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Statistical micromechanical damage model for SH-SFRC under tensile load considering the interfacial slip-softening and matrix spalling effects

Hehua Zhu, Xiangyang Wei, J. W. Ju, Qing Chen, Zhiguo Yan, Yi Shen

2021International Journal of Damage Mechanics20 citationsDOI

Abstract

Strain hardening behavior can be observed in steel fiber reinforced concretes under tensile loads. In this paper, a statistical micromechanical damage framework is presented for the strain hardening steel fiber reinforced concrete (SH-SFRC) considering the interfacial slip-softening and matrix spalling effects. With a linear slip-softening interface law, an analytical model is developed for the single steel fiber pullout behavior. The crack bridging effects are reached by averaging the contribution of the fibers with different inclined angles. Afterwards, the traditional snubbing factor is modified by considering the fiber snubbing and the matrix spalling effects. By adopting the Weibull distribution, a statistical micromechanical damage model is established with the fracture mechanics based cracking criteria and the stress transfer distance. The comparison with the experimental results demonstrates that the proposed framework is capable of reproducing the SH-SFRC’s uniaxial tensile behavior well. Moreover, the impact of the interfacial slip-softening and matrix spalling effects are further discussed with the presented framework.

Topics & Concepts

SpallMaterials scienceComposite materialSlip (aerodynamics)SofteningUltimate tensile strengthCrackingWeibull distributionFiber-reinforced concreteHardening (computing)Strain hardening exponentStructural engineeringFiberEngineeringLayer (electronics)StatisticsMathematicsAerospace engineeringInnovative concrete reinforcement materialsStructural Behavior of Reinforced ConcreteRock Mechanics and Modeling
Statistical micromechanical damage model for SH-SFRC under tensile load considering the interfacial slip-softening and matrix spalling effects | Litcius