Potential for Utilizing POME to Produce Biohydrogen Gas Using Microbial Electrolysis Cell

Ferdy Christian Hartanto, N. Atikah, Mohammad Sahid Indrawan, A. Tambunan
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Abstract

Palm oil mill effluent contains organic matter and microorganisms that can potentially be reused despite of its impact to the environment. Microbial electrolysis cell is a method that utilizes electrogenic bacteria to produce hydrogen gas. This study aims to explore the potential for utilizing palm oil mill effluent to produce hydrogen gas using microbial electrolysis cells. Experiments were conducted in a specially built MEC reactor with a 3.5 L capacity with 0.5, 1.0, and 1.5 V with carbon fiber cloth as electrodes. A gas analyzer was used to measure hydrogen gas over the course of 24 h at a 2 h interval. Palm oil mill effluent was utilized as a substrate, while distilled water was used as a control. Experiments demonstrate that the amount of hydrogen gas produced increases as the voltage increases, with values of 37 mg m-3 at 0.5 V, 136 mg m-3 at 1.0 V, and 358 mg m-3 at 1.5 V. When comparing the yield of hydrogen gas produced with distilled water substrate at 1.5 V, the yield of palm oil mill effluent substrate is always higher. This could be due to microbial activity increasing the rate of electrolysis of the substrate into hydrogen gas.
微生物电解池利用POME生产生物氢气的潜力
棕榈油厂的废水中含有有机物质和微生物,尽管对环境有影响,但仍有可能被重新利用。微生物电解池是利用生电细菌产生氢气的一种方法。本研究旨在探索利用微生物电解电池利用棕榈油厂废水生产氢气的潜力。实验在特制的MEC反应器中进行,反应器容量为3.5 L,电压为0.5、1.0和1.5 V,电极为碳纤维布。用气体分析仪在24小时内每隔2小时测量一次氢气。棕榈油厂的废水被用作基质,蒸馏水被用作对照。实验表明,氢气的产出量随着电压的增加而增加,0.5 V时为37 mg m-3, 1.0 V时为136 mg m-3, 1.5 V时为358 mg m-3。对比1.5 V下蒸馏水底物产氢率,棕榈油厂出水底物产氢率始终较高。这可能是由于微生物活动增加了底物电解成氢气的速率。
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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