An experimentally validated numerical analysis of UHP-FRC subjected to blast loading

IF 2.1 Q2 ENGINEERING, CIVIL International Journal of Protective Structures Pub Date : 2022-09-07 DOI:10.1177/20414196221120512
M. Sherif, H. Othman, H. Marzouk, H. Aoude
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Abstract

This paper presents a new material constitutive model for simulating the uniaxial material behavior of ultra-high performance fiber reinforced concrete (UHP-FRC). The model accounts for the contribution of the steel fiber content to the tensile behavior. The model variables are the fracture energy, the characteristic length, and the crack bandwidth. Thus, it guarantees a mesh size independent numerical modeling of UHP-FRC. The model is developed based on the reported results of a state-of-the-art and highly accurate experimental investigation for the uniaxial behavior of UHP-FRC. This paper also adopts the concrete damage plasticity model (CDP) as a multi-axial yield surface criterion and presents the applicability of the material constitutive model and CDP for modeling UHP-FRC under unconfined non-contact blast loading. The results of the numerical models are validated against the experimental data of shock tube testing conducted by the authors at the University of Ottawa shock tube in collaboration with Ryerson University. The results revealed that the developed material constitutive model accurately represented the uniaxial behavior of UHP-FRC. The CDP model combined with the material constitutive model developed in this study can accurately model UHP-FRC structures under unconfined non-contact blast loading.
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UHP-FRC在爆炸载荷作用下的实验验证数值分析
本文提出了一种新的材料本构模型,用于模拟超高性能纤维混凝土(UHP-FRC)的单轴材料行为。该模型考虑了钢纤维含量对拉伸行为的贡献。模型变量为断裂能、特征长度和裂纹带宽。因此,它保证了UHP-FRC的网格大小无关的数值建模。该模型是基于UHP-FRC单轴行为的最先进且高度准确的实验研究结果开发的。本文还采用混凝土损伤塑性模型(CDP)作为多轴屈服面准则,并介绍了材料本构模型和CDP在无侧限非接触爆破载荷下对UHP-FRC建模的适用性。数值模型的结果与作者在渥太华大学冲击管与瑞尔森大学合作进行的冲击管测试的实验数据进行了验证。结果表明,所建立的材料本构模型准确地反映了UHP-FRC的单轴行为。CDP模型与本研究开发的材料本构模型相结合,可以准确地对UHP-FRC结构在无侧限非接触爆破荷载下进行建模。
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来源期刊
CiteScore
4.30
自引率
25.00%
发文量
48
期刊最新文献
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