whole seed, kernel, and hull), as solid biofuel. These biomasses showed good carbon contents (39.8–44.5%), whereas, fewer amounts were observed for sulfur (0.15–0.90%), chlorine (0.64–1.76%), nitrogen (0.9–7.2%) and ash contents (4.0–8.7%). Their volatile matter (60.23–81.6%) and calorific values (17.68–19.98 MJ/kg) were found to be comparable to coal. FT-IR and chemical analyses supported the presence of good amount of cellulose, hemicellulose and lower lignin. The pellets prepared without any additional binder, showed better compaction ratio, bulk density and compressive strength. XRF analysis carried out for determination of slagging–fouling indices, suggested their ash deposition tendencies in boilers, which can be overcome significantly with the optimization of the blower operations and control of ash depositions. Thus, overall various chemical, physical properties, thermal decomposition, surface morphological studies and their high biofuel reactivity indicated that residual biomasses of Jatropha and Karanja seeds have high potential to be utilized as a solid biofuel.     

Comparing differential tolerance of native and non-indigenous marine species to metal pollution using novel assay techniques

Recent research suggests anthropogenic disturbance may disproportionately advantage non-indigenous species (NIS), aiding their establishment within impacted environments. This study used novel laboratory- and field-based toxicity testing to determine whether non-indigenous and native bryozoans (common within marine epibenthic communities worldwide) displayed differential tolerance to the common marine pollutant copper (Cu). In laboratory assays on adult colonies, NIS showed remarkable tolerance to Cu, with strong post-exposure recovery and growth. In contrast, native species displayed negative growth and reduced feeding efficiency across most exposure levels. Field transplant experiments supported laboratory findings, with NIS growing faster under Cu conditions. In field-based larval assays, NIS showed strong recruitment and growth in the presence of Cu relative to the native species. We suggest that strong selective pressures exerted by the toxic antifouling paints used on transport vectors (vessels), combined with metal contamination in estuarine environments, may result in metal tolerant NIS advantaged by anthropogenically modified selection regimes.     

MBR工艺处理含50%海水的污水试验研究

采用MBR工艺对含50%海水的污水生物处理进行了试验研究。实验条件为进水COD为300～2 600 mg/L,NH₃-N为50～300 mg/L,pH值为6～9,混合液污泥浓度为7 000 mg/L,溶解氧浓度为2～4 mg/L,温度为20～25℃。试验结果表明,系统的最佳运行条件为：有机负荷＜3.2 kg COD/（m³·d）,氨氮负荷＜0.35 kg/（m³·d）,pH值在7.5～8.5之间,HRT＞12 h。在此条件下,COD与氨氮的去除率可同时达到90%。高盐环境下微生物所分泌的大量胞外多聚物是造成MBR工艺处理含盐废水过程中膜污染的主要原因。     

复合式膜生物反应器的膜污染控制机理

采用常规膜生物反应器(CMBR)和复合式膜生物反应器(HMBR)处理城市生活污水,对HMBR的膜污染控制机理进行了研究。试验结果表明,HMBR能够有效去除胞外多聚物(EPS),反应器内溶解性EPS(S-EPS)、松散附着性EPS(LB-EPS)和紧密附着性EPS(TB-EPS)的含量比CMBR分别降低了42.8%、41.5%和2.1%。附着性EPS(B-EPS)特别是LB-EPS与活性污泥的物理性能密切相关,随着其含量的降低,HMBR中活性污泥的絮凝性能和沉淀性能比CMBR分别提高了24.4%和34.8%。由于滤饼层污泥主要来源于活性污泥,因此随着活性污泥絮凝性能和沉淀性能的提高,HMBR中的滤饼层比阻比CMBR降低了31.1%。作为结果,当跨膜压差(TMP)到达20 kPa时,HMBR运行了143 d,而CMBR仅运行了57 d。     

生物强化MBR-AF工艺短程硝化反硝化研究

本试验将短程硝化功能菌和反硝化功能菌分别接种至膜生物反应器(MBR)和上流式厌氧生物滤池(AF)中,构建了生物强化的MBR-AF短程硝化反硝化工艺,并以活性污泥作空白对照,考察该工艺对高氨氮废水的短程脱氮性能.结果表明,强化体系MBR的启动期短,仅需30d,而活性污泥体系MBR的启动期长达100d;强化体系MBR亚硝酸氮积累率始终维持在95%以上;在30℃下,随着运行时间的延长,强化体系MBR-AF工艺总氮去除率不断升高,最高达90%以上,比活性污泥体系高20%;强化体系MBR膜污染程度轻,膜的使用寿命长.说明功能菌强化在高效亚硝酸氮积累和氨氮转化方面起关键作用,可作为实现短程硝化反硝化的有效手段.     

苦咸水反渗透淡化中影响膜面的污染因素

由于苦咸水的化学组成和浓度分布在不同地区有着显著的差异,以及淡化工艺中普遍较高的浓缩因子(concentrate factor,CF)值(在4—10之间),苦咸水反渗透(brackish water reverse osmosis,BWRO)淡化过程中的膜污染现象、类型和程度较海水反渗透(seawater reverse osmosis,SWRO)淡化过程有明显的不同.目前,膜污染已成为BWRO大规模应用于苦咸水淡化领域的瓶颈之一,如何解决这一问题成为该领域的研究热点.本文详细综述了国内外BWRO淡化过程中影响膜面污染因素的应用研究进展,重点介绍了进水来源污染成分及污染倾向、进水水质优劣指标和进水物性对膜面污染的影响;按照分离技术的不同,分类讨论了常规预处理和膜法预处理工艺,指出后者不易受进水水质变化的影响,能够更好地降低膜面污染潜能,并针对目前的研究现状提出了建议.