微波联合MEC处理市政污泥运行性能研究
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摘要
以微波预处理污泥为底物,厌氧消化污泥为接种物,构建单室无膜微生物电解池(MEC)进行批式实验,考察外加电压对系统运行性能的影响。结果表明:在外加电压为0~1.2 V的范围内,系统甲烷产量、溶解性有机物(SCOD)去除率及挥发性悬浮物(VSS)去除率均随电压的升高而升高,最大值分别为286 mL、85.1%和59.6%,比0 V电压组分别提高了89.4%、56.9%和39.9%。更高的外加电压(1.6 V)则对微生物代谢活性产生抑制作用,导致系统运行性能下降。
The single-chamber membrane-free microbial electrolysis cell(MEC) was constructed for batch experiment using microwave pretreated sludge and anaerobic digested sludge as substrate and inoculum,respectively. Different voltages were applied to investigate its influence on the running performance of MECs. The results showed that when the applied voltages in the range of 0 to 1.2 V,methane production,SCOD removal rate and VSS removal rate were increased gradually with improved voltage. The maximum methane production,SCOD removal rate and VSS removal rate were determined to be 286 m L,85.1% and 59.6%. Compared with 0 V voltage group,they increased by 89.4%,56.9%,and 39.9%,respectively. However,higher applied voltage(1.6 V) could inhibit the activities of anaerobic microorganisms,which resulted in the decrease of system running performance.
The single-chamber membrane-free microbial electrolysis cell(MEC) was constructed for batch experiment using microwave pretreated sludge and anaerobic digested sludge as substrate and inoculum,respectively. Different voltages were applied to investigate its influence on the running performance of MECs. The results showed that when the applied voltages in the range of 0 to 1.2 V,methane production,SCOD removal rate and VSS removal rate were increased gradually with improved voltage. The maximum methane production,SCOD removal rate and VSS removal rate were determined to be 286 m L,85.1% and 59.6%. Compared with 0 V voltage group,they increased by 89.4%,56.9%,and 39.9%,respectively. However,higher applied voltage(1.6 V) could inhibit the activities of anaerobic microorganisms,which resulted in the decrease of system running performance.
引文
[1]Xiao B Y,Chen X,Han Y P,et al. Bioelectrochemical enhancement of the anaerobic digestion of thermal-alkaline pretreated sludge in microbial electrolysis cells[J]. Renewable Energy,2018,115(4):1177-1183.
[2]徐友,陈思思,董滨,等.酶处理强化污泥厌氧消化效能及脱水性能的研究进展[J].工业水处理,2018,38(3):6-11.
[3]王万成,陶冠红.微生物燃料电池运行条件的优化[J].环境化学,2008,27(4):527-530.
[4]Kim J,Yu Y,Lee C. Thermo-alkaline pretreatment of waste activated sludge at low-temperatures:Effects on sludge disintegration,methane production,and methanogen community structure[J]. Bioresource Technology,2013,144(12):194-201.
[5]张万钦,戚丹丹,吴树彪,等.不同预处理方式对污泥厌氧发酵的影响[J].农业机械学报,2014, 45(9):187-198.
[6]Zhou Cuihong,Huang Xintong,Zeng Meng. Experimental continuous sludge microwave system to enhance dehydration ability and hydrogen production from anaerobic digestion of sludge[J/OL]. Journal of Environmental Science,2017. https://doi.org/10.1016/j.jes.2017.08.016.
[7]Zhao Zisheng,Zhang Yaobin,Quan Xie,et al. Evaluation on direct interspecies electron transfer in anaerobic sludge digestion of microbial electrolysis cell[J]. Bioresource Technology,2016,200:235-244.
[8]国家环境保护总局.水与废水检测分析方法[M]. 4版.北京:中国环境科学出版社,2002.
[9]Ding Aqiang,Yang Yu,Sun Guodong,et al. Impact of applied voltage on methane generation and microbial activities in an anaerobic microbial electrolysis cell(MEC)[J]. Chemical Engineering Journal,2016,283(2):260-265.
[10]向元英,杨暖,孙霞,等.单室微生物电解池强化混合脂肪酸产甲烷[J].应用与环境生物学报,2016,22(5):872-877.
[11]Park J Y,Lee B,Tian D J,et al. Bioelectrochemical enhancement of methane production from highly concentrated food waste in a combined anaerobic digester and microbial electrolysis cell[J]. Bioresource Technology,2018,247(56):226-233.
[12]Appels L,Baeyens J,Degreve J,et al. Principles and potential of the anaerobic digestion of waste-activated sludge[J]. Process in Energy and Combustion Science,2008,34(11):755-781.
[2]徐友,陈思思,董滨,等.酶处理强化污泥厌氧消化效能及脱水性能的研究进展[J].工业水处理,2018,38(3):6-11.
[3]王万成,陶冠红.微生物燃料电池运行条件的优化[J].环境化学,2008,27(4):527-530.
[4]Kim J,Yu Y,Lee C. Thermo-alkaline pretreatment of waste activated sludge at low-temperatures:Effects on sludge disintegration,methane production,and methanogen community structure[J]. Bioresource Technology,2013,144(12):194-201.
[5]张万钦,戚丹丹,吴树彪,等.不同预处理方式对污泥厌氧发酵的影响[J].农业机械学报,2014, 45(9):187-198.
[6]Zhou Cuihong,Huang Xintong,Zeng Meng. Experimental continuous sludge microwave system to enhance dehydration ability and hydrogen production from anaerobic digestion of sludge[J/OL]. Journal of Environmental Science,2017. https://doi.org/10.1016/j.jes.2017.08.016.
[7]Zhao Zisheng,Zhang Yaobin,Quan Xie,et al. Evaluation on direct interspecies electron transfer in anaerobic sludge digestion of microbial electrolysis cell[J]. Bioresource Technology,2016,200:235-244.
[8]国家环境保护总局.水与废水检测分析方法[M]. 4版.北京:中国环境科学出版社,2002.
[9]Ding Aqiang,Yang Yu,Sun Guodong,et al. Impact of applied voltage on methane generation and microbial activities in an anaerobic microbial electrolysis cell(MEC)[J]. Chemical Engineering Journal,2016,283(2):260-265.
[10]向元英,杨暖,孙霞,等.单室微生物电解池强化混合脂肪酸产甲烷[J].应用与环境生物学报,2016,22(5):872-877.
[11]Park J Y,Lee B,Tian D J,et al. Bioelectrochemical enhancement of methane production from highly concentrated food waste in a combined anaerobic digester and microbial electrolysis cell[J]. Bioresource Technology,2018,247(56):226-233.
[12]Appels L,Baeyens J,Degreve J,et al. Principles and potential of the anaerobic digestion of waste-activated sludge[J]. Process in Energy and Combustion Science,2008,34(11):755-781.
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