Removal of heavy metals (Cr6+,Ni2+)from polluted water using decaying leaves of plane (Plantanus orientalis)

plane decaying leaves have been found capable of removing chromium and nickel ions from aqueous solutions. The removal efficiency depends upon the pH conditions, ions components and concentrations, and concentrations of leaves in media. The maximum removal for unique Cr⁶⁺ is about 7.5-8.0g/kg leaves at pH 4. 0, for unique Ni²⁺ about 2. 6g/kg at the region of PH5. 0-5.5. Under the described conditions nickel increases chromium uptake by plane decaying leaves from solution.     

焙烧温度对铁覆膜砂IOCS吸附Cr(VI)的影响

采用序批试验研究了焙烧温度对铁覆膜砂(Iron Oxide Coated Sand,IOGS)吸附6价铬Cr(VI)的吸附平衡和吸附速率的影响.结果表明,铬在IOCS上的吸附平衡符合Langmuir吸附模型.低温制备IOCS具有较高吸附容量且对pH不敏感.110℃制备IOGS在pH 7的最大吸附容量(0.181 mg·g-1)远高于660℃制备10CS(0.023 m8·8-1).吸附过程符合准二级动力学模型.吸附速率随焙烧温度提高而下降.     

铬在土壤-地下水系统中的污染研究

根据铬在土壤-地下水环境中的化学特性,通过实验,研究了两种价态的铬[Cr(Ⅲ),Cr(Ⅵ)]在水、土中的污染过程,并着重分析了Cr(Ⅵ)在水土体系中所产生的物理化学作用及其在土中的稳定性。结合铬污染实例,阐明了铬在水-土体系中污染的条件和迁移过程。     

化工铬渣冷固结球团还原解毒实验研究

采用铬渣冷固结球团方法来处理铬渣，研究了不同原料配比的铬渣冷固结球团的成球性能和强度，并用煤气进行了球团的还原实验。结果表明：铬渣的成球性能较好，在自然养护20d后，球团的抗压强度可达30kg／球以上。在900℃用煤气还原铬渣冷固结球团后，铬渣中的Cr^6含量在5mg／L以下：在1200℃还原后，有的铬渣中未检出Cr^6铬渣完全解毒，还原后的铬渣冷固结球团可进行综合利用。     

微型反应柱在含铬废水处理试验研究中的应用

针对镀铬车间废水,采用活性炭吸附处理法对Cr6 和Cr3 的去除效果进行了系统的试验.通过微型反应柱集成装置对穿透时间、吸附容量及活性炭再生方法进行了研究,动态试验表明该装置能有效地处理含铬废水.     

混合填充体系对铬渣中六价铬的阻留作用

以铬渣和粉煤灰为混合填充体系的主要填料，采用柱子淋洗法，通过改变混合填料的配比来研究其对铬渣中Cr(Ⅵ)的阻留作用。试验结果表明，各种混合填充体系对Cr(Ⅵ)均有一定程度的阻留作用，其中I—5校对Cr(Ⅵ)的阻留固定效果最佳，淋出液中Cr(Ⅵ)的质量分数为0．删％，相对阻留效果达94．53％。     

水环境中铬的存在形态及迁移转化规律

综合评述了水环境中铬的存在形态、污染特征及其迁移转化规律的研究现状.水体中铬主要是三价和六价,存在形态分为溶解态、离子交换态、有机结合态、无机沉淀态、残留态,迁移转化过程主要是水解、沉淀、络合、吸附和氧化还原等.对铬在水体中迁移和转化过程的动力学模型进行了论述.     

用微波消解-光度法测定废钻井液中的总铬

采用微波消解-光度法处理钻井液废水中的总铬。该方法克服了常规消解方法的缺点,测定步骤简单、快速,准确性高。通过实验探讨了微波功率、加热时间、样品体积对样品消解的影响。与常压的硫酸-硝酸消解法进行比较的结果表明,用微波消解-光度法处理泥浆废水可将消解时间由原来的6h缩短为20min,加标回收率由60%提高到92%,降低了工作强度,改善了工作环境。     

磁性生物炭负载Mg-Fe水滑石的制备及其吸附水中Cd（Ⅱ）和Ni（Ⅱ）的性能

合成了一种高吸附容量的磁性生物炭负载Mg-Fe水滑石复合材料（L-BC）,并用于去除水中的Cd²⁺和Ni²⁺。表征结果表明,采用浸渍联合热解法成功制备了磁性生物炭（M-BC）,水热合成法成功地将Mg-Fe水滑石负载在M-BC上。动力学研究结果表明,Cd²⁺和Ni²⁺吸附符合伪二级动力学模型,化学吸附为速率控制步骤。等温吸附研究结果表明,L-BC对Cd²⁺和Ni²⁺的吸附符合Langmuir模型,为单分子层化学吸附,最大吸附量分别为263.156 mg/g和43.291 mg/g。吸附机理主要为Mg-Fe水滑石层间CO₃^2-和表面羟基与Cd²⁺和Ni²⁺产生表面共沉淀。L-BC具有良好的吸附和重复利用性能,是一种很有前景的去除Cd²⁺和Ni²⁺的吸附材料。     

Vermicomposting as an advanced biological treatment for industrial waste from the leather industry

The leather industry (tanneries) generates high amounts of toxic wastes, including solid and liquid effluents that are rich in organic matter and mineral content. Vermicomposting was studied as an alternative method of treating the wastes from tanneries. Vermicompost was produced from the following tannery residues: tanned chips of wet-blue leather, sludge from a liquid residue treatment station, and a mixture of both. Five hundred earthworms (Eisenia fetida) were added to each barrel. During the following 135 days the following parameters were evaluated: pH, total organic carbon (TOC), organic matter (OM), cation exchange capacity (CEC), C:N ratio, and chromium content as Cr (III) and Cr (VI). The results for pH, TOC and OM contents showed decreases in their values during the composting process, whereas values for CEC and total nitrogen rose, indicating that the vermicompost reached maturity. For chromium, at 135 days, all values of Cr (VI) were below the detectable level. Therefore, the Cr (VI) content had probably been biologically transformed into Cr (III), confirming the use of this technique as an advanced biological treatment. The study reinforces the idea that vermicomposting could be introduced as an effective technology for the treatment of industrial tannery waste and the production of agricultural inputs.