Research

Intuitive interactive form finding of optimised fabric-cast concrete


Reference:

Bak, A., Shepherd, P. and Richens, P., 2012. Intuitive interactive form finding of optimised fabric-cast concrete. In: Second International Conference on Flexible Formwork (icff2012), 2012-06-27 - 2012-06-29, University of Bath.

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Official URL:

http://people.bath.ac.uk/jjo20/icff/ICFF2012/

Abstract

Producing organic shapes in concrete has been a challenging problem since complex freeform buildings became a major trend in contemporary architecture. Many different techniques for casting doubly-curved shapes have been proposed. Most of them produce elements which exactly match a preconceived design, but at a high cost in manufacture. Fabric formwork techniques (such as those pioneered at the Centre of Architectural Structures and Technology at the University of Manitoba (CAST)) are relatively economical, but require a form-finding approach which takes into account the physics of casting, as well as structural and functional requirements of the finished element. The research presented here involves a specialised methodology for the design and manufacture of optimised concrete elements cast in fabric formwork. Using a novel software tool, our approach lies in between the largely intuitive methods reported by CAST and the precise but expensive computer-controlled manufacturing methods normally used in practice. Combining topological optimisation with computational form-finding, the developed software guides the designer towards a shape that is economical in both material and manufacturability. By combining knowledge of computational structural analysis, optimisation algorithms, fabric simulation and the practical casting techniques of fabric formwork; the gap between structurally optimised forms, and those developed intuitively by fabric casting, can be bridged. This is demonstrated through a case study involving the computational design of a centrally supported slab, supplemented with design studies realised using plaster scale models.

Details

Item Type Conference or Workshop Items (Paper)
CreatorsBak, A., Shepherd, P. and Richens, P.
DepartmentsFaculty of Engineering & Design > Architecture & Civil Engineering
RefereedYes
StatusPublished
ID Code30492

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