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.     

Supercritical water oxidation of polyvinyl alcohol and desizing wastewater：Influence of NaOH on the organic decomposition

Polyvinyl alcohol is a refractory compound widely used in industry. Here we report supercritical water oxidation of polyvinyl alcohol solution and desizing wastewater with and without sodium hydroxide addition. However, it is difficult to implement complete degradation of organics even though polyvinyl alcohol can readily crack under supercritical water treatment. Sodium hydroxide had a significant catalytic effect during the supercritical water oxidation of polyvinyl alcohol. It appears that the OH ion participated in the C-C bond cleavage of polyvinyl alcohol molecules, the CO2-capture reaction and the neutralization of intermediate organic acids, promoting the overall reactions moving in the forward direction. Acetaldehyde was a typical intermediate product during reaction. For supercritical water oxidation of desizing wastewater, a high destruction rate (98.25%) based on total organic carbon was achieved. In addition, cases where initial wastewater was alkaline were favorable for supercritical water oxidation treatment, but salt precipitation and blockage issues arising during the process need to be taken into account seriously.     

Waste oyster shell as a kind of active filler to treat the combined wastewater at an estuary

Estuaries have been described as one of the most difficult environments on Earth. It is difficult to know how to treat the combined wastewater in tidal rivers at the estuary, where the situation is very different from ordinary fresh water rivers. Waste oyster shell was used as the active filler in this study in a bio-contact oxidation tank to treat the combined wastewater at the Fengtang Tidal River. With a middle-experimental scale of 360 ma/day, the average removal efficiency of COD, BOD, NH3-N, TP and TSS was 80.05%, 85.02%, 86.59%, 50.58% and 85.32%, respectively, in this bio-contact oxidation process. The living microbes in the biofilms on the waste oyster shell in this bio-contact oxidation tank, which were mainly composed of zoogloea, protozoa and micro-metazoa species, revealed that waste oyster shell as the filler was suitable material for combined wastewater degradation. This treatment method using waste oyster shell as active filler was then applied in a mangrove demonstration area for water quality improvement near the experiment area, with a treatment volume of 5 × 10^3 m^3/day. Another project was also successfully applied in a constructed wetland, with a wastewater treatment volume of 1 ×10^3 m^3/day. This technology is therefore feasible and can easily be applied on a larger scale,     

磁性多孔陶粒生物膜反应器处理焦化废水的试验研究

以磁性材料为原料,经过特定的工艺处理,对多孔陶瓷进行磁化改性获得磁性多孔载体,并将该载体应用于生物膜反应器中进行焦化废水处理试验。对不同类型的多孔陶粒载体进行对比试验,结果表明:磁性载体生物膜反应器对COD、NH3-N的去除率比普通活性污泥法高出25%³0%,比非载体生物膜反应器高出15%30%,比非载体生物膜反应器高出15%²0%左右。反应器的曝气量为1.5 L/h,曝气时间为10 h/d,温度为2520%左右。反应器的曝气量为1.5 L/h,曝气时间为10 h/d,温度为25³0℃。焦化废水经磁性载体生物膜反应器处理后,上清液中COD,NH3-N的去除率均在90%左右。出水浓度达到国家工业废水排放二级标准(GB18918-2002)。     

呼和浩特地区污水厂能耗评价与碳排放分析

污水处理过程的能耗和温室气体排放方面的研究对于应对能源危机和气候危机具有重要作用。文章利用层次分析法,建立了具有4层15项指标的能耗评价体系。结合城镇污水处理系统的绿色指标体系,选取呼和浩特地区具有代表性、处理规模相近的2座中小型污水厂进行能耗评价。结果表明:处理能力利用率、处理工艺系统稳定性和污水厂高程布置所对应的3项评价指标在所选择的能耗影响因素中所占权重较大,分别为:0.143 0,0.302 4和0.145 6。进一步运用IPCC计算方法对污水处理厂进行碳排放概算,得出A、B污水处理厂的碳排放量分别为:19.401 t CO2/104t、18.378 t CO2/104t。A、B污水处理厂的实际比能耗分别为0.293 kW.h/m3、0.195 kW.h/m3。将碳排放数据与实际能耗情况对比得出:污水处理厂的能耗水平越高,单位碳排放量也越大。     

纳米Fe_3O_4/膨润土的制备、表征及光催化降解焦化废水

以铝柱撑膨润土负载纳米Fe_3O_4制备出性能良好的复合型催化剂。结合X射线粉末衍射(XRD)、扫描电镜(SEM)和比表面孔隙分析(BET)对催化剂的晶相、比表面积和粒度进行表征。负载的纳米Fe_3O_4粒径约为20～30nm,均匀分散到膨润土表面,未发生明显的团聚。在紫外光作用下用该催化剂对焦化厂二沉池出水进行深度处理。结果表明,在催化剂投加量为0.7 g/L,pH为2.5,温度40℃,H_2O_2初始浓度为17.6mmol/L的反应条件下,二沉池出水(化学需氧量COD=140mg/L,色度=400度)经催化氧化降解后,COD和色度可分别降低到54.44 mg/L和10度,达到国家工业再生用水水质标准GB/T 19923-2005(COD≤60 mg/L,色度≤30度)。催化剂重复使用4次时,废水COD和色度去除率保持稳定。     

氨法脱硫生产氨肥的清洁生产研究

我国因燃煤导致的SO2污染危害十分严重。从清洁生产角度出发,通过比较锅炉烟气脱硫各种方法的优缺点,确定氨法脱硫作为化工企业处理锅炉烟气的工艺。介绍了氨法脱硫机理,工艺各系统结构组成,进行了经济及社会效益分析。氨法脱硫工艺可以去除93％的SO2,处理后的烟气达到了国家排放标准,脱硫副产品硫酸铵可以转交给同区域的企业,深加工为优质化肥。说明发展清洁生产和循环经济是企业预防和控制污染的有效途径,是实现可持续发展战略的必然选择,有利于企业技术进步,提高管理水平,增强综合竞争能力。     

铅酸蓄电池生命周期评价

铅酸蓄电池是世界上产量最大、用途最广的一种二次电池。铅酸蓄电池生命周期过程中每一个环节都有可能对环境带来不利影响,评估从生产到废弃处理关键过程中对环境的影响,可以为制定有效的管理政策提供科研支撑。目前,尚缺乏针对我国特色的铅酸蓄电池行业全生命周期评价的研究,造成此行业的污染防治无据可依。因此,本研究针对铅酸蓄电池的生命周期进行评价,通过设定研究目的与范围、收集数据与分析清单、获得影响评价和解释结果,研究了铅酸蓄电池对环境的影响,结果表明铅酸蓄电池在生产环节的板栅浇铸过程和废弃处理环节的脱硫过程应属于管理中着重控制的部分。     

非均相类Fenton试剂的制备及其在焦化废水处理中的应用研究

利用浸渍法,将Fe3＋负载在经酸碱改性后的粉状活性炭上,当浸渍液浓度为2．5％,固化温度为270℃时,制成的催化剂催化活性较高。用自制的非均相类benton试剂降解焦化废水,通过正交试验和极差分析得出,影响因素的主次顺序为催化剂用量〉初始pH值〉反应时间〉H：0：投加量。结果表明,在100ml水样中。室温条件下,初始pH值为4．0,催化剂使用量为1．5g,H20：投加量为5ml（分两次投加）,反应时间为90min时,COD去除率可达99％。采用混凝＋化学沉淀＋非均相类Fenton试剂法处理焦化废水,各主要出水水质指标为：色度lO倍;COD浓度38．5mg／L;氨氮浓度8．4mg／L,达到国家一级排放标准。     

电化学强化低能耗废水生物处理技术研究

以碳布为阴阳极材料构建一种新型的生物电化学系统（BES）,研究该系统在不曝气条件下对城市污水的处理效果,并与传统的厌氧和好氧处理方法进行比较。结果表明,该BES处理城市污水是可行的,与传统曝气法相比能够显著降低能耗。在进水CODcr,为350mg／L、NH3-N为15mg／L、水力停留时间（HRT）为24h时,电化学强化生物处理系统对CODcr和NH3-N的去除率达84％和80％,优于同等条件下的厌氧、好氧生物处理方法。BES的输出电压最高为211mV。