Durability of SFCB reinforced low-alkalinity seawater sea sand concrete beams in marine environment
Durability of SFCB reinforced low-alkalinity seawater sea sand concrete beams in marine environment
Seawater sea-sand concrete (SWSSC) provides an alternative to normal concrete, while Steel-FRP Composite Bars (SFCB) offer corrosion resistance in offshore and marine structures. Despite their benefits, the long-term performance of SFCB-reinforced SWSSC structures remains under-explored. This study evaluated the durability of such beams, particularly focusing on the effects of using Portland cement versus low-alkalinity calcium sulphoaluminate (CSA) cement. The investigation involved tensile and pull-out tests conducted on SFCB, and flexural tests conducted on the beam components after accelerated marine environmental exposure over periods ranging from one to six months. Results highlighted that SFCB embedded in low-alkalinity CSA cement exhibited improved retention of tensile strength, elastic modulus, and bonding strength by 32.0 %, 39.1 %, and 56.7 % respectively, compared to that embedded in normal Portland cement concrete. Microstructural analyses showed much less hydrolysis of the resin matrix and shallower corrosion of the basalt FRP (BFRP) cover on the SFCB. Furthermore, flexural tests demonstrated superior cooperative performance between low-alkalinity CSA concrete with SFCB in beam components, showing only marginal degradation in crack density, crack strength, and yielding points. The ultimate failure load of beams made with CSA concrete was 1.89 times higher than those made with normal SWSSC after 6 months of exposure. These results underscore the potential of low-alkalinity concrete in improving the long-term durability and structural performance of SFCB-reinforced marine concrete infrastructures.
Wang, Haodong
bd36d0d4-12de-4a21-86fe-a0aaf78ea68a
Liu, Tiejun
07e72a65-be75-4b13-b54d-9ed949c93470
Zhang, Zheng
bff0bf52-52c6-4297-a5aa-0a975ea9d929
Zou, Dujian
f932d3d9-b218-4268-a86e-0bb63aec1e31
Zhou, Ao
5b42c2a4-26b2-416e-ab3c-446f1ece7a20
Li, Ye
86d13351-982d-46c3-9347-22794f647f86
23 July 2024
Wang, Haodong
bd36d0d4-12de-4a21-86fe-a0aaf78ea68a
Liu, Tiejun
07e72a65-be75-4b13-b54d-9ed949c93470
Zhang, Zheng
bff0bf52-52c6-4297-a5aa-0a975ea9d929
Zou, Dujian
f932d3d9-b218-4268-a86e-0bb63aec1e31
Zhou, Ao
5b42c2a4-26b2-416e-ab3c-446f1ece7a20
Li, Ye
86d13351-982d-46c3-9347-22794f647f86
Wang, Haodong, Liu, Tiejun, Zhang, Zheng, Zou, Dujian, Zhou, Ao and Li, Ye
(2024)
Durability of SFCB reinforced low-alkalinity seawater sea sand concrete beams in marine environment.
Engineering Structures, 317.
(doi:10.1016/J.ENGSTRUCT.2024.118616).
Abstract
Seawater sea-sand concrete (SWSSC) provides an alternative to normal concrete, while Steel-FRP Composite Bars (SFCB) offer corrosion resistance in offshore and marine structures. Despite their benefits, the long-term performance of SFCB-reinforced SWSSC structures remains under-explored. This study evaluated the durability of such beams, particularly focusing on the effects of using Portland cement versus low-alkalinity calcium sulphoaluminate (CSA) cement. The investigation involved tensile and pull-out tests conducted on SFCB, and flexural tests conducted on the beam components after accelerated marine environmental exposure over periods ranging from one to six months. Results highlighted that SFCB embedded in low-alkalinity CSA cement exhibited improved retention of tensile strength, elastic modulus, and bonding strength by 32.0 %, 39.1 %, and 56.7 % respectively, compared to that embedded in normal Portland cement concrete. Microstructural analyses showed much less hydrolysis of the resin matrix and shallower corrosion of the basalt FRP (BFRP) cover on the SFCB. Furthermore, flexural tests demonstrated superior cooperative performance between low-alkalinity CSA concrete with SFCB in beam components, showing only marginal degradation in crack density, crack strength, and yielding points. The ultimate failure load of beams made with CSA concrete was 1.89 times higher than those made with normal SWSSC after 6 months of exposure. These results underscore the potential of low-alkalinity concrete in improving the long-term durability and structural performance of SFCB-reinforced marine concrete infrastructures.
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Accepted/In Press date: 11 July 2024
e-pub ahead of print date: 23 July 2024
Published date: 23 July 2024
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Local EPrints ID: 498355
URI: http://eprints.soton.ac.uk/id/eprint/498355
ISSN: 0141-0296
PURE UUID: be80c021-e5a7-4f54-afe0-0340ada21b9a
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Date deposited: 17 Feb 2025 17:39
Last modified: 18 Feb 2025 03:12
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Author:
Haodong Wang
Author:
Tiejun Liu
Author:
Zheng Zhang
Author:
Dujian Zou
Author:
Ao Zhou
Author:
Ye Li
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