Structural behavior of the steel fiber reinforced concrete beam under multiple impact loadings: An experimental investigation

Jin, Liu; Zhang, Renbo; Du, Xiuli; Dou, Guoqin

doi:10.1177/1056789519862331

Cited by 7 publications

(4 citation statements)

References 35 publications

(66 reference statements)

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“…However, the reform damage under the second impact was due to the first impact's flexural crack, w duced the shear transfer capacity of the concrete section. Usually, the failure mode of the RC members under repeated impact loading at the same location should be determined by the damage pattern from the very first impact [19]. However, the findings in this research showed that this theory only applies to a specimen without axial load.…”

Section: Damage Patternmentioning

confidence: 71%

“…The difference in the energy dissipation of each posterior impact load led to different damage patterns and deformation of the specimens induced by the prior impact. Furthermore, Jin et al [19] reveal that the damage caused by the initial impact determines the total damage pattern of the beam. If repetitive impact occurs in the same area, the original cracks widen.…”

Section: Introductionmentioning

confidence: 99%

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Nonlinear Response of RC Columns Subjected to Equal Energy-Double Impact Loads

et al. 2022

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Defining the damage and deflection from impact by using only the impact energy could be misleading due to the effect of impact momentum. In addition, reinforced concrete columns might be subjected to repeated impact loading. Hence, this study presents the numerical simulation of 16 RC columns with identical sizing and reinforcement details, subjected to equal energy-double impact loadings using a free-falling mass at midspan. The impact energy was kept constant for both impacts. For each analysis, the impact momentum was varied by varying the velocity and mass of the impactor. The axial load ratios of the columns are between 0.0 to 0.3 of the compressive strength of the concrete cross-section. The results clearly addressed the momentum effect on the impact responses. The momentum level affected the specimens’ damage behavior under the same input impact energy. A high momentum impact yielded more global flexural damage with large deflection, and a low momentum impact produced more local damage with a slight deflection. The axial load helps maintain the impact resistance capacity. However, the failure determined by the flexural damage pattern under the first impact was changed when subjected to the second impact to the shear mode with the presence of axial load. Further, the colliding index considering the momentum was used in the deflection prediction equation. The proposed equation improved the deflection calculation accuracy of reinforced concrete beams under equal energy but different momentum impact.

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Section: Damage Patternmentioning

confidence: 71%

Section: Introductionmentioning

confidence: 99%

Nonlinear Response of RC Columns Subjected to Equal Energy-Double Impact Loads

et al. 2022

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“…Under external loads including seismic action, fatigue stress, and dynamic motion, the mechanical properties of HFRC members will suffer an obvious degradation as well because of the continuous growth of initial defects within the concrete matrix, although quite different from the brittle manner of the plain concrete (Brandt, 2008;Abbas et al, 2014;Jin et al, 2020;Zhang et al, 2020). With respect to the potential failure attributed to the accumulation of unrecoverable deformation and irreversible damage, extensive test results have shown that the inclusion of fibers can effectively inhibit the cracking propagation and improve the damage threshold, resulting in a much more ductile failure mode featured with enhanced nonlinear stress-strain behaviors (Xu et al, 2018a).…”

Section: Introductionmentioning

confidence: 99%

An elastoplastic damage constitutive model for hybrid steel-polypropylene fiber reinforced concrete

Wang

et al. 2022

International Journal of Damage Mechanics

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An appropriate constitutive model to characterize the mechanical behavior of fiber reinforced concrete (FRC) plays a critical role in accurate prediction of structural performance. In this study, an elastoplastic damage constitutive model is developed for hybrid steel-polypropylene fiber reinforced concrete (HFRC), which can predict the versatile mechanical responses of HFRC as a result of various hybrid fiber inclusions. For plasticity growth, the Willam-Warnke five-parameter failure envelope is modified in the effective stress space to govern the yield condition of HFRC, while a nonlinear Drucker-Prager type plastic potential function is proposed to control the non-associated plastic flow. Regarding the damage evolution, the damage criterion and evolution laws are established in the Cauchy stress space, in which the plastic hardening and unilateral behaviors are taken into consideration. Upon two parallel integration algorithms to describe the development of plasticity and damage, as well as the identification of fiber-dependent parameters, the proposed model is numerically implemented and then validated by the experimental results from available research. The comparisons between the numerical predictions and the test results at both material scale and structural scale solidly demonstrate the capacity of the model in capturing the main features of HFRC when subjected to different loading paths.

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“…Recently various fiber-reinforced cement based materials, such as high-performance fiber-reinforced cement composites (HPFRCC), ultra-high performance fiber reinforced concrete (UHPFRC), and ultra-high performance steel fiber reinforced concrete (UHP-SFRC), among others, have been developed through the use of concrete with high matrix strength levels of 100 MPa or more with the addition of steel fibers to ensure a high level of protection of structures subjected to blast and impact loadings (Jin et al., 2020; Li et al., 2015; Liu et al., 2018; Wang et al., 2016; Yoo et al., 2017). Here, HPFRCC is referred to as the representative name of these materials in this paper.…”

Section: Introductionmentioning

confidence: 99%

Impact simulations for high-performance fiber-reinforced cement composites using a coupled finite element and smoothed particle Galerkin method

Lee

Kwak

2022

International Journal of Damage Mechanics

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This paper presents a projectile impact analysis of high-performance fiber-reinforced cement composite (HPFRCC) structures based on the coupling of the finite element method (FEM) and the smoothed particle Galerkin (SPG) model in the LS-DYNA program. The K&C material model is calibrated for the HPFRCC. Through a quasi-static analysis using the calibrated model, the criteria for the element size of a FEM and the nodal particle distance of the SPG model are determined. Numerical simulations of the coupled SPG-FEM model are conducted to predict the structural responses of HPFRCC structures subjected to high impact velocities ranging from 342 m/s to 808 m/s. The results for the coupled model are compared with experimental data as well as numerical results for a pure FEM model to determine the relative accuracy and efficiency of a coupled FEM and SPG model for the large deformation problem. The convergence of the numerical results is also investigated in terms of the residual velocity and penetration depth. Moreover, the effects of various parameters on the models are discussed through a sensitivity analysis, and suitable parameter ranges that improve the accuracy of the numerical results are suggested.

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Structural behavior of the steel fiber reinforced concrete beam under multiple impact loadings: An experimental investigation

Cited by 7 publications

References 35 publications

Nonlinear Response of RC Columns Subjected to Equal Energy-Double Impact Loads

Nonlinear Response of RC Columns Subjected to Equal Energy-Double Impact Loads

An elastoplastic damage constitutive model for hybrid steel-polypropylene fiber reinforced concrete

Impact simulations for high-performance fiber-reinforced cement composites using a coupled finite element and smoothed particle Galerkin method

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