Open AccessA Phased Array Approach to Rock Blasting
Author(s) -
Leslie Gertsch,
Jason Baird
Publication year - 2006
Publication title -
osti oai (u.s. department of energy office of scientific and technical information)
Language(s) - English
Resource type - Reports
DOI - 10.2172/891935
Subject(s) - rock mass classification , shock wave , rock blasting , homogeneous , isotropy , interference (communication) , mortar , shock (circulatory) , geology , scale (ratio) , acoustics , computer science , geotechnical engineering , engineering , optics , physics , aerospace engineering , telecommunications , medicine , channel (broadcasting) , oceanography , thermodynamics , quantum mechanics
A series of laboratory-scale simultaneous two-hole shots was performed in a rock simulant (mortar) to record the shock wave interference patterns produced in the material. The purpose of the project as a whole was to evaluate the usefulness of phased array techniques of blast design, using new high-precision delay technology. Despite high-speed photography, however, we were unable to detect the passage of the shock waves through the samples to determine how well they matched the expected interaction geometry. The follow-up mine-scale tests were therefore not conducted. Nevertheless, pattern analysis of the vectors that would be formed by positive interference of the shockwaves from multiple charges in an ideal continuous, homogeneous, isotropic medium indicate the potential for powerful control of blast design, given precise characterization of the target rock mass
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