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CF&I Steel Corporation <br /> January 20, 1982 <br /> Page 2 <br /> with a friction angle of 38. 10. The field shear strength of the overall <br /> spoil material will be somewhat greater than that of the finer fraction. <br /> However, this friction value will be used because, to a large degree, <br /> the fine fraction of a soil governs its resulting behavior. In addition, <br /> the use of this laboratory value will be on the conservative side. <br /> Stability Analysis <br /> As indicated to us by CF&I, the Allen coal processing waste pile is dry. <br /> Since the refuse is "soil-like granular" , the stability of this pile was <br /> estimated by nomographic techniques described by Huang. This procedure <br /> was recommended by MLRB in their correspondence to CF&I , dated October <br /> 14, 1981 . The portion of the nomograph used in this analysis and a <br /> summary of the calculations is shown on Table 1 . This analysis resulted <br /> in a safety factor of 1 .70. <br /> The analysis of the Maxwell Spoil Piles was conducted on a cross section <br /> provided by CF&I. This cross section and the material parameters used <br /> in this analysis are shown on Figure 4. The density and strength of <br /> the coal was selected on the basis of laboratory tests summarized in <br /> this report and a field density test of the Allen spoils conducted by <br /> CF&I. The values for the other strata were obtained from a report to <br /> CF&I entitled "Preliminary Engineering Geology and Subsoil Investigation <br /> for a New Mine Site, Picketwire Valley, Las Animas County, Colorado" , by <br /> Chen and Associates , Inc. dated November 14, 1975. <br /> Analysis of the slope for static loading conditions utilized the computer <br /> program BISHOP. This program was developed by the U.S. Bureau of Mines <br /> and is based on the Modified Bishop method of analysis. The minimum <br /> factor of safety was determined by performing analyses for trial circular <br /> failure surfaces having centers at nodal points on a grid system. At <br /> each point of the grid system, circles with different radii were used <br /> until a minimum value was found. The critical circle was located and the <br /> minimum value of safety factor was computed for the overall slope. <br /> The critical circle determined by that method is drawn on Figure 4. As <br /> indicated, a minimum factor of safety of 1 .56 for static loading conditions <br /> was computed. As may be seen on Figure 4, the critical circle is relatively <br /> shallow and relates to surficial sloughs on the face of the pile. The <br /> safety factor against deep rotational shear failure, such as the dash circle <br /> shown on Figure 4, is much higher. For this particular deep failure, the <br /> safety factor was computed to be 2.20. <br /> The Maxwell slope was also analyzed for potential failure -along the <br /> interface between the spoil pile and the existing ground using computer <br /> program STABL. This method is a form of the Modified Bishop method that <br /> has been revised to allow consideration of noncircular failure surfaces. <br />