| id |
ijac202220302 |
| authors |
Kabošová, Lenka; Angelos Chronis; Theodoros Galanos |
| year |
2022 |
| title |
Fast wind prediction incorporated in urban city planning |
| source |
International Journal of Architectural Computing 2022, Vol. 20 - no. 3, pp. 511–527 |
| summary |
Digital design and analysis tools are continually progressing, enabling more seamless integration of climatic impacts into the conceptual design stage, which naturally means enhanced environmental performance of the final designs. Planning sustainable urban configurations and, consequently, environment-derived architectural forms becomes more rapid and requires less effort enabling smooth incorporation into day-to-day practice. This research paper presents a wind prediction-based architectural design method for improving outdoor wind comfort through urbanism and architecture. The added value of the environment-driven design loop consisting of parametric design, wind flow analysis, and necessary design modifications lies in leveraging the newly developed wind prediction tool InFraRed. As is demonstrated in the application study in Kosice, Slovakia, iterating through various design options and evaluating their impact on the wind flow is swift and reliable. That enables the designer to explore the best-performing design alternatives for outdoor wind comfort, yet the extra time required for the analysis is negligible |
| keywords |
real-time wind predictions, wind comfort, parametric design, computational fluid dynamics analysis, machine learning, infrared |
| series |
journal |
| references |
Content-type: text/plain
|
Asghari Mooneghi M and Kargarmoakhar R (2016)
 Aerodynamic Mitigation and Shape Optimization of Buildings: Review
, J Build Eng 2016; 6: 225–235.
|
|
|
|
|
Blocken B, Stathopoulos T and van Beeck JPAJ (2016)
Pedestrian-level wind conditions around buildings: Review of windtunnel and CFD techniques and their accuracy for wind comfort assessment
, Build Environ 2016; 100: 50–81.
|
|
|
|
|
Carpo M (2017)
The Second Digital Turn
, Cambridge, MA: The MIT Press. Epub ahead of print 2017
|
|
|
|
|
Chronis A, Dubor A, Cabay E, et al (2017)
Integration of CFD in computational design: An evaluation of the current state of the art
, A Fioravanti, S Cursi, S Elahmar, et al (eds) Proceedings of the 35th International Conference eCAADe: ShoCK! Sharing of Computable Knowledge! Rome, Italy: Sapienza University of Rome, 2017, pp 601–610.
|
|
|
|
|
Chronis A, Liapi KA and Sibetheros I (2012)
A parametric approach to the bioclimatic design of large scale projects: The case of a student housing complex
, Autom Constr 2012; 22: 24–35.
|
|
|
|
|
Chronis A, Turner A and Tsigkari M (2011)
Generative Fluid Dynamics: Integration of Fast Fluid Dynamics and Genetic Algorithms for Wind Loading Optimization of Free Form Surfaces
, SimAUD2011 2011; 8: 79–85.
|
|
|
|
|
Chung DHJ and Choo M-LL (2010)
Computational Fluid Dynamics for urban design: The prospects for greater integration
, Int J Archit Comput 2010; 09: 33–53.
|
|
|
|
|
Du Y, Mak CM, Kwok K, et al (2017)
New criteria for assessing low wind environment at pedestrian level in Hong Kong
, Build Environ 2017; 123: 23–36
|
|
|
|
|
Dubois C, Cloutier G, Potvin A, et al (2015)
Design support tools to sustain climate change adaptation at the local level: A review and reflection on their suitability
, Front Archit Res 2015; 4: 1–11.
|
|
|
|
|
Duering S, Chronis A and Koenig R (2020)
Optimizing Urban Systems : Integrated Optimization of Spatial Configurations
, SimAUD: Symposium on Simulation for Architecture & Urban Design, Vienna, 2020, pp 503–510.
|
|
|
|
|
Galanos T and Chronis A (2022)
Time for Change – The InFraRed Revolution: How AI-driven Tools can Reinvent Design for Everyone
, Archit Des 2022; 92: 108–115.
|
|
|
|
|
Janssen W, Blocken B and Van Hooff T (2013)
Use of CFD Simulations to Improve the Pedestrian Wind Comfort Around a High-Rise Building in a Complex Urban Area
, 13th Conference of International Building Performance Simulation Association, Chambery, France, August 26-28, Chamb ´ ery, France, 2013, pp 1918 ´ –1925.
|
|
|
|
|
Janssen WD, Blocken B and Van Hooff T (2014)
Computational evaluation of pedestrian wind comfort and wind safety around a high-rise building in an urban area
, DP Ames, NWT Quinn and AE Rizzoli (eds) Proceedings of the 7th Int Congress on Env Modelling and Software San Diego, CA, USA: iEMSs, 2014, pp 1–8.
|
|
|
|
|
Kabosov ˇ a L, Chronis A and Galanos T (2021)
Leveraging urban con ´ figurations for achieving wind comfort in cities
, P Gomez and F Braida (eds) SIGgraDi 2021: Designing Possibilities Brazil/Georgia/online Brazil: Blucher Design Proceedings, 2021, pp 79–90.
|
|
|
|
|
Kabosov ˇ a L, Katunsk ´ ´ y D and Kmet S (2020)
Wind-based parametric design in the changing climate
, Appl Sci 2020; 10: 1–18.
|
|
|
|
|
Kaijima S, Bouffanais R and Willcox K (2013)
Computational Fluid Dynamics for architectural design
, R Stouffs, PHT Janssen, S Roudavski, et al (eds) Proceedings of the 18th International Conference of the Association of ComputerAided Architectural Design Research in Asia CAADRIA 2013 Hong Kong: CAADRIA, 2013.
|
|
|
|
|
Kuenstle MW (2001)
Computational flow dynamic applications in wind engineering for the design of building structures in wind hazard prone urban areas
, Proceedings of the 5th SIGradi conference, Concepcion, Chile, 2001, pp 67–70.
|
|
|
|
|
Latifi M, Prohasky D, Moya JBR, et al (2016)
Breathing skins for wind modulation through morphology : Toward integrating turbulence studies within tectonic scale for design of façade components
, CAADRIA 2016, 21st Int Conf Comput Archit Des Res Asia - Living Syst Micro-Utopias Towar Contin Des, Hong Kong, 2016: 219–228.
|
|
|
|
|
Pellitteri G, Lattuca R, Concialdi S, et al (2009)
Architectural shape generating through environmental forces
, Joining Languages, Cultures and Visions: Proceedings of the 13th International CAAD Futures Conference, Montreal, ´ Canada, 2009, Les Presses de Universite de Montr ´ eal, pp 875 ´ –886.
|
|
|
|
|
Pitman M and Kongsgaard C (2021)
Run your simulation in the cloud
, Chicago, IL: The AnyLogic, 2021, https://compute. procedural.build/.
|
|
|
|
| last changed |
2024/04/17 14:29 |
|
