Effects of superabsorbent polymer and natural zeolite on shrinkage, mechanical properties, and porosity in ultra-high performance concretes

IF 6.2 2区 工程技术 Q1 CONSTRUCTION & BUILDING TECHNOLOGY
Yuxiang Tan , Bo Li , Yung-Tsang Chen , Yifeng Ling , Weizhuo Shi
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引用次数: 0

Abstract

The low water-to-binder ratio of ultra-high performance concrete (UHPC) often causes shrinkage and cracking due to early-age self-desiccation. This leads to significant initial dimensional instability, which may compromise structural integrity. As a promising solution, internal curing agents such as superabsorbent polymers (SAP) and natural zeolite have the potential to mitigate shrinkage and achieve self-stressing properties. This research aims to provide a comprehensive comparison between SAP and zeolite's effects within a consistent UHPC formulation. Six UHPC mixtures (including the reference mixture) were designed: three with SAP dosages of 0.2%, 0.4%, and 0.6% by cement mass, and two with zeolite replacing silica fume at 25% and 50% by mass. Various testing methods, including autogenous and drying shrinkage assessment, heat of hydration and thermogravimetric analysis, compressive strength evaluation, mercury intrusion porosimetry (MIP), nuclear magnetic resonance (NMR), were employed to assess the mixtures at different stages of curing. The result reveals that the incorporation of SAP and zeolite in the mixtures significantly reduces UHPC's early-age autogenous shrinkage. Moreover, SAP and zeolite additions impact mechanical properties, demonstrating that a balance between shrinkage control and compressive strength can be reached, through an optimization of the additions to achieve the desired performance. Microstructural analysis through MIP and NMR reveals increased overall porosity of the UHPC with SAP and zeolite, suggesting that low-field NMR can be a valuable tool for complementing conventional test methods. The outcome of this study provided valuable insights into optimizing the balance between durability and mechanical performance, paving the way for more sustainable and cost-effective applications of UHPC in modern construction practices.
超吸收聚合物和天然沸石对超高性能混凝土收缩率、机械性能和孔隙率的影响
超高性能混凝土(UHPC)的水粘结比很低,常常会因早期龄期自干燥而导致收缩和开裂。这会导致初始尺寸严重不稳定,从而损害结构的完整性。作为一种有前途的解决方案,超吸收聚合物(SAP)和天然沸石等内部固化剂有可能缓解收缩并实现自应力特性。本研究旨在全面比较 SAP 和沸石在一致的 UHPC 配方中的效果。研究人员设计了六种 UHPC 混合物(包括参考混合物):三种混合物的 SAP 用量分别为水泥质量的 0.2%、0.4% 和 0.6%,两种混合物的沸石取代硅灰的比例分别为 25% 和 50%。采用了各种测试方法,包括自生收缩和干燥收缩评估、水化热和热重分析、抗压强度评估、汞侵入孔隙比拟法(MIP)、核磁共振(NMR),以评估处于不同固化阶段的混合物。结果表明,在混合物中加入 SAP 和沸石可显著降低 UHPC 早期的自生收缩。此外,SAP 和沸石的添加对机械性能也有影响,这表明可以通过优化添加量来实现收缩控制和抗压强度之间的平衡,从而达到所需的性能。通过 MIP 和 NMR 进行的微观结构分析表明,添加了 SAP 和沸石的 UHPC 整体孔隙率增加,这表明低场 NMR 可以成为补充传统测试方法的重要工具。这项研究的成果为优化耐久性和机械性能之间的平衡提供了宝贵的见解,为在现代建筑实践中以更具可持续性和成本效益的方式应用 UHPC 铺平了道路。
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来源期刊
CiteScore
7.40
自引率
1.20%
发文量
31
审稿时长
22 days
期刊介绍: Developments in the Built Environment (DIBE) is a recently established peer-reviewed gold open access journal, ensuring that all accepted articles are permanently and freely accessible. Focused on civil engineering and the built environment, DIBE publishes original papers and short communications. Encompassing topics such as construction materials and building sustainability, the journal adopts a holistic approach with the aim of benefiting the community.
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