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Residential building forms and energy efficiency in the Saharan climate: the case of Adrar, Algeria

Treść / Zawartość
Identyfikatory
Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
Algeria is a country that has witnessed rapid development as a result of its abundant oil supplies. The country’s GDP to energy consumption ratio clearly shows the need to adopt energy efficiency policies. Taking into account the regulation of excess solar radiation in the desert environment, this study examines the relationship between the shape of different buildings and their energy use. This research was divided into two stages. In the first stage, the ideal building shape for the city of Adrar, in terms of energy consumption, was determined by studying three basic geometric shapes, including square, rectangular, and triangle shapes. According to simulation research conducted using Design Builder (version 6.1.0), a square building was the best shape to maximize energy performance. To analyze the thermal behavior of different building shapes, all structures with expanded shapes were simulated based on the ideal shape discovered in the first stage. Of the three extended alternative cases, the case of the Mini Arrival offers the best energy efficiency and sufficient natural lighting thanks to its 90 cm depth and no vertical offset from the top of the window. By adding design principles to the design process, this study helps improve the energy efficiency of new buildings and also gives another angle on research methods for solving energy performance issues regarding desert buildings.
Rocznik
Tom
Strony
85--98
Opis fizyczny
Bibliogr. 20 poz., rys., tab.
Twórcy
  • Department of City Management, University of Msila, Algeria, Laboratory of City Hydraulic Environment and Sustainable Development
  • Department of City Management, University of Msila, Algeria, Laboratory of City Hydraulic Environment and Sustainable Development
autor
  • Department of City Management, University of Msila, Algeria, Laboratory of City Hydraulic Environment and Sustainable Development
  • Department of City Management, University of Msila, Algeria, Laboratory of City Hydraulic Environment and Sustainable Development
Bibliografia
  • Abu Qadourah J., Al-Falahat A.M., Alrwashdeh S., Nytsch‐Geusen S. 2022. Improving the energy performance of the typical multi-family buildings in Amman, Jordan. City, Territory and Architecture, 9(1), 6.
  • Alghoul S.K. 2017. A comparative study of energy consumption for residential hvac systems using EnergyPlus. American Journal of Mechanical and Industrial Engineering, 2(2), 98–103.
  • Ascione F., Bianco N., Mauro G.M. 2021. Knowledge and energy retrofitting of neighborhoods and districts. A comprehensive approach coupling geographical information systems, building simulations and optimization engines. Energy Conversion and Management, 230, 113786.
  • Benaissa F.T., Khalfallah B. 2021. Industrial Activity Land Suitability Assessment Using Delphi and AHP to Control Land Consumption. The Case Study of Bordj Bouarreridj, Algeria. Engineering, Technology & Applied Science Research, 11(5), 7738–7744.
  • Caruso G., Kämpf J.H. 2015. Building shape optimisation to reduce air-conditioning needs using constrained evolutionary algorithms. Solar Energy, 118, 186–196.
  • Chel A., Geetanjali K. 2018. Renewable energy technologies for sustainable development of energy efficient building. Alexandria Engineering Journal, 57(2), 655–669.
  • Depecker P., Menezo C., Virgone J., Lepers S. 2001. Design of buildings shape and energetic consumption. Building and Environment, 36(5), 627–635.
  • Enescu D. 2017. A review of thermal comfort models and indicators for indoor environments. Renewable and Sustainable Energy Reviews, 79, 1353–1379.
  • Ferrari S., Valentina Z. 2012. Adaptive comfort: Analysis and application of the main indices. Building and Environment, 25–32.
  • Kim H., Yeo M. 2020. Thermal bridge modeling and a dynamic analysis method using the analogy of a steady-state thermal bridge analysis and system identification process for building energy simulation: methodology and validation. Energies, 13(17), 4422.
  • Lotfabadi P., Polat H. 2019. A comparative study of traditional and contemporary building envelope construction techniques in terms of thermal comfort and energy efficiency in hot and humid climates. Sustainability, 11(13), 3582.
  • Mohsenzadeh M., Marzbali M.H., Tilaki M.J. 2021. Building form and energy efficiency in tropical climates: A case study of Penang Urbe. Revista Brasileira de Gestão Urbana, 13.
  • Montenegro D.L., Carriço J.G., Zemero B.R., De Souza A.C. 2021. Building Information Modeling approach to optimize energy efficiency in educational buildings. Journal of Building Engineering, 43, 102587.
  • Ourdane A., Aouar B., Zeghmati B., Hamouda M. 2017. Study and calculation of the solar flux density for a simple habitat in the Adrar region. Journal of Renewable Energies, 20(1), 51–60.
  • Pathirana S., Rodrigo A., Halwatura R. 2019. Effect of building shape, orientation, window to wall ratios and zones on energy efficiency and thermal comfort of naturally ventilated houses in tropical climate. Int. J. Energy Environ. Eng., 107–120.
  • Renghi A., Perra C., Caffi M. 2021. Simulating and Comparing Different Vertical Greenery Systems Grouped into Categories Using EnergyPlus. Applied Sciences, 11(11), 4802.
  • Sanaieian H., Tenpierik M., Van den Linden K., Shemrani S. 2014. Review of the impact of urban block form on thermal performance, solar access and ventilation. Renewable and Sustainable Energy Reviews, 38, 551–560.
  • Šujanova P., Rychtarikova M., Sotto Mayor T., Hyder A. 2019. A healthy, energy-efficient and comfortable indoor environment, a review. Energies, 12(8), 1414.
  • Wang L., Nyuk H.W., Li S. 2007. Facade design optimization for naturally ventilated residential buildings in Singapore. Energy and Buildings, 39(8), 954–961.
  • Yixuan W., Xingxing Z., Yong S., Liang X., Song P., Jinshun W., Xiaoyun Z. 2018. A review of data-driven approaches for prediction and classification of building energy consumption. Renewable and Sustainable Energy Reviews, 82(1), 1027–1047.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-3fcb4391-2ef3-4f2e-a3a6-c3e52b904f84
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