TY - GEN
T1 - Adaptive tectonic systems
T2 - 33rd Annual Conference of the Association for Computer Aided Design in Architecture: Adaptive Architecture, ACADIA 2013
AU - Raspall, Felix
AU - Imbern, Matías
AU - Choi, William
N1 - Publisher Copyright:
© 2013 ACADIA. All rights reserved.
PY - 2013
Y1 - 2013
N2 - In order to design adaptable systems, the requirements include flexible models to generate a range of alternative configurations, analytical engines to evaluate performance, and well-defined selection criteria to identify suitable options. In most cases, design processes driven by performance concentrate on environmental or structural parameters; fabrication often remains disconnected from the generative process. Nonetheless, as design-to-fabrication methods become more robust, it is possible to extend the digital process to introduce fabrication variables to the definition of the project. The main focus of the research presented in this paper is the development of a digital and material workflow that connects design, structural and climate-specific topics (such as sun lighting and water drainage) toward producing a range of efficient structural and spatial assemblies. A case study serves as the main support for this investigation. Miguel Fisac’s “bones” is a lightweight roof system developed during the 1960’s, which had a very well-calibrated structural, natural-lighting, drainage and construction performance, as well as a highly refined spatial output. The system, despite its intelligence, lacked the flexibility possible today: using digital technologies, it can adapt to a significantly wider range of applications. Using “bones” as a starting point, this research develops a design-to-fabrication workflow that attempts to move forward tools, material systems and processes to enable an adaptable tectonic system. This paper describes the background research, concept, form-finding, construction process, methodology, results and conclusions of the investigation.
AB - In order to design adaptable systems, the requirements include flexible models to generate a range of alternative configurations, analytical engines to evaluate performance, and well-defined selection criteria to identify suitable options. In most cases, design processes driven by performance concentrate on environmental or structural parameters; fabrication often remains disconnected from the generative process. Nonetheless, as design-to-fabrication methods become more robust, it is possible to extend the digital process to introduce fabrication variables to the definition of the project. The main focus of the research presented in this paper is the development of a digital and material workflow that connects design, structural and climate-specific topics (such as sun lighting and water drainage) toward producing a range of efficient structural and spatial assemblies. A case study serves as the main support for this investigation. Miguel Fisac’s “bones” is a lightweight roof system developed during the 1960’s, which had a very well-calibrated structural, natural-lighting, drainage and construction performance, as well as a highly refined spatial output. The system, despite its intelligence, lacked the flexibility possible today: using digital technologies, it can adapt to a significantly wider range of applications. Using “bones” as a starting point, this research develops a design-to-fabrication workflow that attempts to move forward tools, material systems and processes to enable an adaptable tectonic system. This paper describes the background research, concept, form-finding, construction process, methodology, results and conclusions of the investigation.
UR - http://www.scopus.com/inward/record.url?scp=84926211185&partnerID=8YFLogxK
M3 - Conference contribution
AN - SCOPUS:84926211185
T3 - ACADIA 2013: Adaptive Architecture - Proceedings of the 33rd Annual Conference of the Association for Computer Aided Design in Architecture
SP - 327
EP - 336
BT - ACADIA 2013
A2 - Beesley, Philip
A2 - Stacey, Michael
A2 - Khan, Omar
PB - ACADIA
Y2 - 21 October 2013 through 27 October 2013
ER -