The study focuses on the blockage of Escherichia coli during the recharge process of underground water source heat pumps. The migration and deposition of Escherichia coli in the pores and channels of Porous medium were dynamically observed through the self-developed sand particle migration and deposition test system. In this paper, three test boxes with different lengths were used to carry out the migration and deposition of Escherichia coli in Porous medium. Through the test, the following conclusions were drawn: The internal friction force inside the quartz stone particles is conducive to the deposition of Escherichia coli, and the flow speed plays a key role in the microbial blockage caused by Escherichia coli; Three types of test boxes with different lengths (60, 80, 100 cm) were used as objects under the action of flow velocity, and the sedimentation rate increased by 57.1% for 100 cm and 80 cm; Compared with 80 and 60 cm, the sedimentation rate increased by 27.3%; The recovery rate of Escherichia coli is also positively correlated with fluid velocity, and its principle is similar to sedimentation rate. The experimental research conclusion has on-site guidance significance for microbial blockage in groundwater source heat pump recharge.
Key words
underground water source heat pump /
Escherichia coli /
porous medium /
sedimentary characteristics /
migration sedimentation /
test system
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References
[1] 亢涵, 王谋薇, 藏春月, 等. 地下水源热泵回灌堵塞的研究现状与展望[J]. 地球环境学报, 2017, 8(4): 320-326.
KANG H, WANG M W, ZANG C Y, et al.Research status and prospect of recharge clogging of groundwater heat pump[J]. Journal of earth environment, 2017, 8(4): 320-326.
[2] 赵军, 张程远, 刘泉声. 地源热泵井回灌阻塞实验研究[J].岩石力学与工程学报, 2013, 32(S2): 3364-3369
ZHAO J, ZHANG C Y, LIU Q S.Experimental study on clogging of ground source heat pump[J]. Journal of rock mechanics and engineering, 2013, 32(S2): 3364-3369
[3] 赵军, 刘泉声, 张程远. 水源热泵井回灌堵塞颗粒迁移模型的建立[J]. 岩土力学, 2013, 34(11): 3249-3253.
ZHAO J, LIU Q S, ZHANG C Y.Establishment of particle transport model in water source heat pump of physical clogging reinjection well[J]. Rock and soil mechanics, 2013, 34(11): 3249-3253.
[4] 赵军, 张程远, 刘泉声. 水源热泵回灌井悬浮颗粒运移和沉积物理特性试验模型研究[J]. 岩石力学与工程学报, 2014, 33(2): 257-263.
ZHAO J, ZHANG C Y, LIU Q S.Test study of physical properties of suspended particles migration and deposition in water source heat pump injection well[J]. Chinese journal of rock mechanics and engineering, 2014, 33(2): 257-263.
[5] BEAR J.Dynamics of fluids in porous media[M]. New York : Dover Publications, 1988.
[6] GUO Z, LIU X M, MA L, et al.Effects of particle morphology, pore size and surface coating of mesoporous silica on Naproxen dissolution rate enhancement[J]. Colloids and surfaces B: biointerfaces, 2013, 101: 228-235.
[7] MESTICOU Z, KACEM M, DUBUJET P.Influence of ionic strength and flow rate on silt particle deposition and release in saturated porous medium: experiment and modeling[J]. Transport in porous media, 2014, 103(1): 1-24.
[8] GODINHO J R A, CHELLAPPAH K, COLLINS I, et al. Time-lapse imaging of particle invasion and deposition in porous media using in situ X-ray radiography[J]. Journal of petroleum science and engineering, 2019, 177: 384-391.
[9] CERVANTES-AVILÉS P, HUANG Y X, KELLER A A. Multi-technique approach to study the stability of silver nanoparticles at predicted environmental concentrations in wastewater[J]. Water research, 2019, 166: 115072.
[10] BERGENDAHL J A, GRASSO D.Mechanistic basis for particle detachment from granular media[J]. Environmental science & technology, 2003, 37(10): 2317-2322.
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