Thermal Potential of Soil as a Source of Energy for Heating and Cooling of Buildings
Anton A. Zharov , Alexey V. Kasatkin , Artem V. Borisenko
Refrigeration Technology ›› 2021, Vol. 110 ›› Issue (3) : 137 -144.
Thermal Potential of Soil as a Source of Energy for Heating and Cooling of Buildings
This article describes the problem of the operation of modern and, in the future, under-construction buildings and the need to install energy-efficient heating and cooling systems. The proposed system utilizes the thermal potential of the soil with an annual cycle for heating and cooling purposes of the building. In winter mode, the refrigerant circulates in the system via gravitational forces when it boils at the bottom of the heat pipe immersed in the soil, taking heat from the latter, and condenses at the top of the heat pipe, transferring heat to the air or liquid coolant of the building heating system. The refrigerant then flows downward due to gravity. However, during the summer, lifting the refrigerant condensed in the lower in-ground portion of the heat pipe to the top to evaporate and cool the building is a difficult engineering task, especially if the goal is not to use electricity. Liquid lift options used in an energy-efficient building HVAC system were described. A review of possible solutions that can lift fluids to the top with minimal energy input was also performed. Two different types of capillary lift systems, ultrasonic lift, the possibility of combining the above methods, and osmotic lift, steam pump lift, and the classic submersible pump were all considered. A qualitative comparative analysis of the proposed variants was performed, and the final result based on the scheme was provided. The tasks for further research and experiment setting were also proposed.
energy efficiency / bioclimatic buildings / energy-efficient buildings / heat pipe / thermosiphon / systems with natural heating and cooling of buildings and structures
| [1] |
Patent USA 2350348A 1942 / 21.12.1942. Gaugler RS. Heat transfer device. [Accessed: 09.04.2021] Available from: https://patents.google.com/patent/US2350348A/en?oq=2350348 |
| [2] |
Patent USA 2350348A 1942 / 21.12.1942. Gaugler R.S. Heat transfer device. [дата обращения: 09.04.2021] Доступ по ссылке: https://patents.google.com/patent/US2350348A/en?oq=2350348 |
| [3] |
Patent USA 3229759A 1963 / 02.12.1963. Grover GM. Evaporation-condensation heat transfer device [Accessed: 09.04.2021] Available from: https://patents.google.com/patent/US3229759A/en?oq=U.S.+Patent+No.+3%2c229%2c759. |
| [4] |
Patent USA 3229759A 1963 / 02.12.1963. Grover G.M. Evaporation-condensation heat transfer device [дата обращения: 09.04.2021] Доступ по ссылке: https://patents.google.com/patent/US3229759A/en?oq=U.S.+Patent+No.+3%2c229%2c759. |
| [5] |
Patent USA 3965970A 1973 / 10.10.1974. Chisholm D. Control of two-phase thermosyphons [Accessed: 09.04.2021] Available from: https://patents.google.com/patent/US3965970A/en?q=(Anti-gravity+thermosiphon+Chisholm)&oq=Anti-gravity+thermosiphon+Chisholm. |
| [6] |
Patent USA 3965970A 1973 / 10.10.1974. Chisholm D. Control of two-phase thermosyphons [дата обращения: 09.04.2021] Доступ по ссылке: https://patents.google.com/patent/US3965970A/en?q=(Anti-gravity+thermosiphon+Chisholm)&oq=Anti-gravity+thermosiphon+Chisholm. |
| [7] |
Patent RUS 2098141C1 1990 / 17.12.1991. Sheriff Sheikh Roland. Osmotic pump. (In Russ). [Accessed: 09.04.2021] Available from: https://patents.google.com/patent/RU2098141C1/ru?oq=2098141. |
| [8] |
Патент РФ 2098141C1 1990 / 17.12.1991. Шериф Шейкх Ролан. Осмотический насос [дата обращения: 09.04.2021] Доступ по ссылке: https://patents.google.com/patent/RU2098141C1/ru?oq=2098141. |
| [9] |
Zhang Q, Scholar M, Stewart SW, et al. Bubble pump modeling for solar hot water heater system design optimization. Penn State McNair J. 2011;18:167–187. [Accessed: 09.04.2021] Available from: https://gradschool.psu.edu/sites/GradSchool/McNairJournals/mcnair_jrnl2011/files/PSU_McNair_Vol18.pdf#page=181 |
| [10] |
Zhang Q., Scholar M., Stewart S.W., et al. Bubble pump modeling for solar hot water heater system design optimization // The Penn State McNair Journal. 2011. Vol. 18. P 167–187. [дата обращения: 09.04.2021] Доступ по ссылке: https://gradschool.psu.edu/sites/GradSchool/McNairJournals/mcnair_jrnl2011/files/PSU_McNair_Vol18.pdf#page=181 |
| [11] |
Sathe ABHIJIT. Experimental and theoretical studies on a bubble pump for a diffusion absorption refrigeration system. India Institute of Technology, Madras, India; 2001. [Accessed: 09.04.2021] Available from: https://citeseerx.ist.psu.edu/document?repid=rep1&type=pdf&doi=618cf1ab4919a8fcfa0152872af6d6030ae84bd2 |
| [12] |
Sathe A.B.H.I.J.I.T. Experimental and Theoretical Studies on a Bubble Pump for a Diffusion-Absorption Refrigeration System. Master of technology project report, Universitat Stuttgart, 2001. [дата обращения: 09.04.2021] Доступ по ссылке: https://citeseerx.ist.psu.edu/document?repid=rep1&type=pdf&doi=618cf1ab4919a8fcfa0152872af6d6030ae84bd2 |
| [13] |
Shelton SV, Stewart SW, Erickson D, et al. Bubble pump design for single pressure absorption refrigeration cycles. Ashrae Transactions. 2002;108(1):867–876. [Accessed: 09.04.2021] Available from: https://www.researchgate.net/profile/Sam-Shelton-3/publication/280015230_Bubble_Pump_Design_for_Single_Pressure_Absorption_Refrigeration_Cycles/links/004635318bc935ad47000000/Bubble-Pump-Design-for-Single-Pressure-Absorption-Refrigeration-Cycles.pdf |
| [14] |
Shelton S.V., Stewart S.W., Erickson D., et al. Bubble pump design for single pressure absorption refrigeration cycles. Ashrae Transactions. 2002. Vol. 108(1). P. 867–876. [дата обращения: 09.04.2021] Доступ по ссылке: https://www.researchgate.net/profile/Sam-Shelton-3/publication/280015230_Bubble_Pump_Design_for_Single_Pressure_Absorption_Refrigeration_Cycles/links/004635318bc935ad47000000/Bubble-Pump-Design-for-Single-Pressure-Absorption-Refrigeration-Cycles.pdf |
| [15] |
Li J, Zou Y, Cheng L. Experimental study on capillary pumping performance of porous wicks for loop heat pipe. Experimental Thermal and Fluid Science. 2010;34(8):1403–1408. doi: 10.1016/j.expthermflusci.2010.06.016 |
| [16] |
Li J., Zou Y., Cheng L. Experimental study on capillary pumping performance of porous wicks for loop heat pipe // Experimental Thermal and Fluid Science. 2010. Vol. 34, N 8. P. 1403–1408. doi: 10.1016/j.expthermflusci.2010.06.016 |
| [17] |
Renard E. Implantable closed-loop glucose-sensing and insulin delivery: the future for insulin pump therapy. Current opinion in pharmacology. 2002;2(6):708–716. doi: 10.1016/S1471-4892(02)00216-3 |
| [18] |
Renard E. Implantable closed-loop glucose-sensing and insulin delivery: the future for insulin pump therapy // Current opinion in pharmacology. 2002. Vol. 2, N 6. P. 708–716. doi: 10.1016/S1471-4892(02)00216-3 |
| [19] |
Zimmermann M, Schmid H, Hunziker P, et al. Capillary pumps for autonomous capillary systems. Lab on a Chip. 2007;7(1):119–125. doi: 10.1039/B609813D |
| [20] |
Zimmermann M., Schmid H., Hunziker P., et al. Capillary pumps for autonomous capillary systems // Lab on a Chip. 2007. Vol. 7, N. 1. P. 119–125. doi: 10.1039/B609813D |
Eco-Vector
/
| 〈 |
|
〉 |
PDF
