Numerical Investigation of Top Coal Drawing Evolution in Longwall Top Coal Caving by the Coupled Finite Difference Method-Discrete Element Method

Yuming Huo,Defu Zhu,Zhonglun Wang,Xuanmin Song

doi:10.3390/en14010219

Yuming Huo, Defu Zhu + Show 2 more

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https://doi.org/10.3390/en14010219

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Abstract

In longwall top coal caving (LTCC), the resource recovery ratio of the working face is directly determined by the top coal recovery ratio. An investigation of the evolution of top coal drawing characteristics and revealing the evolution of top coal drawing parameters is necessary when providing guidance for caving parameter selection and improving the top coal recovery ratio. Based on in-situ measurements of the size distribution of caved top coal blocks in Wangjialing coal mine, a finite difference method (FDM)–discrete element method (DEM) coupled method was applied to establish a “continuous–discontinuous” numerical model and the process from the first coal drawing to the common coal drawing was simulated with 17 separate working face advances. The evolution of the drawing body (DB), loose body (LB), and top coal boundary (TCB) was obtained. The results show that, the evolution of parameters of DB such as shape and size, drawing amount, length and deflection angle of the long axis of the profile ellipsoid tended to decrease first, then increase, decrease again, and finally stabilise; the increment of the LB advance coal wall distance and the coal pillar distance was close to 0 m in the common coal drawing stage, while width increment of the LB was close to the drawing interval (0.865 m). The TCB formed after each coal drawing round was fitted based on the improved “Hook” function. The evolution of height and radius of curvature of TCB’s stagnation point was analysed. This was divided into three stages: the first (first to third drawing rounds) was the initial mining influence stage, the second (fourth to ninth drawing rounds) was the transitional caving stage, and the third (after tenth drawing round) was the common coal drawing stage.

Highlights

Introduction nal affiliationsAs one of the main methods for underground thick seam mining, longwall top coal caving (LTCC) has been fully developed and applied in China [1]
The results showed that the drawing body (DB) obviously protruded to the side of the working face, and the recovery ratio of top coal in the middle of the working face was higher than that of the two ends
After five steps involving this coal cutting and support advance, the range range of the loose body (LB) reached the immediate roof, which triggered the termination of the calcuof the LB reached the immediate roof, which triggered the termination of the calculation

Summary

Introduction

As one of the main methods for underground thick seam mining, longwall top coal caving (LTCC) has been fully developed and applied in China [1]. The coal seam is divided into two parts in LTCC: bottom coal and top coal. Bottom coal is cut directly by the shearer, while top coal is caved from the drawing opening under its self-weight due to the fracture gradually developing under the influence of mining pressure [2,3]. Based on the drawing characteristics of top coal during the caving process of the LTCC, the caving process can be divided into first coal drawing and common coal drawing [4]. First coal drawing refers to the first round in the top coal caving process of the LTCC working face. As most operations of the LTCC mining face fall within the common coal drawing stage, most scholars focus

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