Automating Concrete Construction: Digital Design of Non-prismatic Reinforced Concrete Beams

Eduardo Costa; Paul Shepherd; John Orr; Tim Ibell; Robin Oval

doi:10.1007/978-3-030-49916-7_84

Automating Concrete Construction: Digital Design of Non-prismatic Reinforced Concrete Beams

Eduardo Costa
, Paul Shepherd
, John Orr
, Tim Ibell
, Robin Oval

Research output: Chapter in Book/Report/Conference proceeding › Chapter › peer-review

Abstract

The construction industry is responsible for nearly half of the UK’s carbon emissions, mainly due to the large amount of concrete used. Traditional formwork methods for concrete result in prismatic building elements with a constant cross-section, but the shear forces and bending moments that beams have to withstand are far from constant along their length. Up to 40% of the concrete in a typical beam could be removed. An iterative optimisation process has been implemented in a parametric modelling framework to generate and analyse optimal forms for non-prismatic beams that take into account the constraints imposed by the fabrication process, namely the use of fabric formwork. The aim of the resulting design tool is to facilitate the adoption of non-prismatic elements by the construction industry.

Original language	English
Title of host publication	RILEM Bookseries
Publisher	Springer
Pages	863-872
Number of pages	10
DOIs	https://doi.org/10.1007/978-3-030-49916-7_84
Publication status	Published - 1 Jan 2020
Externally published	Yes

Publication series

Name	RILEM Bookseries
Volume	28
ISSN (Print)	2211-0844
ISSN (Electronic)	2211-0852

Keywords

Automated design
Fabric formwork
Non-prismatic beam
Parametric modelling
Reinforced concrete
Structural analysis

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10.1007/978-3-030-49916-7_84

Cite this

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abstract = "The construction industry is responsible for nearly half of the UK{\textquoteright}s carbon emissions, mainly due to the large amount of concrete used. Traditional formwork methods for concrete result in prismatic building elements with a constant cross-section, but the shear forces and bending moments that beams have to withstand are far from constant along their length. Up to 40\% of the concrete in a typical beam could be removed. An iterative optimisation process has been implemented in a parametric modelling framework to generate and analyse optimal forms for non-prismatic beams that take into account the constraints imposed by the fabrication process, namely the use of fabric formwork. The aim of the resulting design tool is to facilitate the adoption of non-prismatic elements by the construction industry.",

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AU - Costa, Eduardo

AU - Shepherd, Paul

AU - Orr, John

AU - Ibell, Tim

AU - Oval, Robin

PY - 2020/1/1

Y1 - 2020/1/1

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AB - The construction industry is responsible for nearly half of the UK’s carbon emissions, mainly due to the large amount of concrete used. Traditional formwork methods for concrete result in prismatic building elements with a constant cross-section, but the shear forces and bending moments that beams have to withstand are far from constant along their length. Up to 40% of the concrete in a typical beam could be removed. An iterative optimisation process has been implemented in a parametric modelling framework to generate and analyse optimal forms for non-prismatic beams that take into account the constraints imposed by the fabrication process, namely the use of fabric formwork. The aim of the resulting design tool is to facilitate the adoption of non-prismatic elements by the construction industry.

KW - Automated design

KW - Fabric formwork

KW - Non-prismatic beam

KW - Parametric modelling

KW - Reinforced concrete

KW - Structural analysis

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ER -

Automating Concrete Construction: Digital Design of Non-prismatic Reinforced Concrete Beams

Abstract

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