Al13形态的凝胶层析分离及分离级分特性对比

采用聚丙烯酰胺凝胶柱层析法分离纯化聚合氯化铝(PAC)中的Al₁₃形态,并采用Al- Ferron逐时络合比色法、透射电镜(TEM)和ZATESIZER测定仪对分离纯化过程中所得3个级分进行了分析表征和电荷特性的研究;采用烧杯实验法对3个级分处理实际和模拟水样的混凝效果进行了对比性研究.Al- Ferron逐时络合比色法和TEM结果表明,在层析法分离中级分随着洗脱时间延长按分子的大小依次洗脱下来,因此截取中间组分即可得到含量95 %左右的纳米Al₁₃形态;电荷特性和混凝效果研究结果表明,第3个级分其他两者具有更好的除浊、除腐殖酸和脱色效果,并且具有更强的电中和能力,因此Al₁₃形态是一种具有较高正电荷和较高的水解稳定性以及宽的pH适用范围,在给水和废水处理中是一种较为有效的Al形态.     

粉末活性炭预处理对超滤膜通量的影响

研究了粉末活性炭预处理对改善超滤膜过滤通量的效果.试验采用了4种具有不同亲疏水性的水样,着重探讨粉末活性炭对有机物的疏水性和亲水性组分的去除效果以及所带来的通量改善.试验结果表明,对于4种水样,超滤膜直接过滤原水时,通量下降严重.虽然粉末活性炭预处理能在一定程度上提高通量,但通量下降的趋势仍未改善.对有机物各组分的分析表明,直接过滤原水时,膜主要截留疏水性有机物;粉末炭吸附主要去除亲水性有机物,而超滤膜过滤粉末炭处理水时,主要截留疏水性有机物.由此,超滤膜的通量下降主要是由疏水性有机物引起的,亲水性组分对通量的影响较小.     

Effectiveness of tertiary treatment processes in removing different classes of emerging contaminants from domestic wastewater

● Different advanced treatment processes were tested for ECs removal from wastewater. ● UV radiation showed low to moderate removal for 5 of the 38 micropollutants. ● Among tested membrane processes, nanofiltration showed the better performance. ● The use of PAC achieved high or partially removal for 31 out of the 38 compounds. ● The environmental and economical evaluation of a pilot-scale PAC unit is suggested. In this work, 38 different organic emerging contaminants (ECs), belonging to various chemical classes such as pharmaceuticals (PhCs), endocrine-disrupting chemicals (EDCs), benzotriazoles (BTRs), benzothiazoles (BTHs), and perfluorinated compounds (PFCs), were initially identified and quantified in the biologically treated wastewater collected from Athens’ (Greece) Sewage Treatment Plant (STP). Processes already used in existing STPs such as microfiltration (MF), nanofiltration (NF), ultrafiltration (UF), UV radiation, and powdered activated carbon (PAC) were assessed for ECs’ removal, under the conditions that represent their actual application for disinfection or advanced wastewater treatment. The results indicated that MF removed only one out of the 38 ECs and hence it was selected as pretreatment step for the other processes. UV radiation in the studied conditions showed low to moderate removal for 5 out of the 38 ECs. NF showed better results than UF due to the smaller pore sizes of the filtration system. However, this enhancement was observed mainly for 8 compounds originating from the classes of PhCs and PFCs, while the removal of EDCs was not statistically significant. Among the various studied technologies, PAC stands out due to its capability to sufficiently remove most ECs. In particular, removal rates higher than 70% were observed for 9 compounds, 22 were partially removed, while 7 demonstrated low removal rates. Based on our screening experiments, future research should focus on scaling-up PAC in actual conditions, combining PAC with other processes, and conduct a complete economic and environmental assessment of the treatment.     

UF膜与混凝粉末活性炭联用处理微污染原水

采用混凝、粉末活性炭和UF膜分离的联用技术对黄浦江原水进行试验 ,结果表明 ,混凝、粉末活性炭可有效地去除溶解性有机物 .混凝处理主要去除大分子量的有机物 ,粉末活性炭主要去除低分子量的有机物 .混凝、粉末活性炭还能有效地去除三氯甲烷生成潜能 (THMFP) ,对于低分子量的THMFP ,混凝去除效果很差 ,而粉末活性炭去除很好 .试验还表明 ,混凝、粉末活性炭还可大大降低膜的滤饼层阻力 ,当混凝剂投加量为 4mg/L时 ,膜的滤饼层阻力最小 .     

以活性染料为主要成分的印染废水的混凝脱色试验

用硫酸亚铁、碱式氯化铝(PAC)和聚丙烯酰胺(PAM)对以活性染料为主要成分的印染废水进行混凝脱色试验,阐述了混凝脱色机理,对脱色影响因素和控制条件等进行了试验研究.     

利用Al（OH）3凝胶废渣生产聚合氯化铝（PAC）

介绍了对处理铝材加工含Ａｌ＾３＋的酸性废液过程中产生的二次污染物Ａｌ（ＯＨ）３凝胶废渣的应用。     

应用投加粉末活性炭的膜生物反应器处理生活污水的研究

应用向间歇曝气的膜生物反应器内投加粉末活性炭的新工艺，进行了处理模拟生活污水的研究，将此研究结果与未投加粉末活性炭时的研究结果相比较，表明该工艺不仅可以取得更优的出水水质，而且可以从根本上减少膜阻力，维持高膜通量。     

PAC-DMBR处理生活污水的研究

将粉末活性炭(PAC)技术与动态膜生物反应器(DMBR)相结合,应用于处理生活污水,在HRT为8.5h,MLSS为4500mg/L,平均温度为32℃条件下,PAC-DMBR较单一的DMBR对COD和NH3-N的平均去除率分别提高了11.3%和3.3%,且PAC-DMBR系统的出水浊度低达0.99NTU。     

PAC-MBR处理垃圾渗滤液的硝化性能研究

研究了粉末活性炭(PAC)作为载体的膜生物反应器(MBR)处理吹脱后垃圾渗滤液的硝化性能.在HRT=3 d、NH 4-N=200～500 mg/L条件下,进水pH＞8.7时,PAC-MBR和没有添加PAC的普通MBR均只能将氨氮转化为NO-2;降低pH至7.6～8.2时,PAC-MBR中的亚硝酸盐氧化菌迅速恢复活性,将NO-2完全转化为硝酸盐,而普通MBR仍然停留在亚硝化阶段;当吹脱取消后,NO-2迅速消失,这可能与取消吹脱后,不再使用大量硫酸进行pH调节有关.研究发现,当SO2-4为3 g/L时,氨氮氧化速度出现了明显的下降,表明SO2-4对硝化菌具有抑制作用;同时,微生物代谢产物(SMP)分泌量越高,NO-2含量越低,但是SMP不是影响NO-2积累的主要原因.     

膜生物反应器投加PAC处理生活污水效能的试验

在一体式MBR系统中投加少量的粉末活性炭，运行效果良好，并且可以很好地降低膜污染。粉末活性炭在形成生物活性炭后，对难降解有机物具有很好的降解能力；NH4^ -N的去除率得到进一步提高，NO3^-的含量升高；但反硝化作用不明显，致使总氮去除率不高；生物活性炭很好地吸附并降解了易引起膜污染的有机物，改变了污泥的性质，对膜组件起到了很好的保护作用。