Attenuation Law of Stress Waves in Cracked Rock Mass under Different Confining Pressures

Lou, Xiaoming; Luo, Rui; Yu, Jin

doi:10.1155/2019/7325634

Cited by 6 publications

(3 citation statements)

References 18 publications

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“…The model casting was carried out layer by layer so as to fix the fissure and plant the strain brick; the vibration stirrer was used in the pouring process to ensure that the density of the model was uniform and to reduce the influence of interface delamination on the wave propagation. The effectiveness of stress waves tested by such tests has been verified in previous studies [13].…”

Section: Experimental Program and Validation Of Effectivenesssupporting

confidence: 53%

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Stress wave propagation in different number of fissured rock mass based on nonlinear analysis

Lou

Sun

2020

International Journal of Nonlinear Sciences and Numerical Simulation

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The fissures are ubiquitous in deep rock masses, and they are prone to instability and failure under dynamic loads. In order to study the propagation attenuation of dynamic stress waves in rock mass with different number of fractures under confining pressure, nonlinear theoretical analysis, indoor model test and numerical simulation are used respectively. The theoretical derivation is based on displacement discontinuity method and nonlinear fissure mechanics model named BB model. Using ABAQUS software to establish a numerical model to verify theoretical accuracy, and indoor model tests were carried out too. The research shows that the stress attenuation coefficient decreases with the increase of the number of fissures. The numerical simulation results and experimental results are basically consistent with the theoretical values, which verifies the rationality of the propagation equation.

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Section: Experimental Program and Validation Of Effectivenesssupporting

confidence: 53%

“…where A is the peak stress after passing through the cracks. When the stress wave P-wave propagates through multiple fissures, assume the rock materials between the fissures are linear elastic materials, then the P-wave satisfies the time-shifting function [13]:…”

Section: Stress Propagation Equations Of Multiple Fissures Under Confmentioning

confidence: 99%

Stress wave propagation in different number of fissured rock mass based on nonlinear analysis

Lou

Sun

2020

International Journal of Nonlinear Sciences and Numerical Simulation

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“…Stress wave attenuation occurs when the joint filling reaches a certain thickness and becomes nonnegligible. In addition, it can cause the attenuation of wave propagation velocity and energy which can further affect the stability of rock mass [1][2][3]. e incidence condition of stress waves at any angle can be more complicated than that of the vertical incidence condition in the rock joint.…”

Section: Introductionmentioning

confidence: 99%

Fluctuation Characteristic Test of Oblique Stress Waves in Infilled Jointed Rock and Study of the Analytic Method

Liu

et al. 2020

Advances in Civil Engineering

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The propagation of stress waves in filled jointed rocks involves two important influencing factors: transmission-reflection phenomena and energy attenuation. In this paper, the split Hopkinson pressure bar (SHPB) test is used to shock the filled rock with joint angles of 0, 30, and 45° and the thickness of 4 mm and 10 mm, respectively, in three different velocities. The wave curves of the incident wave, reflected wave, and transmission are obtained. The effects of the filling angle and joint thickness on wave propagation are analyzed. Based on the propagation characteristics of stress waves in joints, the stress expression of oblique incident stress waves propagating in filling joints is derived, and the energy coefficient of transmission and reflection is calculated. The results show that the propagation of stress wave in filling joints is related to the impact rate. The larger the impact rate is, the larger the maximum voltage amplitude of the three waves is. And the increasing amplitude of the incident and reflected waves is larger than the transmitted wave; the greater the impact velocity is, the smaller the stress-strain curve gap of the three dip joints is, and the fracture strength of the specimen decreases with the increase of the joint dip angle. The larger the joint dip angle is, the smaller the deformation of the rock-like specimen is. The change of the transmission coefficient is related to the joint angle, and the larger joint angle weakens the influence of the joint width on the transmission of the transmitted wave; under each impact velocity, the theoretical and experimental stress peaks are approximately the same, and the transmission coefficient maintains a good consistency with the oblique incident angle.

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Study on the Bottom-Hole Rock-Breaking Law of Electrohydraulic Shockwave

Liu

Zhang

et al. 2023

Rock Mech Rock Eng

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Attenuation Law of Stress Waves in Cracked Rock Mass under Different Confining Pressures

Cited by 6 publications

References 18 publications

Stress wave propagation in different number of fissured rock mass based on nonlinear analysis

Stress wave propagation in different number of fissured rock mass based on nonlinear analysis

Fluctuation Characteristic Test of Oblique Stress Waves in Infilled Jointed Rock and Study of the Analytic Method

Study on the Bottom-Hole Rock-Breaking Law of Electrohydraulic Shockwave

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