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| Investigation on heat transfer characteristics of PHC energy piles in multi-layer strata |
| CHEN Jiawei1,2,ZHANG Guozhu1,2,GUO Yimu1,2,CHEN Le1,2,NING Bowen1,
ZHANG Shuqi1,YA Zhou1,GAO Pengju1 |
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Abstract The PHC energy pile and traditional vertical ground heat exchanger have significant differences in heat exchanger structure,environmental sensitivity and heat transfer behavior. The long-term in-situ thermal response test of PHC energy pile in multi-layer strata was carried out at the energy pile testing site of Jiulonghu campus of Southeast University. The pile length is 24 m,and the heat exchange pipe is a single U-shape pipe. The duration of test reaches 1 100 h. The 20 m deep ground temperature borehole is set at 0.5,0.65 and 1.15 m from the center of the energy pile to monitor the ground temperature. Field test combined with numerical simulation to analyze and study the heat transfer behavior of PHC energy pile in multi-layer strata and the influence of multi-layer strata on the heat transfer performance of energy pile. The research results show that:(1) At the beginning of heating,the closer the soil to the energy pile,the faster the temperature rises. After a long heating period,the amplitude and velocity of ground temperature rise of each soil layer have decreased. For instance, after heating for 760 h,the temperature rise rate of each point in the soil decreased by more than 80% compared with the first continuous heating. (2) When the thermal response power changes,the closer the soil is to the energy pile,the greater the temperature of the energy pile and the more sensitive the response. As the distance increases,the temperature influence becomes smaller. The soil temperature response has a delay effect,and the further away from the energy pile,the greater the delay. (3) At the soil layer with high thermal conductivity and thermal diffusivity,the ground temperature amplitude and velocity of the soil near the energy pile are both small. Conversely,at the soil layer with lower thermal conductivity,the soil temperature near the energy pile rises faster and rises at a greater speed. (4) After the TRT unit stopped heating,the ground temperature at all points decreased and recovered quickly in the vicinity,while in the distance,the ground temperature showed a first increasing and then decreasing trend due to the delay effect. (5) Numerical simulation results show that thermal conductivity and specific heat capacity produce different effects on soil heat transfer. The heat exchange of the energy pile increases when the soil thermal conductivity is higher.
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Corresponding Authors:
(1. Institute of Geotechnical Engineering,Southeast University,Nanjing,Jiangsu 210096,China;2. Jiangsu Key Laboratory of Urban Underground Engineering and Environmental Safety,Southeast University,Nanjing,Jiangsu 210096,China)
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| [1] 夏才初,张国柱,孙 猛. 能源地下结构的理论及应用:地下结构内埋管的地源热泵系统[M]. 上海:同济大学出版社,2015:3–4.(XIA Caichu,ZAHNG Guozhu,SUN Meng. Theory and application of energy geo-structure:ground source heat pump system with ground heat exchanger in geo-structure[M]. Shanghai:Tongji University Press,2015:3–4.(in Chinese))
[2] 吕塞?拉卢伊(Lyesse Laloui),何莉塞?迪?唐纳(Alice Di Donna)编著. 能源地下结构[M]. 孔纲强 译. 北京:中国建筑工业出版社,2016:2–6.(LALOUI Lyesse,DI DONNA Alice. Energy Geo- structure[M]. KONG Gangqiang,ed. Beijing:China Architecture and Building Press,2016:2–6. (in Chinese))
[3] 夏才初,曹诗定,王 伟. 能源地下工程的概念、应用与前景展 望[J]. 地下空间与工程学报,2009,5(3):419–424.(XIA Caichu,CAO Shiding,WANG Wei. An introduction to energy geotechnical engineering[J]. Chinese Journal of Underground Space and Engineering,2009,5(3):419–424.(in Chinese))
[4] BRANDL H. Energy foundations and other thermo-active ground structures[J]. Geotechnique,2006,56(2):81–122.
[5] RYOZO O. Investigation of a ground source heat pump system for use in large and dense city areas in Japan[J]. IEA Heat Pump Centre Newsletter,2005,23(4):33–35.
[6] HASSANI N G E,UOTINEN V M,KUJALA K. Numerical modeling of thermal regimes in steel energy pile foundations:A case study[J]. Energy and Buildings,2014,69:165–174.
[7] MAN Y,YANG H X,DIAO N R,et al. A new model and analytical solutions for borehole and pile ground heat exchangers[J]. International Journal of Heat and Mass Transfer,2010,53(13/14): 2 593–2 601.
[8] GAO J,ZHANG X,LIU J,et al. Thermal performance and ground temperature of vertical pile-foundation heat exchangers:a case study[J]. Applied Thermal Engineering,2008,28(17):2 295–2 304.
[9] HAMADA Y,SAITOH H,NAKAMURA M,et al. Field performance of an energy pile system for space heating[J]. Energy and Buildings,2007,39(5):517–524.
[10] 赵 军,吴 挺,朱 强,等. U型管桩埋换热器稳态传热模拟研究[J]. 太阳能学报,2005,26(1):59–62.(ZHAO Jun,WU Ting,ZHU Qiang,et al. Thermal simulation on the steady heat transfer of the U-pipe pile heat exchanger[J]. Acta Energiae Solaris Sinica,2005,26(1):59–62.(in Chinese))
[11] 余乐渊,赵 军,李新国,等. 竖埋螺旋管地热换热器理论模型及实验研究[J]. 太阳能学报,2004,25(5):690–694.(YU Leyuan,ZHAO Jun,LI Xinguo,et al. A heat transfer model and the experiments for vertical spiral geothermal heat pump[J]. Acta Energiae Solaris Sinica,2004,25(5):690–694.(in Chinese))
[12] 桂树强,程晓辉,张志鹏. 地源热泵桩基与钻孔埋管换热器换热性能比较[J]. 土木建筑与环境工程,2013,35(3):151–156.(GUI Shuqiang,CHENG Xiaohui,ZHANG Zhipeng. Comparative Analysis of Heat Exchange Performance of Energy Piles and Borehole Heat Exchangers in GSHP System[J]. Journal of Civil,Architectural and Environmental Engineering,2013,35(3):151–156.(in Chinese))
[13] 孔纲强,刘汉龙,吴宏伟. 能量桩工程应用研究进展及PCC能量桩技术开发[J]. 岩土工程学报,2014,36(1):176–181.(KONG Gangqiang,LIU Hanlong,WU Hongwei. Applications of energy piles and technical development of pcc energy piles[J]. Chinese Journal of Geotechnical Engineering,2014,36(1):176–181.(in Chinese))
[14] BRANDL H. Energy piles and diaphragm walls for heat transfer from and into the ground[C]// Proceedings of the 3rd International Symp. on Deep Foundations on Bored and Auger Piles. [S. l.]:[s. n.],1998:37–60.
[15] LALOUI L,MOREINI M,VULLIET L. Comportement d′un pieu bi-fonction,foundation et échangeur de chaleur[J]. Can Geotechn 2003,40(2):388–402.
[16] LALOUI L,NUTH M,VULLIET L. Experimental and numerical investigation of the behavior of a heat exchanger pile[J]. Numer Anal Methods Geomech,2006,30(8):763–81.
[17] MCCARTNEY J,ROSENBERG J. Impact of heat exchange on the axial capacity of thermo-active foundations[C]// GeoFrontiers conference. [S. l.]:[s. n.],2011:488–498.
[18] MCCARTNEY J,MURPHY K. Strain distributions in full-scale energy foundations[J]. DFI. 2012,6(2):28–36.
[19] OLGUN G,MARTIN J,ABDELAZIZ S,et al. Field testing of energy piles at Virginia Tech[C]// Proceedings of the 37th Annual Conference on Deep Foundations. [S. l.]:[s. n.],2012:1–8.
[20] WITTE H. Advances In Geothermal Response Testing[M]. Thermal Energy Storage for Sustainable Energy Consumption. Netherlands:Springer,2007:177–192.
[21] YOU S,CHENG X H,GUO H X,et al. In-site experimental study of heat exchange capacity of CFG pile geothermal exchangers[J]. Energy and Building,2005,26(2):261–264.
[22] XIA C C,SUN M,ZHANG G Z. Experimental study of geothermal heat exchangers buried in diaphragm walls[J]. Energy and Buildings,2012,52(4):50–55.
[23] BOURNE-WEBB P J,AMATYA B,SOGA K,et al. Energy pile test at Lambeth College,London:geotechnical and thermodynamic aspects of pile response to heat cycles[J]. Géotechnique,2009,59(3):237–248.
[24] 赵海丰,唐荣彬,桂树强,等. 双U型埋管能源桩桩周岩土体温度场分布特征试验研究[J]. 土木建筑与环境工程,2016,38(5):157–163.(ZHAO Haifeng,TANG Rongbin,GUI Shuqiang,et al. Experimental analysis of ground temperature distribution of double-U type energy piles[J]. Journal of Civil,Architectural and Environmental Engineering,2016,38(5):157–163.(in Chinese))
[25] 刘爱华,佟红兵,冉伟彦. 北京某垂直地埋管区地温场变化规律研究[J]. 水文地质工程地质,2016,43(4):165–170.(LIU Aihua,TONG Hongbing,RAN Weiyan. A study of ground temperature changes in a vertical heat exchanger area of Beijing[J]. Hydrogeology and Engineering Geology,2016,43(4):165–170.(in Chinese))
[26] 王小清,王万忠. 地埋管地源热泵系统运行期地温监测与分析[J]. 上海国土资源,2013,34(2):76–79.(WANG Xiaoqing,WANG Wanzhong. Soil-temperature monitoring and analysis of a ground source heat pump system during the operating period[J]. Shanghai Land and Resources,2013,34(2):76–79.(in Chinese))
[27] 那 威,刘俊跃,宋 艳. 地埋管地源热泵水平埋管冬夏季工况换热性能及土壤温度场[J]. 暖通空调,2009,39(11):12–16.(NA Wei,LIU Junyue,SONG Yan. Heat transfer performance and temperature field of soil around horizontal buried heat exchangers for ground-coupled heat pump system[J]. Heating Ventilating and Air Conditioning,2009,39(11):12–16.(in Chinese))
[28] 杨露梅,鄂 建,朱明君,等. 典型地埋管系统模拟工况地温场特征研究[J]. 水文地质工程地质,2017,44(2):178–183.(YANG Lumei,E Jian,ZHU Mingjun,et al. Characteristics of the ground temperature of the typical ground-source heat pumps system in Nanjing[J]. Hydrogeology and Engineering Geology,2017,44(2):178–183.(in Chinese))
[29] 曾召田,徐云山,吕海波,等. 制热工况下岩溶区地源热泵实验研究[J]. 防灾减灾工程学报,2017,37(4):644–649.(ZENG Zhaotian,XU Yunshan,Lü Haibo,et al. Experimental study on ground source heat pump in karst area under heating condition[J]. Journal of Disaster Prevention and Mitigation Engineering,2017,37(4):644–649.(in Chinese))
[30] 王成龙,刘汉龙,孔纲强,等. 不同埋管形式下能量桩热力学特性模型试验研究[J]. 工程力学,2017,34(1):85–91.(WANG Chenglong,LIU Hanlong,KONG Gangqiang,et al. Model tests on thermal mechanical behavior of energy piles influenced with heat exchangers types[J]. Engineering Mechanics,2017,34(1):85–91.(in Chinese))
[31] 王泽生,颜爱斌,郭进京. 地下层状结构土体中埋管换热器的传热分析[J]. 太阳能学报,2009,30(2):188–192.(WANG Zesheng,YAN Aibin,GUO Jinjing,et al. Heat transfer analysis of underground heat exchangers in multi-soil beds[J]. Acta Energiae Solaris Sinica,2009,30(2):188–192.(in Chinese))
[32] 杨卫波,杨晶晶,孔 磊. 桩基螺旋型地埋管换热器换热性能的数值模拟与验证[J]. 农业工程学报,2016,(5):200–205.(YANG Weibo,YANG Jingjing,KONG Lei. Numerical simulation and validation on heat exchange performance of pile spiral coil ground heat exchanger[J]. Transactions of the Chinese Society of Agricultural Engineering,2016,(5):200–205.(in Chinese))
[33] 中华人民共和国国家标准编写组. GB50366—2005 地源热泵系统工程技术规范[S]. 北京:中国建筑工业出版社,2009.(The National Standards Compilation Group of People?s Republic of China. B50366—2005 Technical code for ground-source heat pump system[S]. Beijing:China Building Industry Press,2009.(in Chinese))
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2020, Vol. 39 
