成果归属机构：

工程技术学院

作者：

Khan, Majid ; He, Xueqiu ; Song, Dazhao ; Li, Zhenlei ; Tian, Xianghui

单位：

Univ Sci & Technol Beijing, Sch Resources & Safety Engn, Beijing 100083, Peoples R China;Univ Sci & Technol Beijing, Minist Educ Efficient Min & Safety Met Mine, Key Lab, Beijing 100083, Peoples R China;Univ Sci & Technol Beijing, Res Inst Macrosafety Sci, Beijing 100083, Peoples R China;China Univ Geosci Beijing, Sch Engn & Technol, Beijing 100083, Peoples R China

关键词：

MOMENT TENSOR ANALYSIS; LINK CLUSTER-ANALYSIS; UNIAXIAL COMPRESSION; DAMAGE MECHANISMS; CRACK COALESCENCE; EVOLUTION; FLAWS; FAILURE; SAMPLES; ENERGY

摘要：

The formation of coalesced fractures critically alters the mechanical properties of the surrounding virgin material, significantly changing the stress distribution and deformation behavior of the rock mass. However, understanding the generation mechanism and accurate prediction of rock fracture growth remain challenging in many engineering projects. Despite, wide range of conventional approaches including field investigations, laboratory-scale tests, and numerical modeling, the complex geological conditions hinder their accurate determination. This study introduces a new robust and cost-effective holistic geophysical approach to determine fractures propagation and predict failure in coal-rock masses at laboratory scale applicable across scales. The proposed approach combines rock mechanics and Acoustic Emission (AE) testing systems to make useful correlation between AE source parameters and deformation kinetics. This correlation analyzes the spatiotemporal distribution of AE events to elucidate the evolution of fracture patterns in coal-rock specimens from a complex mining project. Results showed dense and complex fracturing networks within coal specimens due to higher density, compaction, and mechanical strength compared to rock samples. This is indicated by peak acoustic events at 80%-100% load versus minimal events at 0-15% load. Simulated fracture patterns closely matched observed acoustic events, identifying key lineaments (macro-cracks) representing the transition from microcracks to macro-fractures. The convergence of these lineaments indicated intensely deformed zones prone to failure, consistent with previous field investigations. Acoustic parameters describing critical damage revealed an inverse relationship between stress and AE event magnitude. At roughly 70% sigma max, a dramatic fall is seen in acoustic parameters indicated the shift from small-scale to large-scale microfractures, ultimately leading to catastrophic failure of the samples. Furthermore, Single Link Cluster (SLC) analysis demonstrated strong correlation among AE events, spatial correlation length (xi) and information entropy (H). Both increased significantly at the onset of loading and fluctuated in proximity to ultimate failure. Using the micro-crack density criterion and 3D-crack growth theory, changes in above parameters verified the cracks transformation process. These findings showed that, the proposed approach compared with the conventional approaches, can improve disaster control and management plans, predict critical failures, and save lives in global mining projects when applied to field-scale studies.

基金：

Natural Science Foundation of Beijing Municipality [IS23116]; Beijing Natural Science Foundation (International Scientists Project) [42250410327]; Research Fund for International Young Scientists (RFIS-I) of National Science Foundation of China; University of Science and Technology Beijing (USTB), Beijing, China

语种：

英文

DOI：

10.1007/s40789-025-00768-3

来源：

INTERNATIONAL JOURNAL OF COAL SCIENCE & TECHNOLOGY,2025(1):.

出版日期：

2025-12

提交日期：

2025-03-25

引用参考：

Khan, Majid; He, Xueqiu; Song, Dazhao; Li, Zhenlei; Tian, Xianghui. Predicting deformation kinetics and fractures propagation in coal-rock masses using acoustic emission testing[J]. INTERNATIONAL JOURNAL OF COAL SCIENCE & TECHNOLOGY,2025(1):.