Set up of a Microbial Fuel Cell for the Treatment of a Garden Compost Leachate: Impact of the External Polarizing Electric Resistance Upon the Chemical Oxygen Demand Removal

Q2 Engineering

Applied Science and Engineering Progress Pub Date : 2023-05-24 DOI:10.14416/j.asep.2023.05.005

Imene Laaz, M. Kameche, C. Innocent

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Abstract

Microbial fuel cells (MFCs) are new and growing renewable energy devices. They transform chemical products into electricity with the help of microorganisms (enzymes, bacteria, microbes, etc.) acting as biocatalysts. They are nowadays displaying technological development since they concomitant simultaneously the wastewater treatment and the electric power generation. These two novelties incite researchers in the field, the utilization of this promising technology. As a matter of fact, a bioelectrochemical fuel cell has been elaborated and set up for garden compost leachate treatment. Following a previous study on the microbial anode formed from wastewater under the application of an electric potential either positive or negative by using chronoamperometry. In this work, we propose the simple method of connecting the two electrodes (anode and cathode) by electrical resistance, to flow a current. The impact of the polarizing electric load on the achievement of the MFC has therefore been studied. Moreover, the chemical oxygen demand (COD) removal for the MFC running for 7 days has been also investigated. It decreased and showed simultaneously an increase in the cell voltage. Thus, the effects of the external load on the current and power generation, as well as on pollutant removal, have been studied by modifying each time the external load. The external polarizing resistance (EPR) was increased from 1 to 10 kΩ, to assess the pollutant decay of the organic matter contained in the wastes. As a result of this, the voltage was increased, whilst the current was decreased, with increasing values of the EPR. The results have been discussed with respect to the type and the predominant microorganisms (electrogenic/fermentative) being involved during the generation of the electric current. This new technology is very promising for converting waste into electricity by offering a way to clean up the polluted environment.

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处理花园堆肥渗滤液的微生物燃料电池的建立：外极化电阻对化学需氧量去除的影响

微生物燃料电池是一种新兴的可再生能源设备。它们在微生物（酶、细菌、微生物等）作为生物催化剂的帮助下将化学产品转化为电能。由于它们同时伴随着废水处理和发电，因此如今正显示出技术的发展。这两个新颖之处激发了该领域研究人员对这项有前景的技术的利用。事实上，已经开发并建立了一种用于花园堆肥渗滤液处理的生物电化学燃料电池。根据之前对废水在施加正电位或负电位下形成的微生物阳极的研究，使用计时电流法。在这项工作中，我们提出了一种简单的方法，通过电阻连接两个电极（阳极和阴极），使电流流动。因此，研究了极化电负载对MFC实现的影响。此外，还研究了MFC运行7天的化学需氧量（COD）去除情况。它降低了，同时显示出电池电压的增加。因此，通过每次修改外部负载，研究了外部负载对电流和发电以及污染物去除的影响。外极化电阻（EPR）从1Ω增加到10 kΩ，以评估废物中有机物的污染物衰减。结果，随着EPR值的增加，电压增加，而电流减少。已经就电流产生过程中涉及的主要微生物（产电/发酵）的类型和主要微生物对结果进行了讨论。这项新技术提供了一种清洁污染环境的方法，非常有希望将废物转化为电力。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Applied Science and Engineering Progress Engineering-Engineering (all)

CiteScore

4.70

自引率

0.00%

发文量