Semester
Fall
Date of Graduation
2021
Document Type
Dissertation
Degree Type
PhD
College
Statler College of Engineering and Mineral Resources
Department
Mining Engineering
Committee Chair
Ihsan Berk Tulu
Committee Member
Yi Luo
Committee Member
Brijes Mishra
Committee Member
Qingqing Huang
Committee Member
Gabriel Esterhuizen
Committee Member
Christopher Mark
Abstract
Mining-induced stresses in underground coal mines play a significant role in pillar and support design, hence in the safety of mining operations. Adequate design of pillars and roof control plans rely on the accurate assessment of the mining-induced loads, as well as the load-bearing capacities of the supports. In pillar design tools frequently used by the underground coal mining industry and Mine Safety and Health Administration (MSHA), overburden loading is estimated by geometric concepts such as the tributary area and the abutment angle method. These methods do not explicitly consider important mechanical responses such as specific overall ground behavior. The mine-specific overburden geology is one of the major influencing factors for these complex mechanical responses.
In this research, to include the effect of geology in the overburden load estimations, a new parameter was defined as the total strong layer thickness (tstr) that represents the strength and stiffness of the overburden with a single value. This parameter is a function of the strength of overburden layers, thicknesses of strong beds, relative locations of the strong beds in the overburden, and the panel width and overburden depth. In this study, to develop a site-specific tstr, 13 field measurement case studies from 12 different U.S. longwall mines with different overburden geologies were used. 2D numerical models of the case studies were verified against the field measurements such as surface subsidence, and stress. After verifying the numerical models, parametric studies were performed to be able to assess the influence of panel dimensions on mining-induced stresses and to simulate different panel conditions such as critical, subcritical, and supercritical. Overburden stress redistribution on the pillar system, gob, and adjacent solid coal is estimated from the modeling results.
Using these results, a regression analysis is conducted for a loading model with the tstr as a variable, and a method to estimate the percentages of loads carried by the gob was constructed. The proposed method is used to calculate the percentage of load carried by the gob and was found to have a coefficient of determination (R2) of 85% when compared to the field measurements and the parametric runs. The new methodology was compared against the empirical estimates for the field study cases and was found to give better results.
The method was then tested with field measurement case studies that were not included in the initial analysis. One case was used to test the estimation accuracy and the other cases were tested for LaModel implementation. The percentages of load carried by the gob as estimated by the new method were implemented into the LaModel program by simply entering it into the material wizard and re-calculating the required gob modulus to achieve the desired gob load percentage. The results obtained from LaModel were compared to the available field stress measurements, and the new method, implemented into LaModel, was found to give successful results. This methodology was found to be successful in implementing the effect of site-specific overburden geology into commonly used pillar design tools such as LaModel.
Recommended Citation
Tuncay, Deniz, "Geology Oriented Loading Approach for Underground Coal Mines" (2021). Graduate Theses, Dissertations, and Problem Reports. 10337.
https://researchrepository.wvu.edu/etd/10337
Embargo Reason
Publication Pending