A mercury-resistant bacterial strain which is able to reduce ionic mercury to metallic mercury was used to remediate in laboratory columns mercury-containing wastewater produced during electrolytic production of chlorine. Factory effluents from several chloralkali plants in Europe were analyzed, and these effluents contained total mercury concentrations between 1.6 and 7.6 mg/liter and high chloride concentrations (up to 25 g/liter) and had pH values which were either acidic (pH 2.4) or alkaline (pH 13.0). A mercury-resistant bacterial strain, Pseudomonas putida Spi3, was isolated from polluted river sediments. Biofilms of P. putida Spi3 were grown on porous carrier material in laboratory column bioreactors. The bioreactors were continuously fed with sterile synthetic model wastewater or nonsterile, neutralized, aerated chloralkali wastewater. We found that sodium chloride concentrations up to 24 g/liter did not inhibit microbial mercury retention and that mercury concentrations up to 7 mg/liter could be treated with the bacterial biofilm with no loss of activity. When wastewater samples from three different chloralkali plants in Europe were used, levels of mercury retention efficiency between 90 and 98% were obtained. Thus, microbial mercury removal is a potential biological treatment for chloralkali electrolysis wastewater.
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机译:使用能够将离子型汞还原为金属型汞的耐汞细菌菌株,在实验室塔中修复在电解生产氯气中产生的含汞废水。分析了欧洲几家氯碱工厂的工厂废水,这些废水的总汞浓度在1.6至7.6 mg / L之间,氯化物浓度较高(最高25 g / L),pH值为酸性(pH 2.4)或碱性(pH 13.0)。从污染的河流沉积物中分离出一种耐汞细菌菌株恶臭假单胞菌Spi3。恶臭假单胞菌Spi3的生物膜在实验室柱生物反应器中的多孔载体材料上生长。给生物反应器连续注入无菌合成模型废水或非无菌,中和的充气氯碱废水。我们发现浓度高达24 g / l的氯化钠不会抑制微生物的汞保留,并且浓度高达7 mg / l的汞可以用细菌生物膜处理而不会损失活性。当使用来自欧洲三个不同氯碱工厂的废水样品时,汞保持效率水平在90%至98%之间。因此,去除微生物中的汞是氯碱电解废水的潜在生物处理方法。
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