A Study of Energy Efficiency Simulation Programs and Energy Saving Optimization Analysis of Building Envelopment Parameters in Turkey

Baneaez, Mustafa Obaid Omar; Akkoyunlu, Mustafa Tahir

doi:10.12911/22998993/169178

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Tytuł artykułu

A Study of Energy Efficiency Simulation Programs and Energy Saving Optimization Analysis of Building Envelopment Parameters in Turkey

Autorzy

Baneaez Mustafa Obaid Omar , Akkoyunlu Mustafa Tahir

Treść / Zawartość

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DOI

10.12911/22998993/169178

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Języki publikacji

Abstrakty

This study focused on optimizing energy consumption in buildings by improving the building envelope, which accounts for a significant portion of heating and cooling energy usage. The research took an existing building in the Konya-Meram region as an example and conducted experiments on insulation, window-to-wall ratio, and glass thickness. Simulations were performed considering the climate of the Turkey-Konya region for comparative analysis. Various programs, such as Revit, Ecotect, Hap, and the Izoder TS-825 calculator (the Turkish standard) were utilized to evaluate energy efficiency. The results of the comparative analysis indicated that the Ecotect program provides the closest match to the calculations, hence enabling optimization experiments throughout the study. The optimal insulation thickness was determined to be between 7–11 cm; implementing an insulation thickness of 11 cm results in a substantial 46.71% reduction in heating load and an overall annual energy savings of 3.896%. However, further increases in insulation thickness beyond 11 cm do not yield significant energy savings. Regarding window-to-wall ratios, the optimal ratio in Konya was determined to be 75%, resulting in savings of 5.04%. In conclusion, this study emphasized the importance of the building envelope for energy efficiency and presented optimized solutions for insulation, window-to-wall ratio, and glass thickness in Konya city. The results of this study make a valuable contribution towards achieving notable reductions in energy consumption and highlight the possibility of enhancing energy efficiency in the structures located in the study area.

Słowa kluczowe

energy efficiency optimal thickness ecotect window-wall ratio simulation

Wydawca

Polskie Towarzystwo Inżynierii Ekologicznej
Lublin University of Technology

Czasopismo

Journal of Ecological Engineering

Rocznik

2023

Tom

Vol. 24, nr 9

Strony

202--217

Opis fizyczny

Bibliogr. 14 poz., rys., tab.

Twórcy

autor

Baneaez Mustafa Obaid Omar

mcan9765@gmail.com

Energy System Engineering Department, Necmettin Erbakan University, Yaka District, Yeni Meram Street, Kasim Halife No. 11/1 A blok, Konya, Turkey

https://orcid.org/0000-0002-4931-5615

autor

Akkoyunlu Mustafa Tahir

Energy System Engineering Department, Necmettin Erbakan University, Yaka District, Yeni Meram Street, Kasim Halife No. 11/1 A blok, Konya, Turkey

https://orcid.org/0000-0001-5748-6759

Bibliografia

1. Turker M. 2010. Green Building Rating Systems: Evaluations on Turkey and Erzurum Shopping Center Example – Turkey’s First Bream Certified Green Building. Master Thesis, Istanbul Technical University, Istanbul.
2. Erdede B., Bektas, S. 2016. Evaluation of Sustainable Green Buildings and Certification Systems. Remote Sensing-GIS symposium, Istanbul.
3. Ozturk A. 2015. Analysis of Green Building Certification Systems. Master Thesis, Istanbul Technical University, Istanbul.
4. Said F. 2017. Analytical Hierarchy Process-Based Approach to Determine the Most Appropriate Green Buildings Certification System for Turkey. Master Thesis, Cankaya University, Istanbul.
5. Indra O. 2010. Subsidies for Fossil Fuels and Climate Change: A Comparative Perspective. International Journal of Environmental Studies, 67, 203–217.
6. Evans M., Yu S., Song B., Deng Q., Liu J., Delgado A. 2014. Building energy efficiency in rural China. Energy Policy, 64, 243–251.
7. Han J., Yang W., Zhou J., Zhang G., Zhang Q., Moschandreas D.J. 2009. A comparative analysis of urban and rural residential thermal comfort under natural ventilation environment. Energy Build, 41, 139–145.
8. He B., Yang L., Ye M. 2014. Building energy efficiency in China rural areas: Situation, drawbacks, challenges, corresponding measures and policies. Sustain. Cities Soc., 11, 7–15.
9. He B., Yang L., Ye M., Mou B., Zhou Y. 2014. Overview of rural building energy efficiency in China. Energy Policy, 69, 385–396.
10. Toja-Silva F., Lopez-Garcia O., Peralta C., Navarro J., Cruz I. 2016. An empirical–heuristic optimization of the building-roof geometry for urban wind energy exploitation on high-rise buildings. Appl. Energy, 164, 769–794.
11. Negendahl K., Nielsen T.R. 2015. Building energy optimization in the early design stages: A simplified method. Energy Build, 105, 88–99.
12. Huang Y., Niu J. 2016. Optimal building envelope design based on simulated performance: History, current status and new potentials. Energy Build, 117, 387–398.
13. Liu J., Liu B., He L., Gao Y. 2015. Investigation on the Winter Building Energy Consumption in Rural Areas in Jinan, China. Procedia Eng, 121, 1819–1826.
14. Mirrahimi S., Mohamed M.F., Haw L.C., Ibrahim N.L.N., Yosef W.F.M., Aflaki A. 2016. The effect of the building envelope on the thermal comfort and energy saving for high-rise buildings in hot–humid climate. Renew. Sustain. Energy Rev., 53, 1508–1519.

Typ dokumentu

Bibliografia

Identyfikator YADDA

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