Show simple item record

dc.contributor.author Wataru, I
dc.contributor.author Daisuke, F
dc.contributor.author Yoshiaki, T
dc.contributor.author Tei, S
dc.contributor.author Shiro, K
dc.contributor.author Jun-ichi, K
dc.contributor.author Yoshiaki, F
dc.contributor.editor Jayawardena, CL
dc.date.accessioned 2022-12-28T07:15:20Z
dc.date.available 2022-12-28T07:15:20Z
dc.date.issued 2022-12-23
dc.identifier.citation Wataru, I., Daisuke, F., Yoshiaki, T., Tei, S., Shiro, K., Jun-ichi, K., & Yoshiaki, F. (2022). Development of a blasting simulator considering gas-rock interaction. In C. L. Jayawardena (Ed.), Proceedings of International Symposium on Earth Resources Management & Environment 2022 (pp. 1-6). Department of Earth Resources Engineering, University of Moratuwa. http://dl.lib.uom.lk/handle/123/19696
dc.identifier.uri http://dl.lib.uom.lk/handle/123/19919
dc.description.abstract Optimization of rock blasting in mining engineering is essential for energy efficiency, cost reduction, and safety. In contrast, the dynamic rock fracture process due to blasting involves highly complex and rapid processes. Thus, it is crucial to develop a reasonable numerical simulator for blasting which can model the following processes: (i)detonation-induced shock wave and gas expansion, (ii)complex dynamic fracture process of rocks, (iii)gas-rock interaction including the impact of shock waves on the blasthole surface and the inflow of blast-induced gas into a dynamically evolving fracture network. Besides, massively parallel computation is indispensable to dealing with the computationally expensive coupling processes (i)~(iii). To this end, this study couples the cubic-interpolated pseudo particle (CIP) method, the combined finite-discrete element method (FDEM) and the immersed boundary method to model the processes (i)~(iii), respectively. A massively parallel computing scheme with general-purpose graphics-processing units (GPGPU) is incorporated for the parallel computation. The applicability of the developed simulator is investigated using a single hole blasting problem. Although further improvements must be achieved, the proposed blasting simulation results indicate that all the processes (i)~(iii) can be reasonably traced. In conclusion, the developed simulator is expected to help investigate the optimization of rock blasting. en_US
dc.language.iso en en_US
dc.publisher Department of Earth Resources Engineering, University of Moratuwa, Sri Lanka en_US
dc.subject FDEM en_US
dc.subject Fluid-structure-interaction en_US
dc.subject GPGPU parallel computation en_US
dc.subject Numerical simulation en_US
dc.subject Rock blasting en_US
dc.title Development of a blasting simulator considering gas-rock interaction en_US
dc.type Conference-Full-text en_US
dc.identifier.faculty Engineering en_US
dc.identifier.department Department of Earth Resources Engineering en_US
dc.identifier.year 2022 en_US
dc.identifier.conference International Symposium on Earth Resources Management & Environment 2022 en_US
dc.identifier.place Colombo en_US
dc.identifier.pgnos pp. 1-6 en_US
dc.identifier.proceeding Proceedings of International Symposium on Earth Resources Management & Environment 2022 en_US
dc.identifier.email wataru-ikw@eis.hokudai.ac.jp en_US
dc.identifier.doi https://doi.org/10.31705/ISERME.2022.1 en_US


Files in this item

This item appears in the following Collection(s)

Show simple item record