Design of spiral coil PHC energy pile considering effective borehole thermal resistance and groundwater advection effects

Applied Energy

Volumn 125, Issue , 2014, Pages 165-178

  Go, Gyu Hyun ^a   Lee, Seung Rae ^a   Yoon, Seok ^a   Kang, Han byul ^a  

^a Korea Advanced Institute of Science and Technology (KAIST)   (South Korea)

Author keywords

Borehole thermal resistance; Groundwater advection; Multiple linear regression analysis; Numerical analysis; Spiral coil energy pile

Indexed keywords

ADVECTION; GROUNDWATER; LASER OPTICS; LINEAR REGRESSION; NUMERICAL ANALYSIS;

COEFFICIENT OF DETERMINATION; ENERGY PILES; GROUNDWATER ADVECTIONS; HIGH STRENGTH CONCRETES; MULTIPLE LINEAR REGRESSION ANALYSIS; MULTIPLE REGRESSION EQUATIONS; REGRESSION EQUATION; THERMAL RESPONSE TEST;

PILES;

ADVECTION; BOREHOLE; ENERGY FLOW; GROUNDWATER FLOW; PILE; THERMAL POWER;

HELICODISCUS BONAMICUS;

EID: 84899885974     PISSN: 03062619     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.apenergy.2014.03.059     Document Type: Article

References (46)

1. Choi J.C., Park J., Lee S.R. Numerical evaluation of the effects of groundwater flow on borehole heat exchanger arrays. Renew Energy 2013, 52:230-240.
2. Bose JE, Parker JD, MacQuison FC. Design/data manual for closed-loop ground coupled heat pump system, Oklahoma State University for ASHRAE; 1985.
3. Pahud D., Fromentin A., Hubbuch M. Heat exchanger pile system for heating and cooling at Zürich airport. IEA Heat Pump Centre Newslett 1999, 17(1):15-16.
4. Laloui L., Moreni M., Vulliet L. Behavior of a dual-purpose pile as foundation and heat exchanger. Can Geotech J 2003, 40(2):388-402.
5. Brandle H. Energy foundations and other thermo-active ground structures. Géotechnique 2006, 56(2):81-122.
6. Cui P., Li X., Man Y., Fang Z. Heat transfer analysis of pile geothermal heat exchangers with spiral coils. Appl Energy 2011, 88:4113-4119.
7. Boennec O. Shallow ground energy systems. Energy 2008, 161:57-61.
8. Man Y., Yang H.X., Diao N.R., Liu J.H., Fang Z.H. A new model and analytical solutions for borehole and pile ground heat exchangers. Int J Heat Mass Transf 2010, 53:2593-2601.
9. Florides G., Kalogirou S. First in situ determination of the thermal performance of a U-pipe borehole heat exchanger in Cyprus. Appl Therm Eng 2008, 28:157-163.
10. Shonder J.A., Beck J.V. Field test of a new method for determining soil formation thermal conductivity and borehole resistance. ASHRAE Trans 1999, 106:843-850.
11. Gu Y., O'Neal D.L. Development of an equivalent diameter expression for vertical U-tubes used in groundcoupled heat pumps. ASHRAE Trans 1998, 104:347-355.
12. Remund C.P. Borehole thermal resistance: laboratory and field studies. ASHRAE Trans 1999, 105(1):439-445.
13. Bennet J., Claesson J., Hellstrom G. Mutipole method to compute the conductive heat flows to and between pipes in a composite cylinder. Notes Heat Transfer 1987, 3:1-42.
14. Claesson J., Hellstrom G. Multipole method to calculate borehole thermal resistance in a borehole heat exchanger. HVAC R Res 2011, 17:895-911.
15. Man Y., Yang H.X., Diao N.R., Li X., Cui P., Fang Z.H. Development of spiral heat source model for novel pile ground heat exchangers. HVAC R Res 2011, 17(6):1075-1088.
16. Park S.K., Lee S.R., Park H.K., Yoon S., Chung J.W. Characteristics of an analytical solution for a spiral coil type ground heat exchanger. Comput Geotech 2013, 49:18-24.
17. Li M., Lai A.C.K. New temperature response functions (G functions) for pile and borehole ground heat exchangers based on composite-medium line-source theory. Energy 2012, 38:255-263.
18. Li M., Lai A.C.K. Heat-source solutions to heat conduction in anisotropic media with application to pile and borehole ground heat exchangers. Appl Energy 2012, 96:451-458.
19. Zarrella A., De Carli M., Galgaro A. Thermal performance of two types of energy foundation pile: helical pipe and triple U-tube. Appl Therm Eng 2013, 61:301-310.
20. Zarrella A., De Carli M. Heat transfer analysis of short helical borehole heat exchangers. Appl Energy 2013, 102(2):1477-1491.
21. Ingersoll L.R., Zobel O.J., Ingersoll A.C. Heat conduction: with engineering and geological applications 1954, McGraw-Hill, New York.
22. Kavanaugh S.P., Rafferty K. Ground-source heat pumps: design of geothermal systems for commercial and institutional buildings 1997, ASHRAE, Inc., Atlanta.
23. Carslaw H, Jaeger J. Conduction of heat in solids. Oxford; 1947.
24. Ingersoll L., Plass H. Theory of the ground pipe heat source for the heat pump. Piping Air Cond 1948, 20:119-122.
25. Bose J. Design and installations standards 1991, International Ground Source Heat Pump Association, Stillwater.
26. Man Y., Cui P., Fang Z.H. Heat transfer modeling of the ground heat exchangers for the ground-coupled heat pump systems. Modeling and optimization of renewable energy systems 2012, InTech, [Chapter 6].
27. Sutton M.G., Nutter D.W., Couvillion R.J. A ground resistance for vertical borehole heat exchangers with groundwater flow. J Energy Resour ASME 2003, 125(3):183-189.
28. Diao N.R., Li Q.Y., Feng Z.H. Heat transfer in ground heat exchangers with groundwater advection. Int J Therm Sci 2004, 43(12):1203-1211.
29. Nelson M.G., Philipp B., Zhu K., Bayer P., Fang Z.H. A moving finite line source model to simulate borehole heat exchangers with groundwater advection. Int J Therm Sci 2011, 50:2506-2513.
30. Kang HB. Improved design method of ground-source heat pump system and develop design program. Master thesis, Korea Advanced Institute of Science and Technology, Korea; 2014.
31. Hukseflux. User manual of TP08: small size non-steady probe for thermal conductivity measurement. Hukseflux Thermal Sensors. Delft, Netherlands; 2006.
32. ASTM D 5334. Standard test method for determination of thermal conductivity of soil and soft rock by needle probe procedure. Annual Book of ASTM Standards, vol. 04.09; 1995. p. 225-29.
33. IEEE Standard 442-1981. IEEE guide for soil thermal resistivity measurements. doi:10.1109/IEEESTD.1981.81018.
34. Park H.K., Park H.S., Lee S.R., Go G.H. Estimation of thermal conductivity of weathered granite soils". J Korean Soc Civ Eng 2012, 32(2):69-77.
35. Jeong S.S., Song J.Y., Min H.S., Lee S.J. Thermal influential factors of energy pile. J Korean Soc Civ Eng 2010, 6(6C):231-239.
36. Comsol Inc., Comsol multiphysics user's manual Ver. 4.3a. USA; 2012.
37. Incropera F.P., DeWitt D.P. Fundamentals of heat and mass transfer 1996, John Wiley & Sons. 4th ed.
38. Rees S.W., Adjali M.H., Zhou Z., Davies M., Thomas H.R. Ground heat transfer effects on the thermal performance of earth-contact structures. Renew Sust Energy Rev 2000, 4(3):213-265.
39. Choi J.C., Lee S.R., Lee D.S. Numerical simulation of vertical ground heat exchangers: Intermittent operation in unsaturated soil conditions. Comput Geotech 2011, 38:949-958.
40. Lurie M.V. Modeling of oil product and gas pipeline transportation 2008, WILEY-VCH Verlag GmbH & Co., KGaA, Weinheim.
41. Churchill S.W. Friction factor equations span all fluid-flow regimes. Chem Eng 1997, 84(24):91.
42. Park H.K., Lee S.R., Yoon S., Choi J.C. Evaluation of thermal response and performance of PHC energy pile: field experiments and numerical simulation. Appl Energy 2013, 103:12-24.
43. Jalauddin A., Miyara A. Thermal performance investigation of several types of vertical ground heat exchangers with different operation mode. Appl Therm Eng 2012, 33-34:167-174.
44. Li X., Chen Y., Chen Z., Zhao J. Thermal performances of different types of underground heat exchangers. Energy Build 2006, 38:543-547.
45. Durbin J., Watson G.S. Testing for serial correlation in least squares regression. III. Biometrika 1971, 58(1):1-19.
46. Sweet S., Grace-Martin K. Data analysis with SPSS: a first course in applies statistics 2011, Pearson Education Inc., Boston. 4th ed.