GUO Hao; QIAN Yong; YUAN Guang-xiang; WANG Chun-xiao

doi:10.19637/j.cnki.2305-7068.2020.01.006

doi: 10.19637/j.cnki.2305-7068.2020.01.006

基金项目:

WANG Chun-xiao

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出版历程
- 刊出日期: 2020-03-28

Research progress on the soil vapor extraction

1North China University of Water Resources and Electric Power, Zhengzhou 450046, China.2Institute of Hydrogeology and Environmental

Funds:

WANG Chun-xiao

摘要

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Abstract: Soil vapor extraction (SVE), the most common, efficient and economical means of remediation, is an in-situ remediation technique for removing volatile pollutants from unsaturated soil. The paper briefly introduced the technological rationale and cha?racteristics, summarized the theories and application research for SVE at home and abroad, and made the expectations and suggestions for the research on SVE. The international scholars have systematically researched the influence factors, remediation mechanism and numerical simulation of SVE. At present, SVE has been mostly integrated with other techniques to form enhanced SVE techniques, such as thermally enhanced SVE and AS-SVE (Air sparging-SVE), to be used for the field remediation widely. Compared with foreign countries, researches of Chinese scholars mainly focus on the laboratory research, especially on the influence factors, but rarely study the SVE model and the mass transfer mechanism of pollutant in SVE process. The SVE pilot studies are rare in China, and the field application has not been reported. In view of this situation, Chinese scholars in the future research can focus on the following aspects: (1) strengthening the research and systematized summary of SVE technical parameters and related knowledge; (2) strengthening the research on the mechanism and model of gas-phase mass transfer of pollutants in soil during SVE process; (3) strengthening the research on the enhanced SVE techniques and its application to actual site remediation.
- Soil vapor extraction (SVE) /
- In situ remediation /
- Organic pollution /
- Soil remediation

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参考文献(52)

WANG Hui-ling, WANG Feng, ZHANG Xue-ping, et al. 2015. Field study on influencing factors in removal of volatile organic compounds by soil vapor extracton. Science Technique and Engineering, 15(10): 238-242,246.

XIA Chun-lin. 1995. Soil venting technique to remediate sites contaminated with organic chemicals. Acta Scientiae Circumstantiae, 15(2): 246-250.

HE Wei, CHEN Hong-han, LIU Fei, et al. 2007. Effects of airflow velocity on the venting efficiency of gasoline polluted soil and the estimation of remediation time. Journal of Agro-Environment Science, 26(6): 2062-2066.

SUN Tie-xi, LI Pei-jun, ZHOU Qi-xing, et al. 2005. Soil pollution formation mechanism and remediation technique. Beijing: China Science Publishing & Media Ltd.

LI Jin-hui, NIE Yong-feng, MA Hai-bin, et al. 2002. Vapor Extraction Technique in Oil Contaminated Soil Remediation. Environmental Science, (01): 92-96.

Price S L, Kasevich R S, Johnson M A, et al. 1999. Radio frequency heating for soil remediation. Journal of the Air & Waste Management Association, 49(2): 136-142.

Albergaria J T, Alvim-Ferrazb M C M, Matosa C D. 2006. Remediation efficiency of vapour extraction of sandy soils contaminated with cyclohexane: Influence of air flow rate, water and natural organic matter content. Environmental Pollution, 143: 146-152.

Poulsen Tjalfe G, Moldrup Per, Yamaguchi Toshiko, et al. 1999. Predicting soil-water and soil-air transport properties and their effects on soil-vapor extraction efficiency. Ground Water Monitoring & Remediation, 19: 61-70.

Dustin G Poppendieck, Raymond C Loehr, Matthew T Webster. 1999. Predicting hydrocarbon removal from thermally enhanced soil vapor extraction systems 1, Laboratory studies. Journal of Hazardous Materials, 69(1): 81-93.

Crow, W L, et al. 1987. Subsurface venting of vapors emanating from hydrocarbon product on ground water. Ground water Monitoring Review, 7(l): 51-56.

Armstrong J E, Find E O, McClellan R D. 1994. Nonequilibrium mass transfer between the vapor, aqueous, and solid phases in unsaturated soils during vapor extraction. Water Resources Research, 30(2): 355-368.

DU Chuan, CHEN Su-yun, NIU Geng. 2017. Application analysis of extracting vacuum and related parameters in SVE technique. Environmental Engineering, 35(12): 189-193.

HUANG Guo-qiang, LI Xin-gang, JIANG Bin, et al. 2003. Numerical analysis of remediation of organic chemicals-contaminated soil by vertical well SVE. Journal of Chemical Industry and Engineering (China), 54(8): 1134-1140.

YANG Le-wei, HUANG Guo-qiang, LI Xin-gang. 2006. Study progress on soil vapor extraction technique. Environmental Protection Science, 32(06): 62-65.

Selker J S, Niemet M, McDufiie N G, et al. 2007. The local geometry of gas injection into saturated homogeneous porous media. Transport in Porous Media, 68: 107-127.

Yoon H K, Kim J H, Liljestrand H M, et al. 2002. Effect of water content on transient nonequilibrium NAPL-gas mass transfer during soil vapor extraction. Journal of Contaminant Hydrology, 64: 1-18.

Alvim-Ferraz M D C M, Albergaria J T, Delerue-Matos C. 2006. Soil remediation time to achieve clean-up goals I: Influence of soil water content. Chemosphere, 62(5): 853-860.

YU Ying, SHAO Zi-ying, LIU Liang, et al. 2017. Factors influencing remediation of semi-volatile petroleum hydrocarbon-contaminated soil by thermally enhanced soil vapor extraction. Chinese Journal of Environmental Engineering, 11(04): 2522-2527.

WANG Shu, WANG Feng, CHEN Su-yun, et al. 2011. Engineering applications of soil vapor extraction technique in contaminated sites. Environmental Engineering, 29(S1): 171-174.

James J，Wilson D J，Bolick J R. 1994. Soil clean up by in-situ aeration, XIV, Effects of random permeability variations on soil vapor extraction clean-up times. Separation Science and Technique, 29(6): 701-725.

SUN Hong-wen, Masafumi T, Michihiko I, et al. 2003. Short-and long-term sorption/desorption of polycyclic aromatic hydrocarbons onto artificial solids: Effects of particle and pore sizes and organic matters. Water Research, 37: 2960-2968.

LUO Cheng-cheng. 2016. Experimental study on remediation of diesel contaminated soil using thermally enhanced soil vapor extraction technique. Beijing: China University of Geosciences.

Hinchee. Rob, Downey Douglas, Dupont Robert, et al. 1991. Enhancing biodegradation of petroleum hydrocarbons through soil venting. Journal of Hazardous Materials, 27: 315-325.

Albergaria J T，Alvim-Ferraz M D C M，Delerue-Matos C. 2008. Soil vapor extraction in sandy soils: Influence of airflow rate. Chemosphere, 73(9): 1557-1561.

YANG Le-wei, SHEN Tie-meng, XIAO Feng, et al. 2008. Mass transfer in Napl (Benzene)-Containing SVE system. Acta Pedologica Sinica, 45(06): 1046-1050.

HE Xiao-zhen, ZHOU You-ya, WANG Li, et al. 2008. Study on influencing factors in removal of volatile organic compounds from red earth by soil vapor extraction. Chinese Journal of Environmental Engineering, 2(5): 679-683.

LU Zhong-hua, PEI Zong-ping, LU Shou-gan, et al. 2011. Tetrachloride from soils by soil vapor extraction. Environmental Science & Technique, 34(6): 20-23.

Tomlinson D W, Thomson N R, Johnson R L, et al. 2003. Air distribution in the borden aquifer during insitu air sparging. Contaminant Hydrology, 67(1-4): 113-132.

Poulsen T G, Moldrup P, Yamaguchi T, et al.1998. VOC vapor sorption in soil: soil type dependent model and implications for vapor extraction. Environ. Eng,124 (2): 146-155.

Reddy K R and Adamas J A. 2001. Effect of soil heterogeneity on airflow patterns and hydrocarbon removal during in situ air sparging. Geotech Geoenviron Eng, 127: 234-247.

R J Lenhard, M Oostrom, J H Dane. 2004. A constitutive model for air-NAPL-water flow in the vadose zone accounting for immobile, non-occluded NAPL strongly water-wet porous media. Journal of Contaminant Hydrology, 73(1-4): 283-304.

Morgan P. 1989. Microbiological methods for the cleanup of soil and groundwater contaminated with halogenated organic compounds. Fems Microbiology Reviews, 63: 277-300.

Marley M C, Hazebrouk D J, Walsh M T. 1992. The application of insitu sparging as an innovative soil and groundwater remediation technique. Groundwater Monitor Remediat, 12(2): 137-144.

Kaleris V, Croise J. 1997. Estimation of cleanup time for continuous and pulsed soil vapor extraction. Journal of Hydrology, 194(1-4): 330-356.

Wilkins M D, Abriola L M, Pennell K D. 1995. An experimental investigation of rate-limited nonaqueous phase liquid volatilization in unsaturated porous media：Steady state mass transfer. Water Resources Research, 31(9): 2159-2172.

Frank U，Barkley N. 1995. Remediation of low permeability subsurface formations by fracturing enhancement of soil vapor extraction. Journal of Hazardous Materials, 40(2): 191-201.

FENG Jun-sheng, ZHANG Qiao-chen. 2014. A review on the Study on Practice of Soil Remediation in situ. Ecology and Environmental Sciences, 23(11): 1861-1867.

YANG Le-wei, ZHANG Xiao-bin, GUO Li-li, et al. 2016. An application case of ex-situ soil vapor extraction in a subway remediation project in Beijing. Environmental Engineering, 34(5): 170-172.

Nguyen V T, ZHAO L, Zytner R G. 2013. Three-dimensional numerical model for soil vapor extraction. Journal of Contaminant Hydrology, 147: 82-95.

ZHOU You-ya, HE Xiao-zhen, HOU Hong, et al. 2009. Removal of benzene and ethylbenzene from soil by soil vapor extraction. CIESC Journal, 60(10): 2590-2595.

USEPA. 2017. Superfund Remedy Report. US Environmental Protection Agency.

LIAO Zhi-qiang. 2013. The Research about remediation of volatile organic contaminant by thermal enhanced soil vapor extraction. Shanghai: East China University of Science and Technique.

USEPA. 1997. Best management practices (BMP) for soils treament techniques. 530-R-97-007.

ZHOU You-ya, HE Xiao-zhen, LI Fa-sheng, et al. 2010. Decontamination mechanism of the volatile organic compound removal from red earth by soil vapor extraction. Environmental Chemistry, 29(01): 39-43.

HUANG Guo-qiang, LI Ling, LI Xin-gang. 2000. In-situ soil remediation of polluted soil. Environmental Science Trends, (3): 25-27.

ZHOU Qi-xing，SONG Yu-fang. 2004. Remediation of contaminated soils: Principles and methods. Beijing: China Science Publishing & Media Ltd.

MA Yan-fei，ZHENG Xi-lai，FENG Xue-dong, et al. 2011. Study on influence factor of soil vapor extraction restoring oil-contaminated soil. Non-Metallic Mines, 34(4): 53-58.

Downey Douglas C, Guest Peter R, Ratz John W. 1995. Results of a two-year in situ bioventing demonstration. Environmental Progress, 14: 121-125.

LI Jin-hui, ZHANG Xiao-yong, ZHANG Bu-wei, et al. 2008. Research on decontamination influence of moisture on two-dimensional vapor extraction. Jiangsu Environmental Science and Technique, 21(04): 1-5.

ZHANG Sheng, ZHANG Cui-yun, HE Ze et al. 2016. Application research of enhanced in-situ micro-ecological remediation of petroleum contaminated soil. Journal of Groundwater Science and Engineering, 4(3):157-164.

XIANG Xiu-bao. 2015. Engineering application in remediation of petroleum contaminated site by soil vapor extraction. Beijing: Beijing University of Chemical Technique.

Rathfelder K M, Lang J R, Abriola L M. 2000. A numerical model (MISER) for the simulation of couple physieal, chemical and biological proeesses in soil vapor extraction and bioventing systems. Journal of Contaminant Hydrology, 43(3-4): 239-270.

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