Building Information Modelling in Interior Design Processes and its Role in Improving the Quality of Sustainable Interior Spaces
DOI:
https://doi.org/10.35560/jcofarts1553Keywords:
Building Information Modelling, Design Processes, Indoor Space Quality, SustainabilityAbstract
This research aims to validate the integration of building information modelling (BIM) into interior design processes to enhance the quality and sustainability of indoor spaces by improving air quality and lighting quality (BIM) has emerged as a powerful tool in the industries of architecture and construction, revolutionizing the way projects are planned, designed, created and managed however, its application in interior design remains relatively unexplored, especially with regard to sustainable design objectives this study seeks to bridge this gap from the study of how (BIM) can facilitate the creation of sustainable interior spaces while improving the quality. After a thorough review of the literature and case studies, the research will explore the benefits, challenges and potential best practices of applying (BIM) in interior design projects with a focus on sustainability criteria the results will contribute to deeper values of the role of (BIM) in the development of sustainable interior design practices and provide practical insights for professionals, researchers and academics and policy makers in this area
References
(n.d.). Retrieved from https://devenneygroup.com/
(n.d.). Retrieved from https://www.clarkebanks.com/
(n.d.). Retrieved from https://www.seradesign.com/projects/ac-hotel-portland-downtown
Berlyne, D. (1971). Aesthetics and Psychobiology. New York: Appleton Century-Crofts.
Brown, T. a. (2010). Design Thinking for Social Innovation. Stanford Social Innovation Review (Winter 2010) Vol. 8, No. 1, pp. 30-35.
Collin, A. (2012). "The Master Architect Series: DP Architects". The Images Publishing Group Pty Ltd,Australia.
Crisinel, M. (2007). "Glass, Interactive Building Envelopes. IOS Press, Amsterdam, Netherland.
Knaack. Ulrich, K. T. (2014). Façades: Principles of Construction. irkhäuser Verlag GmbH, Basel, Ger-many.
Konbr, U. (2005). Sustainability of the Residential Zones in the New Urban Communities in Greater Cairo Region-An Approach for Sustainabil-ity Aspects Assessment. Ph.D., at Department of architecture, Al-Azhar University, Faculty of Engineering, Department of Architecture.
Lu, M. F., Osman, N. B., & Konbr, U. (2021). Green Energy Harvesting Strategies on Edge-based Urban Computing in Sustainable Internet of Things. Sustainable Cities and Society, 75(2210-6707), 103349. doi:https://dx.doi.org/10.1016/j.scs.2021.103349
Turan, A. (2014). The use of BIM for sustainable design and easy analysis methods. National ITU Faculty of Architecture, Istanbul.
V., L. (2020). Sustainable built environments: Introduction. In: Loftiness V. (eds) sustainable built environments. Encyclopaedia of sustain-ability science and technology series. Springer. New York. doi:DOI: https://doi.org/10.1007/978-1-0716-0684-1_925
Ziman, J. (2000). Evolutionary models for technological change. In J. Ziman (Ed.). Technological innovation as an evolutionary process. Cambridge: Cambridge University Press.
