The Median Versus the Mean Fragment Size and Other Issues with the Kuz-Ram Model
Research output: Contribution to journal › Article › Research › peer-review
Authors
Organisational units
Abstract
Soviet precursors to Cunningham’s Kuz-Ram model from 1983 are described. They are rooted in the mean fragment size and Rosin-Rammler (RR) fits to sieving data and rely on approximations.Three versions of Kuz-Ram model are presented and all three are de facto based on the median fragment size x50, even if the term mean is used in the papers. This discrepancy caused
Spathis in 2004 to suggest a correction procedure for the Kuz-Ram rock factor A, which was said to explain some of the missing fines in the model. This correction, while applicable to Cunningham’s 1983 paper, does not apply to his 1987 paper in which he presents his own A factor.
Common fixes of the Kuz-Ram model’s fines issue are fragmentation models where the fines are mainly generated in a crushed zone around a blast hole. This is contradicted by careful model blasting tests. The lack of a largest block size in the RR function may lead to spurious values of the uniformity coefficient n, e.g. in conjunction with image based fragmentation measurements or crusher modeling. These issues may be solved by using the transformed RR function,
which has a largest block size xmax or its replacement by the Swebrec function such as in the KCO model.
The mean to median issue is investigated in some detail and it is found that using x50 instead of the mean 1) has a sounder theoretical background, 2) is less prone to errors and 3) is not contradicted by the original Soviet data. It is finally suggested that future work on fragmentation prediction equations focus on the use of distribution independent quantities like percentiles, e.g. x50, x20 and x80. Some previous work in this direction is briefly analyzed and one
consequence is e.g. that the n-value of the Kuz-Ram model should depend on specific charge.
Spathis in 2004 to suggest a correction procedure for the Kuz-Ram rock factor A, which was said to explain some of the missing fines in the model. This correction, while applicable to Cunningham’s 1983 paper, does not apply to his 1987 paper in which he presents his own A factor.
Common fixes of the Kuz-Ram model’s fines issue are fragmentation models where the fines are mainly generated in a crushed zone around a blast hole. This is contradicted by careful model blasting tests. The lack of a largest block size in the RR function may lead to spurious values of the uniformity coefficient n, e.g. in conjunction with image based fragmentation measurements or crusher modeling. These issues may be solved by using the transformed RR function,
which has a largest block size xmax or its replacement by the Swebrec function such as in the KCO model.
The mean to median issue is investigated in some detail and it is found that using x50 instead of the mean 1) has a sounder theoretical background, 2) is less prone to errors and 3) is not contradicted by the original Soviet data. It is finally suggested that future work on fragmentation prediction equations focus on the use of distribution independent quantities like percentiles, e.g. x50, x20 and x80. Some previous work in this direction is briefly analyzed and one
consequence is e.g. that the n-value of the Kuz-Ram model should depend on specific charge.
Details
Original language | English |
---|---|
Pages (from-to) | 1-18 |
Journal | Blasting and Fragmentation |
Volume | 10 |
Issue number | 1 |
Publication status | Published - 2016 |