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Experimental study of a stand-alone earth to air heat exchanger for heating and cooling in arid regions

Year 2021, Volume: 7 Issue: 5, 1206 - 1215, 01.07.2021
https://doi.org/10.18186/thermal.978023

Abstract

Earth to air heat exchanger EAHE is a renewable technique based on a geothermal source. Arid regions are characterised by hard winter and summer weather conditions, which lead to a large thermal discomfort for the big part of the year. In this paper, we study by experiments the performance of stand-alone earth-to-air heat exchanger without external devices (fans, etc.), but only with the local climatic conditions of the region of Bechar (located in the Southwest of Algeria). The EAHE contains a PVC pipe with 66 meters of length and 110 mm of diameter, and it is buried at a depth of 1.5 m in an agriculture zone, where the annual undisturbed sub-soil at 1.5 m is 28°C. The stand-alone EAHE has the capacity to raise the air temperature by 10°C in the heating regime and reduce it by 11.9°C in the cooling regime. Furthermore, the relative humidity is raised by19% in the humidification regime and reduced by 27% in the dehumidification regime. The daily working regime was: 62.5% of heating (from 00h to 08h and from 18h to 23h) and 37.5% of cooling (from 09h to 17h) for the thermal regime, 62.5% of dehumidification (from 00h to 09h and from 18h to 23h) and 37.5% of humidification (from 10h to 17h) for the hygrometric regime. The stand-alone EAHE technique presents a great potential for the pre-heating, pre-cooling, and natural ventilation of dwellings and buildings in arid regions.

References

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  • [2] Hussein AK, Walunj A, Kolsi L. Applications of nanotechnology to enhance the performance of the direct absorption solar collectors. Journal of Thermal Engineering 2016;2(1):529-40.
  • [3] Li D, Li Z, Zheng Y, Liu C, Hussein AK, Liu X. Thermal performance of a PCM-filled double-glazing unit with different thermophysical parameters of PCM. Solar Energy 2016;133:207-20.
  • [4] Hussein AK. Applications of nanotechnology to improve the performance of solar collectors – Recent advances and overview. Renewable and Sustainable Energy Reviews 2016;62:767-92.
  • [5] Hussein AK, Li D, Kolsi L, Kata S, Sahoo B. A review of nano fluid role to improve the performance of the heat pipe solar collectors. Energy Procedia 2017;109:417- 24.
  • [6] Tiwari GN, Akhtar MA, Shukla A, Khan ME. Annual thermal performance of greenhouse with an earth-air heat exchanger: An experimental validation. Renewable Energy 2006;31:2432-46.
  • [7] Trombe A, Pettit M, Bourret B. Air cooling by earth tube heat exchanger: experimental approach. Renewable Energy 1991;1:699-707.
  • [8] Ozgener L. A review on the experimental and analytical analysis of earth to air heat exchanger (EAHE) systems in Turkey. Renewable and Sustainable Energy Reviews 2011;15:4483-90.
  • [9] Ozgener O, Ozgener L. Determining the optimal design of a closed loop earth to air heat exchanger for greenhouse heating by using exergoeconomics. Energy and Buildings 2011;43:960-5.
  • [10] Nayak S, Tiwari GN. Energy metrics of photovoltaic/thermal and earth air heat exchanger integrated greenhouse for different climatic conditions of India. Applied Energy 2010;87:2984-93.
  • [11] Yildiz A, Ozgener O, Ozgener L. Exergetic performance assessment of solar photovoltaic cell (PV) assisted earth to air heat exchanger (EAHE) system for solar greenhouse cooling. Energy and Buildings 2011;43:3154-60.
  • [12] Sobti J, Singh SK. Earth-air heat exchanger as a green retrofit for Chandīgarh - a critical review. Geotherm Energy 2015;3(1):1-9.
  • [13] Nayak S, Tiwari GN. Theoretical performance assessment of an integrated photovoltaic and earth air heat exchanger greenhouse using energy and exergy analysis methods. Energy and Buildings 2009;41:888-96.
  • [14] Ghalambaz M, Mehryan SAM, Hajjard A, Veismoradi A. Unsteady natural convection flow of a suspension comprising Nano-Encapsulated Phase Change Materials (NEPCMs) in a porous medium. Advanced Powder Technology 2019.
  • [15] Mehryan SAM, Heidarshenas MH, Hajjar A, Ghalambaz M. Numerical study of melting-process of a non-Newtonian fluid inside metal foam. Alexandria Engineering Journal 2020;59(1):191-207.
  • [16] Mehryan SAM, Vaezi M, Sheremet M, Ghalambaz M. Melting heat transfer of power-law non-Newtonian phase change nano-enhanced n-octadecane-mesoporous silica (MPSiO2). International Journal of Heat and Mass Transfer 2020;151:119385.
  • [17] Zhu CX, Wang CC, Tang YC. Performance and flow distribution of the plate heat exchanger with supercritical fluid of carbon dioxide. Journal of Thermal Engineering 2015;1(3):143-51.
  • [18] Vaza J, Sattler MA, dos Santos ED, Isoldi LA. Experimental and numerical analysis of an earth-air heat exchanger. Energy and Buildings 2011;43:2476-82.
  • [19] Kumara R, Kaushik SC, Garg SN. Heating and cooling potential of an earth-to-air heat exchanger using artificial neural network. Renewable Energy 2006;31:1139-55.
  • [20] Ghosal MK, Tiwari GN, Das DK, Pandey KP. Modelling and comparative thermal performance of ground air collector and earth air heat exchanger for heating of greenhouse. Energy and Buildings 2005;37:613-21.
  • [21] Ghosal MK, Tiwari GN. Modelling and parametric studies for thermal performance of an earth to air heat exchanger integrated with a greenhouse. Energy Conversion and Management 2006;47:1779-98.
  • [22] Ghosal MK, Tiwari GN. Parametric studies for heating performance of an earth to air heat exchanger coupled with a greenhouse. Int. J. Energy Res. 2005;29:991-1005.
  • [23] Ghosal MK, Tiwari GN, Srivastava NSL. Thermal modeling of a greenhouse with an integrated earth to air heat exchanger: an experimental validation. Energy and Buildings 2004;36:219-27.
  • [24] Pongsoi P, Wongwises S. Determination of fin pitches for maximum performance index of l-footed spiral fin-and-tube heat exchangers. Journal of Thermal Engineering 2015;1:251-62.
  • [25] Tittelein P, Achard G, Wurtz E. Modelling earth-to-air heat exchanger behaviour with the convolutive response factors method. Applied Energy 2009;86(9):1683-91.
  • [26] Ramírez-Dávila L, Xamán J, Arce J, Álvarez G, Hernández-Pérez I. Numerical study of earth-to-air heat exchanger for three different climates. Energy and Buildings 2014;76:238-48.
  • [27] Doğan B, Erbay LB. Experimental analysis of the effect of cold fluid inlet temperature on the thermal performance of a heat exchanger. Journal of Thermal Engineering 2016;2(1):583-92.
  • [28] Shukla A, Tiwari GN, Sodha MS. Parametric and experimental study on thermal performance of an earth-air heat exchanger. Int. J. Energy Res. 2006;30:365-79.
  • [29] Sharma B, Bhushan G, Sachdeva G. Effect of flow structure on heat transfer in compact heat exchanger by using finite thickness winglet at acute angle. Journal of Thermal Engineering 2017;3(2):1149-62.
  • [30] Chel A, Tiwari GN. Performance evaluation and life cycle cost analysis of earth to air heat exchanger integrated with adobe building for New Delhi composite climate. Energy and Buildings 2009;41:56-66.
  • [31] Diaz-Mendez SE, Patiño-Carachure C, Herrera-Castillo JA. Reducing the energy consumption of an earth-air heat exchanger with a PID control system. Energy Conversion and Management 2014;77:1-6.
  • [32] Ravisankar R, Venkatachalapathy VSK, Alagumurthi N. Application of nanotechnology to improve the performance of tractor radiator using cu-water nanofluid. Journal of Thermal Engineering 2018;4(4):2188-200.
  • [33] Thiers S, Peuportier B. Thermal and environmental assessment of a passive building equipped with an earth-to-air heat exchanger in France. Solar Energy 2008;82:820-31.
  • [34] Shukla A, Tiwari GN, Sodha MS. Thermal modelling for greenhouse heating by using thermal curtain and an earth-air heat exchanger. Building and Environment 2006;41:843-50.
  • [35] Kumar KP, Siddhardha R, Raju R, Kumar KS. Response surface based optimization of ribbed isosceles triangular twisted tape heat exchanger using entropy augmentation generation number with al2o3 nano working fluid. Journal of Thermal Engineering 2019;5(3):210-21.
  • [36] Misra R, Bansal V, Agarwal GD, Mathura J, Aseri T. Thermal performance investigation of hybrid earth air tunnel heat exchanger. Energy and Buildings 2012;49:531-5.
  • [37] Misra R, Bansal V, Agrawal GD, Mathur J, Aseri TK. CFD analysis based parametric study of derating factor for earth air tunnel heat exchanger. Applied Energy 2013;103:266-77.
  • [38] Darius D, Misaran MS, Rahman MdM, Ismail MA, Amaludin A. Working parameters affecting earth-air heat exchanger (EAHE) system performance for passive cooling: a review. IOP Conf. Series: Materials Science and Engineering 2017;217:12-21.
  • [39] Pourfayaz F, Kasaeian A, Fard MM. A proper selection of hot and cold utilities in a plant containing multiple heat exchanger networks. Journal of Thermal Engineering 2019;5(4):341-54.
  • [40] Oudjehani N, Abahri K, Tahakourt A, Belarbi R. Evaluation of earth-air heat exchangers efficiency in hot and dry climates. Advanced Materials Research 2013;739:318-24.
  • [41] Menni Y, Azzi A, Chamkha AJ. Modeling and analysis of solar air channels with attachments of different shapes. International Journal of Numerical Methods for Heat & Fluid Flow 2019;29(5):1815-45.
  • [42] Menni Y, Azzi A, Chamkha AJ, Harmand S. Effect of wall-mounted V-baffle position in a turbulent flow through a channel: analysis of best configuration for optimal heat transfer. International Journal of Numerical Methods for Heat & Fluid Flow 2019;29(10):3908-37.
  • [43] Menni Y, Azzi A, Chamkha A. Computational thermal analysis of turbulent forced convection flow in an air channel with a flat rectangular fin and downstream V-baffle. Heat Transfer Research 2019;50(18):1781-818.
  • [44] Maurya RS, Singh S. Numerical investigation of isothermal flow around impingement plates in a shell and tube exchanger. Journal of Thermal Engineering 2017;3(5):1442-52.
  • [45] Sakhri N, Menni Y, Chamkha AJ, Lorenzini E, Kaid N, Ameur H, Bensafi M, Sahel D. Study of heat and mass transfer through an earth to air heat exchanger equipped with fan in south west of Algeria. International Journal of Heat and Technology 2019;37(3):689-95.
  • [46] Sakhri N, Draoui B, Menni Y. Experimental study of earth to air heat exchanger performance in arid region. First step: in - situ measurement of ground vertical temperature profile for different depths. Journal of Advanced Research in Fluid Mechanics and Thermal Sciences 2019;56(2):183-94.
  • [47] Sakhri N, Menni Y, Chamkha AJ, Salmi M, Ameur H. Earth to Air Heat Exchanger and Its Applications in Arid Regions - An Updated Review. Italian Journal of Engineering Sciences 2020;64(1):83-90.
  • [48] Sakhri N, Menni Y, Chamkha AJ. Heating capacity of an Earth to Air Heat Exchanger in Arid regions – Experimental investigation. Journal of Applied and Computational Mechanics 2020. Doi: 10.22055/JACM.2020.31237.1843.
  • [49] Sakhri N. La ventilation naturelle dans les régions arides, Enjeux, Potentiels et perspectives. Editions Universitaires Européennes- ISBN: 978-613-8-46249-1. 2019 international Book Market Service Ltd., member of Omni Sriptum Publishing Group.
  • [50] Moussaoui A, Sakhri N, Draoui B, Rahmani L, Bensafi M. Design and modeling of a solar tower chimney effect intended for electrical energy production in Beni-Abbes site. IOSR journal of Mechanical and Civil Engineering 2016;13(5):134-41.
  • [51] Anand Y, Gupta A, Tyagi SK, Anand S. Variable capacity absorption cooling system performance for building application. Journal of Thermal Engineering 2018;4(5):2303-17.
  • [52] Ameur H, Menni Y. Laminar cooling of shear thinning fluids in horizontal and baffled tubes: Effect of perforation in baffles. Thermal Science and Engineering Progress 2019;14:100430.
  • [53] Bansal V, Misra R, Agrawal GD, Mathur J. Performance analysis of earth-pipe-air heat exchanger for summer cooling. Energy and Buildings 2010;42:645-8.
  • [54] Bansal V, Misra R, Agrawal GD, Mathur J. Performance analysis of earth-pipe-air heat exchanger for winter heating. Energy and Buildings 2009;41:1151-4.
  • [55] Bansal V, Mathur J. Performance enhancement of earth air tunnel heat exchanger using evaporative cooling. International Journal of Low-Carbon Technologies 2009;4:150-8.
  • [56] Mohapatra T, Rout SK. Experimental investigation and performance optimization of a cross flow heat exchanger by entropy generation minimization approach. Journal of Thermal Engineering 2019;5(2):1-12.
  • [57] Moussaoui A, Sakhri N, Draoui B, Rahmani L, Bensafi M. Changing the geometry of the Wind Tower and its Influence on Aerodynamic Behavior and Natural Ventilation. IOSR Journal of Mechanical and Civil Engineering 2016;1(4):13-9.
  • [58] Maerefat M, Haghighi AP. Passive cooling of buildings by using integrated earth to air heat exchanger and solar chimney. Renewable energy 2010;35:2316-24.
  • [59] Mohammed AH , Al-zuwaini H, Sergeev V, Socolova E, Skulkin S. Passive cooling by integrate solar chimney with earth to air heat exchanger. International Journal of Mechanical Engineering and Technology 2019;10(2):1375-90.
  • [60] Li H, Ni L, Yao Y, Sun C. Experimental investigation on the cooling performance of an Earth to Air Heat Exchanger (EAHE) equipped with an irrigation system to adjust soil moisture. Energy & Buildings 2019;196:280-92.
Year 2021, Volume: 7 Issue: 5, 1206 - 1215, 01.07.2021
https://doi.org/10.18186/thermal.978023

Abstract

References

  • [1] Hussein AK. Applications of nanotechnology in renewable energies-A comprehensive overview and understanding. Renewable and Sustainable Energy Reviews 2015;42:460-76.
  • [2] Hussein AK, Walunj A, Kolsi L. Applications of nanotechnology to enhance the performance of the direct absorption solar collectors. Journal of Thermal Engineering 2016;2(1):529-40.
  • [3] Li D, Li Z, Zheng Y, Liu C, Hussein AK, Liu X. Thermal performance of a PCM-filled double-glazing unit with different thermophysical parameters of PCM. Solar Energy 2016;133:207-20.
  • [4] Hussein AK. Applications of nanotechnology to improve the performance of solar collectors – Recent advances and overview. Renewable and Sustainable Energy Reviews 2016;62:767-92.
  • [5] Hussein AK, Li D, Kolsi L, Kata S, Sahoo B. A review of nano fluid role to improve the performance of the heat pipe solar collectors. Energy Procedia 2017;109:417- 24.
  • [6] Tiwari GN, Akhtar MA, Shukla A, Khan ME. Annual thermal performance of greenhouse with an earth-air heat exchanger: An experimental validation. Renewable Energy 2006;31:2432-46.
  • [7] Trombe A, Pettit M, Bourret B. Air cooling by earth tube heat exchanger: experimental approach. Renewable Energy 1991;1:699-707.
  • [8] Ozgener L. A review on the experimental and analytical analysis of earth to air heat exchanger (EAHE) systems in Turkey. Renewable and Sustainable Energy Reviews 2011;15:4483-90.
  • [9] Ozgener O, Ozgener L. Determining the optimal design of a closed loop earth to air heat exchanger for greenhouse heating by using exergoeconomics. Energy and Buildings 2011;43:960-5.
  • [10] Nayak S, Tiwari GN. Energy metrics of photovoltaic/thermal and earth air heat exchanger integrated greenhouse for different climatic conditions of India. Applied Energy 2010;87:2984-93.
  • [11] Yildiz A, Ozgener O, Ozgener L. Exergetic performance assessment of solar photovoltaic cell (PV) assisted earth to air heat exchanger (EAHE) system for solar greenhouse cooling. Energy and Buildings 2011;43:3154-60.
  • [12] Sobti J, Singh SK. Earth-air heat exchanger as a green retrofit for Chandīgarh - a critical review. Geotherm Energy 2015;3(1):1-9.
  • [13] Nayak S, Tiwari GN. Theoretical performance assessment of an integrated photovoltaic and earth air heat exchanger greenhouse using energy and exergy analysis methods. Energy and Buildings 2009;41:888-96.
  • [14] Ghalambaz M, Mehryan SAM, Hajjard A, Veismoradi A. Unsteady natural convection flow of a suspension comprising Nano-Encapsulated Phase Change Materials (NEPCMs) in a porous medium. Advanced Powder Technology 2019.
  • [15] Mehryan SAM, Heidarshenas MH, Hajjar A, Ghalambaz M. Numerical study of melting-process of a non-Newtonian fluid inside metal foam. Alexandria Engineering Journal 2020;59(1):191-207.
  • [16] Mehryan SAM, Vaezi M, Sheremet M, Ghalambaz M. Melting heat transfer of power-law non-Newtonian phase change nano-enhanced n-octadecane-mesoporous silica (MPSiO2). International Journal of Heat and Mass Transfer 2020;151:119385.
  • [17] Zhu CX, Wang CC, Tang YC. Performance and flow distribution of the plate heat exchanger with supercritical fluid of carbon dioxide. Journal of Thermal Engineering 2015;1(3):143-51.
  • [18] Vaza J, Sattler MA, dos Santos ED, Isoldi LA. Experimental and numerical analysis of an earth-air heat exchanger. Energy and Buildings 2011;43:2476-82.
  • [19] Kumara R, Kaushik SC, Garg SN. Heating and cooling potential of an earth-to-air heat exchanger using artificial neural network. Renewable Energy 2006;31:1139-55.
  • [20] Ghosal MK, Tiwari GN, Das DK, Pandey KP. Modelling and comparative thermal performance of ground air collector and earth air heat exchanger for heating of greenhouse. Energy and Buildings 2005;37:613-21.
  • [21] Ghosal MK, Tiwari GN. Modelling and parametric studies for thermal performance of an earth to air heat exchanger integrated with a greenhouse. Energy Conversion and Management 2006;47:1779-98.
  • [22] Ghosal MK, Tiwari GN. Parametric studies for heating performance of an earth to air heat exchanger coupled with a greenhouse. Int. J. Energy Res. 2005;29:991-1005.
  • [23] Ghosal MK, Tiwari GN, Srivastava NSL. Thermal modeling of a greenhouse with an integrated earth to air heat exchanger: an experimental validation. Energy and Buildings 2004;36:219-27.
  • [24] Pongsoi P, Wongwises S. Determination of fin pitches for maximum performance index of l-footed spiral fin-and-tube heat exchangers. Journal of Thermal Engineering 2015;1:251-62.
  • [25] Tittelein P, Achard G, Wurtz E. Modelling earth-to-air heat exchanger behaviour with the convolutive response factors method. Applied Energy 2009;86(9):1683-91.
  • [26] Ramírez-Dávila L, Xamán J, Arce J, Álvarez G, Hernández-Pérez I. Numerical study of earth-to-air heat exchanger for three different climates. Energy and Buildings 2014;76:238-48.
  • [27] Doğan B, Erbay LB. Experimental analysis of the effect of cold fluid inlet temperature on the thermal performance of a heat exchanger. Journal of Thermal Engineering 2016;2(1):583-92.
  • [28] Shukla A, Tiwari GN, Sodha MS. Parametric and experimental study on thermal performance of an earth-air heat exchanger. Int. J. Energy Res. 2006;30:365-79.
  • [29] Sharma B, Bhushan G, Sachdeva G. Effect of flow structure on heat transfer in compact heat exchanger by using finite thickness winglet at acute angle. Journal of Thermal Engineering 2017;3(2):1149-62.
  • [30] Chel A, Tiwari GN. Performance evaluation and life cycle cost analysis of earth to air heat exchanger integrated with adobe building for New Delhi composite climate. Energy and Buildings 2009;41:56-66.
  • [31] Diaz-Mendez SE, Patiño-Carachure C, Herrera-Castillo JA. Reducing the energy consumption of an earth-air heat exchanger with a PID control system. Energy Conversion and Management 2014;77:1-6.
  • [32] Ravisankar R, Venkatachalapathy VSK, Alagumurthi N. Application of nanotechnology to improve the performance of tractor radiator using cu-water nanofluid. Journal of Thermal Engineering 2018;4(4):2188-200.
  • [33] Thiers S, Peuportier B. Thermal and environmental assessment of a passive building equipped with an earth-to-air heat exchanger in France. Solar Energy 2008;82:820-31.
  • [34] Shukla A, Tiwari GN, Sodha MS. Thermal modelling for greenhouse heating by using thermal curtain and an earth-air heat exchanger. Building and Environment 2006;41:843-50.
  • [35] Kumar KP, Siddhardha R, Raju R, Kumar KS. Response surface based optimization of ribbed isosceles triangular twisted tape heat exchanger using entropy augmentation generation number with al2o3 nano working fluid. Journal of Thermal Engineering 2019;5(3):210-21.
  • [36] Misra R, Bansal V, Agarwal GD, Mathura J, Aseri T. Thermal performance investigation of hybrid earth air tunnel heat exchanger. Energy and Buildings 2012;49:531-5.
  • [37] Misra R, Bansal V, Agrawal GD, Mathur J, Aseri TK. CFD analysis based parametric study of derating factor for earth air tunnel heat exchanger. Applied Energy 2013;103:266-77.
  • [38] Darius D, Misaran MS, Rahman MdM, Ismail MA, Amaludin A. Working parameters affecting earth-air heat exchanger (EAHE) system performance for passive cooling: a review. IOP Conf. Series: Materials Science and Engineering 2017;217:12-21.
  • [39] Pourfayaz F, Kasaeian A, Fard MM. A proper selection of hot and cold utilities in a plant containing multiple heat exchanger networks. Journal of Thermal Engineering 2019;5(4):341-54.
  • [40] Oudjehani N, Abahri K, Tahakourt A, Belarbi R. Evaluation of earth-air heat exchangers efficiency in hot and dry climates. Advanced Materials Research 2013;739:318-24.
  • [41] Menni Y, Azzi A, Chamkha AJ. Modeling and analysis of solar air channels with attachments of different shapes. International Journal of Numerical Methods for Heat & Fluid Flow 2019;29(5):1815-45.
  • [42] Menni Y, Azzi A, Chamkha AJ, Harmand S. Effect of wall-mounted V-baffle position in a turbulent flow through a channel: analysis of best configuration for optimal heat transfer. International Journal of Numerical Methods for Heat & Fluid Flow 2019;29(10):3908-37.
  • [43] Menni Y, Azzi A, Chamkha A. Computational thermal analysis of turbulent forced convection flow in an air channel with a flat rectangular fin and downstream V-baffle. Heat Transfer Research 2019;50(18):1781-818.
  • [44] Maurya RS, Singh S. Numerical investigation of isothermal flow around impingement plates in a shell and tube exchanger. Journal of Thermal Engineering 2017;3(5):1442-52.
  • [45] Sakhri N, Menni Y, Chamkha AJ, Lorenzini E, Kaid N, Ameur H, Bensafi M, Sahel D. Study of heat and mass transfer through an earth to air heat exchanger equipped with fan in south west of Algeria. International Journal of Heat and Technology 2019;37(3):689-95.
  • [46] Sakhri N, Draoui B, Menni Y. Experimental study of earth to air heat exchanger performance in arid region. First step: in - situ measurement of ground vertical temperature profile for different depths. Journal of Advanced Research in Fluid Mechanics and Thermal Sciences 2019;56(2):183-94.
  • [47] Sakhri N, Menni Y, Chamkha AJ, Salmi M, Ameur H. Earth to Air Heat Exchanger and Its Applications in Arid Regions - An Updated Review. Italian Journal of Engineering Sciences 2020;64(1):83-90.
  • [48] Sakhri N, Menni Y, Chamkha AJ. Heating capacity of an Earth to Air Heat Exchanger in Arid regions – Experimental investigation. Journal of Applied and Computational Mechanics 2020. Doi: 10.22055/JACM.2020.31237.1843.
  • [49] Sakhri N. La ventilation naturelle dans les régions arides, Enjeux, Potentiels et perspectives. Editions Universitaires Européennes- ISBN: 978-613-8-46249-1. 2019 international Book Market Service Ltd., member of Omni Sriptum Publishing Group.
  • [50] Moussaoui A, Sakhri N, Draoui B, Rahmani L, Bensafi M. Design and modeling of a solar tower chimney effect intended for electrical energy production in Beni-Abbes site. IOSR journal of Mechanical and Civil Engineering 2016;13(5):134-41.
  • [51] Anand Y, Gupta A, Tyagi SK, Anand S. Variable capacity absorption cooling system performance for building application. Journal of Thermal Engineering 2018;4(5):2303-17.
  • [52] Ameur H, Menni Y. Laminar cooling of shear thinning fluids in horizontal and baffled tubes: Effect of perforation in baffles. Thermal Science and Engineering Progress 2019;14:100430.
  • [53] Bansal V, Misra R, Agrawal GD, Mathur J. Performance analysis of earth-pipe-air heat exchanger for summer cooling. Energy and Buildings 2010;42:645-8.
  • [54] Bansal V, Misra R, Agrawal GD, Mathur J. Performance analysis of earth-pipe-air heat exchanger for winter heating. Energy and Buildings 2009;41:1151-4.
  • [55] Bansal V, Mathur J. Performance enhancement of earth air tunnel heat exchanger using evaporative cooling. International Journal of Low-Carbon Technologies 2009;4:150-8.
  • [56] Mohapatra T, Rout SK. Experimental investigation and performance optimization of a cross flow heat exchanger by entropy generation minimization approach. Journal of Thermal Engineering 2019;5(2):1-12.
  • [57] Moussaoui A, Sakhri N, Draoui B, Rahmani L, Bensafi M. Changing the geometry of the Wind Tower and its Influence on Aerodynamic Behavior and Natural Ventilation. IOSR Journal of Mechanical and Civil Engineering 2016;1(4):13-9.
  • [58] Maerefat M, Haghighi AP. Passive cooling of buildings by using integrated earth to air heat exchanger and solar chimney. Renewable energy 2010;35:2316-24.
  • [59] Mohammed AH , Al-zuwaini H, Sergeev V, Socolova E, Skulkin S. Passive cooling by integrate solar chimney with earth to air heat exchanger. International Journal of Mechanical Engineering and Technology 2019;10(2):1375-90.
  • [60] Li H, Ni L, Yao Y, Sun C. Experimental investigation on the cooling performance of an Earth to Air Heat Exchanger (EAHE) equipped with an irrigation system to adjust soil moisture. Energy & Buildings 2019;196:280-92.
There are 60 citations in total.

Details

Primary Language English
Subjects Engineering
Journal Section Articles
Authors

N. Sakhrı This is me 0000-0003-0821-3847

Y. Mennı This is me 0000-0003-1475-3743

H. Ameur This is me 0000-0003-2087-7574

A.j. Chamkha This is me 0000-0002-8335-3121

Publication Date July 1, 2021
Submission Date February 1, 2020
Published in Issue Year 2021 Volume: 7 Issue: 5

Cite

APA Sakhrı, N., Mennı, Y., Ameur, H., Chamkha, A. (2021). Experimental study of a stand-alone earth to air heat exchanger for heating and cooling in arid regions. Journal of Thermal Engineering, 7(5), 1206-1215. https://doi.org/10.18186/thermal.978023
AMA Sakhrı N, Mennı Y, Ameur H, Chamkha A. Experimental study of a stand-alone earth to air heat exchanger for heating and cooling in arid regions. Journal of Thermal Engineering. July 2021;7(5):1206-1215. doi:10.18186/thermal.978023
Chicago Sakhrı, N., Y. Mennı, H. Ameur, and A.j. Chamkha. “Experimental Study of a Stand-Alone Earth to Air Heat Exchanger for Heating and Cooling in Arid Regions”. Journal of Thermal Engineering 7, no. 5 (July 2021): 1206-15. https://doi.org/10.18186/thermal.978023.
EndNote Sakhrı N, Mennı Y, Ameur H, Chamkha A (July 1, 2021) Experimental study of a stand-alone earth to air heat exchanger for heating and cooling in arid regions. Journal of Thermal Engineering 7 5 1206–1215.
IEEE N. Sakhrı, Y. Mennı, H. Ameur, and A. Chamkha, “Experimental study of a stand-alone earth to air heat exchanger for heating and cooling in arid regions”, Journal of Thermal Engineering, vol. 7, no. 5, pp. 1206–1215, 2021, doi: 10.18186/thermal.978023.
ISNAD Sakhrı, N. et al. “Experimental Study of a Stand-Alone Earth to Air Heat Exchanger for Heating and Cooling in Arid Regions”. Journal of Thermal Engineering 7/5 (July 2021), 1206-1215. https://doi.org/10.18186/thermal.978023.
JAMA Sakhrı N, Mennı Y, Ameur H, Chamkha A. Experimental study of a stand-alone earth to air heat exchanger for heating and cooling in arid regions. Journal of Thermal Engineering. 2021;7:1206–1215.
MLA Sakhrı, N. et al. “Experimental Study of a Stand-Alone Earth to Air Heat Exchanger for Heating and Cooling in Arid Regions”. Journal of Thermal Engineering, vol. 7, no. 5, 2021, pp. 1206-15, doi:10.18186/thermal.978023.
Vancouver Sakhrı N, Mennı Y, Ameur H, Chamkha A. Experimental study of a stand-alone earth to air heat exchanger for heating and cooling in arid regions. Journal of Thermal Engineering. 2021;7(5):1206-15.

IMPORTANT NOTE: JOURNAL SUBMISSION LINK http://eds.yildiz.edu.tr/journal-of-thermal-engineering