Your search keyword '"Panshi Xie"' showing total 2 results

1. Influence of the Coal Seam Strength on the Boundary of a Top Coal Limit Equilibrium Zone in a Fully Mechanized Top Coal Caving Stope

Author

Kun Feng, Panshi Xie, Ding Lang, Xiaobo Wu, Jiandong Yu, Yongping Wu, and Xiaobo Zhang

Subjects

Deformation (mechanics), General equilibrium theory, business.industry, Thermodynamic equilibrium, Mechanical Engineering, Numerical analysis, technology, industry, and agriculture, Metals and Alloys, Coal mining, Boundary (topology), General Chemistry, respiratory system, Geotechnical Engineering and Engineering Geology, complex mixtures, respiratory tract diseases, Mining engineering, Control and Systems Engineering, otorhinolaryngologic diseases, Materials Chemistry, Coal, Limit (mathematics), business

Abstract

In a fully mechanized top coal caving mining process, the mechanical properties of the top coal deteriorate constantly, and the stability of the support is determined by the boundary position of the top coal entering the limit equilibrium state. Top coal flaking occurs more easily along the advancing direction owing to an increase in the distance of the boundary from the wall. Moreover, the strength of the coal seam is an important factor that determines the boundary position. The equation of the top coal limit equilibrium zone boundary, used in fully mechanized top coal caving mining, was determined based on the limit equilibrium theory, continuum damage mechanics, and the Hoek–Brown rock empirical strength criterion. Using the RFPA3D and UDEC numerical analysis methods, the effect of top coal strength on the mechanical behavior during the mining process was determined; and the space–time relationship between the top coal deformation failure, damage evolution, and boundary of the limit equilibrium zone was established. The results revealed that when the coal mass entered the limit equilibrium zone, accelerated crack development, accelerated damage, and axial unloading occurred. Moreover, an increase in the coal seam strength caused the boundary of the top coal limit equilibrium zone to be closer to the wall. By comparing the numerical results with the theoretical results, the overall trend was found to be consistent, allowing the verification of the rationality and reliability of the determination equation of the boundary position of the limit equilibrium zone.

Published

2021

2. Roof Deformation Associated with Mining of Two Panels in Steeply Dipping Coal Seam Using Subsurface Subsidence Prediction Model and Physical Simulation Experiment

Author

Gao Xicai, Shenghu Luo, Wu Yongping, Zeng Youfu, Yi Luo, and Panshi Xie

Subjects

business.industry, Mechanical Engineering, Metals and Alloys, Coal mining, Subsidence, General Chemistry, Bending, Deformation (meteorology), Geotechnical Engineering and Engineering Geology, Mining engineering, Control and Systems Engineering, Materials Chemistry, Perpendicular, Compression (geology), business, Roof, Intensity (heat transfer)

Abstract

This research investigates roof deformation and failure characteristics, as well as mechanical interaction between the panels of the roof strata above two adjacent working faces in a steeply inclined coal seam. Physical modeling with photogrammetry measurement method has been employed in this investigation. The movement of roof strata and section pillar, as well as the stratum morphological characteristics, was quantitatively analyzed. Results show that the roof movement direction above the two panels has zoning characteristics, especially in the lower panel. Roof migration in the lower panel of the working face is larger than that in the upper panel. The roof to floor closure perpendicular to the seam direction is larger than the sliding along the seam. The maximum roof concave and convex bending occurred at the middle and upper parts of both panels; the roof bending in the upper panel mining area indicates a larger mining disturbance induced by lower panel mining. The void ratio contour of the lower panel is an asymmetrically arched shape, which is different from that of the upper panel area. The higher roof strata above the upper panel exhibit separation and breaking, whereas the lower roof exhibits compression due to mining in lower panel. The section pillar is compressed and slides slightly, which aggravates the mechanical interaction between the panels and increases the caving height of the roof over the lower panel and the periodic weighting intensity.

Published

2019