Energy Factor - The Next Logical Step

The proper utilization of energy in an explosive column is of paramount importance to the success of any blast. Historically, Powder Factor (the weight of explosive per mass or volume of material to be blasted or its inverse), has dictated the blast design. The concept of Energy Factor is a more effective method to design a blast. In order to utilize explosives efficiently, the energy contained in any given product must be quantified. The Powder Factor method, although historically successful, assumes that a pound of cast pentolite affects the material to be blasted the same as a pound of ammonium nitrate / me1 oil (ANFO.) Years of experience and scientific testing have led the blaster in the field to believe otherwise. The next logical technological step is Energy Factor. The Energy Factor method that will be discussed in this paper takes into consideration not only the weight of the explosive, but also the weight strength (Cal/g) and the density (g/cc) to yield a constant relative Energy Factor. The result of such a method is a factor that can be used in the field exactly the same as Powder Factor, but that reflects the relative energy of any given product in terms that will reflect the relative cost benefit of that explosive selection. The Energy Factors associated with different available explosives make it possible to compare the difference in the amount of energy per loaded pound in each unit length of borehole. This paper will examine the concept of Energy Factor in an in depth manner and also compare this quantification method to that of Powder Factor. It will also demonstrate the value of using Energy Factor and how it can improve the efficiency of a blast design. The misconceptions that come along with using Powder Factor will be examined and comparisons will be made between boreholes loaded using Powder Factor and those that are loaded using Energy Factor. This paper will clearly define the differences between these blast design methods and allow the reader to realize the production, quality, and economic advantages of using the Energy Factor method.