A novel numerical approach for imposing a temperature boundary condition at the borehole wall in borehole fields

Geothermics

Volumn 56, Issue , 2015, Pages 35-44

  Monzó, Patricia ^a   Mogensen, Palne ^a   Acuña, José ^a   Ruiz Calvo, Félix ^a   Montagud, Carla ^a  

^a ROYAL INSTITUTE OF TECHNOLOGY   (Sweden)

Author keywords

Borehole; G Function; Long term performance; Uniform borehole temperature

Indexed keywords

BOUNDARY CONDITIONS; CONDUCTIVE MATERIALS; ENTHALPY; HEAT EXCHANGERS; HEAT TRANSFER; ISOTHERMS; OFFICE BUILDINGS;

BOREHOLE HEAT EXCHANGERS; BOREHOLE TEMPERATURE; BOREHOLE WALL; FLUID TEMPERATURES; G-FUNCTIONS; HEAT-FLOW; LONG TERM PERFORMANCE; TEMPERATURE BOUNDARY; UNIFORM BOREHOLE TEMPERATURE; UNIFORM TEMPERATURE;

HEAT FLUX;

BOREHOLE GEOPHYSICS; BOREHOLE LOGGING; DESIGN; HEAT FLOW; NUMERICAL MODEL; TEMPERATURE;

CALLUNA VULGARIS;

EID: 84925424683     PISSN: 03756505     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.geothermics.2015.03.003     Document Type: Article

References (25)

1. Andersson O., Bjelm L. Geothermal energy use, country update for Sweden. Proceeding of European Geothermal Congress 2013, EGC2013-CUR30 2013.
2. Claesson J., Javed S. An analytical method to calculate borehole fluid temperatures for time-scales from minutes to decades. ASHRAE Trans. 2011, 117(2):279-288.
3. Cimmino M., Bernier M., Adams F. A contribution towards the determination of g-functions using the finite line source. Appl. Therm. Eng. 2013, 51:101-412.
4. Cimmino M., Bernier M. Preprocessor for the generation of g-functions used in the simulation of geothermal systems. Proceedings of BS2013: 13th Conference of International Building Performance Simulation Association 2013.
5. Cimmino M., Bernier M. A semi-analytical method to generate g-functions for geothermal bore fields. Int. J. Heat Mass Transfer 2014, 70:641-650.
6. Corberán J.M., Finn D.P., Montagud C., Murphy F.T., Edwards K.C. A quasi-steady state mathematical model of an integrated ground source heat pump for building space control. Energy Build. 2011, 43:82-92.
7. Cullin J., Montagud C., Ruiz-Calvo F., Spitler J.D. Experimental validation of ground heat exchanger design methodologies using real monitored data. ASHRAE Trans. 2013, 120(2):357-369.
8. Cullin J. Advancements in the simulations of ground source heat pump systems 2014, (PhD thesis), School of Mechanical and Aerospace Engineering, Oklahoma State University.
9. Cullin J.R., Spitler J.D., Montagud C., Ruiz-Calvo F., Rees S.J., Naicker S.S., Konečný P., Southard L.E. Validation of vertical ground heat exchanger design methodologies. Sci. Technol. Built Environ. 2015, 21(2):137-149. 10.1080/10789669.2014.974478.
10. Eskilson P. Superposition Borehole Model. Manual for Computer Code 1986, Dept. of Mathematical Physics, Lund Institute of Technology, Lund, Sweden.
11. Eskilson P. Thermal analyses of heat extraction Boreholes 1987, (PhD thesis), Dept. of Mathematical Physics, Lund Institute of Technology, Lund, Sweden.
12. Fossa M. A fast method for evaluating the performance of complex arrangements of borehole heat exchangers. HVAC&R 2011, 17(6):948-958.
13. Fossa M. The temperature penalty approach to the design of borehole heat exchangers for heat pump applications. Energy Build. 2011, 43:1473-1479.
14. Ground-Med, 2011 D.6.5: University Polytechnic of Valencia demo system 696 in Spain. Work Package 6: 697 Integrated ground source heat pump demonstration systems. Seventh FP No TREN/FP7EN/218895. 698 . http://www.groundmed.eu/uploads/media/Deliverable_6.5_UPV_demo_system_01.pdf%2024/04/2012.
15. Hellström G., Sanner B. Earth energy designer: software for dimensioning of deep boreholes for heat extraction. Proceedings of Calorstock - 6th International Conference on Thermal Energy Storage 1994.
16. Lamarche L., Beauchamp B. A new contribution to the finite line-source model for geothermal boreholes. Energy Build. 2007, 39:188-198.
17. Lazzarotto A. A network-based methodology for the simulation of borehole heat storage systems. Renew. Energy 2014, 62:265-275.
18. Malayappan V., Spitler J.D. Limitations of using heat flux assumptions in sizing vertical borehole heat exchanger fields. Proceeding of Clima 2013 2013.
19. Marshall C.L., Spitler J.D. GLHEPRO - The Professional Ground Loop Heat Exchanger Design Software, Users Guide School of Mechanical and Aerospace Engineering 1994, Oklahoma State University, Stillwater, Oklahoma.
20. Montagud C., Corberán J.M., Montero Á., Urchueguía J.F. Analysis of the energy performance of a ground source heat pump system after five years of operation. Energy Build. 2011, 43:3618-3626.
21. Monzó P., Acuña J., Fossa M., Palm B. Numerical generation of the temperature response factors for a borehole heat exchanger field. European Geothermal Congress, ISBN 978-2-8052-0226-1, EGC2013-SG118 2013.
22. Monzó P., Acuña J., Mogensen P., Palm B. A study of the thermal response of a borehole field in winter and summer. Proceedings of 5th International Conference on Applied Energy, ICAE2013-524 2013, Pretoria, South Africa.
23. Urchueguía J. Curso de doctorado sobre "Técnicas Energéticas Avanzadas" 2006, Universitat Politècnica de València.
24. Yang H., Cui P., Fang Z. Vertical-borehole ground-coupled heat pumps: a review of models and systems. Appl. Energy 2010, 87:16-27.
25. Zeng H., Diao N., Fang Z. A finite line-source model for boreholes in geothermal heat exchangers. Heat Transf. - Asian Res. 2002, 31:558-567.