An empirical approach for predicting burden velocities in rock blasting

An analytical relation between burden velocity and ratio of burden to blasthole diameter is developed in this paper. This relation is found to be consistent with the measured burden velocities of all 37 full-scale blasts found from published articles. These blasts include single-hole blasts, multi-h...

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Bibliographic Details
Published inJournal of Rock Mechanics and Geotechnical Engineering Vol. 13; no. 4; pp. 767 - 773
Main Authors Zhang, Zong-Xian, Chi, Li-Yuan, Yi, Changping
Format Journal Article
LanguageEnglish
Published Elsevier B.V 01.08.2021
Oulu Mining School,University of Oulu,Oulu,FI-90014,Finland%State Key Laboratory of Explosion Science and Technology,Beijing Institute of Technology,Beijing,China%Division of Mining and Geotechnical Engineering,Lule(a) University of Technology,Lule(a),Sweden
Elsevier
Subjects
Burden velocity
Delay time
Gruv- och berganläggningsteknik
Kinetic energy
Mining
Mining and Rock Engineering
Rock blasting
Tunnelling
Rock blasting
Mining
Tunnelling
Delay time
Kinetic energy
Burden velocity
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Summary:An analytical relation between burden velocity and ratio of burden to blasthole diameter is developed in this paper. This relation is found to be consistent with the measured burden velocities of all 37 full-scale blasts found from published articles. These blasts include single-hole blasts, multi-hole blasts, and simultaneously-initiated blasts with various borehole diameters such as 64 mm, 76 mm, 92 mm, 115 mm, 142 mm and 310 mm. All boreholes were fully charged. The agreement between measured and calculated burden velocities demonstrates that this relation can be used to predict the burden velocity of a wide range of full-scale blast with fully-coupled explosive charge and help to determine a correct delay time between adjacent holes or rows in various full-scale blasts involved in tunnelling (or drifting), surface and underground mining production blasts and underground opening slot blasts. In addition, this theoretical relation is found to agree with the measured burden velocities of 9 laboratory small-scale blasts to a certain extent. To predict the burden velocity of a small-scale blast, a further study or modification to the relation is necessary by using more small-scale blasts in the future.
ISSN:1674-7755
DOI:10.1016/j.jrmge.2021.04.004