Achieving effective confinement through utilization of non-Newtonian fluid mixture as stemming structure

• Main Authors: Luís Felipe Gomes Marinho, Hiago Gonçalves Vasconcelos, Braden Lusk, Giuliano Antonio Pizzatto Rapucci
• Format: Article
• Language: English
• Published: Fundação Gorceix
• Series: REM: International Engineering Journal
• Subjects: effective confinement; non-Newtonian mixture; stemming; strain propagation
• Online Access: http://www.scielo.br/scielo.php?script=sci_arttext&pid=S2448-167X2017000100077&lng=en&tlng=en

Abstract The economics of a mining operation is directly influenced by blasting outcomes, where blasting aims to comminute the rock mass in order to attain smaller grain sizes to be loaded and hauled at a minimum cost for its first processing stage. In order to promote adequate rock breakage, the stemming structure needs to provide proper confinement for the borehole charged with explosives, reflecting the energy released during the detonation in form of shock waves and gases to act throughout the in situ rock mass, enlarging its failures and fractures, and also creating new ones. To build up a stemming column, literature recommends the usage of dry granular materials instead of elements with plastic behavior. However, a study was performed using Gypsum plaster as stemming; a kind of material that exhibits solid-like behavior when it is dry. Following this theory, this test verified improvements regarding confinement effectiveness and energy propagation throughout the rock mass when a non-Newtonian mixture (NNM) was applied as stemming; a material that shows a solid-like behavior when is under shear stress. When the stemming arrangement was composed of NNM, it was able to reduce energy and gas losses to the atmosphere, because of the liquid's property of filling voids into the borehole. The NNM yielded high results due to its better confinement effectiveness, a reduction of air overpressure, and an increase of the strain propagation and ground vibration throughout the rock.