张紫薇1,
苑文仪2,
李培中3,
王临才2,
王晓岩1,
张承龙2,
白建峰2,
王景伟2
1.上海第二工业大学环境与材料工程学院,上海 201209
2.上海电子废弃物资源化创新协调中心,上海第二工业大学电子废弃物研究中心,上海 201209
3.北京轻工业环境保护研究所工业场地污染与修复北京市重点实验室,北京 100089
基金项目: 国家自然科学基金资助项目(21407105)
上海第二工业大学研究生项目基金资助项目(A01GY17F022)
上海第二工业大学校级特色-飞跃计划项目资助(EGD18XQD27)
上海第二工业大学学科建设基金资助项目(A20NH1609B10-2)
Treatment of Cr(VI)-contaminated soil through mechanochemical reduction with ferrous sulfate
XU Weitong1,,ZHANG Ziwei1,
YUAN Wenyi2,
LI Peizhong3,
WANG Lincai2,
WANG Xiaoyan1,
ZHANG Chenglong2,
BAI Jianfeng2,
WANG Jingwei2
1.School of Environmental and Materials Engineering, Shanghai Polytechnic University, Shanghai 201209, China
2.WEEE Research Centre of Shanghai Polytechnic University, Shanghai Collaborative Innovation Centre for Waste Electrical and Electronic Equipment Recycling, Shanghai 201209, China
3.Beijing Key Laboratory of Industrial Land Contamination and Remediation, Environmental Protection Research Institute of Light Industry, Beijing 100089, China
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摘要:通过机械化学还原法对六价铬污染土壤进行固化稳定化处理,采用《固体废物 浸出毒性浸出方法 硫酸硝酸法》(HJ/T 299-2007)对处理效果进行评价,以及使用激光粒度仪、SEM和XPS对处理前后土壤样品的粒径、形貌以及铬的价态变化等性质进行表征。分析结果显示,机械化学还原法处理可以有效降低土壤中六价铬的浸出浓度。当未添加七水合硫酸亚铁时,土壤中六价铬的浸出浓度由115 mg·L-1降低至2.0 mg·L-1;而添加七水合硫酸亚铁作为还原剂时,六价铬浸出浓度由115 mg·L-1降至0.16 mg·L-1。另外,经过机械化学还原处理后的土壤样品颗粒变细并形成致密的团聚体以及发生六价铬向三价铬的转化。
关键词: 铬污染土壤修复/
机械化学/
还原/
固化稳定化/
硫酸亚铁
Abstract:In this research, the solidification and stabilization treatment of Cr(Ⅵ)-contaminated soil through mechanochemical reduction with ferrous sulfate was investigated. The properties of soil after remediation by ball milled with or without ferrous sulfate were characterized by XRD, SEM and XPS analysis. And the leachable fraction of Cr(Ⅵ) from the treated samples is also analyzed through the method HJ/T 299-2007. The results indicate that mechanochemical remediation is very effective for the solidification and stabilization of Cr(Ⅵ)-contaminated soil. Cr(Ⅵ) leaching concentration decreased from 115 to 2.0?and 0.16?mg·-1, respectively, when without and with ferrous sulfate. In addition, during mechanochemical treatment, decrease in particle size, agglomeration and the conversion between Cr(Ⅵ) and Cr(Ⅲ) in contaminated soil are observed.
Key words:Cr(Ⅵ)-contaminated soil remediation/
mechanochemistry/
reduction/
solidification/stabilization/
ferrous sulfate.
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基于硫酸亚铁的机械化学还原法处理六价铬污染土壤
许维通1,,张紫薇1,
苑文仪2,
李培中3,
王临才2,
王晓岩1,
张承龙2,
白建峰2,
王景伟2
1.上海第二工业大学环境与材料工程学院,上海 201209
2.上海电子废弃物资源化创新协调中心,上海第二工业大学电子废弃物研究中心,上海 201209
3.北京轻工业环境保护研究所工业场地污染与修复北京市重点实验室,北京 100089
基金项目: 国家自然科学基金资助项目(21407105) 上海第二工业大学研究生项目基金资助项目(A01GY17F022) 上海第二工业大学校级特色-飞跃计划项目资助(EGD18XQD27) 上海第二工业大学学科建设基金资助项目(A20NH1609B10-2)
关键词: 铬污染土壤修复/
机械化学/
还原/
固化稳定化/
硫酸亚铁
摘要:通过机械化学还原法对六价铬污染土壤进行固化稳定化处理,采用《固体废物 浸出毒性浸出方法 硫酸硝酸法》(HJ/T 299-2007)对处理效果进行评价,以及使用激光粒度仪、SEM和XPS对处理前后土壤样品的粒径、形貌以及铬的价态变化等性质进行表征。分析结果显示,机械化学还原法处理可以有效降低土壤中六价铬的浸出浓度。当未添加七水合硫酸亚铁时,土壤中六价铬的浸出浓度由115 mg·L-1降低至2.0 mg·L-1;而添加七水合硫酸亚铁作为还原剂时,六价铬浸出浓度由115 mg·L-1降至0.16 mg·L-1。另外,经过机械化学还原处理后的土壤样品颗粒变细并形成致密的团聚体以及发生六价铬向三价铬的转化。
English Abstract
Treatment of Cr(VI)-contaminated soil through mechanochemical reduction with ferrous sulfate
XU Weitong1,,ZHANG Ziwei1,
YUAN Wenyi2,
LI Peizhong3,
WANG Lincai2,
WANG Xiaoyan1,
ZHANG Chenglong2,
BAI Jianfeng2,
WANG Jingwei2
1.School of Environmental and Materials Engineering, Shanghai Polytechnic University, Shanghai 201209, China
2.WEEE Research Centre of Shanghai Polytechnic University, Shanghai Collaborative Innovation Centre for Waste Electrical and Electronic Equipment Recycling, Shanghai 201209, China
3.Beijing Key Laboratory of Industrial Land Contamination and Remediation, Environmental Protection Research Institute of Light Industry, Beijing 100089, China
Keywords: Cr(Ⅵ)-contaminated soil remediation/
mechanochemistry/
reduction/
solidification/stabilization/
ferrous sulfate
Abstract:In this research, the solidification and stabilization treatment of Cr(Ⅵ)-contaminated soil through mechanochemical reduction with ferrous sulfate was investigated. The properties of soil after remediation by ball milled with or without ferrous sulfate were characterized by XRD, SEM and XPS analysis. And the leachable fraction of Cr(Ⅵ) from the treated samples is also analyzed through the method HJ/T 299-2007. The results indicate that mechanochemical remediation is very effective for the solidification and stabilization of Cr(Ⅵ)-contaminated soil. Cr(Ⅵ) leaching concentration decreased from 115 to 2.0?and 0.16?mg·-1, respectively, when without and with ferrous sulfate. In addition, during mechanochemical treatment, decrease in particle size, agglomeration and the conversion between Cr(Ⅵ) and Cr(Ⅲ) in contaminated soil are observed.
