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林梅,卢国贤,农富钧,卢波,廖思明,黄俊,高晓梅,覃秋容,梁士颉,肖宁,彭立新.微生物燃料电池用于低品位锰矿浸提的研究[J].广西科学,2022,29(2):368-374. [点击复制]
- LIN Mei,LU Guoxian,NONG Fujun,LU Bo,LIAO Siming,HUANG Jun,GAO Xiaomei,QIN Qiurong,LIANG Shijie,XIAO Ning,PENG Lixin.Study on Microbial Fuel Cell for Low-grade Manganese Ore Leaching[J].Guangxi Sciences,2022,29(2):368-374. [点击复制]
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| 微生物燃料电池用于低品位锰矿浸提的研究 |
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林梅1, 卢国贤2, 农富钧2, 卢波1, 廖思明1, 黄俊1, 高晓梅1, 覃秋容1, 梁士颉1, 肖宁1, 彭立新1
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| (1.广西科学院, 国家非粮生物质能源工程技术研究中心, 非粮生物质酶解国家重点实验室, 广西生物炼制重点实验室, 广西南宁 530007;2.南方锰业集团有限责任公司大新锰矿分公司, 广西南宁 532315) |
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| 摘要: |
| 为提高低品位锰矿的利用,实现有机废水对锰矿物粉的浸提,通过改造微生物燃料电池(MFC),在阴极反应池中增加电解室及矿物质室,构建用于锰矿湿法浸提的MFC反应器,实现有机废水与锰矿物粉的还原氧化反应的分离。结果显示,以乙酸钠为碳源,以低品位锰矿粉为阴极的MFC输出电压最高可达0.81 V,是以K3[Fe(CN)6]为阴极液(0.631 V)的1.23倍。在相同条件下,矿物浸提MFC对COD的去除率可达90.9%,高于对照组(87.5%),而降解时间为3 d,显著少于对照组(5.2 d)。在降解COD能力的提升上,可实现对低品位锰矿粉中MnO2的还原,其锰含量由原矿粉的23%降至0.98%,浸提率可达95.7%。进一步通过高通量测序对阳极端菌群结构进行分析发现,其主要菌群为地杆菌属(Geobacter),相对于对照组的85%,矿物浸提MFC中该属比例占总菌群的95%。结果表明,矿物浸提MFC可有效地将有机降解与矿物浸提耦合,避免两者直接混合反应带来的二次废水污染及浸提产物硫酸锰的净化问题,在提高MFC产电效率、处理废水的同时,实现对低品位锰矿的浸提。 |
| 关键词: 微生物燃料电池 矿物浸提 低品位锰矿 产电微生物 生物浸提 |
| DOI:10.13656/j.cnki.gxkx.20220526.018 |
| 投稿时间:2021-04-26 |
| 基金项目:国家自然科学基金项目(32060216),广西科技重大专项(桂科AA17202032-8),广西自然科学基金项目(2017GXNSFAA198167,2018GXNSFAA138203),广西重大科技创新基地建设项目(2018-15-Z03-1203),广西科技基地和人才专项(桂科计字[2020]297号)资助。 |
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| Study on Microbial Fuel Cell for Low-grade Manganese Ore Leaching |
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LIN Mei1, LU Guoxian2, NONG Fujun2, LU Bo1, LIAO Siming1, HUANG Jun1, GAO Xiaomei1, QIN Qiurong1, LIANG Shijie1, XIAO Ning1, PENG Lixin1
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| (1.National Engineering Research Center for Non-Food Biorefinery, State Key Laboratory of Non-Food Biomass and Enzyme Technology, Guangxi Key Laboratory of Biorefinery, Guangxi Academy of Sciences, Nanning, Guangxi, 530007, China;2.South Manganese Group limited, Daxin Manganese Mine Branch, Nanning, Guangxi, 532315, China) |
| Abstract: |
| In order to improve the utilization of low-grade manganese ore and realize the leaching of manganese ore powder by organic waste water,by modifying the Microbial Fuel Cell (MFC),adding electrolysis chamber and mineral chamber in the cathode reaction tank,MFC reactor for wet leaching of manganese ore was constructed to realize the separation of organic wastewater and manganese mineral powder.The results show that the maximum output voltage of MFC with sodium acetate as carbon source and low-grade manganese ore powder as cathode can reach up to 0.81 V,which is 1.23 times of that with K3[Fe(CN)6] as cathode liquid (0.631 V).Under the same conditions,the removal rate of COD by mineral leaching MFC can reach 90.9%,which is higher than 87.5% of the control group,and the degradation time is 3 d,which is significantly less than 5.2 d of the control group.In terms of the improvement of COD degradation ability,the reduction of MnO2 in low grade manganese ore powder can be realized.The manganese content decreases from 23% of raw ore powder to 0.98%,and the leaching rate can reach 95.7%.Further high-throughput sequencing was used to analyze the structure of positive flora,which was mainly Geobacter.Compared with 85% of the control group,the proportion of Geobacter in ore leaching MFC accounted for 95%.The results show that the ore leaching MFC can effectively couple the organic degradation and ore leaching,avoid the secondary wastewater pollution caused by the direct mixed reaction of the two and the purification of the leaching product manganese sulfate.The leaching of low-grade manganese ore is realized while improving the power generation efficiency of MFC and treating wastewater. |
| Key words: microbial fuel cell ore leaching low-grade manganese ore exoelectrogenic microorganisms bioleaching |
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