Study on Heat Transfer Characteristics of Energy Piles in Stratified Seepage Soil

CHEN Xi; TONG Meng-yu; ZHANG Zheng-wei

doi:10.13204/j.gyjzG21082101

Volume 52 Issue 9

Sep. 2022

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CHEN Xi, TONG Meng-yu, ZHANG Zheng-wei. Study on Heat Transfer Characteristics of Energy Piles in Stratified Seepage Soil[J]. INDUSTRIAL CONSTRUCTION, 2022, 52(9): 198-205. doi: 10.13204/j.gyjzG21082101

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CHEN Xi, TONG Meng-yu, ZHANG Zheng-wei. Study on Heat Transfer Characteristics of Energy Piles in Stratified Seepage Soil[J]. INDUSTRIAL CONSTRUCTION, 2022, 52(9): 198-205. doi: 10.13204/j.gyjzG21082101

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Study on Heat Transfer Characteristics of Energy Piles in Stratified Seepage Soil

doi: 10.13204/j.gyjzG21082101

College of Landscape Architecture, Zhejiang A&F University, Hangzhou 311300, China

Received Date: 2021-08-21
Available Online: 2023-02-06

Abstract

Abstract

Taking energy piles as the reasearch object, combined with the actual geological layered seepage, the differential equation for heat transfer of energy piles was established according to the principle of energy conservation. The excess temperature equation for heat transfer of energy piles in layered seepage soil was obtained by the method of seperation variables and Laplace Transform. The calculation software was programmed to verify the accuracy of the heat transfer model. Based on the model, the influence for thermophysical properties of soil and seepage velocities on the distribution of excess temperature was discussed. The results showed that changes in thermophysical properties of adjacent soil layers under and below the piles would influence the excess temperature distribution at the top and bottom of the piles, and had a certain impact on the total heat transfer of piles. Seepage had a significant impact on the distribution of excess temperature in stratified soil. At the same distance apart from the centers of energy piles, the excess temperature of the upper-stream was lower than that of the lower-stream in the same soil layer. The higher the seepage velocity, the more significant the isotherm deviation of excess temperature in the soil layer; the more obvious the heat transfer, and the higher the heat exchange efficiency of energy piles.
- layered soil,
- seepage,
- energy pile,
- calculation model,
- heat transfer characteristics

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References(16)

References

[1]	陈忠购, 张正威.分层渗流地层中竖直地埋管的换热计算模型[J].太阳能学报, 2013, 34(5):831-838.
[2]	DIAO N, LI Q, FANG Z.Heat transfer in ground heat exchangers with groundwater advection[J].International Journal of Thermal Sciences, 2004, 43(12):1203-1211.
[3]	MOLINA-GIRALDO N, BLUM P, ZHU K, et al.A moving finite line source model to simulate borehole heat exchangers with groundwater advection[J].International Journal of Thermal Sciences, 2011, 50(12):2506-2513.
[4]	王子阳, 张仪萍, 战国会, 等.有渗流时埋管换热器传热模型[J].浙江大学学报(工学版), 2012, 46(8):1450-1456.
[5]	CHOI J C, PARK J, LEE S R.Numerical evaluation of the effects of groundwater flow on borehole heat exchanger arrays[J].Renewable Energy, 2013, 52:230-240.
[6]	TYE-GINGRAS M, GOSSELIN L.Generic ground response functions for ground exchangers in the presence of groundwater flow[J].Renewable Energy, 2014, 72:354-366.
[7]	ZANCHINI E, LAZZARI S, PRIARONE A.Long-term performance of large borehole heat exchanger fields with unbalanced seasonal loads and groundwater flow[J].Energy, 2012, 38(1):66-77.
[8]	ANGELOTTI A, ALBERTI L, LA LICATA I, et al.Energy performance and thermal impact of a Borehole Heat Exchanger in a sandy aquifer:Influence of the groundwater velocity[J].Energy Conversion and Management, 2014, 77:700-708.
[9]	RIVERA J A, BLUM P, BAYER P.Analytical simulation of groundwater flow and land surface effects on thermal plumes of borehole heat exchangers[J].Applied Energy, 2015, 146:421-433.
[10]	LIUZZO-SCORPO A, NORDELL B, GEHLIN S.Influence of regional groundwater flow on ground temperature around heat extraction boreholes[J].Geothermics, 2015, 56:119-127.
[11]	王华军, 齐承英, 杜红普, 等.地下水渗流条件下埋地换热器传热性能的实验研究[J].太阳能学报, 2010, 31(12):1610-1614.
[12]	冯琛琛, 王沣浩, 张鑫, 等.地下水渗流对垂直埋管换热器换热性能影响的实验研究[J].制冷与空调, 2011, 25(4):328-331.
[13]	白冰.空心圆柱饱和多孔介质热固结问题的解析解[J].岩土力学, 2011, 32(10):2901-2906.
[14]	LUO J, ROHN J, BAYER M, et al.Analysis on performance of borehole heat exchanger in a layered subsurface[J].Applied Energy, 2014, 123:55-65.
[15]	HU J.An improved analytical model for vertical borehole ground heat exchanger with multiple-layer substrates and groundwater flow[J].Applied Energy, 2017, 202:537-549.
[16]	EROL S, FRANÇOIS B.Multilayer analytical model for vertical ground heat exchanger with groundwater flow[J].Geothermics, 2018, 71:294-305.