Affiliation:
1. School of Mines China University of Mining and Technology Xuzhou China
2. School of Engineering University of Tasmania Hobart Australia
3. Key Laboratory of Deep Coal Resource Mining China University of Mining and Technology, Ministry of Education of China Xuzhou China
4. Discipline of Civil, Surveying & Environmental Engineering, School of Engineering The University of Newcastle Callaghan Australia
Abstract
AbstractIn order to mitigate the risk of geological disasters induced by fault activation when roadways intersect reverse faults in coal mining, this paper uses a combination of mechanical models with PFC2D software. A mechanical model is introduced to represent various fault angles, followed by a series of PFC2D loading and unloading tests to validate the model and investigate fault instability and crack propagation under different excavation rates and angles. The results show that (1) the theoretical fault model, impacted by roadway advancing, shows a linear reduction in horizontal stress at a rate of −2.01 MPa/m, while vertical stress increases linearly at 4.02 MPa/m. (2) At field excavation speeds of 2.4, 4.8, 7.2, and 9.6 m/day, the vertical loading rates for the model are 2.23, 4.47, 6.70, and 8.93 Pa/s, respectively. (3) Roadway advancement primarily causes tensile‐compressive failures in front of the roadway, with a decrease in tensile cracks as the stress rate increases. (4) An increase in the fault angle leads to denser cracking on the fault plane, with negligible cracking near the fault itself. The dominant crack orientation is approximately 90°, aligned with the vertical stress.
Funder
Australian Research Council
National Natural Science Foundation of China
Graduate Research and Innovation Projects of Jiangsu Province