Influences of density effect on the migration of remedial reagent in aquifer-Laboratory study using KMnO4 solution as an example
FU Yu-feng1,2, LIAN Jing-ru1,2, GUO Chao1,2, HE Yu1,2, QIN Chuan-yu1,2
1. Key Laboratory of Groundwater Resources and Environment Ministry of Education, Jilin University, Changchun 130021, China; 2. College of Environment and Resources, Jilin University, Changchun 130021, China
Abstract:The solution of KMnO4 was used in this study to investigate the migration and distribution of KMnO4 in simulated aquifer.This study focused on the influence of concentration and aquifer material size on density effect through a series of two-dimensional simulation tank experiments.The sinking phenomenon of KMnO4 solution in the medium and coarse sand simulated aquifers was obvious.The sinking degree of migration front was more and more obvious during the migration process,which changed the migration form from plug flow to stratified flow and resulted in the failure of KMnO4 distribution at shallow simulated aquifer.The greater the material size and the higher the concentration of remedial reagent,the more obvious the frontal sinking phenomenon at the preliminary stage was,but the extent of solution sinking was inversely proportional to the medium size and the concentration at the later stage.For the main migration region behind the migration front,KMnO4 gradually distributed more uniformly with the extension of migration time.
付玉丰, 廉静茹, 郭超, 何宇, 秦传玉. 密度效应对修复药剂在含水层迁移的影响——以KMnO4溶液为例的室内实验研究[J]. 中国环境科学, 2018, 38(3): 993-1000.
FU Yu-feng, LIAN Jing-ru, GUO Chao, HE Yu, QIN Chuan-yu. Influences of density effect on the migration of remedial reagent in aquifer-Laboratory study using KMnO4 solution as an example. CHINA ENVIRONMENTAL SCIENCECE, 2018, 38(3): 993-1000.
Mosmeri H, Alaie E, Shavandi M, et al. Benzene-contaminated groundwater remediation using calcium peroxide nanoparticles:synthesis and process optimization[J]. Environmental Monitoring & Assessment, 2017,189(9):452.
Konz M, Ackerer P, Younes A, et al. Two-dimensional stable-layered laboratory-scale experiments for testing density-coupled flow models[J]. Water Resources Research, 2009,45(2):142-143.
[8]
Swartz C H, Schwartz F W. An experimental study of mixing and instability development in variable-density systems[J]. Journal of Contaminant Hydrology, 1998,34(3):169-189.
[9]
Frind E O. Simulation of long-term transient density-dependent transport in groundwater[J]. Advances in Water Resources, 1982, 5(2):73-88.
Gemitzi A, Tolikas D. HYDRA model:Simulation of salt intrusion in coastal aquifers using Visual Basic and GIS[J]. Environmental Modelling & Software, 2007,22(7):924-936.
Jawitz J W, Annable M D, Rao P S C. Miscible fluid displacement stability in unconfined porous media:Two-dimensional flow experiments and simulations[J]. Journal of Contaminant Hydrology, 1998,31(3/4):211-230.
[16]
Taylor T P, Pennell K D, Abriola L M, et al. Surfactant enhanced recovery of tetrachloroethylene from a porous medium containing low permeability lenses:2. Numerical simulation[J]. Journal of Contaminant Hydrology, 2001,48(3):351-374.
[17]
Agaoglu B, Copty N K, Scheytt T, et al. Interphase mass transfer between fluids in subsurface formations:A review[J]. Advances in Water Resources, 2015,79:162-194.
[18]
Shokrollahi A, Majidi S M J, Ghazanfari M H. Monitoring and characterizing the finger patterns developed by miscible displacement in fractured heavy oil systems[J]. Industrial & Engineering Chemistry Research, 2013,52(31):10853-10863.
[19]
Satyajit P, Kumar H T, Manoranjan M. Influence of viscosity contrast on buoyantly unstable miscible fluids in porous media[J]. Journal of Fluid Mechanics, 2015,780:388-406.
[20]
Schincariol R A, Schwartz F W. An experimental investigation of variable density flow and mixing in homogeneous and heterogeneous media[J]. Water Resources Research, 1990,26(10):2317-2329.
[21]
Hawthorne R G. Two-phase flow in two-dimensional systems-Effects of rate, viscosity and density on fluid displacement in porous media[J]. Society of Petroleum Engineers, 1960,219:81-87.
[22]
Lake L W. Enhanced oil recovery[M]. Englewood Cliffs, NJ:Prentice-Hall Inc., 1989:128-233.
[23]
Zhong L, Oostrom M, Wietsma T W, et al. Enhanced remedial amendment delivery through fluid viscosity modifications:experiments and numerical simulations[J]. Journal of Contaminant Hydrology, 2008,101(1):29-41.
[24]
Crane F E, Kendall H A, Gardner G H F. Some experiments on the flow of miscible fluids of unequal density through porous media[J]. Society of Petroleum Engineers Journal, 1963,3(3):277-280.