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KILDUFF RMR Aggregates, Inc. <br /> U N D E R G R D U N C Rock Failure Analyses and Stabilization Report <br /> N G I N E E R I N G.I N C Mid Continent Limestone Quarry <br /> The spatial intent of the slope configuration models discussed in section 6 should be to extend north <br /> to where the upper limestone layers pinch out above the current mining activities. The bedrock <br /> bedding slope, which is the boundary between the massive limestone below and the adverse <br /> limestone units above, was observed as very laterally continuous but could undulate locally creating a <br /> slight change in dip direction.To meet the established minimum FOS for the slope, using a bench <br /> slope geometry of 1.4H:1V or greater that leaves varying thicknesses of the upper limestone layers in <br /> place will likely require the use of mechanical stabilization. This is considered a lesser option for long- <br /> term stability and safety but is considered below on an as needed basis. <br /> 9. MINE STABILIZATION <br /> A summary of the mine operation plan recommendations, from a geotechnical perspective, is <br /> provided here to inform a full mine operation plan provided by RMRA under separate cover. The <br /> overall intent is to achieve long-term slope stability by eliminating the potential for headwall failure <br /> along the upper and lower limestone beds stratigraphically atop the massive limestone. The mine <br /> plan works under the assumption the upper and lower limestone beds planar slide failure mode atop <br /> the massive limestone, dipping to the south along the laterally continuous bedding plane, will only <br /> release in that direction. The mine plan is a phased and stepped approach working from the <br /> southwest corner of the headwall to the northeast with the intent to eliminate the possibility of <br /> permanent or temporary condition of the upper and lower limestone beds in the cutslope wall. <br /> It is the opinion of KUE that the upper and lower limestone beds should be removed completely from <br /> the highwall to minimize the risk of another release. This can be performed via multiple mining <br /> methods. RMRA will develop and discuss the process under their full mining plan. RMRA will perform <br /> this work from a safe position outside of the release plane. This approach stabilizes the slope for long <br /> term stability within the massive limestone. As stated above, there is a possibility of local wedges of <br /> the upper or lower limestone beds remaining where the bedding slope has locally dipped differently <br /> or a unknown joint in the top of the massive limestone has created a wedge. In these circumstances, <br /> if the wedge cannot be scaled or blasted safely, mechanical stabilization would be warranted for life <br /> safety. <br /> 9.1. ACTIVE MECHANICAL STABILIZATION <br /> Mechanical stabilization shall be utilized on the Mid Continent Limestone Quarry if the upper and/or <br /> lower limestone beds are encountered within a highwall or bench. Mechanical stabilization will be <br /> utilized to pin the upper and/or lower limestone beds to the massive limestone below with the use of <br /> tiebacks to increase the resisting force of the upper and/or lower limestone beds. <br /> A preliminary design of the anchorage system was performed. For this analysis, a general limit <br /> equilibrium method slope stability analyses for the East and West face were performed using the <br /> software program RocPlane from RocScience (v.4.011). A FOS is calculated by modeling the effects of <br /> joint shear strength (in this case, primarily the weak interbed), water pressure within the joint,joint <br /> orientation and slope geometry intersections within a Monte Carlo sampling method. Potential upper <br /> Page 15 <br /> 535 16th STREET,SUITE 620 1 DENVER,CO 80202 1 (303)732-3692 1 WWW.KILDUFFUNDERGROUND.COM <br />