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The Porch and its Interaction with Building Design in Arid Zones

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Identyfikatory
Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
Improving the energy performance of buildings has thus become a major challenge, as the building sector is now one of the main sources of energy consumption and one of the main contributors to greenhouse gas emissions. Faced with these alarming challenges, current building design in the north is based on minimizing heat loss. However, this logic is not necessarily the most relevant in southern countries, characterized by excessive heat and insufficient, variable rainfall. The best way to achieve this is through sustainable design, with its intrinsic, energy_saving qualities, exploited by effective modeling. This article focuses on ideas and innovations that are helping to overcome these challenges. The results of introducing a porch into building design represent best practice in arid zones and beyond in terms of how it is thermally insulated. This has resulted in a significant reduction in thermal load in the energy ratio of up to 53.55%. This latest research aims to provide construction professionals with concrete examples of the design process, its technical feasibility, optimization and digitization based on climatic data from the arid zone.
Rocznik
Strony
50--62
Opis fizyczny
Bibliogr. 28 poz., il., rys., wykr.
Twórcy
  • Institute of Applied Science and Technology (ISTA), University 20 August 1955, Skikda, Algéria
  • Quebec Infrastructure Society, Canada
  • Higher National School of Renewable Energies, Batna, Algeria
Bibliografia
  • 1. Abdollahzadeh, SM, Heidari, SH and Einifar, A 2023. "Evaluating thermal comfort and neutral temperature in residential apartments in hot and dry climate: A case study in Shiraz, Iran." Journal of Building Engineering Journal of Building Engineering".
  • 2. Ajaj, A and Pugnaloni, F 2017. "Re-Thinking Traditional Arab Architecture: A Traditional Approach to Contemporary Living." International Journal of Engineering and Technology "6. no. August 2014, 286-289.
  • 3. Attia, S et al. 2017. "Overview and Future Challenges of Nearly Zero Energy Buildings (NZEB) design in Southern Europe." Energy and Buildings", 155, 439-458.
  • 4. Berghout, B, 2012. Effet de l'implantation d'un batiment sur le confort. Ets, 184, Quebec, Canada.
  • 5. Berghout, B et al. 2014. "Simulation du confort thermique intérieur pour l’orientation d’un bâtiment collectif à Biskra, Algérie, Algérie." eSim (2014). Ottawa, Canada.
  • 6. Berghout, B and Daniel, F 2019. "The passive ambient comfort and correlation of strategies and vernacular devices for habitat design in arid zones in "Buildings". 9 (87).
  • 7. Berghout, B and Daniel, F 2019. "The passive ambient comfort and interaction of strategies and vernacular devices for habitat design in arid zones « in Advances in Building Energy Research".
  • 8. Berghout, B and Daniel, F 2019. "The passive ambient comfort and design integration feasibility of vernacular devices in arid housing." in International Journal of Global Environmental Issues".
  • 9. Berghout, B and Daniel, F 2019. "Intégration des Aspects Énergétiques et du Confort Ambiant Passif dans la Conception de l'Habitat en Milieu Arides " Ets (2019). Quebec, Canada.
  • 10. Conan, M 1990. "Concevoir un projet d’architecture." L’harmattan", Paris.
  • 11. Dabaieh, M et al. 2015. "Reducing cooling demands in a hot dry climate: A simulation study for non-insulated passive cool roof thermal performance in residential buildings." Energy and Buildings" 89: 142-152.
  • 12. Denis, D 2012. Bâti vernaculaire & Développement urbain durable. "Etudes et conseil en environnement et développement durable". Paris, France, Ile de France: 108.
  • 13. Dutreix, A 2010. "Bioclimatisme et pérformances énergétiques des Batiments". Paris.
  • 14. Ibrahim, T and Seyed, M 2023. "Benchmarking indoor headroom heights of residential buildings based on ASHRAE Standard "55. Intelligent Buildings International.
  • 15. Jules, D 2015. Global Research. https://suds-en-ligne.ird.fr/desertif/carte.html.
  • 16. Konstantinou, T, 2023. "Enjeux, solutions et méthodes pour la transition énergétique dans le parc de logements existan." Énergie et bâtiments".
  • 17. Moreno, Santamaria, B et al. 2020. "Application and validation of a dynamic energy simulation tool: A case study with water flow glazing envelope." Energies, 13 (2).
  • 18. Muselli, M 2010. " Passive cooling for air-conditioning energy savings with new radiative low-cost coatings." Energy and Buildings" 42(6): 945-954.
  • 19. Nilmini, RP, Weerasinghe, P et al. 2020. "Renewable energy adoption in the built environment: a sociotechnical network approach." Intelligent Buildings International": 33 (50).
  • 20. Nižetić, S 2023. "Les technologies d'avenir pour le secteur du bâtiment pour accélérer la transition énergétique." Énergie et bâtiments VSI»: Future Buildings (Demande de papiers).
  • 21. Ouf, M 2022. "Stratégies de contrôle centrées sur les occupants pour les systèmes du bâtiment." "Énergie et bâtiment"s.
  • 22. Rawat, M and Singh, R 2021. "Performance evaluation of a cool roof model in composite climate." Materials Today": Proceedings 44.
  • 23. Shady, A et al. 2017. "Overview and future challenges of nearly zero energy buildings (nZEB) design in Southern Europe." Energy and Buildings" 155 (15): 439-458.
  • 24. Taşçı, G 2023. Defining Nearly Zero-Energy Buildings (NZEB) for Turkey in terms of Boundary Conditions. 6th International Conference of Contemporary Affairs in "Architecture and Urbanism (ICCAUA-2023) ".
  • 25. Ying, W 2023. "Construction of intelligent multi-construction management platform for bridges based on BIM technology." Intelligent Buildings International".
  • 26. Yujuan, Jin and Jiaqi, Wang 2023. "Integrated application strategy of large-scale intelligent building based on renewable energy technology." Intelligent Buildings International".
  • 27. Zhao, X, Yin, Y, He, Z and Deng, Z 2023. "State-of-the-art, challenges and new perspectives of thermal comfort demand law for on-demand intelligent control of heating, ventilation, and air conditioning systems " Energy and Buildings", 27.
  • 28. Zinzi, M and Agnoli, S 2012. "Cool and green roofs. An energy and comfort comparison between passive cooling and mitigation urban heat island techniques for residential buildings in the Mediterranean region." Energy and Buildings", 55: 66-76.
Uwagi
Opracowanie rekordu ze środków MNiSW, umowa nr SONP/SP/546092/2022 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2024)
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-283b0293-b94b-4c48-b5e2-24cca800397a
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