A Study on the Mechanical Properties and Bursting Liability of Coal-Rock Composites with Seam Partings

Geological tectonic movements, as well as complex and varying coal-forming conditions, have led to the formation of rock partings in most coal seams. Consequently, the coal in coal-rock composites is characterised by different mechanical properties than those of pure coal. Uniaxial compression tests were performed in this study to determine the mechanical properties and bursting liability of specimens of coal-rock composites (hereinafter referred to as “composites”) with rock partings with different dip angles θ and thicknesses D. The results showed that as θ increased, the failure mode of the composite changed from tensile and splitting failure to slip and shear failure, which was accompanied by a decrease in the brittleness of the composite and an increase in its ductility as well as a decrease in the extent of fragmentation of the coal in the composite. Additionally, as θ increased, the uniaxial compressive strength σu, elastic modulus E, and bursting energy index Ke of the composite decreased. The rock parting in the composite was the key area in which elastic energy accumulated. As D increased, σu, E, and Ke of the composite increased. In addition, as D increased, the ductility of the composite decreased, and the brittleness and extent of coal fragmentation in the composite increased. Notably, the curve for the cumulative acoustic emission (AE) counts of the composite corresponding to the stress-strain curve could be divided into four regimes: pore compaction and closure, a slowly ascending linear elastic section, prepeak steady crack propagation, and peak unsteady crack propagation. The experimental results were used to propose two technologies for controlling the stability of coal-rock composites to effectively ensure safe and efficient production at working faces.

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An Experimental Study of the Uniaxial Failure Behaviour of Rock-Coal Composite Samples with Pre-existing Cracks in the Coal

Advances in Civil Engineering ◽

10.1155/2019/8397598 ◽

2019 ◽

Vol 2019 ◽

pp. 1-12 ◽

Cited By ~ 2

Author(s):

Shaojie Chen ◽

Yao Ge ◽

Dawei Yin ◽

Huisan Yang

Keyword(s):

Crack Propagation ◽

Composite Structure ◽

Shear Failure ◽

Progressive Failure ◽

Strain Curve ◽

Composite Sample ◽

Compression Tests ◽

Failure Characteristics ◽

Splitting Failure ◽

Composite Samples

Many hazards encountered during coal mining can be caused by the instability and failure of the composite structure of the coal seam and the surrounding rock strata. The defects present in the coal affect the structural stability of the composite structure. In this study, uniaxial compression tests were conducted on sandstone-coal composite samples with pre-existing cracks in the coal, combined with tests performed with an acoustic emission (AE) device and a digital video camera. The strength, macrofailure initiation (MFI), and failure characteristics of composite samples, as influenced by the coal’s pre-existing cracks, were analysed. The coal’s pre-existing cracks were shown to reduce the strength, promote the occurrence of MFI, and affect the failure characteristics of the samples. Vertical penetration cracks had much more pronounced effects on strength and MFI occurrence, especially vertical penetration cracks that penetrated through the centre of the coal. Horizontal penetration cracks had a much reduced effect on strength and MFI occurrence. The MFI caused a step shape in the stress-strain curve accompanied with a peak energy index signal and occurred around the original coal cracks. The MFI models predominantly exhibited crack initiation from the pre-existing coal cracks and surface spalling caused by crack propagation. The intact composite sample failure presented as an instantaneous failure, whereas the composite samples containing the pre-existing cracks showed a progressive failure. The failures of composite samples occurred predominantly within the coal and displayed an X-typed shear failure accompanied by a small splitting failure. Both the coal and sandstone were destroyed in the composite sample with vertical penetration cracks through the centre of the coal. Failure of the coal occurred through a splitting failure accompanied by a small X-typed shear failure, while the sandstone showed a splitting failure induced by crack propagation in the coal.

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Application and Effect of Loading Rates on Coal Sample Failure

Shock and Vibration ◽

10.1155/2021/6681082 ◽

2021 ◽

Vol 2021 ◽

pp. 1-12

Author(s):

Genwei Li ◽

Shuaifeng Lu ◽

Sifei Liu ◽

Jing Liu ◽

Peng Shi ◽

...

Keyword(s):

Mechanical Properties ◽

Shear Failure ◽

Loading Rate ◽

Coal Pillar ◽

Test System ◽

Tensile Failure ◽

Compression Tests ◽

Pillar Stability ◽

Loading Rates ◽

The Stability

In order to evaluate the coal pillar stability in recovery of residual room pillars under different mining rates, this paper studies the influence of loading rate on the mechanical properties of the coal body. The uniaxial compression tests of coal samples in Yangcheng area at different loading rates were carried out with the MTS815 electrohydraulic servo rock mechanics test system. The stress-strain curves and the evolution characteristics of AE signals were analyzed. At same time, the mechanism of damage and failure of specimens are also discussed. The results show the following. (1) With the increase in loading rate, the ultimate stress and ultimate strain of specimens decrease first and then increase. (2) Loading rate has a significant effect on the stability adjustment of specimens. With the decrease in loading rate, the earlier the stress adjustment is, the larger the adjustment range is, and the failure mode changes from shear failure to tensile failure. (3) In addition, when the loading rate increases, the AE evolves from continuous dense to discrete catastrophe, which indicates that the failure of the sample at a larger loading rate is sudden, which is not conducive to the maintenance of the stability of the coal pillar. (4) Finally, the failure mechanism of the specimen structure under different loading rates is obtained, and the improvement measures for the effect of mining velocity of working face on the stability of coal pillar are put forward. The results reveal the loading rate effect of mechanical properties of coal and provide a reference for controlling the stability of the residual coal pillar.

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Comparison of Mechanical Behavior and Acoustic Emission Characteristics of Three Thermally-Damaged Rocks

Energies ◽

10.3390/en11092350 ◽

2018 ◽

Vol 11 (9) ◽

pp. 2350 ◽

Cited By ~ 11

Author(s):

Jun Peng ◽

Sheng-Qi Yang

Keyword(s):

Mechanical Properties ◽

Acoustic Emission ◽

Mechanical Behavior ◽

Thermal Damage ◽

Strain Curve ◽

Treatment Temperature ◽

P Wave ◽

High Temperature Treatment ◽

High Porosity ◽

Compression Tests

High temperature treatment has a significant influence on the mechanical behavior and the associated microcracking characteristic of rocks. A good understanding of the thermal damage effects on rock behavior is helpful for design and stability evaluation of engineering structures in the geothermal field. This paper studies the mechanical behavior and the acoustic emission (AE) characteristic of three typical rocks (i.e., sedimentary, metamorphic, and igneous), with an emphasis on how the difference in rock type (i.e., porosity and mineralogical composition) affects the rock behavior in response to thermal damage. Compression tests are carried out on rock specimens which are thermally damaged and AE monitoring is conducted during the compression tests. The mechanical properties including P-wave velocity, compressive strength, and Young’s modulus for the three rocks are found to generally show a decreasing trend as the temperature applied to the rock increases. However, these mechanical properties for quartz sandstone first increase to a certain extent and then decrease as the treatment temperature increases, which is mainly attributed to the high porosity of quartz sandstone. The results obtained from stress–strain curve, failure mode, and AE characteristic also show that the failure of quartz-rich rock (i.e., quartz sandstone and granite) is more brittle when compared with that of calcite-rich rock (i.e., marble). However, the ductility is enhanced to some extent as the treatment temperature increases for all the three examined rocks. Due to high brittleness of quartz sandstone and granite, more AE activities can be detected during loading and the recorded AE activities mostly accumulate when the stress approaches the peak strength, which is quite different from the results of marble.

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Behaviors of Xiashu Loess in the Lower Reaches of China’s Yangtze River under Triaxial Compression and the Microscopic Explanations

Applied Mechanics and Materials ◽

10.4028/www.scientific.net/amm.858.91 ◽

2016 ◽

Vol 858 ◽

pp. 91-97

Author(s):

Jun Hua Xiao ◽

Wen Qi Zheng

Keyword(s):

Mechanical Properties ◽

Yangtze River ◽

Shear Failure ◽

Triaxial Compression ◽

Processing Technique ◽

Point Of View ◽

Image Processing Technique ◽

Test Results ◽

Compression Tests ◽

Triaxial Compression Tests

To investigate the macroscopic mechanical properties of undisturbed structural Xiashu loess in the lower reaches of China’s Yangtze River under triaxial compression, and obtain the intrinsic explanations for the macroscopic mechanical properties from the microscopic point of view, in laboratory, triaxial compression tests were carried out, microstructure images of sheared samples were collected by scanning electron microscope (SEM), and quantitative parameters of microstructure (mainly about particle or pore size, distribution, and alignment) were extracted by digital image processing technique. Based on the test results, the deviator stress-strain relationships of both undisturbed and remoulded Xiashu loess, the structural strength, and the microstructural evolution mechanism about the formation of shear failure zone of Xiashu loess under triaxial compression were analyzed.

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Mechanical Compression and Crushing Properties of a Straw-Lime Material

10.4028/www.scientific.net/cta.1.227 ◽

2022 ◽

Author(s):

Parmo Parmo ◽

Jean-Luc Hanus ◽

Naima Belayachi ◽

Patrice Bailly

Keyword(s):

Mechanical Properties ◽

Linear Part ◽

Strain Curve ◽

Image Correlation ◽

Compression Tests ◽

Stress Plateau ◽

Speed Test ◽

Binder Ratio ◽

Parallel Direction ◽

Strain Stress

The aim of this study was to determine the compressive mechanical properties and the energy absorption characteristics of a bio-composite material based on lime, wheat straw, and additives (protein and entraining agent). The selected samples with fiber to binder ratio of 30% were subjected to compression tests at different strain rates (1 mm/min, 10 mm/min, and 100 mm/min), in the perpendicular and parallel directions to fiber orientation. Image analysis supported with Digital Image Correlation (DIC) method is performed to follow longitudinal and lateral deformations, thus making it possible to evaluate elastic properties. The results show that the highest density and compressive strength in the parallel direction are ~349 kg/m3 and ~0.101 MPa, respectively. The perpendicular specimens at 100 mm/min of speed test showed the highest values of densification strain, stress plateau, energy efficiency, and absorbed-energy of 47.27%, 0.32 MPa, 16.98 %, and 13.84 kJ/m2, respectively. The values of Young’s modulus identified with DIC are significantly different from those determined by the slope of the linear part of the stress-strain curve. A slight influence of strain rate on mechanical properties is observed.

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Effect of porewater pressure on the mechanical properties of red sandstone with different unloading rates

Quarterly Journal of Engineering Geology and Hydrogeology ◽

10.1144/qjegh2019-101 ◽

2020 ◽

pp. qjegh2019-101

Author(s):

Jian-Xi Ren ◽

Xu Chen ◽

Xing-Zhou Chen ◽

Meng-Chen Yun ◽

Xi-TaiLang Cao ◽

...

Keyword(s):

Mechanical Properties ◽

Shear Failure ◽

Strain Curve ◽

Shaanxi Province ◽

Axial Deformation ◽

Aquifer System ◽

Red Sandstone ◽

Rock Samples ◽

Unloading Rate ◽

Porewater Pressure

The red sandstone in the Luohe Formation in Shaanxi Province, China, contains a rich aquifer system. The excavation of coal mines and tunnels through the Luohe Formation affects the mechanical properties of the rocks in the surrounding environment, creating the need to determine the effect of the porewater pressure and unloading rate on the mechanical properties of the red sandstone. Using the constant axial pressure unloading method, triaxial unloading tests were performed under different unloading rates (0.1, 0.3 and 0.6 MPa s−1 and porewater pressure conditions (0, 1.0, 1.5 and 2.0 MPa). Based on the results, an unloading statistical damage model of red sandstone was established under the impacts of unloading rate and porewater pressure. During the loading stage, as the porewater pressure increased, the slope of the stress–strain curve and elastic modulus gradually decreased. During the unloading stage, lateral deformation larger than the axial deformation was observed owing to the influence of porewater pressure. The porewater pressure effect became significant as the unloading rate decreased. An increase in porewater pressure or a decrease in the unloading rate increased the confining strain flexibility. Unloading failure of rock samples was dominated by tensile shear failure, thus indicating that a faster unloading rate or larger porewater pressure causes more tensile cracks and severe fracture in the rock samples.

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Investigation into the gas adsorption-loading coupling damage constitutive model of coal rock

10.21203/rs.3.rs-351996/v1 ◽

2021 ◽

Author(s):

Zhongzhong Liu ◽

Hanpeng Wang ◽

Su Wang ◽

Yang Xue ◽

Chong Zhang

Keyword(s):

Gas Adsorption ◽

Coupling Effect ◽

Influencing Factor ◽

Failure Process ◽

Damage Model ◽

Strain Curve ◽

In Situ Stress ◽

Compression Tests ◽

Damage And Failure ◽

Coal Rock

Abstract Coal and gas outburst is the result of comprehensive action of in-situ stress, gas and mechanical properties of coal rock. The coupling effect of loading and gas adsorption eventually leads to the coal rock failure. Based on the principle of strain equivalence and considering the coupling effect of gas adsorption and stress loading, an adsorption-loading coupling damage model is established which breaks through the bottleneck of only considering single influencing factor. Taking briquette samples with controllable properties as the research object, uniaxial compression tests of coal rock at different gas adsorption pressures are carried out, and the model is verified based on the test results. The results of model calculation and tests show that the meso damage stage of coal body can well correspond to the macroscopic deterioration phenomenon and it is in good agreement with the stress-strain curve. It is proved that the model has good applicability and can accurately describe the damage and failure process of coal rock.

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Investigations of Coal-Rock Parting-Coal Structure (CRCS) Slip and Instability by Excavation

Shock and Vibration ◽

10.1155/2021/1715644 ◽

2021 ◽

Vol 2021 ◽

pp. 1-15

Author(s):

Guang-Jian Liu ◽

Heng Zhang ◽

Ya-Wei Zhu ◽

Wen-Hao Cao ◽

Xian-Jun Ji ◽

...

Keyword(s):

Shear Failure ◽

P Wave ◽

Shear Behaviour ◽

Failure Zone ◽

Stick Slip ◽

Coal Structure ◽

P Wave Velocity ◽

Splitting Failure ◽

Shear And Tensile Cracks ◽

Coal Rock

Slip and instability of coal-rock parting-coal structure (CRCS) subjected to excavation disturbance can easily induce coal-rock dynamic phenomena in deep coal mines. In this paper, the failure characteristics and influencing factors of CRCS slip and instability were investigated by theoretical analysis, numerical simulations, and field observations. The following main results are addressed: (1) the slip and instability of CRCS induced by excavation are due to stress release, and the damage of the rock parting is partitioned into three parts: shear failure zone, slipping zone, and splitting failure zone from inside to outside with slip; (2) the slip and instability process of CRCS is accompanied by initiation, expansion, and intersection of shear and tensile cracks. The development of the cracks is dominated by shear behaviour, while the tensile crack is the main factor affecting fracture and instability of CRCS; and (3) slip and instability of CRCS are characterized by stick-slip first and then stable slip, accompanied with high P-wave velocity and rockburst danger coefficient based on microseismic tomography.

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Experimental study on the mechanical properties of Guiyang red clay considering the meso micro damage mechanism and stress path

Scientific Reports ◽

10.1038/s41598-020-72465-x ◽

2020 ◽

Vol 10 (1) ◽

Author(s):

Yanzhao Zhang ◽

Shuangying Zuo ◽

Rita Yi Man Li ◽

Yunchuan Mo ◽

Guosheng Yang ◽

...

Keyword(s):

Mechanical Properties ◽

Soil Sample ◽

Pore Water ◽

Shear Failure ◽

Pore Water Pressure ◽

Water Pressure ◽

Strain Curve ◽

Friction Angle ◽

Red Clay ◽

Stress Strain

Abstract This study investigated the macroscopic physical and mechanical properties of Guiyang red clay during surcharge loading, lateral excavation and lateral unloading with axial loading, and clarified the failure mechanism of microstructure before and after shear under different stress paths of CTC, RTC and TC. Consolidated undrained triaxial shear permeability, SEM scanning, XRF fluorescence spectrum analysis and XRD diffraction tests were conducted to simulate the actual engineering conditions. The stress–strain curve, shear strength, pore water pressure variation rule and macroscopic failure mode of soil samples under different stress paths were analysed. In addition, Image Pro Plus 6.0 and PCAS were used to study the relationship between the macro mechanical properties and micro microstructure failure under different stress paths. The stress–strain curves from CTC, RTC and TC in CU tests were different, with the peak values of shear stress under the three stress paths being P-increasing, equal P-path and P-decreasing path. Moreover, the internal friction angle and cohesion of the increasing P path were higher than those of equal P path and decreasing P path, hence, the influence of stress paths on the cohesion is greater than that of internal friction angle. The pore water pressure is strongly dependent on the stress path, and the variation characteristics of pore water pressure are consistent with the change in the law of the stress–strain curve. Under the same confining pressure in the P-increasing path, the shear failure zone runs through the whole soil sample, and the shear failure zone is significant, whereas under the condition of the P-reducing path, the shear failure angle of soil sample is about 65°, 55° and 45°, and in the equal P path, the soil sample is dominated by the confining pressure, with no obvious microcrack on the surface of the soil sample. The difference is that the distribution of pores in the path of increasing P and equal P is directional, and the anisotropy rate is small, while the distribution of pores in soil samples with shear failure and before shear is random and the anisotropy rate is high.

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Analysis of Failure Characteristics and Strength Criterion of Coal-Rock Combined Body with Different Height Ratios

Advances in Civil Engineering ◽

10.1155/2020/8842206 ◽

2020 ◽

Vol 2020 ◽

pp. 1-14

Author(s):

Tuo Wang ◽

Zhanguo Ma ◽

Peng Gong ◽

Ning Li ◽

Shixing Cheng

Keyword(s):

Shear Failure ◽

Underground Mining ◽

Triaxial Compression ◽

Peak Stress ◽

Strength Criterion ◽

Confining Pressure ◽

Experimental Results ◽

Compression Tests ◽

Rock Body ◽

Coal Rock

In underground mining and roadway support engineering of coal mine, the coal and rock layers bear loads together; therefore, the deformation and mechanical characteristics of the coal-rock combined bodies are not the same as those of the pure coal or rock bodies. In this paper, conventional triaxial compression tests of coal-rock combined bodies with different height ratios were conducted. And the stress and deformation characteristics of coal-rock combined body were studied and the experimental results were analyzed with different strength criteria. The results show that the peak stress, elastic modulus, and strength reduction coefficient of coal-rock combined body are negatively correlated with the ratio of coal to coal-rock combination height and positively correlated with the confining pressure; the coal-rock combination shows obvious ductility under 10 MPa confining pressure. Under the conventional triaxial condition, the shear failure was the main cause of the lateral deformation of the coal body in the coal-rock combination, which was much larger than that of the rock body. The circle deformation value, volume strain value, and the deformation rate in the postpeak stage of coal-rock combination are much higher than those in the prepeak stage. Mohr–Coulomb and general Hoek–Brown strength criterion fit the experimental results well.

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