Determination of Optimum Insulation Thickness for Building Walls in Iran Using Life Cycle Cost Analysis

Author

Abstract

Air-Conditioning (AC) systems are responsible for a considerable portion of energy consumption in buildings located in high cooling load requiring regions of Iran. In addition, the heat flow through the buildings' external walls plays a major role in cooling load estimations for the country's hot regions. Therefore, the application of insulation materials in external walls has gained more interest in recent years. In the present research, a systematic approach to optimize the insulation material thickness has been developed and applied to those regions in Iran which require high cooling load, namely Bandar abbas and Bushehr, through deploying life cycle cost analysis. Moreover, a correlation between optimum thickness and thermal conductivity of insulation materials has been recommended for the buildings located in the above-mentioned hot regions of the country. The study has showed that the relationship between optimum insulation thickness and thermal conductivity has a non-linear trend and obeys a polynomial function.

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[1] Khodakarami, J. and Ghobadi, P., "Optimizing of energy consumption in an office building equipped with intelligent management System", Energ. Eng. Manag., Vol. 6, pp. 12–23, 2016.
[2] Aktacir, M. A., Buyukalaca, O. and Yılmaz, T. "A case study for influence of building thermal insulation on cooling load and air-conditioning system in the hot and humid regions", Appl. Energy, Vol. 87, pp. 599–607, February 2010.
[3] Mahlia, T. M. I., Taufiq, B. N., Ismail, B. and Masjuki, H. H., "Correlation between thermal conductivity and the thickness of selected insulation materials for building wall", Energ. Buildings, Vol. 39, pp. 182–187, February 2007.
[4] Mahlia, T. M. I. and Iqbal, A.,"Cost benefits analysis and emission reductions of optimum thickness and air gaps for selected insulation materials for building walls in Maldives," Energy, Vol. 35, pp. 2242–2250, May 2010.
[5] A. Bolatturk, "Determination of optimum insulation thickness for building walls with respect to various fuels and climate zones in Turkey," Appl. Therm. Eng., Vol. 26, pp. 1301–1309, August 2006.
[6] Dombyci, Ő. A. Gölcü, M. and Pancar, Y., "Optimization of insulation thickness for external walls using different energy-sources", Appl. Energy, Vol. 83, pp. 921-928, September 2006.
[7] Liu, X., Chen, Y., Ge, H., Fazio, P. and Chena, G., "Determination of optimum insulation thickness of exterior wall with moisture transfer in hot summer and cold winter zone of China", Procedia Engineering, Vol. 121, pp. 1008–1015, 2015.
[8] Ozel, M., "Effect of wall orientation on the optimum insulation thickness by using a dynamic method", Appl. Energy, Vol. 88, pp. 2429–2435, July 2011.
[9] Comaklı, K. and Yuksel, B., "Environmental impact of thermal insulation thickness in buildings", Appl. Therm. Eng., Vol. 24, pp. 933–940, April 2004.
[10] Shekarchian, M., Moghavvemi, M., Rismanchi, B., Mahlia, T. M. I. and Olofsson, T., "The cost benefit analysis and potential emission reduction evaluation of applying wall insulation for buildings in Malaysia", Renew. Sust. Energ. Rev., Vol. 16, pp. 4708–4718, September 2012.
[11] Kurekci, N. A., "Determination of optimum insulation thickness for building walls by using heating and cooling degree-day values of all Turkey’s provincial centers", Energ. Buildings, Vol. 118, pp. 197–213, April 2013.
[12] Gustafsson, S. I. and Karlson, B. G., "Insulation and bivalent heating system optimization: residential housing retrofits and time-of-use tariffs for electricity", Appl. Energy, Vol. 34, pp. 303–315, 1989.
[13] Yuan, J., Farnham, C., Emura, K. and Ashraful Alam, M. D., "Proposal for optimum combination of reflectivity and insulation thickness of building exterior walls for annual thermal load in Japan", Build. Envirn., Vol. 103 , pp. 228–237, July 2016.
[14] Daouas, N., Hassen, Z. and Aissia, H. B., "Analytical periodic solution for the study of thermal performance and optimum insulation thickness of building walls in Tunisia", Appl. Therm. Eng., Vol. 30, pp. 319–326, March 2010.
[15] Ashouri, M., Astaraei, F. R., Ghasempour, R., Ahmadi, M. H. and Feidt, M., "Optimum insulation thickness determination of a building wall using exergetic life cycle assessment", Appl. Therm. Eng., Vol. 106, pp. 307–315, 2016.
[16] Al-Sanea, S. A., Zedan, M. F. and Al-Ajlan, S. A., "Effect of electricity tariff on the optimum insulation-thickness in building walls as determined by a dynamic heat transfer model", Appl. Energy, Vol. 82, pp. 313–330, December 2005.
[17] Al-Khawaji, M. J., "Determination and selecting the optimum thickness of insulation for buildings in hot countries by accounting for solar radiation", Appl. Therm. Eng., Vol. 24, pp. 2601–2610, December 2004.
[18] Soylemez, M. S. and Unsal, M., "Optimum insulation thickness for refrigeration applications", Energ. Convers. Manage., Vol. 40, pp. 13–21, January 1999.
[19] Derradji, L., Imessad, K. Amara, M. and Errebai, F. B., "A study on residential energy requirement and the effect of the glazing on the optimum insulation thickness", Appl. Therm. Eng., Vol. 112, pp. 975–985, February 2017.
[20] Kaynakli, O., "A study on residential heating energy requirement and optimum insulation thickness", Renew. Energ., Vol. 33, pp. 164–172, June 2008.
[21] Kameni, M., Ricciardi, N. P., Reiter, S. and Yvon, A., "A comparative study on optimum insulation thickness of walls and energy savings in equatorial and tropical climate", Int. J. Sust. Built. Environ. Vol. 6, pp. 170–182, June 2017.
[221] Ozel, M. and Pihtili, K., "Optimum location and distribution of insulation layers on building walls with various orientations", Build. Environ., Vol. 42, pp. 3051–3059, August 2007. 
[23] ASHRAE, ASHRAE Handbook, HVAC Applications (SI), 2007.
[24] Solar Energy Laboratory, U.o.W.-M. TRNSYS 16, A Transient System Simulation program, http://www.wisc.edu.
[25] Tabatabaei, S. M., Buildings Installations Calculations, 15ed ed., Rozbahan, Iran, 2014.