Your search keyword '"Beijing Xie"' showing total 8 results

1. 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

2. 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

3. 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

4. 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

5. 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

6. 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

7. 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

8. 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