基于矿渣的单组分土工聚合物混凝土的力学性能和应力应变关系:比较研究

IF 6 Q1 ENGINEERING, MULTIDISCIPLINARY
Amgad Alhamoud, Hossein Tajmir Riahi, Abdolreza Ataei
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引用次数: 0

摘要

全面了解单组分矿渣基土工聚合物混凝土(SBGC)的工程特性有助于促进其广泛应用和优化设计,改善施工实践,推动建筑环境的可持续发展。本研究考察了单组分 SBGC 的工作性、抗压强度的发展、抗拉强度、弹性模量和应力应变行为。此外,还考察了 SBGC 在常温固化和水固化条件下的长期抗压强度。根据活化剂比率、骨料大小、水与粘结剂比率、固化条件和活化剂类型等不同因素,对多种混合物组合进行了评估。这项研究还提出了预测单组分 SBGC 拉伸强度和弹性模量的新公式。研究结果表明,与在环境条件下固化的试样相比,水固化试样的抗压强度最高可提高 43%,抗拉强度最高可提高 52%。提高混合物中活化剂的比例可显著加快抗压强度和 SBGC 弹性模量的早期发展。此外,单组分 SBGC 的长期强度发展比传统混凝土高出 20% 以上。此外,SBGC 的应力-应变行为显示出其固有的脆弱性,其特点是近乎完美的线性弹性突然过渡到完全和突然的坍塌,这使其有别于普通混凝土。微观结构分析表明,提高活化剂比率可减少混合物中未反应的 GGBFS 颗粒和石英的存在,从而促进凝胶的形成。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Mechanical properties and stress-strain relationship of slag-based one-part geopolymer concrete: A comparative study
A comprehensive understanding of the engineering characteristics of one-part slag-based geopolymer concrete (SBGC) is instrumental in promoting its widespread adoption and optimized design, improving construction practices, and advancing sustainability in the built environment. This study examined the workability, development of compressive strength, tensile strength, modulus of elasticity, and stress-strain behavior of one-part SBGC. The long-term compressive strength of SBGC, under both ambient curing and water curing conditions, has also been examined. Multiple combinations of mixtures were assessed, accounting for diverse factors such as activator ratio, aggregate size, water-to-binder ratio, curing conditions and activator types. This research also proposes new equations for predicting tensile strength and modulus of elasticity for one-part SBGC. The findings reveal that water-cured specimens demonstrate up to 43 % higher compressive strength and 52 % higher tensile strength compared to those cured under ambient conditions. Increasing the activator proportion in the mixture notably accelerates the early-stage development of compressive strength and SBGC's modulus of elasticity. Furthermore, one-part SBGC exhibits a long-term strength development that surpasses conventional concrete by over 20 %. In addition, the stress-strain behavior of SBGC reveals its inherent fragility, marked by near-perfect linear elasticity that abruptly transitions to complete and sudden collapse, distinguishing it from ordinary concrete. Microstructural analyses indicate that elevating the activator ratio reduces the presence of unreacted GGBFS particles and quartz in the mixture, thereby promoting the formation of gel.
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来源期刊
Results in Engineering
Results in Engineering Engineering-Engineering (all)
CiteScore
5.80
自引率
34.00%
发文量
441
审稿时长
47 days
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