Interfacial Shear Behavior of Composite Concrete Substrate to High-Performance Concrete Overly After Exposure to Elevated Temperature

IF 3.6 3区 工程技术 Q1 CONSTRUCTION & BUILDING TECHNOLOGY International Journal of Concrete Structures and Materials Pub Date : 2024-03-27 DOI:10.1186/s40069-023-00654-9
Nagat M. Zalhaf, Sabry Fayed, Mohamed H. Zakaria
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Abstract

Basically, the interface shear strength between two concrete layers of varying ages must be sufficient to withstand the applied actions on the structure, specifically fire attack, which may cause the complete collapse of the composite structure. Thus, interfacial shear behavior was investigated and analyzed in this paper under the influence of a set of parameters, including temperature (25, 200, 400, and 600 °C), time exposure (30, 60, 90, 120, and 180 min), concrete type, and fibers type (polypropylene fiber (PPF), steel fiber (SF), and hybrid fiber) by employing a Z-shape push-off test. The test consists of two parts with different ages: normal strength concrete (NCS) and high-performance concrete (HPC). HPC includes high-strength concrete (HSC) and fly ash concrete (FAC). Initially, twenty-five Z-shaped push-off tests were made, four of which were cast as one unit (NSC/or concrete with hybrid (FSP)), and the rest were composite specimens. Furthermore, a 3D finite element model of a composite push-off specimen was developed to simulate and analyze the impact of various time and temperature exposures on the interfacial shear strength of composite specimen N-FSP. The results indicated that temperature degree and exposure time adversely affected the interfacial shear strength. Also, interfacial shear strength is significantly influenced by fiber types. Including combined fiber (SF + PPF) improved the interfacial shear strength by 114% compared to the composite specimen NSC-NSC after exposure to a temperature of 600 °C. In contrast, using PPF negatively affected the interfacial shear strength, recording only 84% of the composite specimen NSC-NSC. In addition, the inclusion of supplementary cementitious material enhanced the interfacial shear strength by 60.5% in the NSC-FAC composite specimen with 30% FA, compared to the NSC-NSC specimen. Finally, a finite element (FE) model was proposed with a satisfactory level of accuracy (0.95 to 1.03) in predicting the maximum shear strength. Additionally, the difference between the FE and experimental stiffness was between 0.92 and 1.07.

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高温暴露后复合混凝土基材与高性能混凝土的界面剪切行为
从根本上说,不同龄期的两层混凝土之间的界面剪切强度必须足以承受结构上的外力作用,特别是可能导致复合结构完全坍塌的火灾。因此,本文通过 Z 型推移试验,研究和分析了在温度(25、200、400 和 600 °C)、暴露时间(30、60、90、120 和 180 分钟)、混凝土类型和纤维类型(聚丙烯纤维 (PPF)、钢纤维 (SF) 和混合纤维)等一系列参数影响下的界面剪切行为。试验包括两个不同龄期的部分:普通强度混凝土(NCS)和高性能混凝土(HPC)。高性能混凝土包括高强度混凝土(HSC)和粉煤灰混凝土(FAC)。最初共进行了 25 次 Z 型推移试验,其中 4 次为整体浇注(NSC 和/或混合混凝土(FSP)),其余为复合试件。此外,还建立了复合材料推移试件的三维有限元模型,模拟和分析了不同时间和温度暴露对 N-FSP 复合材料试件界面剪切强度的影响。结果表明,温度程度和暴露时间对界面剪切强度有不利影响。此外,界面剪切强度还受到纤维类型的显著影响。与暴露温度为 600 °C 的复合试样 NSC-NSC 相比,复合纤维(SF + PPF)的界面剪切强度提高了 114%。相反,使用 PPF 会对界面剪切强度产生负面影响,仅为 NSC-NSC 复合试样的 84%。此外,与 NSC-NSC 试样相比,添加 30% FA 的 NSC-FAC 复合试样的界面剪切强度提高了 60.5%。最后,提出的有限元(FE)模型在预测最大剪切强度方面具有令人满意的精确度(0.95 至 1.03)。此外,FE 和实验刚度之间的差异在 0.92 和 1.07 之间。
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来源期刊
International Journal of Concrete Structures and Materials
International Journal of Concrete Structures and Materials CONSTRUCTION & BUILDING TECHNOLOGY-ENGINEERING, CIVIL
CiteScore
6.30
自引率
5.90%
发文量
61
审稿时长
13 weeks
期刊介绍: The International Journal of Concrete Structures and Materials (IJCSM) provides a forum targeted for engineers and scientists around the globe to present and discuss various topics related to concrete, concrete structures and other applied materials incorporating cement cementitious binder, and polymer or fiber in conjunction with concrete. These forums give participants an opportunity to contribute their knowledge for the advancement of society. Topics include, but are not limited to, research results on Properties and performance of concrete and concrete structures Advanced and improved experimental techniques Latest modelling methods Possible improvement and enhancement of concrete properties Structural and microstructural characterization Concrete applications Fiber reinforced concrete technology Concrete waste management.
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