Stress distribution ahead of mechanized longwall top coal caving face with great cutting height

Journal of Mining and Earth Sciences Pub Date : 2021-12-01 DOI:10.46326/jmes.2021.62(5a).02

Tung Manh Bui, H. Nguyen, T. Nguyen

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Abstract

Longwall Top Coal Caving (LTCC) technology with great cutting height is a new development trend in mining thick coal seam. The cutting height of LTCC face typically ranges from 2.8 m to 3.2 m in many coal mining countvies, but it recently reaches up to 4.2 m in many coal mines in China. Because the cutting height increases, the caving height accordingly decreases that changes the stress distribution around coal face and law of roof rock caving. Based on the geological condition of Longwall 4108 at Ping Shou coal mine, ShanXi province, China, this paper presents a modelling of LTCC mining process with a cutting height of 4.2 m by using the numerical program FLAC3D. From the modelling, the paper presents an analysis of stress distribution ahead of LTCC face with great cutting height. The results show that as the coal face advances, the stress magnitude ahead of coal face increases. The peak front abutment stress moves further away from coal face. The stress concentration ratio increases, and stress concentration zone expands correspondingly. These changes of stress facilitate the failure of top coal, increasing the efficiency of top coal recovery and improving longwall face stability.

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大切高综放工作面前方应力分布

大截高长壁顶放煤技术是厚煤层开采的新发展趋势。在许多煤矿县，LTCC工作面切割高度一般在2.8 ~ 3.2 m之间，但最近在中国许多煤矿，LTCC工作面切割高度达到了4.2 m。随着采煤高度的增加，落放高度相应降低，从而改变了工作面周围的应力分布和顶板落放规律。根据山西平寿煤矿4108长壁的地质条件，利用FLAC3D数值模拟程序，对切割高度为4.2 m的LTCC开采过程进行了数值模拟。从模型出发，分析了大切削高度下LTCC工作面前方的应力分布。结果表明:随着工作面推进，工作面前方应力强度增大;峰值前支承应力向工作面偏移较大。应力集中比增大，应力集中区相应扩大。这些应力变化有利于顶煤破坏，提高顶煤回采效率，改善长壁工作面稳定性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Journal of Mining and Earth Sciences

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