炭铁可渗透反应墙修复氯代烃及淤堵性能研究

摘要
图/表
参考文献
相关文章 (15)

全文: PDF (434 KB) HTML (1 KB)
输出: BibTeX | EndNote (RIS)

摘要通过PRB室内柱实验,对PRB在修复氯代烃污染地下水过程中(24h内的不同时间点)的渗透性能,淤堵程度,修复效果等方面开展相关研究.研究结果发现,24h内炭铁复合材料渗透系数随着时间的增加而增加.PRB模拟柱运行4h时复合材料对三氯乙烯(TCE)的去除率最高为74.23%,在8h时该去除率最低为64.59%.复合材料对TCE去除率的变化是多影响因子多方位综合作用的结果.渗透系数较低时,水流速度较慢,并且系统内不断有(OH)-产生,各种离子沉淀反应稳定发生且反应完全,导致PRB系统淤堵程度不断提高;高渗透性能的条件下,水流速度快,系统内虽有较高浓度(OH)-,该条件沉淀反应不完全,冲刷占主导,导致淤堵程度会降低.

	服务

	把本文推荐给朋友
	加入我的书架
	加入引用管理器
	E-mail Alert
	RSS
	作者相关文章
	陈睿鑫
	姜美洋
	王菲

关键词 ：可渗透性反应墙(PRB), 氯代烃, 淤堵, 渗透, 冲刷

Abstract：Column tests were used to study the permeability, clogging and remediation performance of PRB in treating chlorinated hydrocarbon-contaminated groundwater (at different time points within 24hours). The results show that the permeability of carbon iron composite increased with time in 24hours. The removal rate of these PRB columns was the highest at 74.23% after 4hs of operation. The removal rate of which decreases to 64.59% after 8hs’ operation. The removal rate of PRB reactive materials in remediating trichloro ethylene was affected by multiple factors. When the permeability of PRB is low, the water flow rate through which is low as well. Under this condition, hydroxide ions are formed in these PRB system. Hence, ions in the groundwater are precipitated stably and completely, which leads to the clogging of the PRB system. When the water flow is fast, although there are hydroxide ions generated all the time, flushing leads to a higher permeability of the PRB system.

Key words： permeable reactive barrier chlorinated hydrocarbon clogging permeability flushing

收稿日期: 2023-01-29

PACS:

X523

基金资助:国家自然科学基金资助项目(5197081294)

通讯作者: 王菲,教授,101012020@seu.edu.cn E-mail: 101012020@seu.edu.cn

作者简介: 陈睿鑫(1998-),男,湖南郴州人,硕士研究生,主要从事环境岩土方面研究.357688122@qq.com

引用本文:

陈睿鑫, 姜美洋, 王菲. 炭铁可渗透反应墙修复氯代烃及淤堵性能研究[J]. 中国环境科学, 2023, 43(9): 4578-4584. CHEN Rui-xin, JIANG Mei-yang, WANG Fei. The remediation and clogging performance of chlorinated hydrocarbons treated by biochar-iron permeable reactive barrier. CHINA ENVIRONMENTAL SCIENCECE, 2023, 43(9): 4578-4584.

链接本文:

http://www.zghjkx.com.cn/CN/ 或 http://www.zghjkx.com.cn/CN/Y2023/V43/I9/4578

[1]	万梅,刘锐,汤灵容,等.工业区域土壤和地下水中挥发性氯代烃的污染现状与防治法规[J]. 环境工程, 2011,29(S1):397-401,411. Wan M, Liu R, Tang L R, et al. Pollution status and prevention regulations of volatile chlorinated hydrocarbons in soil and groundwater in industrial areas[J]. Environmental Engineering, 2011, 29(S1):397-401,411.
[2]	Liu Z, Betterton E A, Arnold R G. Electrolytic reduction of low molecular weight chlorinated aliphatic compounds:Structural and thermodynamic effects on process kinetics[J]. Environmental Science &Technology, 2000,34(5):804-811.
[3]	Song H, Carraway E R. Reduction of chlorinated ethane by nanosized zero-valent iron:Kinetics, pathways, and effects of reaction conditions[J]. Environmental Science & Technology, 2005,39(16):6237-6245.
[4]	Dai C, Zhou Y, Peng H, et al. Current progress in remediation of chlorinated volatile organic compounds:Areview[J]. Journal of Industrial and Engineering Chemistry, 2018,65:106-119.
[5]	马欣程,徐红霞,孙媛媛,等.氯代烃污染场地生物自然衰减修复研究进展[J]. 中国环境科学, 2022,42(11):5285-5298. Ma X C, Xu H X, Sun Y Y, et al. Research progress on natural biological attenuation remediation of chlorinated hydrocarbon contaminated sites[J]. China Environmental Science, 2022,42(11):5285-5298.
[6]	张永祥,杜伟,李雅君,等.纳米零价铁在水处理中的应用研究综述[J]. 中国环境科学, 2022,42(11):5163-5178. Zhang Y X, Du W, Li Y J, et al. A review of the application of nano-ZVI iron in water treatment[J]. China Environmental Science, 2022,42(11):5163-5178.
[7]	林琳,万金忠,李群,等.生物炭负载纳米零价铁材料的制备及还原降解性能[J]. 生态与农村环境学报, 2017,33(7):660-664. Lin L, Wan J Z, Li Q, et al. Preparation and reduction degradation performance of biochar-supported nano-zero-valent iron materials[J]. Journal of Ecology and Rural Environment, 2017,33(7):660-664.
[8]	薛嵩.生物炭负载纳米零价铁对有机污染物的去除研究[D]. 苏州:苏州科技学院, 2015. Xue S. Study on the removal of organic pollutants by biochar-loaded nano-zero-valent iron[D]. Suzhou:University of Science and Technology of Suzhou, 2015.
[9]	郭明帅.生物炭/铁复合材料填充PRB对地下水中三氯乙烯的去除研究[D]. 南京:东南大学, 2021.DOI:10.27014/d.cnki.gdnau.2021. 003615. Guo M S, Study on the removal of trichloroethylene from groundwater by prb filled with biochar/iron composite material[D]. Nanjing:Southeast University, 2021.DOI:10.27014/d.cnki.gdnau.2021.003615.
[10]	Arnold W A, Roberts A L. Pathways and Kinetics of Chlorinated Ethylene and Chlorinated Acetylene Reaction with Fe(0) Particles[J]. Environmental Science & Technology, 2000,34(9):1794-1805.
[11]	Orth W S, Gillham R W. Dechlorination of trichloroethene in aqueous solution using Fe0[J]. Environmental Science & Technology, 1996,30(1):66-71.
[12]	Tosco T, Petrangeli Papini M, Cruz Viggi C, et al. Nanoscale zerovalent iron particles for groundwater remediation:a review[J]. Journal of Cleaner Production, 2014,77:10-21.
[13]	Bayer P, Finkel M. Modelling of sequential groundwater treatment with zero valent iron and granular activated carbon[J]. Journal of Contaminant Hydrology, 2005,78(1/2):129-146.
[14]	赖晶星,周建伟,张彦鹏,等.基于正交试验法的零价铁降解水环境中的氯代烃[J]. 安全与环境工程, 2010,17(3):17-20. Lai J X, Zhou J W, Zhang Y P, et al. Degradation of chlorinated hydrocarbons in aqueous environments by zero-valent iron based on orthogonal test method[J]. Safety and Environmental Engineering, 2010,17(3):17-20.
[15]	Scherer M M, Richter S, Valentine R L, et al. Chemistry and microbiology of permeable reactive barriers for in situ groundwater clean up[J]. Critical reviews in microbiology, 2000,26(4):221-264.
[16]	杨宏斌,童张法,金朝晖,等.正己烷萃取-气相色谱法快速测定水中三氯乙烯[J]. 中国环境监测, 2007(4):37-39.DOI:10.19316/j.issn. 1002-6002.2007.04.012. Yang H B, Tong Z F, Jin Z H, et al. Fast determination of trichloroethylene in water by hexane extraction and gas chromatography[J]. China Environmental Monitoring, 2007,(4):37-39.DOI:10.19316/j.issn.1002-6002.2007.04.012.
[17]	Indraratna B, Pathirage P U, Rowe R K, et al. Coupled hydro-geochemical modelling of a permeablereactive barrier for treating acidic groundwater[J]. Computers And Geotechnics, 2014,55:429-439.
[18]	Cipollone M G, Hassan S M, Wolfe N L. Kinetic studies on the use of metallic iron to reduce organic compounds in water under environmental conditions[R]. American Chemical Society, Washington, DC (United States), 1995.
[19]	Gallant W A, Myller B. The results of a zero valence metal reactive wall demonstration at Lowry AFB, Colorado[R]. Air and Waste Management Association, Pittsburgh, PA (United States), 1997.
[20]	Lee D R, Smyth D J A, Shikaze S G, et al. Wall-and-curtain for passive collection/treatment of contaminant plumes[C]//Designing and Applying Treatment Technologies (Eds. GB Wickramanayake and RE Hinchee), 1st Int conf on remediation of chlorinated and recalcitrant compounds, May. 1998:18-21.
[21]	Sheu Y T, Lien P J, Chen K F, et al. Application of NZVI-contained emulsified substrate to bioremediate PCE-contaminated groundwater-A pilot-scale study[J]. Chemical Engineering Journal, 2016,304:714-727.
[22]	Min J E, Kim M, Pardue J H, et al. Reduction of trichloroethylene and nitrate by zero-valent iron with peat[J]. Journal of Environmental Science and Health, Part A, 2008,43(2):144-153.
[23]	Lien H-L, Wilkin R T. High-level arsenite removal from groundwater by zero-valent iron[J]. Chemosphere, 2005,59(3):377-86.
[24]	Phillips D H, Van Nooten T, Bastiaens L, et al. Ten year performance evaluation of a field-scale zero-valent iron permeable reactive barrier installed to remediate trichloroethene contaminated groundwater[J]. Environmental Science & Technology, 2010,44(10):3861-3869.
[25]	王丹亮.离子交换法除去离子液体中氯离子杂质的研究[D]. 南京:南京大学, 2011. Wang D L. Study on the removal of chloride impurities from ionic liquids by ion exchange method[D]. Nanjing:Nanjing University, 2011.