| id |
ijac201917401 |
| authors |
Kabošová, Lenka; Isak Foged, Stanislav Kmet’ and Dušan Katunský |
| year |
2019 |
| title |
Hybrid design method for wind-adaptive architecture |
| source |
International Journal of Architectural Computing vol. 17 - no. 4, 307-322 |
| summary |
The linkage of individual design skills and computer-based capabilities in the design process offers yet unexplored environment-adaptive architectural solutions. The conventional perception of architecture is changing, creating a space for reconfigurable, “living” buildings responding, for instance, to climatic influences. Integrating the element of wind to the architectural morphogenesis process can lead toward wind-adaptive designs that in turn can enhance the wind microclimate in their vicinity. Geometric relations coupled with material properties enable to create a tensegrity- membrane structural element, bending in the wind. First, the properties of such elements are investigated by a hybrid method, that is, computer simulations are coupled with physical prototyping. Second, the system is applied to basic- geometry building envelopes and investigated using computational fluid dynamics simulations. Third, the findings are transmitted to a case study design of a streamlined building envelope. The results suggest that a wind-adaptive building envelope plays a great role in reducing the surface wind suction and enhancing the wind microclimate. |
| keywords |
Wind, computational fluid dynamics, tensegrity structure, responsive envelope, computational design |
| series |
journal |
| email |
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| full text |
 file.pdf ( bytes) |
| references |
Content-type: text/plain
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| last changed |
2020/11/02 13:34 |
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