Validated Model of Helical Pipe Earth Air Tunnel Heat Exchanger
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Author(s)
Abstract
This work is oriented to fulfil the cooling or heating demand of building space using ground renewable energy to get the independency on conventional energy. In this paper, EATHE (Earth Air Tunnel Heat Exchanger) simulated model has been developed using ANSYS Fluent. The grid independency study has been done for CFD model at different mash size has and model has been validated by experimental data. Further analysis has been done for EATHE model consists of 50 m length of helical PVC pipe. The diameter of pipe, thickness are 0.15 m and 0.002 m respectively. Velocity of air through the channel is set to 7 m/s. The EATHE is used to cool a building room having cooling load of 0.8 TR and floor area of 156 square feet situated in the dry climate of Bikaner city in Rajasthan, India.
Keywords
Thermal conductivity, CFD, Temperature, Velocity, Earth Air Tunnel Heat Exchanger
Cite this paper
Nasim Hasan, Mohd. Arif,
Validated Model of Helical Pipe Earth Air Tunnel Heat Exchanger
, SCIREA Journal of Energy.
Volume 4, Issue 3, June 2019 | PP. 44-50.
References
[ 1 ] | T. S. Bisoniya, A. Kumar, and P. Baredar, “Experimental and analytical studies of earth-air heat exchanger (EAHE) systems in India: a review,” Renewable and Sustainable Energy Reviews, vol. 19, pp. 238–246, 2013. |
[ 2 ] | V. Bansal, R. Misra, G. D. Agrawal, and J. Mathur, “Performance analysis of earth-pipe-air heat exchanger for winter heating,” Energy and Buildings, vol. 41, no. 11, pp. 1151–1154, 2009. |
[ 3 ] | V. Bansal, R. Misra, G. D. Agrawal, and J. Mathur, “Performance analysis of earth-pipe-air heat exchanger for summer cooling,” Energy and Buildings, vol. 42, no. 5, pp. 645–648, 2010. |
[ 4 ] | N. K. Bansal, M. S. Sodha, and S. S. Bharadwaj, “Performance of Earth-air tunnel system,” International Journal of Energy Research, vol. 7, no. 4, pp. 333–345, 1983. S. S. Bharadwaj and N. K. Bansal, “Temperature distribution inside ground for various surface conditions,” Building and Environment, vol. 16, no. 3, pp. 183–192, 1981. |
[ 5 ] | M. Santamouris, A. Argiriou, and M. Vallindras, “Design and operation of a low energy consumption passive solar agricultural greenhouse,” Solar energy, vol. 52, no. 5, pp. 371–378, 1994. |
[ 6 ] | R. Kumar, S. C. Kaushik, and S. N. Garg, “Heating and cooling potential of an earth-to-air heat exchanger using artificial neural network,” Renewable Energy, vol. 31, no. 8, pp. 1139–1155, 2006. |
[ 7 ] | M. Zukowski, B. Sadowska, and W. Sarosiek, “ASSESSMENT OF THE COOLING POTENTIAL OF AN EARTH-TUBE HEAT EXCHANGER IN RESIDENTIAL BUILDINGS,” pp. 830–834, 2011. |
[ 8 ] | A. Trząski and B. Zawada, “The influence of environmental and geometrical factors on air-ground tube heat exchanger energy efficiency,” Build. Environ., vol. 46, no. 7, pp. 1436–1444, Jul. 2011. |
[ 9 ] | H. Su, X.-B. Liu, L. Ji, and J.-Y. Mu, “A numerical model of a deeply buried air–earth–tunnel heat exchanger,” Energy Build., vol. 48, pp. 233–239, May 2012. |
[ 10 ] | V. Bansal, R. Mishra, G. Das Agarwal, and J. Mathur, “Performance analysis of integrated earth – air-tunnel-evaporative cooling system in hot and dry climate,” vol. 47, pp. 525–532, 2012. |
[ 11 ] | Hasan, N., & Mathur, Y. B. Computational Fluid Dynamics Analysis of Earth Air Tunnel Heat Exchanger for Cooling in Summer Season, Rex Journal Volume 4 Issue 2, 2017 Page 641-646. |
[ 12 ] | Hasan, N., & Mathur, Y. B. Optimizing the Design of Earth Air Tunnel Heat Exchanger for Cooling in Summer Season, International Multidisciplinary Mulitilingual E-Journal, Volume 5 Issue 1 Page 19-29. |
[ 13 ] | Hasan, N., & Mathur, Y. B. Optimizing the Diameter of Earth Air Tunnel Heat Exchanger for Cooling in Summer Season. ACHIEVING SUSTAINABLE STRATEGIC ADVANTAGE, 98, ISBN: 978-93-86608-37-6. |
[ 14 ] | Hasan N, Mathur Y. B., Khader M. K., Validation of Earth Air Tunnel Heat Exchanger CFD Model To Experimental Setup, IOSR Journal of Engineering, Vol. 08, Issue 01 (January. 2018), V2, PP 20-25. |
[ 15 ] | Saifi, M. S., Jakhar, O. P., & Hasan, N. (2016). CFD Parametric Investigation for Two Phase Flow of Refrigerant 134a In an Adiabatic Capillary tube. International Journal of Civi, Mechanical and Energy Science, 2(2), 94-98. |
[ 16 ] | Khader, M. A., Hasan, N., & Degefe, M. Optimization of Bajaj three-wheeler carburetor fuel tube for better performance, International Digital Library of Technology & Research Volume 1, Issue 6, June 2017. |
[ 17 ] | Daniel A., Yilma T. B. & Hasan N., “Experimental Analysis of Cook Stove for Efficient Utilization of Biomass Energy in Ethiopia”, International Journal of Multidisciplinary Educational Research, Volume 6, Issue 12(3), December 2017. |