化工进展 ›› 2022, Vol. 41 ›› Issue (2): 974-980.DOI: 10.16085/j.issn.1000-6613.2021-0435
高盐废水微生物脱盐池处理研究进展
张群1(
), 陈重军1,2,3(), 谢嘉玮1, 邹馨怡1
- 1.苏州科技大学环境科学与工程学院,江苏 苏州 215009
2.苏州科技大学天平学院,江苏 苏州 215009
3.江苏水处理技术与材料协同创新中心,江苏 苏州 215009
-
收稿日期:2021-03-04修回日期:2021-03-26出版日期:2022-02-05发布日期:2022-02-23 -
通讯作者:陈重军 -
作者简介:张群(1996—),女,硕士研究生。E-mail:1145499912@qq.com 。 -
基金资助:江苏省自然科学基金(BK20201450);中国博士后科学基金(2020M671400);苏州市民生科技项目(SS202016);江苏水处理技术与材料协同创新中心预研项目(XTCXSZ2019-3)
Research progress on the microbial desalination cell for high-salt wastewater treatment
ZHANG Qun1(), CHEN Chongjun1,2,3(), XIE Jiawei1, ZOU Xinyi1
- 1.School of Environmental Science and Engineering, Suzhou University of Science and Technology, Suzhou 215009, Jiangsu, China
2.Tianping College of Suzhou University of Science and Technology, Suzhou 215009, Jiangsu, China
3.Jiangsu Collaborative Innovation Center of Water Treatment Technology and Material, Suzhou 215009,Jiangsu, China
-
Received:2021-03-04Revised:2021-03-26Online:2022-02-05Published:2022-02-23 -
Contact:CHEN Chongjun
摘要:
高盐度是限制废水生化高效处理的重要指标,脱盐处理势在必行。微生物脱盐池因其脱盐效率高、经济性好等优势受到众多学者的关注。本文首先回顾了微生物脱盐池的机理,分析了离子交换膜、pH、电子供体、阴极电解液及电极材料等影响因素对脱盐池脱盐效能的影响,并阐述了微生物脱盐池的进一步耦合工艺,认为微生物脱盐池未来发展趋势应着重于电极模块化、离子交换膜的优化、耦合系统的开发以及工艺的实际应用。
中图分类号:
引用本文
张群, 陈重军, 谢嘉玮, 邹馨怡. 高盐废水微生物脱盐池处理研究进展[J]. 化工进展, 2022, 41(2): 974-980.
ZHANG Qun, CHEN Chongjun, XIE Jiawei, ZOU Xinyi. Research progress on the microbial desalination cell for high-salt wastewater treatment[J]. Chemical Industry and Engineering Progress, 2022, 41(2): 974-980.
图1 MDC反应器原理
图1 MDC反应器原理
图2 几种典型的微生物脱盐池
图2 几种典型的微生物脱盐池
表1 生物脱盐池优化工艺及脱盐率
| 反应器 | 阳极材料 | 阴极材料 | 阳离子交换膜 | 阴离子交换膜 | 阳极液 | 阴极液 | 初始盐浓度 /g·L-1 | 脱盐率 /% | 参考文献 |
|---|---|---|---|---|---|---|---|---|---|
| UMDC① | 碳刷 | 碳布 | CMI-7000 | AMI-7001 | 以乙酸盐为碳源的合成废水 | pH为2.5的酸化水 | 30 | 99 | [ |
| SMDC② | 石墨纤维刷 | Pt | Selemion CMV | Selemion AMV | 乙酸钠的磷酸盐缓冲液 | 合成海水 | 35 | 98 | [ |
| USMDC③ | 碳毡 | 碳布 | CMI-7000 | AMI-7001 | 乙酸钠 | — | 25 | 91.9 | [ |
| OsMDC④ | 碳刷 | 碳布 | CMI-7000 | FO | 乙酸钠、碳酸氢钠、氯化钠 | 铁氰化钾 | 5 | 65.9 | [ |
| MCDC⑤ | 碳刷 | Pt | CMI-7000 | AMI-7001 | PBS | KH2PO4、K2HPO4 | 5 | 47.83 | [ |
| MEDC⑥ | 石墨刷 | 不锈钢网 | CMI-7000 | AMI-7001 | 乙酸盐 | 50mmol/L PBS | 10 | 98.8 | [ |
| MEDCC⑦ | 石墨刷 | 碳布 | CMI-7000 | AMI-7001 | 成熟的MFC阳极液 | 10g/L NaCl | 10 | 86±2 | [ |
表1 生物脱盐池优化工艺及脱盐率
| 反应器 | 阳极材料 | 阴极材料 | 阳离子交换膜 | 阴离子交换膜 | 阳极液 | 阴极液 | 初始盐浓度 /g·L-1 | 脱盐率 /% | 参考文献 |
|---|---|---|---|---|---|---|---|---|---|
| UMDC① | 碳刷 | 碳布 | CMI-7000 | AMI-7001 | 以乙酸盐为碳源的合成废水 | pH为2.5的酸化水 | 30 | 99 | [ |
| SMDC② | 石墨纤维刷 | Pt | Selemion CMV | Selemion AMV | 乙酸钠的磷酸盐缓冲液 | 合成海水 | 35 | 98 | [ |
| USMDC③ | 碳毡 | 碳布 | CMI-7000 | AMI-7001 | 乙酸钠 | — | 25 | 91.9 | [ |
| OsMDC④ | 碳刷 | 碳布 | CMI-7000 | FO | 乙酸钠、碳酸氢钠、氯化钠 | 铁氰化钾 | 5 | 65.9 | [ |
| MCDC⑤ | 碳刷 | Pt | CMI-7000 | AMI-7001 | PBS | KH2PO4、K2HPO4 | 5 | 47.83 | [ |
| MEDC⑥ | 石墨刷 | 不锈钢网 | CMI-7000 | AMI-7001 | 乙酸盐 | 50mmol/L PBS | 10 | 98.8 | [ |
| MEDCC⑦ | 石墨刷 | 碳布 | CMI-7000 | AMI-7001 | 成熟的MFC阳极液 | 10g/L NaCl | 10 | 86±2 | [ |
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