2019
DOI: 10.1155/2019/3069029
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Microcrack Growth Properties of Granite under Ultrasonic High‐Frequency Excitation

Abstract: The failure of most rock materials is essentially a process of crack initiation and propagation. It is of great significance to study the microcrack growth characteristics of granite under ultrasonic high-frequency excitation for understanding the failure mechanism of rock under ultrasonic vibration. In this paper, the experimental and numerical simulation methods are used to study the propagation characteristics of rock cracks under ultrasonic vibration. Scanning electron microscopy (SEM) was used to observe … Show more

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Cited by 26 publications
(18 citation statements)
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“…Again, Quartz is the deviant behaving in a strongly nonlinear manner while Feldspar and Biotite show practically linear temperature dependence within the present range of interest 7 . The Quartz data by Polyakova 39 is approximated by the 6 th order polynomial written along with the linear fits for Feldspar and Biotite as: αnormalqθ=6.1321θ61.3817θ5+1.1914θ44.7512θ3+8.1310θ2false[1/Kfalse] αnormalfθ=αf0θ=293K+Kαfθfalse(θ293Kfalse)false[1/Kfalse],Kαfθ=αfmaxαf0550K αnormalbθ=αb0θ=293K+Kαbθθ293K1/K,Kαbθ=αbmaxαb0550Kwhere …”
Section: Numerical Simulationsmentioning
confidence: 66%
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“…Again, Quartz is the deviant behaving in a strongly nonlinear manner while Feldspar and Biotite show practically linear temperature dependence within the present range of interest 7 . The Quartz data by Polyakova 39 is approximated by the 6 th order polynomial written along with the linear fits for Feldspar and Biotite as: αnormalqθ=6.1321θ61.3817θ5+1.1914θ44.7512θ3+8.1310θ2false[1/Kfalse] αnormalfθ=αf0θ=293K+Kαfθfalse(θ293Kfalse)false[1/Kfalse],Kαfθ=αfmaxαf0550K αnormalbθ=αb0θ=293K+Kαbθθ293K1/K,Kαbθ=αbmaxαb0550Kwhere …”
Section: Numerical Simulationsmentioning
confidence: 66%
“…Temperature dependence of Quartz Young's modulus (A); thermal expansion coefficients for granite forming minerals (B); temperature dependence of Quartz thermal conductance (C); specific heat (D) (data after Toifl et al 7 . and Polyakova 39 )…”
Section: Numerical Simulationsmentioning
confidence: 99%
“…To properly predict the failure mode in tension, the tensile strength is assumed to be heterogeneous, i.e., mineral specific. In this respect, the numerical rock consists of quartz (33%), feldspar (59%) and biotite (8%) minerals, with their respective tensile strengths [27] of 14 MPa, 11 MPa and 7 MPa. Moreover, the mode I specific fracture energies, G Ic , are [28] 40 J/m 2 for quartz and felspar, and 28 J/m 2 for biotite.…”
Section: Materials Properties and Model Parametersmentioning
confidence: 99%
“…The material properties and model parameters used in the initial crack population simulations are given in Table 1. The numerical rock consists of Quartz (33%), Feldspars (59%) and Biotite (8%) minerals, and most of their properties are taken from Zhao et al [53], Mahabadi [10], and Vasquez et al [45]. The rock heterogeneity is described by random clusters of finite elements assigned with the material properties of the constituent minerals.…”
Section: Materials Properties and Model Parametersmentioning
confidence: 99%
“…Due to its importance in geology and rock engineering, the effect of microcracks on rock under various loading conditions has been widely investigated both experimentally [5,14,16,29,49,52] and numerically [5,11,13,16,18,20,22,25,26,53]. The focus in numerical modelling has been on the effect of microcracks under compression as it is the natural state of bedrock.…”
Section: Introductionmentioning
confidence: 99%