EAHE-Solar Chimney Coupled Passive Cooling System and the Simulation

Alam, Chowdhury Sadid; Dhrubo, Tm Abir Ahsan

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dc.contributor.author	Alam, Chowdhury Sadid
dc.contributor.author	Dhrubo, Tm Abir Ahsan
dc.date.accessioned	2021-10-07T05:30:41Z
dc.date.available	2021-10-07T05:30:41Z
dc.date.issued	2017-11-15
dc.identifier.citation	1. Rahman, M.M., Khan, M.M.U.H., Ullah, M.A., Zhang, X. and Kumar, A., 2016. A hybrid renewable energy system for a North American off-grid community. Energy, 97, pp.151-160. 2. Rahman, M.M., Canter, C. and Kumar, A., 2015. Well-to-wheel life cycle assessment of transportation fuels derived from different North American conventional crudes. Applied Energy, 156, pp.159-173. 3. Rahman, M.M., Canter, C. and Kumar, A., 2014. Greenhouse gas emissions from recovery of various North American conventional crudes. Energy, 74, pp.607-617. 4. Rahman, M.M., Islam, A.S., Salehin, S. and Al-Matin, M.A., 2016. Development of a Model for Techno-economic Assessment of a Stand-alone Off-grid Solar Photovoltaic System in Bangladesh. International Journal of Renewable Energy Research (IJRER), 6(1), pp.140-149. 5. Li, H., Yu, Y., Niu, F., Shafik, M. and Chen, B., 2014. Performance of a coupled cooling system with earth-to-air heat exchanger and solar chimney. Renewable Energy, 62, pp.468-477. 6. Nugroho, A.M., Ahmad, M.H. and Hiung, T.J., 2006, April. Evaluation of parametrics for the development of vertical solar chimney ventilation in hot and humid climate. In The 2nd International Network for Tropical Architecture Conference, at Christian Wacana University, Jogjakarta. 7. Bisoniya, T.S., Kumar, A. and Baredar, P., 2013. Experimental and analytical studies of earth–air heat exchanger (EAHE) systems in India: a review. Renewable and Sustainable Energy Reviews, 19, pp.238-246. 8. Vaz, J., Sattler, M.A., dos Santos, E.D. and Isoldi, L.A., 2011. Experimental and numerical analysis of an earth–air heat exchanger. Energy and Buildings, 43(9), pp.2476-2482. 9. Ozgener, L., 2011. A review on the experimental and analytical analysis of earth to air heat exchanger (EAHE) systems in Turkey. Renewable and Sustainable Energy Reviews, 15(9), pp.4483-4490. 10. Ming, T., Liu, W., Pan, Y. and Xu, G., 2008. Numerical analysis of flow and heat transfer characteristics in solar chimney power plants with energy storage layer. Energy Conversion and Management, 49(10), pp.2872-2879. 28 11. Harris, D.J. and Helwig, N., 2007. Solar chimney and building ventilation. Applied Energy, 84(2), pp.135-146. 12. Chen, Z.D., Bandopadhayay, P., Halldorsson, J., Byrjalsen, C., Heiselberg, P. and Li, Y., 2003. An experimental investigation of a solar chimney model with uniform wall heat flux. Building and Environment, 38(7), pp.893-906. 13. M.Santamouris,Use of Earth To Air Heat Exchanger For Cooling. Air Infiltration and Ventilation Centre. International Energy Agency. Energy Conservation in Buildings and Community Systems Programme. 14. Macias, M., Gaona, J.A., Luxan, J.M. and Gomez, G., 2009. Low cost passive cooling system for social housing in dry hot climate. Energy and Buildings, 41(9), pp.915-921. 15. Maerefat, M. and Haghighi, A.P., 2010. Passive cooling of buildings by using integrated earth to air heat exchanger and solar chimney. Renewable Energy, 35(10), pp.2316-2324. 16. Calderaro, V. and Agnoli, S., 2007. Passive heating and cooling strategies in an approaches of retrofit in Rome. Energy and Buildings, 39(8), pp.875-885. 17. Raman, P., Mande, S. and Kishore, V.V.N., 2001. A passive solar system for thermal comfort conditioning of buildings in composite climates. Solar Energy, 70(4), pp.319-329. 18. Chungloo, S. and Limmeechokchai, B., 2009. Utilization of cool ceiling with roof solar chimney in Thailand: The experimental and numerical analysis. Renewable energy, 34(3), pp.623-633. 19. Dai, Y.J., Sumathy, K., Wang, R.Z. and Li, Y.G., 2003. Enhancement of natural ventilation in a solar house with a solar chimney and a solid adsorption cooling cavity. Solar energy, 74(1), pp.65-75. 20. Trilok Singh Bisoniya, Anil Kumar, and Prashant Baredar, Review Article. Study on Calculation Models of Earth-Air Heat Exchanger Systems. 21.F. Al-Ajmi, D. L. Loveday, and V. I. Hanby, “The cooling potential of earth-air heat exchangers for domestic buildings in a desert climate,” Building and Environment, vol. 41, no. 3, pp. 235–244, 2006. 22. X. Li, J. Zhao, and Q. Zhou, “Inner heat source model with heat andmoisture transfer in soil around the underground heat exchanger,” Applied Thermal Engineering, vol. 25, no. 10, pp. 1565–1577, 2005. 23. P. Hollmuller, “Analytical characterisation of amplitudedampening and phase-shifting in air/soil heat-exchangers,”International Journal of Heat and Mass Transfer, vol. 46, no. 22,pp. 4303–4317, 2003. 29 24. H. Wu, S. Wang, and D. Zhu, “Modelling and evaluation of cooling capacity of earth-air-pipe systems,” Energy Conversion and Management, vol. 48, no. 5, pp. 1462–1471, 2007. 25. J. Darkwa, G. Kokogiannakis, C. L. Magadzire, and K. Yuan, “Theoretical and practical evaluation of an earth-tube (E-tube) ventilation system,” Energy and Buildings, vol. 43, no. 2-3, pp. 728–736, 2011 26. Lee, K.H. and Strand, R.K., 2008. The cooling and heating potential of an earth tube system in buildings. Energy and Buildings, 40(4), pp.486-494. 27. Mihalakakou, G., Santamouris, M. and Asimakopoulos, D., 1994. Modelling the thermal performance of earth-to-air heat exchangers. Solar energy, 53(3), pp.301-305. 28. Bojic, M., Trifunovic, N., Papadakis, G. and Kyritsis, S., 1997. Numerical simulation, technical and economic evaluation of air-to-earth heat exchanger coupled to a building. Energy, 22(12), pp.1151-1158. 29. Gauthier, C., Lacroix, M. and Bernier, H., 1997. Numerical simulation of soil heat exchanger-storage systems for greenhouses. Solar energy, 60(6), pp.333-346. 30. Hollmuller, P. and Lachal, B., 2001. Cooling and preheating with buried pipe systems: monitoring, simulation and economic aspects. Energy and Buildings, 33(5), pp.509-518. 31. Kabashnikov, V.P., Danilevskii, L.N., Nekrasov, V.P. and Vityaz, I.P., 2002. Analytical and numerical investigation of the characteristics of a soil heat exchanger for ventilation systems. International Journal of Heat and Mass Transfer, 45(11), pp.2407-2418. 32. Santamouris, M., Mihalakakou, G., Argiriou, A. and Asimakopoulos, D.N., 1995. On the performance of buildings coupled with earth to air heat exchangers. Solar Energy, 54(6), pp.375-380. 33. Sehli, A., Hasni, A. and Tamali, M., 2012. The potential of earth-air heat exchangers for low energy cooling of buildings in South Algeria. Energy Procedia, 18, pp.496-506. 34. de Jesus Freire, A., Alexandre, J.L.C., Silva, V.B., Couto, N.D. and Rouboa, A., 2013. Compact buried pipes system analysis for indoor air conditioning. Applied Thermal Engineering, 51(1), pp.1124-1134. 35. Bansal, N.K., Mathur, R. and Bhandari, M.S., 1994. A study of solar chimney assisted wind tower system for natural ventilation in buildings. Building and Environment, 29(4), pp.495-500.	en_US
dc.identifier.uri	http://hdl.handle.net/123456789/1119
dc.description	Supervised by Md Mustafizur Rahman, Department of Mechanical and Chemical Engineering (MCE), Islamic University of Technology (IUT), Board Bazar, Gazipur-1704, Bangladesh.	en_US
dc.description.abstract	In the 21st century the talk of the time has been proper use of renewable energy sources due to the continuous depletion of non-renewable energy sources and global warming as a result of combustion of fossil fuels. The energy situation in the 3rd world countries is even worse. The continuous industrial development in the 1st world countries is hugely responsible for global temperature increase and greenhouse gas (GHG) emissions which badly affect the countries like Bangladesh. As of April 2016, the electricity generation capacity of Bangladesh was 12,399 MW to which only 60% of the total population have access to. The shortage of electricity during the summer season makes life very difficult. Cooling of buildings requires a large quantity of energy in the summer. An alternative cooling system can reduce the dependency on electricity. This paper specially deals with a passive cooling system that reduces pressure on the electricity supply and focuses on renewable energy sources. Here a different process engineering has been discussed which incorporates Earth-to-Air Heat Exchangers with solar collector enhanced solar chimney system. In this study natural ventilation of buildings, using solar chimney system is reviewed extensively. Experimentally it has already been observed that sufficient temperature drop takes place 2-3 m within the undisturbed ground, which can work as a heat sink for ambient air if passed through and can lead to attaining comfort zone at a confined location. During peak hours of summer this kind of system may work as a very efficient cooling system and reduces extra load on electricity supply	en_US
dc.language.iso	en	en_US
dc.publisher	Department of Mechanical and Production Engineering (MPE),Islamic University of Technology(IUT), Board Bazar, Gazipur, Bangladesh	en_US
dc.title	EAHE-Solar Chimney Coupled Passive Cooling System and the Simulation	en_US
dc.type	Thesis	en_US