Mechanism and Prevention Measure of Rib Spalling in 6.5 Meter High Caving Face in Thick Coal Seam with Undulated Floor

Fully mechanized mining technology, with a large cutting height in thick coal seam, has been developed to be large-scale, mechanized, and intelligent. Furthermore, it is also superior to other mining methods because it operates more efficiently and has higher recovery rates of coal resources. Dongpang coal mine (located in north China) is one of the largest coal mining productions in Hebei province. It is significant because it is the first set of coal mines in China to adopt fully mechanized mining technology that has large cutting height potential. When looking at the coal seams of deep mining, specifically in the mine No. 2612 where the working face is 4.5–6.5 m cutting height, the coal walls have low stability due to the way the coal seam fluctuates in a large working face. This paper adopts mechanical analysis, numerical simulation, and field observation research methods to control the rib fall of coal walls in a coal mine. By adopting research methods that analyze the mechanical characteristics of face roof, we are able to conclude the main roof structure of the masonry seam stability criterion in overhead mining with large cutting height. This is done through employing the numerical simulation method, which helped to determine the main factors that influence the rib fall of a coal wall and weighting factor. Through field observations, we discovered the technology method to relieve, control, and mitigate rib falls of coal seam in a coal mine. We also discovered methods that would ensure the smooth mining of the working face of the mine by strengthening the bolting and grouting reinforcement methods used to improve the working face of stope surrounding rock conditions. This paper discusses research results that enrich the stope wall rock control method by expressing how fully mechanized mining technology, with a large cutting height, is meaningful to solve the complex conditions of rock fall caused by thick coal seam.