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DOI
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Języki publikacji
Abstrakty
This paper presents an approach for providing innovative technology by applying fluid mechanics to the field of architectural design. The aim is to make a building’s shape profitable and strengthen environmental protection by using the wind force to create an integrated wind absorption definition for a multifunctional building system model. Furthermore, taking control of the wind flow over an object can have an impact on not only the designed object itself but also on its surroundings. In modern coastal cities there are issues associated with the wind and ventilation that need to be solved. The presented system model and the calculations conducted are part of the new definition of a multifunctional object and the wind force as a significant subsystem. Systematizing this scope can be useful in design practice.
Rocznik
Tom
Strony
27--33
Opis fizyczny
Bibliogr. 13 poz., rys.
Twórcy
autor
- Gdańsk University of Technology, Department of Housing and Architecture of Public Buildings 11/12 Gabriela Narutowicza St., 80-233 Gdynia, Poland
autor
- Gdynia Maritime University, Department of Ship Operation 81-87 Morska St., 81-225 Gdynia, Poland
Bibliografia
- 1. Allard, F., Ghiaus, C. & Szucs, A. (2009) Natural Ventilation in High-Density Cities. In: E. Ng (Ed.) Designing High-Density Cities: For Social and Environmental Sustainability pp. 137–162. Routledge.
- 2. Archer, C.L. & Jacobson, M.Z. (2005) Evaluation of global wind power. Journal of Geophysical Research D: Atmospheres 110 (12), pp. 1–20.
- 3. Aydin, Y.C. & Mirzaei, P.A. (2017) Wind-driven ventilation improvement with plan typology alteration: A CFD case study of traditional Turkish architecture. Building Simulation 10, 2, pp. 239–254.
- 4. Barragán, J.M. & de Andrés, M. (2015) Analysis and trends of the world’s coastal cities and agglomerations. Ocean & Coastal Management 114, pp. 11–20.
- 5. Gerigk, M. (2017) Multi-Criteria Approach in Multifunctional Building Design Process. IOP Conference Series: Materials Science and Engineering 245, 052085.
- 6. Jo, S.J., Jones, J. & Grant, E. (2018) Trends in the application of CFD for architectural design. ARCC Conference Repository. https://doi.org/10.17831/rep:arcc%y489.
- 7. Kim, H.G., Jeon, W.H. & Kim, D.H. (2016) Wind resource assessment for high-rise BIWT using RS-NWP-CFD. Remote Sensing 8 (12), 1019. https://doi.org/10.3390/ rs8121019.
- 8. Lozano, R. (2008) Envisioning sustainability three-dimensionally. Journal of Cleaner Production 16, 17, pp. 1838– 1846.
- 9. Naboni, E., Lee, D.S.-H. & Fabbri, K. (2017) Thermal Comfort-CFD maps for Architectural Interior Design. Procedia Engineering 180, pp. 110–117.
- 10. Shi, Y., Lu, M. & Li, W. (2015) Study on Optimization of Architectural Shape Based on Wind Environment: A Study in Taiyuan, China. Civil Engineering and Architecture 3 (5), pp. 99–106.
- 11. World Commission on Environment and Development (1987) Our Common Future. Oxford: Oxford University Press.
- 12. Wu, K.L. & Hsieh, C.M. (2017) Computational fluid dynamics application for the evaluation of a community atrium open space design integrated with microclimate environment. Applied Ecology and Environmental Research 15 (4), pp. 1815–1831.
- 13. Zhong, W., Zhang, T. & Tamura, T. (2019) CFD Simulation of Convective Heat Transfer on Vernacular Sustainable Architecture: Validation and Application of Methodology. Sustainability 11 (15), 4231.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-00b739dd-bbc8-4df0-b440-598c6506b61f