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Geopolymer concrete-filled aluminium alloy tubular cross-sections

Geopolymer concrete-filled aluminium alloy tubular cross-sections
Geopolymer concrete-filled aluminium alloy tubular cross-sections
Composite steel–concrete members are adopted in structural applications as a cost-effective and high-speed construction practice. Exploiting the superior corrosion and strength-to-weight properties of structural aluminium, research on composite aluminium-concrete members has been reported. Aiming for an even more sustainable and durable structural member, this paper proposes combining structural aluminium alloys with low carbon geopolymer concrete (GC) to form a structural member with lower environmental footprint. To this end, an experimental programme on geopolymer concrete-filled aluminium alloy tubular (GCFAT) cross-sections is performed. A total of 24 tests on stub columns and 12 tests on beams were carried out. In particular, 4 square hollow sections infilled with one-part geopolymer concrete were tested under uniform compression and under uniaxial bending. The hollow sections were fabricated from 6082-T6 heat-treated aluminium alloy. The same cross-sections were also tested as bare and infilled with ordinary Portland cement (OPC) concrete for comparison purposes. It is shown that the strength of the composite sections is significantly increased compared to the bare ones. In particular, the average strength increase was in the range of 16.5%–93.3% and of 23%–93.1% for GC and OPC-aluminium stub columns, respectively. In beams, the strength increase was in the range of 14.1%–53.6% for GC-aluminium and of 10.2%–48.9% for OPC-aluminium specimens. In absence of codified design rules for geopolymer concrete-aluminium structures, design formulae based on the European standards for composite steel–concrete members, with the material properties of steel and concrete replaced by those of aluminium alloy and GC, respectively, are adopted. The obtained results demonstrated that the proposed design methodology is suitable for the design of GCFAT cross-sections and beams, providing reasonably accurate and consistent strength predictions. Overall, the potential of geopolymer concrete-filled aluminium tubular cross-sections as a novel cement-free, sustainable, and structurally efficient composite cross-section is demonstrated.
aluminium alloy, beams, composite structures, european codes, geopolymer concrete, stub columns, European codes, Beams, Stub columns, Geopolymer concrete, Aluminium alloy, Composite structures
2352-0124
528-543
Gkantou, Michaela
e91cc83a-e415-44f2-a616-b88e41049fdf
Georgantzia, Evangelia
915a67f2-6020-4bd3-919e-f6df11f4a031
Kadhim, Abdullah
bea69791-c890-40c2-8a1e-b73babbc284b
Kamaris, George S.
99dc43b0-0a43-4706-8f45-c28bbe0ce99b
Sadique, Monower
94f26e52-ec39-4934-8f58-c38950bff8d3
Gkantou, Michaela
e91cc83a-e415-44f2-a616-b88e41049fdf
Georgantzia, Evangelia
915a67f2-6020-4bd3-919e-f6df11f4a031
Kadhim, Abdullah
bea69791-c890-40c2-8a1e-b73babbc284b
Kamaris, George S.
99dc43b0-0a43-4706-8f45-c28bbe0ce99b
Sadique, Monower
94f26e52-ec39-4934-8f58-c38950bff8d3

Gkantou, Michaela, Georgantzia, Evangelia, Kadhim, Abdullah, Kamaris, George S. and Sadique, Monower (2023) Geopolymer concrete-filled aluminium alloy tubular cross-sections. Structures, 51, 528-543. (doi:10.1016/j.istruc.2023.02.117).

Record type: Article

Abstract

Composite steel–concrete members are adopted in structural applications as a cost-effective and high-speed construction practice. Exploiting the superior corrosion and strength-to-weight properties of structural aluminium, research on composite aluminium-concrete members has been reported. Aiming for an even more sustainable and durable structural member, this paper proposes combining structural aluminium alloys with low carbon geopolymer concrete (GC) to form a structural member with lower environmental footprint. To this end, an experimental programme on geopolymer concrete-filled aluminium alloy tubular (GCFAT) cross-sections is performed. A total of 24 tests on stub columns and 12 tests on beams were carried out. In particular, 4 square hollow sections infilled with one-part geopolymer concrete were tested under uniform compression and under uniaxial bending. The hollow sections were fabricated from 6082-T6 heat-treated aluminium alloy. The same cross-sections were also tested as bare and infilled with ordinary Portland cement (OPC) concrete for comparison purposes. It is shown that the strength of the composite sections is significantly increased compared to the bare ones. In particular, the average strength increase was in the range of 16.5%–93.3% and of 23%–93.1% for GC and OPC-aluminium stub columns, respectively. In beams, the strength increase was in the range of 14.1%–53.6% for GC-aluminium and of 10.2%–48.9% for OPC-aluminium specimens. In absence of codified design rules for geopolymer concrete-aluminium structures, design formulae based on the European standards for composite steel–concrete members, with the material properties of steel and concrete replaced by those of aluminium alloy and GC, respectively, are adopted. The obtained results demonstrated that the proposed design methodology is suitable for the design of GCFAT cross-sections and beams, providing reasonably accurate and consistent strength predictions. Overall, the potential of geopolymer concrete-filled aluminium tubular cross-sections as a novel cement-free, sustainable, and structurally efficient composite cross-section is demonstrated.

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Accepted/In Press date: 25 February 2023
e-pub ahead of print date: 21 March 2023
Published date: May 2023
Additional Information: Funding Information: The authors are grateful to the technicians of School of Civil Engineering and Built Environment and School of Engineering at Liverpool John Moores University for their valuable assistance. Publisher Copyright: © 2023 The Author(s)
Keywords: aluminium alloy, beams, composite structures, european codes, geopolymer concrete, stub columns, European codes, Beams, Stub columns, Geopolymer concrete, Aluminium alloy, Composite structures

Identifiers

Local EPrints ID: 476967
URI: http://eprints.soton.ac.uk/id/eprint/476967
DOI: doi:10.1016/j.istruc.2023.02.117
ISSN: 2352-0124
PURE UUID: f2071ac0-ac9d-466a-a1f9-d2bc75f27eed
ORCID for Evangelia Georgantzia: ORCID iD orcid.org/0000-0001-9140-8236

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Date deposited: 22 May 2023 17:04
Last modified: 17 Mar 2024 04:15

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Contributors

Author: Michaela Gkantou
Author: Evangelia Georgantzia ORCID iD
Author: Abdullah Kadhim
Author: George S. Kamaris
Author: Monower Sadique

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