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通过微生物燃料电池从原始藻类生物质中进行生物电生成:乙酸盐作为共底物的影响。

Bioelectrogenesis from Raw Algal Biomass Through Microbial Fuel Cells: Effect of Acetate as Co-substrate.

作者信息

Kondaveeti Sanath, Mohanakrishna Gunda, Pagolu Raviteja, Kim In-Won, Kalia Vipin C, Lee Jung-Kul

机构信息

1Division of Chemical Engineering, Konkuk University, 1 Hwayang-Dong, Gwangjin-Gu, Seoul, 05029 Republic of Korea.

2Department of Chemical Engineering, College of Engineering, Qatar University, P O Box 2713, Doha, Qatar.

出版信息

Indian J Microbiol. 2019 Mar;59(1):22-26. doi: 10.1007/s12088-018-0769-2. Epub 2018 Dec 28.

DOI:10.1007/s12088-018-0769-2
PMID:30728627
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6328417/
Abstract

Algae are autotrophic organisms that are widespread in water bodies. Increased pollution in water bodies leads to eutrophication. However, algae growing in lakes undergoing eutrophication could be utilized towards the generation of added-value bio-electricity using microbial fuel cells (MFCs). In the present study, two methods of electricity generation using raw algae (RA) and RA + acetate (AC) as co-substrate were analyzed in single chamber air cathode MFCs. MFCs supplemented with RA and RA + AC clearly showed higher power density, greater current generation, and improved COD (chemical oxygen demand) removal, which demonstrated the feasibility of using AC as substrate for MFC. The MFC-RA + AC (0.48 mA) generated 28% higher current relative to that generated by MFC with RA alone. Notably, the maximum power densities generated by MFC-RA and MFC-RA + AC were 230 and 410 mW/m, respectively. MFC-RA and MFC-RA + AC exhibited TCOD (total chemical oxygen reduction) removal values of 77% and 86.6%, respectively. Despite the high influent TCOD (758 mg/l) concentration, the MFC-RA + AC exhibited an 8.5% higher COD removal relative to that of MFC-RA (525 mg/l). Our current findings demonstrated effective energy generation using algae biomass with a co-substrate.

摘要

藻类是广泛存在于水体中的自养生物。水体污染加剧会导致富营养化。然而,在正经历富营养化的湖泊中生长的藻类可通过微生物燃料电池(MFC)用于产生增值生物电。在本研究中,在单室空气阴极MFC中分析了使用生藻(RA)和RA + 乙酸盐(AC)作为共底物的两种发电方法。补充了RA和RA + AC的MFC明显显示出更高的功率密度、更大的电流产生以及改善的化学需氧量(COD)去除效果,这证明了使用AC作为MFC底物的可行性。MFC-RA + AC(0.48 mA)产生的电流比仅使用RA的MFC产生的电流高28%。值得注意的是,MFC-RA和MFC-RA + AC产生的最大功率密度分别为230和410 mW/m。MFC-RA和MFC-RA + AC的总化学需氧量(TCOD)去除率分别为77%和86.6%。尽管进水TCOD浓度较高(758 mg/l),但MFC-RA + AC的COD去除率比MFC-RA(525 mg/l)高8.5%。我们目前的研究结果证明了使用藻类生物质与共底物有效发电。

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