Influence of abnormal stress under a residual bearing coal pillar on the stability of a mine entry

Mine entries close to residual bearing coal pillars (RBCPs) will suffer large deformation that may cause rock burst. To better understand the deformation mechanism and develop safe and practical guidelines for entry design, most studies focus on the absolute size of the stress field in and around th...

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Bibliographic Details
Published in:International journal of mining science and technology 2017-11, Vol.27 (6), p.945-954
Main Authors: Kang, Jizhong, Shen, Wenlong, Bai, Jianbiao, Yan, Shuai, Wang, Xiangyu, Li, Wenfeng, Wang, Ruofan
Format: Article
Language:English
Subjects:
Abnormal stress
analysis
Numerical
bearing
coal
computation
Entry layout
layout
Mechanical
Mechanical analysis
Numerical computation
pillar
Abnormal
Residual
Residual bearing coal pillar
stress
Entry
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Summary:Mine entries close to residual bearing coal pillars (RBCPs) will suffer large deformation that may cause rock burst. To better understand the deformation mechanism and develop safe and practical guidelines for entry design, most studies focus on the absolute size of the stress field in and around the pillar. In this paper, we present a new approach to analyze the abnormal stress field close to a RBCP that uses the stress concentration coefficient (SCC), stress gradient (SG), and coefficient of lateral pressure (CLP) to describe the stress state induced by the RBCP. Based on elastic theory and a mathematical model for the abutment stress in the RBCP, an analytical solution for the abnormal stress in the strata below the RBCP was derived and the characteristics of the abnormal stress for a case study of a coal mine in China were analyzed. The results show that the abnormal stress field around the pillar is characterized by four distinct zones: azone of high SCC, high SG, and CLP less than 1, a zone of high SCC, low SG, and CLP less than 1, a zone of low SCC, SG close to 0, and CLP greater than 1, and a zone of SCC close to 1, SC close to 0, and CLP close to 1. Based on this zoning pattern, a numerical model was established to study the combined effects of the abnormal stress on the stability of the entry. The most stable zone was determined based on a model of the Xinrui coal mine and verified by field measurements at the mine. Our conclusions can be used as guidelines for designing safe entry layouts in similar geological and mining settings.
ISSN:2095-2686
DOI:10.1016/j.ijmst.2017.06.012