Additive construction of concrete deep beams using low-cost characterization methods and FEM-based topological optimization

Guido Silva; Axcel Quispe; Jordan Baldoceda; Suyeon Kim; Gaby Ruiz; Miguel A. Pando; Javier Nakamatsu; Rafael Aguilar

doi:10.1016/j.conbuildmat.2024.135418

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Additive construction of concrete deep beams using low-cost characterization methods and FEM-based topological optimization

Journal article

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Additive construction of concrete deep beams using low-cost characterization methods and FEM-based topological optimization

Guido Silva, Axcel Quispe, Jordan Baldoceda, Suyeon Kim, Gaby Ruiz, Miguel A. Pando, Javier Nakamatsu and Rafael Aguilar

Construction & building materials, v 418, 135418

08 Mar 2024

DOI: https://doi.org/10.1016/j.conbuildmat.2024.135418

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Abstract

Additive construction

Concrete formulation

Experimental characterization

Large-scale production

Topology optimization

Yield strength

Additive manufacturing using concrete for large-scale construction purposes has demonstrated economic, social, and environmental benefits compared to conventional building procedures. These advantages stem from the capabilities of concrete 3D printing, which facilitates a rapid, accurate, and low-waste construction process with substantially less labor and energy requirements compared to traditional casting procedures such as formwork fabrication and stripping, concrete pouring, and concrete consolidation. This technology can pave the way for sustainable and cost-effective housing solutions when coupled with low-carbon concrete formulations and optimized structural designs. However, scientific and industrial experiences have shown that formulating printable concrete requires extensive testing and costly equipment to reach appropriate fresh and hardened-state properties. Therefore, accessible and practical mix-design protocols for the evaluation of printable concrete formulation are needed to enable in-situ control and broader adoption of 3D printing. Once a printable material is developed, innovative design methods, such as topology optimization, that exploit robot-controlled construction to fabricate efficient, safe, and free-form elements can be explored. In this context, this article presents a methodology based on a set of low-cost and accessible experimental tests to develop cement-based matrices with low binder content suitable for layer-by-layer deposition. Furthermore, a framework to design and fabricate efficient structural elements based on numerical-based topological optimization and concrete additive manufacturing is proposed and validated. The systematic experimental campaign carried out indicates that the yield strength obtained from shear vane tests, initially designed for geotechnical field tests, is a reliable reference value for proportioning extrudable, pumpable, and buildable concretes. Employing the proposed framework, four formulations with excellent printing capabilities are presented. These formulations are successfully utilized for additive manufacturing of a topologically optimized deep beam, achieving a remarkable 52% mass reduction compared to a solid element. This showcases the possibility of 3D printing structurally efficient elements with intricate geometries while minimizing material usage, all without the need for formworks.Principio del formulario. •A set of low-cost experimental tests to develop printable cement-based matrices was proposed.•Special attention must be given to the binder/fine-aggregate weight ratio.•A framework to design efficient structural elements based on numerical-based topological optimization was validated.•A deep beam with a 52% mass reduction was fabricated through concrete 3D printing.

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Title: Additive construction of concrete deep beams using low-cost characterization methods and FEM-based topological optimization
Creators: Guido Silva - Engineering Department, Pontificia Universidad Catolica del Peru PUCP, Lima, Peru
Axcel Quispe - Engineering Department, Pontificia Universidad Catolica del Peru PUCP, Lima, Peru
Jordan Baldoceda - Engineering Department, Pontificia Universidad Catolica del Peru PUCP, Lima, Peru
Suyeon Kim - Engineering Department, Pontificia Universidad Catolica del Peru PUCP, Lima, Peru
Gaby Ruiz - Civil Engineering Department, Universidad de Piura, Piura, Peru
Miguel A. Pando - Drexel University
Javier Nakamatsu - Science Department, Pontiﬁcia Universidad Catolica del Peru PUCP, Lima, Peru
Rafael Aguilar - Engineering Department, Pontificia Universidad Catolica del Peru PUCP, Lima, Peru
Publication Details: Construction & building materials, v 418, 135418
Publisher: Elsevier
Resource Type: Journal article
Language: English
Academic Unit: Civil, Architectural, and Environmental Engineering
Web of Science ID: WOS:001198793900001
Scopus ID: 2-s2.0-85185407506
Other Identifier: 991021855266504721

UN Sustainable Development Goals (SDGs)

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#12 Responsible Consumption & Production

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Collaboration types: Domestic collaboration; International collaboration
Web of Science research areas: Construction & Building Technology; Engineering, Civil; Materials Science, Multidisciplinary

Additive construction of concrete deep beams using low-cost characterization methods and FEM-based topological optimization

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UN Sustainable Development Goals (SDGs)

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