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Numerical Simulation of Rock Vibration Response under Ultrasonic High-Frequency Vibration with High Confining Pressure
by
Wang, Minsheng
, Xuan, Lingchao
, Liu, Weikai
, Feng, Jinyu
, Wang, Heng
in
Acoustics
/ Amplitudes
/ Analysis
/ Boundary conditions
/ Breaking
/ Coal
/ Composite materials
/ Confining
/ Crack propagation
/ Crushing
/ Discrete element method
/ Drilling
/ Efficiency
/ Elastoplasticity
/ Excitation
/ Experiments
/ Information processing
/ Load
/ Mathematical analysis
/ Mathematical models
/ Mechanics
/ Methods
/ Numerical analysis
/ Parameters
/ Petroleum mining
/ Porous materials
/ Pressure
/ Pressure effects
/ Propagation
/ Resonance
/ Resonant frequencies
/ Rock properties
/ Simulation
/ Simulation methods
/ Solid mechanics
/ Stress concentration
/ Tensile stress
/ Three dimensional models
/ Ultrasonic imaging
/ Ultrasonic vibration
/ Vibration
/ Vibration analysis
/ Vibration response
/ Vibrations
2024
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Numerical Simulation of Rock Vibration Response under Ultrasonic High-Frequency Vibration with High Confining Pressure
by
Wang, Minsheng
, Xuan, Lingchao
, Liu, Weikai
, Feng, Jinyu
, Wang, Heng
in
Acoustics
/ Amplitudes
/ Analysis
/ Boundary conditions
/ Breaking
/ Coal
/ Composite materials
/ Confining
/ Crack propagation
/ Crushing
/ Discrete element method
/ Drilling
/ Efficiency
/ Elastoplasticity
/ Excitation
/ Experiments
/ Information processing
/ Load
/ Mathematical analysis
/ Mathematical models
/ Mechanics
/ Methods
/ Numerical analysis
/ Parameters
/ Petroleum mining
/ Porous materials
/ Pressure
/ Pressure effects
/ Propagation
/ Resonance
/ Resonant frequencies
/ Rock properties
/ Simulation
/ Simulation methods
/ Solid mechanics
/ Stress concentration
/ Tensile stress
/ Three dimensional models
/ Ultrasonic imaging
/ Ultrasonic vibration
/ Vibration
/ Vibration analysis
/ Vibration response
/ Vibrations
2024
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Numerical Simulation of Rock Vibration Response under Ultrasonic High-Frequency Vibration with High Confining Pressure
by
Wang, Minsheng
, Xuan, Lingchao
, Liu, Weikai
, Feng, Jinyu
, Wang, Heng
in
Acoustics
/ Amplitudes
/ Analysis
/ Boundary conditions
/ Breaking
/ Coal
/ Composite materials
/ Confining
/ Crack propagation
/ Crushing
/ Discrete element method
/ Drilling
/ Efficiency
/ Elastoplasticity
/ Excitation
/ Experiments
/ Information processing
/ Load
/ Mathematical analysis
/ Mathematical models
/ Mechanics
/ Methods
/ Numerical analysis
/ Parameters
/ Petroleum mining
/ Porous materials
/ Pressure
/ Pressure effects
/ Propagation
/ Resonance
/ Resonant frequencies
/ Rock properties
/ Simulation
/ Simulation methods
/ Solid mechanics
/ Stress concentration
/ Tensile stress
/ Three dimensional models
/ Ultrasonic imaging
/ Ultrasonic vibration
/ Vibration
/ Vibration analysis
/ Vibration response
/ Vibrations
2024
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Numerical Simulation of Rock Vibration Response under Ultrasonic High-Frequency Vibration with High Confining Pressure
Journal Article
Numerical Simulation of Rock Vibration Response under Ultrasonic High-Frequency Vibration with High Confining Pressure
2024
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Overview
As deep oil and gas resources and Carbon Capture and Storage (CCS) are developed, enhancing drilling efficiency in hard rock formations has emerged as a critical technology in oil and gas extraction. The advancement of ultrasonic, high-frequency vibration rock-breaking technology significantly facilitates efficient rock crushing. When subjected to ultrasonic high-frequency vibrations, the rock’s response is a crucial issue in implementing ultrasonic vibration rock crushing technology. This study employed numerical simulation and theoretical deduction methods, utilizing a multi-physics approach that couples solid mechanics with pressure acoustics. It integrated information on common influencing parameters of ultrasonic generators and reservoir rock properties to establish model parameters, analyze simulation results, and perform theoretical deductions. The research investigated the response patterns of different-sized rock samples under high-frequency ultrasound vibration excitation across various frequencies, amplitudes, and confining pressure conditions. Through the development of a three-dimensional model and the application of principles from solid mechanics and elastoplasticity, the study derived equations that describe the resonance frequencies of rock blocks under confining pressure as functions of relevant rock parameters. The findings indicate that ultrasonic vibrations can effectively induce rock displacement. Under excitation frequency sources, the rock exhibits a natural frequency correlated with the rock sample size. When the excitation frequency approximates the natural frequency, the rock resonates. At this point, the rock’s surface displacement is maximal. The rock undergoes tensile stress, leading to stress concentration that facilitates rock damage and fragmentation. Increasing the excitation amplitude enhances rock crushing, as it amplifies the maximum surface displacement under the same frequency excitation. Confining pressure exerts an inhibitory effect on the rock’s vibration response, but it does not alter the resonance frequency of the rock sample, a fact verified by both numerical simulation and theoretical results. Based on the research findings in this paper, it can help to optimize the parameters of ultrasonic vibration rock breaking in field application to achieve the best rock-breaking effect.
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