Top coal drawing law for an extra thick coal seam under the single round group drawing method

Pan, Weidong; Zhao, Zhining; Li, Xinyuan; Xu, Yongxin; Zhang, Kunming

doi:10.1038/s41598-024-65831-6

Cited by 2 publications

References 14 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

Research on the Development of a Monitoring Experimental Platform for Top Coal Migration Trajectory in Longwall Top Coal Caving and Optimization of Coal Drawing Process

Zhao,

Pan,

Deng

et al. 2024

Preprint

View full text Add to dashboard Cite

Understanding the migration trajectory characteristics of top coal in longwall top coal caving (LTCC) is crucial for studying the flow properties of granular top coal, drawing laws, and optimizing the coal drawing process. To monitor the migration trajectory of top coal during the drawing process, an experimental platform was developed for monitoring the top coal migration trajectory in LTCC. Using this platform, physical simulation experiments of LTCC were conducted. A multi-step experimental procedure was designed, including "model construction, marker point installation, simulated coal drawing, data collection, and trajectory inversion." The migration trajectories of top coal at different layers during the coal drawing process were obtained, and the drawing body of top coal was inferred. Additionally, a bi-directional top coal drawing body equation was theoretically derived, establishing a quantitative relationship between the gangue content (cumulative and instantaneous) and top coal recovery. Based on this, field process optimization was carried out, adjusting the "four-level" method to a double-opening group coal drawing method. The instantaneous gangue content threshold at the coal drawing openings was set to 35%. The measured top coal recovery at the working face reached 90.12%, an increase of approximately 14.87 percentage points compared to the previous recovery. The cumulative gangue content was controlled at around 9.25%, and the coordination efficiency of coal caving reached 68.2%, which is close to the theoretically derived results. This indicates that the theory can provide certain theoretical guidance for determining relevant process parameters in coal drawing operations.

show abstract

Research on the Development of a Monitoring Experimental Platform for Top Coal Migration Trajectory in Longwall Top Coal Caving and Optimization of Coal Drawing Process

Zhao,

Pan,

Deng

et al. 2024

Preprint

View full text Add to dashboard Cite

show abstract

Study on Surrounding Rock Control of Withdrawal Space in Fully Mechanized Caving Mining of a 19 m Extra-Thick Coal Seam

Chen,

Wang,

Yue

et al. 2024

Applied Sciences

View full text Add to dashboard Cite

The section span of the withdrawal space of fully mechanized top coal caving in an extra-thick coal seam is large, and with the gradual withdrawal of the hydraulic support, a series of strong dynamic pressure disasters occur in the withdrawal space, and the difficulty of surrounding rock support control increases sharply. In order to study the control mechanism of surrounding rock in the final mining withdrawal space in detail and put forward a reasonable support technology scheme, taking the large-section withdrawal space of an 8309 fully mechanized caving face in an extra-thick coal seam of a mine as the research object—through the theoretical investigation of whether the key blocks of the main roof are stably hinged under varied stopping coal caving distances and fracture locations of the main roof—the reasonable and optimal stopping coal caving distances and roadway formation time are determined. Using numerical simulation and similar simulation methods, the vertical stress and the maximum shear stress research indicators were introduced to verify the accuracy of the theoretical analysis results. The results show the following: (1) The reasonable stopping coal caving span is 1~2 times the cycle weighting interval, the best stopping coal caving distance in this geological condition is 30 m, and the best fracture position of the main roof is located above the goaf. (2) The migration of overlying strata in the withdrawal space has obvious zoning characteristics, and the zoning is as follows: a stopping coal caving area, support area of the hydraulic support, withdrawal channel area, and stopping coal pillar area. (3) According to the zoning characteristics of overlying strata movement, the asymmetric zoning support control scheme of the withdrawal space is proposed. The field monitoring results show that the maximum roof subsidence in the withdrawal space is 151 mm, the maximum internal squeezing amount of the stopping coal pillar is 82 mm, and the supporting and anchoring effect of each partition in the withdrawal space is good. The set of partition asymmetric support control schemes has been successfully applied to field practice.

show abstract

Top coal drawing law for an extra thick coal seam under the single round group drawing method

Cited by 2 publications

References 14 publications

Research on the Development of a Monitoring Experimental Platform for Top Coal Migration Trajectory in Longwall Top Coal Caving and Optimization of Coal Drawing Process

Research on the Development of a Monitoring Experimental Platform for Top Coal Migration Trajectory in Longwall Top Coal Caving and Optimization of Coal Drawing Process

Study on Surrounding Rock Control of Withdrawal Space in Fully Mechanized Caving Mining of a 19 m Extra-Thick Coal Seam

Contact Info

Product

Resources

About