Modeling the flexural strength of steel fibre reinforced concrete

IF 1.4 Q4 MATERIALS SCIENCE, MULTIDISCIPLINARY AIMS Materials Science Pub Date : 2023-01-01 DOI:10.3934/matersci.2023006
A. S. Karzad, M. Leblouba, Z. Al-Sadoon, M. Maalej, S. Altoubat
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Abstract

Industrial applications of fibre-reinforced concrete (FRC) in structures require extensive experimental and analytical investigations of the FRC material properties. For design purposes and applications involving the flexural loading of the member, it is essential to have a predictive model for the flexural strength of the FRC material. In the present paper, a fracture mechanics approach based on Bridged Crack Model (BCM) is used to predict the flexural strength of steel fibre-reinforced concrete (SFRC) beams. The model assumes a quadratic tension-softening relationship (σ-δ) governing the bridging action of the steel fibres and a linear profile of the propagating crack. The proposed tension-softening relationship is considered valid for a wide range of fibre-reinforced concrete materials based on the knowledge of either the material micromechanical parameters (such as fibre volume fraction, fibre/matrix bond strength, fibre length, and fibre tensile strength) or an actual experimentally-measured σ-δ relationship. The flexural strength model thus obtained allows the prediction of the flexural strength of SFRC and study the variation of the latter as a function of the micromechanical parameters. An experimental program involving the flexural testing of 13 SFRC prism series was carried out to verify the prediction of the proposed model. The SFRC mixes incorporated two types of steel fibres (straight-end and hooked-end), four different concrete compressive strengths (40, 50, 60, and 70 MPa), three different fibre volume fractions (1, 1.5, and 2%), and three specimen depths (100, 150, and 200 mm). The experimental results were compared to the predictions of the proposed flexural strength model, and a reasonable agreement between the two has been observed. The model provided a useful physical explanation for the observed variation of flexural strength as a function of the test variables investigated in this study.
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钢纤维混凝土的抗弯强度建模
纤维增强混凝土(FRC)在结构中的工业应用需要对纤维增强混凝土材料性能进行广泛的实验和分析研究。对于涉及构件弯曲载荷的设计目的和应用,有一个FRC材料抗弯强度的预测模型是必不可少的。本文采用基于桥梁裂缝模型(BCM)的断裂力学方法对钢纤维混凝土梁的抗弯强度进行了预测。模型假设钢纤维的桥接作用为二次型拉伸-软化关系(σ-δ),裂纹扩展呈线性分布。基于材料微力学参数(如纤维体积分数、纤维/基体粘结强度、纤维长度和纤维抗拉强度)或实际实验测量的σ-δ关系的知识,所提出的拉伸-软化关系被认为适用于广泛的纤维增强混凝土材料。由此得到的抗弯强度模型可以预测钢纤维混凝土的抗弯强度,并研究其随细观力学参数的变化规律。通过13个SFRC系列棱镜的弯曲试验,验证了该模型的预测结果。SFRC混合材料包括两种类型的钢纤维(直端和钩端),四种不同的混凝土抗压强度(40、50、60和70 MPa),三种不同的纤维体积分数(1%、1.5和2%),以及三种试件深度(100、150和200 mm)。将实验结果与所提出的抗弯强度模型的预测结果进行了比较,两者之间有较好的一致性。该模型为观察到的弯曲强度变化作为本研究中研究的测试变量的函数提供了有用的物理解释。
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来源期刊
AIMS Materials Science
AIMS Materials Science MATERIALS SCIENCE, MULTIDISCIPLINARY-
CiteScore
3.60
自引率
0.00%
发文量
33
审稿时长
4 weeks
期刊介绍: AIMS Materials Science welcomes, but not limited to, the papers from the following topics: · Biological materials · Ceramics · Composite materials · Magnetic materials · Medical implant materials · New properties of materials · Nanoscience and nanotechnology · Polymers · Thin films.
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