Sustainable use of recycled autoclaved aerated concrete waste as internal curing materials in ultra-high performance concrete
Sustainable use of recycled autoclaved aerated concrete waste as internal curing materials in ultra-high performance concrete
Great autogenous shrinkage has become a common problem in cement-based materials with a low water-to-binder ratio (w/b). To limit the autogenous shrinkage in ultra-high performance concrete (UHPC) during the process of hydration and curing, sustainable use of recycled micropowder (RMP) made from autoclaved aerated concrete waste (AACW) to cure UHPC internally is proposed in this paper. The influence of RMP (at the levels 5%, 10%, and 15% by mass) with three particle size classes ranging from 0 to 600 μm on the autogenous shrinkage, hydration reaction, internal relative humidity, and compressive strength of UHPC were investigated. The results show that mixtures with different dosages and particle sizes improve the fluidity of UHPC, and its internal curing effect can effectively inhibit the early-age autogenous shrinkage of UHPC and maintain a higher internal humidity compared with the control group. The incorporation of RMP can advance the appearance of a hydration peak and increase the cumulative heat of hydration. Microscale analyses show that the curing water released from RMP promotes the hydration of the unhydrated cement around RMP. The generated hydration product filled the surface pores of RMP and weakened the negative effect of the pores introduced by RMP on the compressive strength of UHPC. Thus, RMP can be utilized as internal curing materials for UHPC to reduce autogenous shrinkage.
Zou, Dujian
f932d3d9-b218-4268-a86e-0bb63aec1e31
Que, Zichao
c1f34f6d-4f51-4fb1-b390-2e04857caadc
Su, Dongchen
ef3b8b52-804b-4428-9908-6db9a3751162
Liu, Tiejun
07e72a65-be75-4b13-b54d-9ed949c93470
Zhou, Ao
5b42c2a4-26b2-416e-ab3c-446f1ece7a20
Li, Ye
86d13351-982d-46c3-9347-22794f647f86
7 September 2022
Zou, Dujian
f932d3d9-b218-4268-a86e-0bb63aec1e31
Que, Zichao
c1f34f6d-4f51-4fb1-b390-2e04857caadc
Su, Dongchen
ef3b8b52-804b-4428-9908-6db9a3751162
Liu, Tiejun
07e72a65-be75-4b13-b54d-9ed949c93470
Zhou, Ao
5b42c2a4-26b2-416e-ab3c-446f1ece7a20
Li, Ye
86d13351-982d-46c3-9347-22794f647f86
Zou, Dujian, Que, Zichao, Su, Dongchen, Liu, Tiejun, Zhou, Ao and Li, Ye
(2022)
Sustainable use of recycled autoclaved aerated concrete waste as internal curing materials in ultra-high performance concrete.
Journal of Cleaner Production, 373, [133910].
(doi:10.1016/j.jclepro.2022.133910).
Abstract
Great autogenous shrinkage has become a common problem in cement-based materials with a low water-to-binder ratio (w/b). To limit the autogenous shrinkage in ultra-high performance concrete (UHPC) during the process of hydration and curing, sustainable use of recycled micropowder (RMP) made from autoclaved aerated concrete waste (AACW) to cure UHPC internally is proposed in this paper. The influence of RMP (at the levels 5%, 10%, and 15% by mass) with three particle size classes ranging from 0 to 600 μm on the autogenous shrinkage, hydration reaction, internal relative humidity, and compressive strength of UHPC were investigated. The results show that mixtures with different dosages and particle sizes improve the fluidity of UHPC, and its internal curing effect can effectively inhibit the early-age autogenous shrinkage of UHPC and maintain a higher internal humidity compared with the control group. The incorporation of RMP can advance the appearance of a hydration peak and increase the cumulative heat of hydration. Microscale analyses show that the curing water released from RMP promotes the hydration of the unhydrated cement around RMP. The generated hydration product filled the surface pores of RMP and weakened the negative effect of the pores introduced by RMP on the compressive strength of UHPC. Thus, RMP can be utilized as internal curing materials for UHPC to reduce autogenous shrinkage.
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Sustainable use of recycled autoclaved aerated concrete waste as internal curing materials in ultra-high performance concrete
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Accepted/In Press date: 27 August 2022
e-pub ahead of print date: 1 September 2022
Published date: 7 September 2022
Identifiers
Local EPrints ID: 497912
URI: http://eprints.soton.ac.uk/id/eprint/497912
ISSN: 0959-6526
PURE UUID: 411f1852-5617-4702-8a66-ea166093c52c
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Date deposited: 04 Feb 2025 17:48
Last modified: 06 Feb 2025 03:15
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Author:
Dujian Zou
Author:
Zichao Que
Author:
Dongchen Su
Author:
Tiejun Liu
Author:
Ao Zhou
Author:
Ye Li
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