人工湿地与微生物燃料电池集成处理含油废水及发电

Treatment of Oil Wastewater and Electricity Generation by Integrating Constructed Wetland with Microbial Fuel Cell.

作者信息

Yang Qiao, Wu Zhenxing, Liu Lifen, Zhang Fengxiang, Liang Shengna

机构信息

School of Food and Environment, Dalian University of Technology, Panjin 124221, China.

Key Lab of Industrial Ecology and Environmental Engineering (Ministry of Education), Dalian University of Technology, Dalian 116024, China.

出版信息

Materials (Basel). 2016 Nov 1;9(11):885. doi: 10.3390/ma9110885.

DOI:10.3390/ma9110885

PMID:28774005

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5457253/

Abstract

Conventional oil sewage treatment methods can achieve satisfactory removal efficiency, but energy consumption problems during the process of oil sewage treatment are worth attention. The integration of a constructed wetland reactor and a microbial fuel cell reactor (CW-MFC) to treat oil-contaminated wastewater, compared with a microbial fuel cell reactor (MFC) alone and a constructed wetland reactor (CW) alone, was explored in this research. Performances of the three reactors including chemical oxygen demand (COD), oil removal, and output voltage generation were continuously monitored. The COD removals of three reactors were between 73% and 75%, and oil removals were over 95.7%. Compared with MFC, the CW-MFC with a MnO₂ modified cathode produced higher power density and output voltage. Maximum power densities of CW-MFC and MFC were 3868 mW/m³ (102 mW/m²) and 3044 mW/m³ (80 mW/m²), respectively. The plants in CW-MFC play a positive role for reactor cathode potential. Both plants and cathode modification can improve reactor performance of electricity generation.

摘要

传统的含油污水处理方法能够实现令人满意的去除效率，但含油污水处理过程中的能耗问题值得关注。本研究探索了将人工湿地反应器与微生物燃料电池反应器（CW-MFC）相结合用于处理含油废水，并将其与单独的微生物燃料电池反应器（MFC）和单独的人工湿地反应器（CW）进行了比较。连续监测了这三种反应器的化学需氧量（COD）、除油效果和输出电压等性能。三种反应器的COD去除率在73%至75%之间，除油率超过95.7%。与MFC相比，具有MnO₂修饰阴极的CW-MFC产生了更高的功率密度和输出电压。CW-MFC和MFC的最大功率密度分别为3868 mW/m³（102 mW/m²）和3044 mW/m³（80 mW/m²）。CW-MFC中的植物对反应器阴极电位起到积极作用。植物和阴极修饰都可以提高反应器的发电性能。

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人工湿地与微生物燃料电池集成处理含油废水及发电

Treatment of Oil Wastewater and Electricity Generation by Integrating Constructed Wetland with Microbial Fuel Cell.

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