Your search keyword '"Beijing XIE"' showing total 23 results

1. Effect of Primary/Artificial Interface on Dynamic Failure Behavior of Combined Coal and Rock: Monitoring by High-Speed Imaging and Scanning Electron Microscopy

Author

Beijing Xie, Zheng Luan, Quan Wang, ChunLei Yao, and Shiqing Zhong

Subjects

Chemistry, QD1-999

Published

2024

2. Experimental study on dynamic mechanical properties of multidirectional constrained water-bearing coal samples under dynamic-static coupling loading

Author

Beijing Xie, Ben Zhang, Shunkun Zhao, and Shanyang Wei

Subjects

Water-bearing coal rocks, Dynamic mechanical properties, Dynamic and static coupling loading, SHPB, Energy dissipation, Fractal theory, Medicine, Science

Abstract

Abstract The objective of this study is to investigate the dynamic mechanical properties of coal and rock under deep water conditions. The research employs an enhanced Split Hopkinson Pressure Bar (SHPB) testing system. Five sets of dynamic impact experiments were conducted on coal samples under varying loading conditions to analyse the changes in dynamic strength, energy dissipation, fractal dimension and other characteristics of coal samples under different water content states were analyzed. The experimental results demonstrate that: (1) Under specific strain rate conditions, the dynamic strength of saturated coal samples is lower than that of natural coal samples. As the strain rate gradually increases, the bonding force generated by free water and the Stefan effect jointly act, and the peak strength of saturated coal samples under high strain rate loading conditions is higher than that of natural coal samples. (2) Under certain strain rate conditions, the absorption energy of saturated coal samples is approximately 10% to30% lower than that of natural coal samples, and deformation hysteresis phenomenon occurs in natural coal samples, thereby improving the dynamic strength of natural coal samples relative to saturated coal samples; (3) The fractal dimension of saturated coal samples with a specific strain rate under three-dimensional dynamic static combination loading is higher than that of natural coal samples, and the percentage of small particle coal samples with debris is higher than that of natural coal samples; Finally, based on the HJC model, some coal samples were selected to simulate the coal rock failure characteristics during the triaxial loading process using ANSYS/LS-DYNA, and their stress–strain curves and failure morphology diagrams were obtained. The discrepancy between the numerical simulation and the experimental results was less than 10%, thereby further elucidating and corroborating the coal failure process and dynamic mechanical characteristics.

Published

2024

3. Dynamic tensile mechanical properties of red sandstone under different pulse widths and amplitudes: Brazilian disk experiment and macroscopic and microscopic analysis

Author

Beijing Xie, Zheng Luan, Heng Li, Bowen Wu, Xiaoxu Li, and Dongxin Chen

Subjects

Shock pulse, SHPB, Dynamic response, DIC, Constitutive model, Mining engineering. Metallurgy, TN1-997

Abstract

To investigate the dynamic tensile mechanical properties of red sandstone under varying impact pulse widths and amplitudes, we employed the response surface methodology to examine the dynamic response characteristics of sandstone under different bullet lengths and impact velocities. Subsequently, a dynamic damage constitutive model for sandstone was developed. Macroscopic and microscopic features of sandstone were analyzed through digital image correlation (DIC) and scanning electron microscopy (SEM) experiments. Additionally, ANSYS software was utilized to analyze stress wave characteristics under controlled shock waves and the impact of geological factors on rock fracturing effects. The findings revealed the following. First, the length and impact velocity of bullets exhibit an interactive effect on the tensile response characteristics of sandstone. Peak load, energy consumption rate, and energy density display a positive correlation with bullet velocity. Second, according to the DIC results, the fractal dimension of the crack is negatively correlated with the length of the bullet during equal energy impacts. Third, microscopic failure modes included fractures along particle cementation and through particles, with section roughness decreasing as bullet length increased under equivalent energy impacts. Fourth, a dynamic damage constitutive model (R2 ≥ 0.84) was established based on the Zhu-Wang-Tang (Z-W-T) model and Drucker-Prager (D-P) criterion, clarifying model parameters and influence rules. Fifth, under controlled shock waves, the pulse width facilitates crack propagation, while the pulse amplitude initiates crack formation. Optimal rock breaking efficiency is achieved when stress waves exhibit a large pulse width and low radiation values, meeting specific threshold conditions.

Published

2024

4. Accurate monitoring and accounting of methane emission in underground coal mine

Author

Beijing XIE, Xiaoxu LI, Jingshun ZHANG, Zheng LUAN, Jun LI, Wei CHEN, Ziyao WANG, and Xiaoping TANG

Subjects

underground coal mine, methane emission, ipcc default value, accurate monitoring and accounting, emission factor, Mining engineering. Metallurgy, TN1-997

Abstract

Methane, the second most prevalent greenhouse gas globally, is characterized by its high global warming potential and short atmospheric lifetime. It is primarily emitted from sectors such as coal mining, oil and gas production, agriculture, livestock rearing, and waste management. Active, prudent, and orderly control of methane emissions offers a multifaceted benefit: it mitigates global warming, enhances the economic value through the resource utilization of energy, provides environmental advantages by control of pollutants, and improves safety by reducing production accidents. Methane is also the principal greenhouse gas emitted in coal mine operations. Currently, monitoring and researching the distribution of methane emissions and their concentration within the three-dimensional space of coal mines have become a key focus in China’s methane emission control efforts, which is of significant importance for coal mining enterprises to align with national strategies. A study conducted on a high-gas mine in Shanxi and a low-gas mine in Shaanxi for methane emission monitoring and accounting utilized fixed monitoring, manual monitoring, drone monitoring, and post-mining activity monitoring to investigate the distribution of methane in high and low gas mines in China and to analyze their methane emissions. The results indicate that: ① The methane emission volumes for a certain high-gas mine in Shanxi and a low-gas mine in Shaanxi published by the U.S.-based Climate TRACE website for the year 2022 show a significant discrepancy from the results calculated using the ground measurement method, with the published annual methane emission volume for a certain low-gas mine being 10.92 times that of the ground measurement calculation. The top-down monitoring and accounting methods have been found to be insufficiently accurate and unable to provide reliable data support for carbon trading. ② In the monitoring and accounting of post-mining activities, the use of default values recommended by the IPCC results in methane emissions that are 3 to 5 times higher than those calculated using the ground measurement method, and there is a significant variation in the emissions calculated based on coal samples of different sizes and exposure durations. There is an urgent need for a unified and precise testing standard to ensure fair and accurate data for future carbon market transactions.

Published

2024

5. Dynamic failure characteristics of primary coal-rock combination under hydrostatic pressure

Author

Beijing XIE, Zheng LUAN, Tianle LIU, Bowen WU, and Shiqing ZHONG

Subjects

hydrostatic pressure, primary combined coal rock, shpb, dynamic characteristics, fractal theory, Geology, QE1-996.5, Mining engineering. Metallurgy, TN1-997

Abstract

The surrounding rock of deep roadway is weak and the fissures are developed. Under the influence of mining disturbance, it is easy to cause dynamic disasters and the overall instability failure of coal rock combination is one of key factors inducing disasters. In order to explore the dynamic damage characteristics of the primary combined coal rock body under impact load, with the help of the split Hopkinson pressure bar and high-speed camera, raw coal, artificial combination and primary combination of coal rock are studied. Based on different hydrostatic pressure and strain rate conditions, this study explores the dynamic stress-strain, crack evolution and fracture fractal characteristics of coal rock and explores the deformation and failure characteristics of coal rock using macroscopic fracture fractal and microscopic electron microscope scanning. The study shows that ① the dynamic stress-strain of raw coal, artificial combination and primary combination of coal rock is significantly nonlinear and the plastic stage of primary coal rock is similar to “plastic platform”. ② Under impact load, the strain rate effect of dynamic compressive strength of coal rock is significant and the dynamic compressive strength and hydrostatic pressure of raw coal, primary combined coal rock show a trend of first increasing and then decreasing. The critical values of hydrostatic pressure (low pressure strengthening and high pressure weakening) are 8 MPa and 10 MPa and the artificial combined coal rock and hydrostatic pressure show a positive correlation trend. ③ Under the impact load, the crack initiations of primary and artificial combined coal rock occur in the coal composition area far from the interface of coal rock. The combined coal-rock interface significantly affects the deformation and failure behavior of the sample and when the impact velocity≥10 m/s, the overall instability failure of coal rock components can occur in the original combined coal rock, while only the coal component failure occurs in the artificial combined coal rock under the same disturbance. Besides, only when the impact velocity≥14 m/s, the tip stress of the crack is greater than the strength of the coal rock, which can penetrate the artificial interface and lead to the overall crushing. The original interface has a “guiding effect” on the crack penetration of the sample, which is easy to induce crack propagation to form a macroscopic fracture surface. ④ The crushing degrees of raw coal, original coal and artificial coal rock increase with the increase of impact velocity and the crushing particle size tends to be granular and powder. Under the same disturbance, the degrees of fragmentation of coal components in three types of coal rocks show a relationship: primary-coal components > artificial-coal components > raw coal.

Published

2023

6. Experimental and numerical simulation study on the dynamic fracture of coal by gas expansion

Author

Qifei Wang, Yuechao Zhao, Chengwu Li, Beijing Xie, and Honglai Xue

Subjects

coal, crack propagation, gas expansion, peridynamic, Technology, Science

Abstract

Abstract The high‐pressure gas expansion‐induced deformation and dynamic fracture of coal are important parts of coal and gas outburst. To better understand the law of this process, laboratory experiments and numerical simulation are used to study the law of damage. A cavity with different pressures of CH4 or N2 was destroyed by a jack to achieve the rapid expansion of the gas and coal fracture inside. The particle size distribution of the coal particles before and after the experiment was measured, and the breakage ratio and the newly added surface area were calculated. The experimental results indicate that during the gas expansion process, the breakage ratio of coal and the newly added surface area clearly increase with the increase in gas pressure. Finally, a numerical model based on peridynamic theory was developed to simulate crack generation and the propagation of coal induced by the expansion of gases at different pressures. The numerical simulation results show that the higher the initial gas pressure is, the higher the number of failure units. Moreover, only when the gas pressure is large enough will the coal crack in various directions at the same time.

Published

2020

7. Numerical Simulation of Split-Hopkinson Pressure Bar Tests for the Combined Coal-Rock by Using the Holmquist–Johnson–Cook Model and Case Analysis of Outburst

Author

Beijing Xie, Dongxin Chen, Hao Ding, Guangyu Wang, and Zheng Yan

Subjects

Engineering (General). Civil engineering (General), TA1-2040

Abstract

In the coal and rock dynamic disasters, such as the rock burst, dynamic load damage often acts simultaneously on the combined coal and rock mass. Based on the split-Hopkinson pressure bar (SHPB) test of the combined coal and rock with a bullet velocity of 4.590–8.791 m/s, the numerical model of four kinds of combined coal and rock with different sandstone-coal-sandstone ratios, including 1 : 1 : 1, 2 : 1 : 1, 1 : 1 : 2, and 1 : 2 : 1, is investigated. A finite element software (LS-DYNA) and the Holmquist–Johnson–Cook (HJC) constitutive model of rock are employed in these regards. The stress waveform, the oscillation phenomenon of stress wave, and the damage process of the specimen in the impact test of the composite coal and rock are studied. The obtained results show that the compression-shear failure is the main failure mode of the coal body and the tensile failure of the sandstone along the axial direction in the composite coal-rock specimens. Moreover, it is found that combination of coal and rock samples is mainly destroyed by the coal body, which has no correlation with the impact speed and combination mode. Finally, numerical simulation about Hongling coalmine extralarge tunnel malfunction is carried out. Obtained results showed the protruding and stress change processes of the coal seam of the tunnel exposing. It is found that the simulation results are in an excellent agreement with those from the field investigation. The present study may provide a reference for further understanding the mechanism of the coal and rock dynamic disasters, such as the rock burst.

Published

2020

8. Experimental Study on Stress Evolution and Microseismic Signals under Vibration Conditions of Coal during Excavation and Subsequent Waiting Time

Author

Qifei Wang, Chengwu Li, Pingyang Lyu, Yuechao Zhao, Dihao Ai, and Beijing Xie

Subjects

Physics, QC1-999

Abstract

An experiment designed to simulate coal during excavation was conducted. Microseismic signals of coal under vibration conditions during excavation and subsequent waiting time of the coal roadway at different excavation speeds were collected and analyzed. During the excavation and subsequent waiting time, the stress in coal is redistributed, and the concentrated stress is gradually transferred to the deeper section of the coal seam. The Hilbert–Huang transform (HHT) is used to effectively denoise the collected signals. According to the noise-reduced signal, the amplitude and pulse number of the microseismic signals emitted during the excavation process are much larger than those of the waiting time process. During excavation, the energy and event numbers of microseismic signals increase first and then decrease as the excavation speed increases. The faster the excavation speed, the more the energy, and the higher the event numbers of the microseismic signals released during the subsequent waiting time. When the excavation speed is faster, more elastic potential accumulates in the coal seam and the concentration stress is greater. As the concentrated stress moves forward in time without excavation, more coal seams fail, and more microseismic signals are released. The microseismic signal and the stress evolution law can provide a reasonable explanation for the forward movement of the concentrated stress and coal failure during roadway excavation.

Published

2019

9. Experimental Study of Fracture Characterizations of Rocks under Dynamic Tension Test with Image Processing

Author

Dihao Ai, Yuechao Zhao, Beijing Xie, and Chengwu Li

Subjects

Physics, QC1-999

Abstract

To investigate the fracture characterizations of rocks under high strain rate tensile failure, a series of dynamic Brazilian tests was conducted using Split Hopkinson pressure bar (SHPB), and a high-speed digital camera at a frame rate of 50,000 frames per second (FPS) with a resolution of 272 × 512 pixels was adopted to capture the real-time images and visualize the failure processes. Using the extracted cracks and image processing technique, the relationship between loading condition (impact velocity), crack propagation process (crack velocity, crack fractal characteristic, and crack morphological features), and dynamic mechanical properties (absorbed energy and strain-stress parameters) was explored and analyzed. The experimental results indicate that (1) impact velocity plays a critical role in both crack propagation process and dynamic mechanical properties, (2) the crack fractal dimension is positively correlated with crack propagation velocity and has a linear relationship with the proposed morphological feature of crack, (3) mean strain rate and max strain of rocks under SHPB loading both decrease with the increase of crack propagation velocity, and (4) the energy absorbed by the rocks increases with increasing impact velocity and has a strong negative correlation with a proposed novel crack descriptor. Experimental studies pertaining to the measurement of crack propagation path and velocity, in particular, some crack feature extraction approaches, present a promising way to reveal the fracture process and failure mechanisms of rock-like materials.

Published

2019

10. Influence of Different Bifurcation Angles on the Flame Propagation of Gas Explosions in Three-Way Bifurcated Pipes

Author

Beijing Xie, Zheng Luan, Dongxin Chen, Shiqing Zhong, Hao Ding, and Yujing Du

Subjects

General Chemical Engineering, General Chemistry

Abstract

Exploring the flame propagation law in the process of gas explosion under different bifurcation angles is of great significance to the design of coal mine roadway and the prevention of gas explosion accidents. To study the variation of flame propagation law with bifurcation angle, an in-house experimental system based on a small scale three-way bifurcated pipe was developed to perform gas explosion experiments using mixtures of premixed methane-air with a methane concentration of 9.5%. Numerical simulations were conducted to study the propagation of the explosion flame. The results show that, (i) during the flame propagation process, the flame morphology evolves in the following manner: hemispherical, concave entrainment-deformation-flattening; (ii) in the case of gas explosion of three-way bifurcated pipes, there are significant differences in damage at different positions, and the damage at the pipe connection is the most serious. (iii) Although the parameters of the explosion flame in the bifurcated pipe exhibit similar trends across four different bifurcation angles, the values of the flame parameters obtained by the experiments and numerical simulations were not completely consistent. (iv) When the bifurcation angle is between the 45 and 75° bifurcation range, the area of the turbulent vortex formed by the air flow increases as the angle of the pipe widens. The research results analyze the propagation law of gas deflagration flame in the bifurcated pipeline, providing reference for the propagation mechanism of gas deflagration in underground bifurcated roadway and the formulation of prevention measures, which is conducive to preventing the propagation of gas explosion, reducing the intensity, and reducing the loss caused by gas explosion. However, large-scale tests are needed to determine the applicability of small-scale tests and calculations in this paper to full-scale mine conditions.

Published

2022

11. Experimental and numerical simulation study on the dynamic fracture of coal by gas expansion

Author

Chengwu Li, Beijing Xie, Yuechao Zhao, Honglai Xue, and Qifei Wang

Subjects

coal, Computer simulation, lcsh:T, business.industry, crack propagation, Fracture mechanics, Mechanics, complex mixtures, lcsh:Technology, gas expansion, peridynamic, General Energy, Fracture (geology), lcsh:Q, Coal, lcsh:Science, Safety, Risk, Reliability and Quality, business, Physics::Atmospheric and Oceanic Physics, Geology, Gas expansion

Abstract

The high‐pressure gas expansion‐induced deformation and dynamic fracture of coal are important parts of coal and gas outburst. To better understand the law of this process, laboratory experiments and numerical simulation are used to study the law of damage. A cavity with different pressures of CH4 or N2 was destroyed by a jack to achieve the rapid expansion of the gas and coal fracture inside. The particle size distribution of the coal particles before and after the experiment was measured, and the breakage ratio and the newly added surface area were calculated. The experimental results indicate that during the gas expansion process, the breakage ratio of coal and the newly added surface area clearly increase with the increase in gas pressure. Finally, a numerical model based on peridynamic theory was developed to simulate crack generation and the propagation of coal induced by the expansion of gases at different pressures. The numerical simulation results show that the higher the initial gas pressure is, the higher the number of failure units. Moreover, only when the gas pressure is large enough will the coal crack in various directions at the same time.

Published

2020

12. A Study on the Characteristics of Electromagnetic Radiation during Deformation and Failure of Different Materials Under Uniaxial Compression

Author

Qifei Wang, Beijing Xie, Dihao Ai, Chengwu Li, and Yuechao Zhao

Subjects

Environmental Engineering, 010504 meteorology & atmospheric sciences, business.industry, Uniaxial compression, Solid material, Deformation (meteorology), 010502 geochemistry & geophysics, Geotechnical Engineering and Engineering Geology, 01 natural sciences, Electromagnetic radiation, Seismic exploration, Geophysics, Fracture (geology), Coal, Geotechnical engineering, business, Geology, 0105 earth and related environmental sciences

Abstract

The detection of electromagnetic radiation (EMR) during the fracture of solid materials such as rocks and coal has been widely used in seismic exploration and mine dynamic disaster prediction. As described in this paper, we conduct uniaxial compression tests on coal, cement, and glass materials to determine the characteristic EMR differences among materials. A band-stop filter based on the Fourier transform and the wavelet packet transform method are used to conduct signal denoising and analysis. Basic analyses of the pulse-time characteristics, energy distribution, cumulative energy, and waveform characteristics of EMR are conducted. The research results show that there is a strong corresponding relation between the loading time, loading stress and EMR energy. A large number of EMR events are released in rapid succession during the main rupture of coal and cement, while the EMR events are evenly distributed throughout the whole loading process of glass. For the same material, the maximum EMR amplitude increases with an increasing peak value of the stress. The EMR pulse waveform of coal and cement agrees well with predictions based on the theoretical formula of the electromagnetic dipole oscillation EMR generation mechanism. The paper provides further theoretical basis for understanding the mechanism of EMR, with great significance for improving coal mining safety.

Published

2020

13. Experimental Study of Fracture Characterizations of Rocks under Dynamic Tension Test with Image Processing

Author

Yuechao Zhao, Beijing Xie, Chengwu Li, and Dihao Ai

Subjects

Materials science, Article Subject, Mechanical Engineering, 0211 other engineering and technologies, Fracture mechanics, Image processing, 02 engineering and technology, Mechanics, Split-Hopkinson pressure bar, Dynamic Tension, Strain rate, Geotechnical Engineering and Engineering Geology, Condensed Matter Physics, Fractal dimension, lcsh:QC1-999, 020303 mechanical engineering & transports, Fractal, 0203 mechanical engineering, Mechanics of Materials, Fracture (geology), lcsh:Physics, 021101 geological & geomatics engineering, Civil and Structural Engineering

Abstract

To investigate the fracture characterizations of rocks under high strain rate tensile failure, a series of dynamic Brazilian tests was conducted using Split Hopkinson pressure bar (SHPB), and a high-speed digital camera at a frame rate of 50,000 frames per second (FPS) with a resolution of 272 × 512 pixels was adopted to capture the real-time images and visualize the failure processes. Using the extracted cracks and image processing technique, the relationship between loading condition (impact velocity), crack propagation process (crack velocity, crack fractal characteristic, and crack morphological features), and dynamic mechanical properties (absorbed energy and strain-stress parameters) was explored and analyzed. The experimental results indicate that (1) impact velocity plays a critical role in both crack propagation process and dynamic mechanical properties, (2) the crack fractal dimension is positively correlated with crack propagation velocity and has a linear relationship with the proposed morphological feature of crack, (3) mean strain rate and max strain of rocks under SHPB loading both decrease with the increase of crack propagation velocity, and (4) the energy absorbed by the rocks increases with increasing impact velocity and has a strong negative correlation with a proposed novel crack descriptor. Experimental studies pertaining to the measurement of crack propagation path and velocity, in particular, some crack feature extraction approaches, present a promising way to reveal the fracture process and failure mechanisms of rock-like materials.

Published

2019

14. An automatic pixel-level crack identification method for coals experiencing SHPB impact tests

Author

Yu Yang, Beijing Xie, and Dihao Ai

Subjects

Identification (information), Geophysics, Pixel, business.industry, Computer science, Geology, Pattern recognition, Artificial intelligence, Management, Monitoring, Policy and Law, Impact test, business, Industrial and Manufacturing Engineering

Published

2019

15. Simulation Experiment Teaching for Airport Fire Escape based on Virtual Reality and Artificial Intelligence Technology

Author

Jun Li, Yubin Xu, Xiaolong Mei, Beijing Xie, and Jinyang Wang

Subjects

Fire escape, Drill, Computer science, business.industry, Fire Dynamics Simulator, Fire protection, Firefighting, Civil aviation, Artificial intelligence, Virtual reality, business, Data modeling

Abstract

This paper proposes a simulation experiment teaching framework for airport fire escape based on virtual reality and artificial intelligence (AI) technology. It uses virtual reality technology and fire science theory to realize the construction of virtual fire scene and management of firefighting facilities, simulates fire dynamics with the help of fire dynamics simulator, and finally evaluates the quality of fire escape based on AI technology. Two example cases demonstrate that the system works well and has promising to become a new teaching mode for fire drill in civil aviation airports.

Published

2020

16. Characteristics and generation mechanism of ULF magnetic signals during coal deformation under uniaxial compression

Author

Shuai Fu, Chengwu Li, Cheng Guan, Tianyu Wan, and Beijing Xie

Subjects

Materials science, 010504 meteorology & atmospheric sciences, business.industry, Uniaxial compression, Geology, Management, Monitoring, Policy and Law, Deformation (meteorology), 010502 geochemistry & geophysics, 01 natural sciences, Industrial and Manufacturing Engineering, Mechanism (engineering), Geophysics, Coal, Composite material, business, 0105 earth and related environmental sciences

Published

2018

17. Crack identification and evolution law in the vibration failure process of loaded coal

Author

Chengwu Li, Dihao Ai, Beijing Xie, and Sun Xiaoyuan

Subjects

Engineering, business.industry, Process (engineering), Mechanical engineering, Geology, 02 engineering and technology, Structural engineering, Management, Monitoring, Policy and Law, 01 natural sciences, Industrial and Manufacturing Engineering, 010309 optics, Vibration, Identification (information), Geophysics, 020401 chemical engineering, 0103 physical sciences, Coal, 0204 chemical engineering, business

Published

2017

18. The correlated characteristics of micro-seismic and electromagnetic radiation signals on a deep blasting workface

Author

Beijing Xie, Xiaomeng Xu, Chuan Wang, Jing Li, Xiaoyuan Sun, and Chengwu Li

Subjects

Acoustics, Geology, 02 engineering and technology, Management, Monitoring, Policy and Law, 010502 geochemistry & geophysics, 01 natural sciences, Electromagnetic radiation, Industrial and Manufacturing Engineering, 020501 mining & metallurgy, Geophysics, 0205 materials engineering, 0105 earth and related environmental sciences, Rock blasting

Published

2016

19. Experimental study on physical structure properties and anisotropic cleat permeability estimation on coal cores from China

Author

Stefan Iglauer, Beijing Xie, Mohammad Sarmadivaleh, Chengwu Li, and Xiaomeng Xu

Subjects

Materials science, Bedding, business.industry, Effective stress, Coal mining, Energy Engineering and Power Technology, Mineralogy, 02 engineering and technology, 010502 geochemistry & geophysics, Geotechnical Engineering and Engineering Geology, 01 natural sciences, Fuel Technology, 020401 chemical engineering, Bed, Permeability (electromagnetism), Coal, 0204 chemical engineering, Porosity, Anisotropy, business, 0105 earth and related environmental sciences

Abstract

Knowledge of the natural structure properties of coal seams is essential for the coal bed methane (CBM) production because of their great influence on the inner flow characteristics and permeability features of hydrocarbons and water. In this paper, a series of laboratory tests, including nondestructive low-field nuclear magnetic resonance (NMR), scanning electron microscopy (SEM), X-ray computed tomography (CT) and core tests were carried out to characterize the physical structure properties of coal. The pore size distribution, pore type, morphological features and three-dimensional rendering of coal cleat structures are presented. The permeability changes of 7 cylindrical coal cores investigated under a varying effective stress range (0–35Mpa) reveal that coal porosity decreased linearly and coal permeability declined exponentially with the rise of stress; while under higher stress conditions, the occurrence of internal crushing and mechanical damage will result in irreversible change for porosity and permeability. Through the comprehensive analysis based on linking permeability to porosity and CT result, a basic estimation on directional cleat permeability is also realized. This method provides a preliminary but satisfactory estimation for local directional cleat permeability, which reflects that both bedding and non-bedding direction permeability owns great heterogeneity for an individual sample; but face cleat permeability always found to be the largest, and the mean bedding plane permeability value is found usually 3.01–11.68 times lower than face and butt cleat permeability.

Published

2016

20. Experimental Study on Stress Evolution and Microseismic Signals under Vibration Conditions of Coal during Excavation and Subsequent Waiting Time

Author

Lyu Pingyang, Dihao Ai, Beijing Xie, Chengwu Li, Yuechao Zhao, and Qifei Wang

Subjects

010504 meteorology & atmospheric sciences, Article Subject, 010502 geochemistry & geophysics, 01 natural sciences, Signal, complex mixtures, Stress (mechanics), Mining engineering, otorhinolaryngologic diseases, Coal, 0105 earth and related environmental sciences, Civil and Structural Engineering, Microseism, business.industry, Mechanical Engineering, Coal mining, Excavation, Geotechnical Engineering and Engineering Geology, Condensed Matter Physics, lcsh:QC1-999, Vibration, Mechanics of Materials, business, lcsh:Physics, Geology, Energy (signal processing)

Abstract

An experiment designed to simulate coal during excavation was conducted. Microseismic signals of coal under vibration conditions during excavation and subsequent waiting time of the coal roadway at different excavation speeds were collected and analyzed. During the excavation and subsequent waiting time, the stress in coal is redistributed, and the concentrated stress is gradually transferred to the deeper section of the coal seam. The Hilbert–Huang transform (HHT) is used to effectively denoise the collected signals. According to the noise-reduced signal, the amplitude and pulse number of the microseismic signals emitted during the excavation process are much larger than those of the waiting time process. During excavation, the energy and event numbers of microseismic signals increase first and then decrease as the excavation speed increases. The faster the excavation speed, the more the energy, and the higher the event numbers of the microseismic signals released during the subsequent waiting time. When the excavation speed is faster, more elastic potential accumulates in the coal seam and the concentration stress is greater. As the concentrated stress moves forward in time without excavation, more coal seams fail, and more microseismic signals are released. The microseismic signal and the stress evolution law can provide a reasonable explanation for the forward movement of the concentrated stress and coal failure during roadway excavation.

Published

2019

21. Crack Detection and Evolution Law for Rock Mass under SHPB Impact Tests

Author

Beijing, Xie, primary, Ai, Dihao, additional, and Yang, Yu, additional

Published

2019

22. Study on Low-Frequency TEM Effect of Coal during Dynamic Rupture

Author

Chuan Wang, Xiaoyuan Sun, Xiaomeng Xu, Chengwu Li, and Beijing Xie

Subjects

Materials science, Article Subject, business.industry, Mechanical Engineering, Resonance, Low frequency, Geotechnical Engineering and Engineering Geology, Condensed Matter Physics, Signal, complex mixtures, Dynamic load testing, lcsh:QC1-999, High strain, Wavelength, Mechanics of Materials, Waveguide (acoustics), Coal, Geotechnical engineering, Composite material, business, lcsh:Physics, Civil and Structural Engineering

Abstract

Dynamic loads provided by the SHPB test system were applied to coal specimens, and the TEM signals that emerged during coal rupture were recorded by the TMVT system. Experiments on coal-mass blasting rupture in excavating workface were also carried out, and the emerged TEM signal was analyzed. The results indicate that the low-frequency TEM signals were detected close to the coal specimens under high strain dynamic load applied by the SHPB, initially rising sharply and dropping rapidly, followed by a small tailing turbulence. And the field test results obtained during coal blasting process coincided with the results from the SHPB tests. Furthermore, its initial part shaped like a pulse cluster had a more pronounced tail and lasted even longer. And the generation mechanism of the low-frequency TEM effect was analyzed. It suggests that the low-frequency TEM effect of coal during dynamic rupture is contributed by the fractoemission mechanism and the resonance or waveguide effects. Because its wavelength is longer than the higher ones, the low-frequency TEM has a good anti-interference performance. That can expand the scope and performance of the coal-rock dynamic disaster electromagnetic monitoring technique.

Published

2015

23. The correlated characteristics of micro-seismic and electromagnetic radiation signals on a deep blasting workface.

Author

Chengwu Li, Xiaoyuan Sun, Chuan Wang, Xiaomeng Xu, Beijing Xie, and Jing Li

Published

2016