AVALIAÇÃO DE ELEMENTOS DE CONTROLE SOLAR MÓVEIS PROJETADOS COM MODELAGEM PARAMÉTRICA
DOI:
https://doi.org/10.46421/entac.v18i.749Keywords:
Solar shading devices, Parametric modelling, Computational simulationAbstract
Considering the importance of solar radiation control and daylight admission in the performance of the buildings, solar shading devices can significantly contribute to comfort and energy efficiency in the built environment, especially if they are dynamic. Parallel to environmental issues, the growing use of digital tools in contemporary architectural production stands out. Based on these considerations, this work aims to improve one of the models of solar shading devices and to continue the performance evaluations presented in the work of Cartana and Domingos (2018). As a method, initially, using the Rhinoceros3D+Grasshopper suite, the algorithm of one of the models previously developed was improved. Subsequently, using the Diva-for-Rhino plug-in, computational simulations of solar radiation admission and daylight performance were carried out, considering the climate of Florianópolis. As a result, can be observed the behavior of the studied element in its different configurations, in which, in general, there was a reduction in the excess of solar radiation and an improvement in the daylight distribution, in addition to allowing the selective admission of radiation between winter and summer. Finally, is highlighted that the present work presents an example of practical application of a parametric modeling tool associated with computer simulation in the design and evaluation of an architectural component.
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