Volume 20, Issue 10 (October 2020)                   Modares Mechanical Engineering 2020, 20(10): 2521-2531 | Back to browse issues page

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Rahaei O, Rezaei Zadeh A. Comparison of Thermal Behavior of Southern Trombe Walls with Different Geometrical Components in Ahwaz Corridor Spaces. Modares Mechanical Engineering 2020; 20 (10) :2521-2531
URL: http://mme.modares.ac.ir/article-15-39132-en.html
1- Department of Architecture, School of Architecture and Urban Design, Shahid Rajaei Teacher Training University, Tehran, Iran , o.rahaei@sru.ac.ir
2- Department of Architectural Engineering, School of Technical and Engineering, Institute for Higher Education ACECR Khuzestan, Ahvaz, Iran
Abstract:   (2256 Views)
Nowadays, the efficient use of solar energy for optimal use in the building industry has become one of the concerns of designers and builders. Studies show that by properly designing the exterior walls of the building, the amount of solar energy absorption can be managed for the building. Ahwaz is a tropical city that needs mechanical cooling most of the year. However, it has five cold months, with 3 months of use of heating systems to provide residents with thermal comfort. Therefore, the thrombus wall has been considered in this study. The aim of this study is to investigate and compare the thermal behavior of thrombus walls with different shapes in the sunny (south) walls of corridor spaces in Ahwaz. Research method is a hybrid method that incorporates empirical research strategies, simulation, and case research. On this basis, after experimental observations and field investigations on real samples, a general pattern was obtained and numerical calculations of the simulations were performed with CTF method after validation and reliability with Energy Plus software. In this study, by studying the sunroof wall (south side) of a default corridor space, five general compositions of the thrombus wall with the same conditions have been simulated and evaluated. The results have shown that in order to manage energy absorption, the geometry of the thrombus wall is of special importance and its chess pattern performs better than other models. At the end, some suggestions have been made.
Full-Text [PDF 1074 kb]   (2705 Downloads)    
Article Type: Original Research | Subject: Renewable Energy
Received: 2019/12/21 | Accepted: 2020/08/21 | Published: 2020/10/11

References
1. Ghosh A, Neogi S. Effect of fenestration geometrical factors on building energy consumption and performance evaluation of a new external solar shading device in warm and humid climatic condition. Solar Energy. 2018;169:94-104. [Link] [DOI:10.1016/j.solener.2018.04.025]
2. Zhuang Z, Guo W, Ye H, Fan R. Thermal performance of building under two ideal heating patterns. Procedia Engineering. 2017;205:3615-3622. [Link] [DOI:10.1016/j.proeng.2017.10.213]
3. Modirrousta S, Boostani H. Analysis of atrium pattern, Trombe wall and solar greenhouse on energy efficiency. Procedia Engineering. 2016;145:1549-1556. [Link] [DOI:10.1016/j.proeng.2016.04.195]
4. Hu Z, He W, Ji J, Zhang S. A review on the application of Trombe wall system in buildings. Renewable and Sustainable Energy Reviews. 2017;70:976-987. [Link] [DOI:10.1016/j.rser.2016.12.003]
5. Kruger E, Suzuki E, Matoski A. Evaluation of a Trombe wall system in a subtropical location. Energy and Buildings. 2013;66:364-372. [Link] [DOI:10.1016/j.enbuild.2013.07.035]
6. Torcellini P, Pless S. Trombe walls in low-energy buildings: Practical experiences. World Renewable Energy Congress, 29-3 August-September, Denver, United States. Golden: National Renewable Energy Laboratory. 2004. [Link]
7. Bojic M, Johannes K, Kuznik F. Optimizing energy and environmental performance of passive Trombe wall. Energy and Buildings. 2014;70:279-286. [Link] [DOI:10.1016/j.enbuild.2013.11.062]
8. Nwachukwu NP, Okonkwo WI. Effect of an absorptive coating on solar energy storage in a Trombe wall system. Energy and Buildings. 2008;40(3):371-374. [Link] [DOI:10.1016/j.enbuild.2007.03.004]
9. Chan HY, Riffat SB, Zhu J. Review of passive solar heating and cooling technologies. Renewable and Sustainable Energy Reviews. 2010;14(2):781-789. [Link] [DOI:10.1016/j.rser.2009.10.030]
10. Hassanain AA, Hokam E, Mallick TK. Effect of solar storage wall on the passive solar heating constructions. Energy and Buildings. 2011;43(2-3):737-747. [Link] [DOI:10.1016/j.enbuild.2010.11.020]
11. Khedari J, Kaewruang S, Pratinthong N, Hirunlabh J. Natural ventilation of houses by a Trombe wall under the climatic conditions in Thailand. International Journal of Ambient Energy. 1999;20(2):85-94. [Link] [DOI:10.1080/01430750.1999.9675323]
12. Liping W, Angui L. A numerical study of Trombe wall for enhancing stack ventilation in buildings. The 23rd Conference on Passive and Low Energy Architecture, 6-8 September 2006, Geneva, Switzerland. Unknown Publisher City: Energy Technologies Area; 2006. [Link]
13. Jaber S, Ajib S. Optimum design of Trombe wall system in Mediterranean region. Solar Energy. 2011;85(9):1891-1898. [Link] [DOI:10.1016/j.solener.2011.04.025]
14. Ghayabklo Z. New wall quality and natural cooling, Sofeh. 2011;21(4). [Persian] [Link]
15. Rabani M, Kalantar V, Rabani M. Heat transfer analysis of a Trombe wall with a projecting channel design. Energy. 2017;134:943-950. [Link] [DOI:10.1016/j.energy.2017.06.066]
16. Sokhandan Sorkhabi Z, Khanmohammadi MA. Optimizing the energy function of non-populated walls on sunny fronts. City Identity. 2015;9(23):73-82. [Persian] [Link]
17. Khalifa AJN, Abbas EF. A comparative performance study of some thermal storage materials used for solar space heating. Energy and Buildings. 2009;41(4):407-415. [Link] [DOI:10.1016/j.enbuild.2008.11.005]
18. Abolhassani N, Saghafi MJ, Mohammad Kari B, Fayaz R. Modular panels with heating and cooling systems. Modares Mechanical Engineering. 2016;6(1):31-41. [Persian] [Link]
19. Chen W, Liu W. Numerical analysis of heat transfer in a passive solar composite wall with porous absorber. Applied Thermal Engineering. 2008;28(11-12):1251-1258. [Link] [DOI:10.1016/j.applthermaleng.2007.10.017]
20. Koyunbaba BK, Yilmaz Z. The comparison of Trombe wall systems with single glass, double glass and PV panels. Renewable Energy. 2012;45:111-118. [Link] [DOI:10.1016/j.renene.2012.02.026]
21. Kameli H. Parameters that affect the performance of Trombe wall using computational fluid dynamics simulation. Iranian Journal of Energy. 2015;17(4):101-117. [Persian] [Link]
22. Shen J, Lassue S, Zalewski L, Huang D. Numerical study on thermal behavior of classical or composite Trombe solar walls. Energy and Buildings. 2007;39(8):962-974. [Link] [DOI:10.1016/j.enbuild.2006.11.003]
23. Dragicevic S, Lambic M. Influence of constructive and operating parameters on a modified Trombe wall efficiency. Archives of Civil and Mechanical Engineering. 2011;11(4):825-838. [Link] [DOI:10.1016/S1644-9665(12)60080-6]
24. Khalesi Doost A, Khani M, Abedini Esfahlani A. Empirical analysis and numerical influence the size and location of the valve Trombe wall using phase-change material (PCM). Journal of Mechanical and Vibration Engineering. 2014;5(3):19-25. [Persian] [Link]
25. Abolhassani N, Mohammadkari B, Fayaz R. The thermal rehabilitation of the building blocks in the cold climate in Iran by taking advantage of features Trombe wall. Iranian Architectural Studies. 2015;(8):107-118. [Persian] [Link]
26. Walton GN. Thermal analysis research program reference manual [Report]. Gaithersburg: National Bureau of Standards; 1983, 198316. [Link] [DOI:10.6028/NBS.IR.83-2655]
27. Lawrence berkeley laboratory. DOE2.1E-053 source code [Internet]. Berkeley: Lawrence Berkeley Laboratory (LBL); 1994 Unknown Cited & Cite. [Link]
28. Seem JE, Klein SA, Beckman WA, Mitchell JW. Comprehensive room transfer functions for efficient calculation of the transient heat transfer processes in buildings. Journal of Heat Transfer. 1989; 111(2):264-273. [Link] [DOI:10.1115/1.3250673]
29. Getter KL, Rowe DB. The role of extensive green roofs in sustainable development. Hort Science. 2006;41(5):1276-1285. [Link] [DOI:10.21273/HORTSCI.41.5.1276]
30. Ahmadi H, Shaemi A. Ilam city climate comfort based on biological indicators, physical spatial planning. 2012;1(1). [Persian] [Link]
31. Hovizavi H, Morshedi J. Determining the thermal comfort range of the building in Ahvaz based on bioclimatic indicators. 3rd Scientific Research Conference on New Horizons in Geography and Architecture and Urban Planning of Iran, 16 June 2016, Tehran, Iran. Tehran: Association for the Development and Promotion of Basic Sciences and Technologies; 2016. [Persian] [Link]
32. Wright JL, Sullivan HF. Natural convection in sealed glazing units: A review. ASHRAE Transactions. 1989;95:592-603. [Link]
33. Hollands KGT, Unny TE, Raithby GD, Konick L. Free convection heat transfer across inclined air layers. Journal of Heat Transfer. 1976;98(2):189-193. [Link] [DOI:10.1115/1.3450517]
34. ISO. 15099:2003-Thermal performance of windows, doors, and shading devices-detailed calculations [Internet]. Geneva: International Organization for Standardization; 2003 Unknown Cited. Available from: https://www.iso.org/standard/26425.html [Link]
35. Sohrabi H, Ghadimi M, Haji Mollaali Kenny A. Sensitivity analysis of energy consumption with respect to window-to-wall ratio in a residential building, in temperate and humid climates (case study: Ramsar city). First National Technology Conference Advanced in Engineering and Environment, 24 February 2019, Tehran, Iran. Tehran: Iranian Association of Environmental Specialists; 2019. [Persian] [Link]
36. Sadeghi Ravesh MH, Tabatabaei SM. Determination of thermal comfort in dry climates. Identity City. 2009;3(4):39-46. [Persian] [Link]

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