Mechanical properties and energy evolution of combined coal-rock body under different stress states and strain rates
The stress environment of deep coal-rock mass is complex, to further reveal the mechanism of rock burst induced by dynamic load. Based on the Split Hopkinson Pressure Bar test system, the dynamic tests under different stress states (non-axial and confining loads, one-dimensional coupled static-dynam...
Saved in:
| Main Authors: | , , , |
|---|---|
| Format: | Article |
| Language: | zho |
| Published: |
Editorial Department of Coal Science and Technology
2025-05-01
|
| Series: | Meitan kexue jishu |
| Subjects: | |
| Online Access: | http://www.mtkxjs.com.cn/article/doi/10.12438/cst.2024-0049 |
| Tags: |
Add Tag
No Tags, Be the first to tag this record!
|
| _version_ | 1849467740725706752 |
|---|---|
| author | Zhihui MA Zhiyong MA Rongkun PAN Feng CUI |
| author_facet | Zhihui MA Zhiyong MA Rongkun PAN Feng CUI |
| author_sort | Zhihui MA |
| collection | DOAJ |
| description | The stress environment of deep coal-rock mass is complex, to further reveal the mechanism of rock burst induced by dynamic load. Based on the Split Hopkinson Pressure Bar test system, the dynamic tests under different stress states (non-axial and confining loads, one-dimensional coupled static-dynamic loads, three-dimensional coupled static-dynamic loads) and strain rates (49.3~137.9 s−1) were carried by using the rock-coal-rock structure samples. The characteristics of strength, deformation, failure and energy evolution of rock-coal-rock structure samples were studied. The results show that there were two types of stress rebound and strain softening after the peak of the stress-strain curve of the composite specimen under non-axial and confining loads and under one-dimensional coupled static-dynamic loads, and there was stress rebound phenomena under three-dimensional coupled static-dynamic loads. Under three stress states, the peak strength of the samples increases roughly with the increase of strain rate, showing an obvious rate correlation. Under three stress states, the proportion of reflected energy to incident energy was the highest, and the proportion of transmitted energy to incident energy was the lowest. The proportion of reflection energy to incident energy under three-dimensional coupled static-dynamic loads was lower than the other two stress states. When the strain rate is lower than 123 s−1, the energy utilization rate and dissipated energy increase gradually with the increase of the strain rate, and the dissipated energy density increases with the increase of the incident energy. The failure modes of the samples show an obvious rate correlation, and the size of coal and sandstone fragments decreased gradually with the increase of strain rate. Under non- axial or confining loads and one-dimensional coupled static-dynamic loads, the samples firstly failed at the coal-rock interface. Many small size fragments of coal and sandstone are secondary cracks caused by the effect of loads. The fracture of coal and rock mass is not obvious under three-dimensional coupled static-dynamic loads. |
| format | Article |
| id | doaj-art-08d4aa07f54540f4b00d0a024c901e49 |
| institution | Kabale University |
| issn | 0253-2336 |
| language | zho |
| publishDate | 2025-05-01 |
| publisher | Editorial Department of Coal Science and Technology |
| record_format | Article |
| series | Meitan kexue jishu |
| spelling | doaj-art-08d4aa07f54540f4b00d0a024c901e492025-08-20T03:26:05ZzhoEditorial Department of Coal Science and TechnologyMeitan kexue jishu0253-23362025-05-0153510211310.12438/cst.2024-00492024-0049Mechanical properties and energy evolution of combined coal-rock body under different stress states and strain ratesZhihui MA0Zhiyong MA1Rongkun PAN2Feng CUI3School of Emergency & Safety, Sichuan University of Science & Engineering, Zigong 643002, ChinaSchool of Emergency & Safety, Sichuan University of Science & Engineering, Zigong 643002, ChinaState Key Laboratory Cultivation Base for Gas Geology and Gas Control, Henan Polytechnic University, Jiaozuo 472300, ChinaYima Coal Industry Group Co., Ltd., Sanmenxia 472300, ChinaThe stress environment of deep coal-rock mass is complex, to further reveal the mechanism of rock burst induced by dynamic load. Based on the Split Hopkinson Pressure Bar test system, the dynamic tests under different stress states (non-axial and confining loads, one-dimensional coupled static-dynamic loads, three-dimensional coupled static-dynamic loads) and strain rates (49.3~137.9 s−1) were carried by using the rock-coal-rock structure samples. The characteristics of strength, deformation, failure and energy evolution of rock-coal-rock structure samples were studied. The results show that there were two types of stress rebound and strain softening after the peak of the stress-strain curve of the composite specimen under non-axial and confining loads and under one-dimensional coupled static-dynamic loads, and there was stress rebound phenomena under three-dimensional coupled static-dynamic loads. Under three stress states, the peak strength of the samples increases roughly with the increase of strain rate, showing an obvious rate correlation. Under three stress states, the proportion of reflected energy to incident energy was the highest, and the proportion of transmitted energy to incident energy was the lowest. The proportion of reflection energy to incident energy under three-dimensional coupled static-dynamic loads was lower than the other two stress states. When the strain rate is lower than 123 s−1, the energy utilization rate and dissipated energy increase gradually with the increase of the strain rate, and the dissipated energy density increases with the increase of the incident energy. The failure modes of the samples show an obvious rate correlation, and the size of coal and sandstone fragments decreased gradually with the increase of strain rate. Under non- axial or confining loads and one-dimensional coupled static-dynamic loads, the samples firstly failed at the coal-rock interface. Many small size fragments of coal and sandstone are secondary cracks caused by the effect of loads. The fracture of coal and rock mass is not obvious under three-dimensional coupled static-dynamic loads.http://www.mtkxjs.com.cn/article/doi/10.12438/cst.2024-0049coupled static-dynamic loadscoal-rock combined bodymechanical propertiesenergy evolutionrock dynamics |
| spellingShingle | Zhihui MA Zhiyong MA Rongkun PAN Feng CUI Mechanical properties and energy evolution of combined coal-rock body under different stress states and strain rates Meitan kexue jishu coupled static-dynamic loads coal-rock combined body mechanical properties energy evolution rock dynamics |
| title | Mechanical properties and energy evolution of combined coal-rock body under different stress states and strain rates |
| title_full | Mechanical properties and energy evolution of combined coal-rock body under different stress states and strain rates |
| title_fullStr | Mechanical properties and energy evolution of combined coal-rock body under different stress states and strain rates |
| title_full_unstemmed | Mechanical properties and energy evolution of combined coal-rock body under different stress states and strain rates |
| title_short | Mechanical properties and energy evolution of combined coal-rock body under different stress states and strain rates |
| title_sort | mechanical properties and energy evolution of combined coal rock body under different stress states and strain rates |
| topic | coupled static-dynamic loads coal-rock combined body mechanical properties energy evolution rock dynamics |
| url | http://www.mtkxjs.com.cn/article/doi/10.12438/cst.2024-0049 |
| work_keys_str_mv | AT zhihuima mechanicalpropertiesandenergyevolutionofcombinedcoalrockbodyunderdifferentstressstatesandstrainrates AT zhiyongma mechanicalpropertiesandenergyevolutionofcombinedcoalrockbodyunderdifferentstressstatesandstrainrates AT rongkunpan mechanicalpropertiesandenergyevolutionofcombinedcoalrockbodyunderdifferentstressstatesandstrainrates AT fengcui mechanicalpropertiesandenergyevolutionofcombinedcoalrockbodyunderdifferentstressstatesandstrainrates |