Numerical Simulation on Cracks Propagation and Coalescence Process in Rock

Qiao, Deng Pan; Sun, Ya; Wang, Shu Hong; Zhang, Juan Xia

doi:10.4028/www.scientific.net/kem.353-358.933

Cited by 2 publications

(1 citation statement)

References 11 publications

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“…Compared to single crack, multiple crack fracture mechanism is relatively complex. Some studies about multiple crack fracture behavior under static loading have been performed in different rock‐like materials either by numerical simulation, by experiment or by combining both of them . Nasri et al used the extended finite element method to analysis the interaction effect between two cracks under tensile load, but experimental study was not carried out due to the limitation of experimental technology.…”

Section: Introductionmentioning

confidence: 99%

The effect of a pre‐existing crack on a running crack in brittle material under dynamic loads

Zhou

Zhu

Wang

et al. 2019

Fatigue Fract Eng Mat Struct

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Brittle material usually contains plenty of cracks or micro‐cracks, which raises a question that how a pre‐existing crack affects a running crack as they are approaching. In order to investigate such issue, impact experiments were conducted by using double crack semi‐circle (DCSC) specimens. Polymethyl methacrylate (PMMA) was selected to make the DCSC specimens, and a modified SHPB system was used to perform the impact tests. The finite difference code AUTODYN was employed to simulate the crack propagation behavior and propagation path, and the simulated crack paths agree well with the impact test results. Meanwhile the stresses around the crack tips were analyzed and the crack propagation direction was investigated. To calculate the crack dynamic stress intensity factors (DSIFs), finite element code ABAQUS was employed. The results show that the spacing D between the vertical crack tip and the inclined crack center affects the stress distribution and fracture behavior of the vertical crack largely. As the vertical crack approaches the inclined crack, the crack speed is slow down, and tensile stress appears at the inclined crack tip. As the spacing D is small than 50 mm, the vertical crack connects with the middle area of the inclined crack. As the spacing D is 50 mm, the vertical crack connects with either the middle area or the upper tip of the inclined crack. As the spacing D is larger than 50 mm, the vertical crack coalesces with the upper crack tip.

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Section: Introductionmentioning

confidence: 99%

The effect of a pre‐existing crack on a running crack in brittle material under dynamic loads

Zhou

Zhu

Wang

et al. 2019

Fatigue Fract Eng Mat Struct

View full text Add to dashboard Cite

show abstract

A Numerical Investigation into the Effect of Homogeneity on the Time-Dependent Behavior of Brittle Rock

et al. 2021

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To investigate the brittle creep failure process of rock material, the time-dependent properties of brittle rocks under the impact of homogeneity are analyzed by the numerical simulation method, RFPA-Creep (2D). Deformation is more palpable for more homogeneous rock material under the uniaxial creep loading condition. At a low stress level, diffusion creep may occur and transition to dislocation creep with increasing applied stress. The law for increasing creep strain with the homogeneity index under a constant confined condition is similar to the uniaxial case, and dislocation creep tends to happen with increasing confining pressure for the same homogeneity index. The dilatancy index reaches its maximum at a high stress level when rock approaches failure, and the evolution of the dilatancy index with the homogeneity index under the same confining pressure is similar to the uniaxial case and is more marked than that under the unconfined condition. Both uniaxial and triaxial creep failure originate from the ductile damage accumulation inside rock. The dominant shear-type failure is exhibited by uniaxial creep and the conventional compression case presents the splitting-based failure mode. Under confining pressure, the creep failure pattern is prone to shear, which is more notable for the rock with higher homogeneity.

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Numerical Simulation on Cracks Propagation and Coalescence Process in Rock

Cited by 2 publications

References 11 publications

The effect of a pre‐existing crack on a running crack in brittle material under dynamic loads

The effect of a pre‐existing crack on a running crack in brittle material under dynamic loads

A Numerical Investigation into the Effect of Homogeneity on the Time-Dependent Behavior of Brittle Rock

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