Delay failure and fast fracturing of notched bedding rock under shear test condition: physical test and discrete element simulation

IF 2.8 3区工程技术 Q1 MATHEMATICS, INTERDISCIPLINARY APPLICATIONS

Computational Particle Mechanics Pub Date : 2024-09-23 DOI:10.1007/s40571-024-00830-y

Seyed Davoud Mohammadi, Rahim Mortezaei, Vahab Sarfarazi, Parastou Salehipor

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引用次数: 0

Abstract

This research investigates the impact of the brittleness of bedding, bedding angel, and the notch length on the delayed failure and rapid fracturing of notched bedding rock under shear conditions subjected to punch tests. Also, this paper analyzed the acoustic emission events throughout the entire process of rock bridge failure. For this purpose, rectangular two layered samples containing both hard- and soft-rock layers were employed. Each model included two vertical edge notches in a single direction, with notch lengths of 20, 40, and 60 mm. The bedding layers were varied from 90° to − 75° with increments of 15°. The results demonstrate that smooth cracks originated from the notch tip and propagated vertically until coalescing with the upper boundary of the model. The occurrence of acoustic emission in hard, ductile gypsum is considerably greater than that in soft, brittle gypsum. The shear stiffness of bedded rock is maximized when a higher percentage of shear surfaces is occupied by hard and ductile gypsum. Delay failure occurs in the hard, ductile layer, while fast fracturing occurs in the soft, brittle layer. In models with constant notch length, delay failure was occurred in models with a positive layer, whereas fast fracturing was observed in models with a negative layer angle. Additionally, delay failure changes to fast fracturing with an increase in the notch length. Failure patterns, shear stiffness, and shear strengths of the notched bedding models are similar to those of notched physical samples.

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来源期刊

Computational Particle Mechanics Mathematics-Computational Mathematics

CiteScore

5.70

自引率

9.10%

发文量

期刊介绍： GENERAL OBJECTIVES: Computational Particle Mechanics (CPM) is a quarterly journal with the goal of publishing full-length original articles addressing the modeling and simulation of systems involving particles and particle methods. The goal is to enhance communication among researchers in the applied sciences who use "particles'''' in one form or another in their research. SPECIFIC OBJECTIVES: Particle-based materials and numerical methods have become wide-spread in the natural and applied sciences, engineering, biology. The term "particle methods/mechanics'''' has now come to imply several different things to researchers in the 21st century, including: (a) Particles as a physical unit in granular media, particulate ﬂows, plasmas, swarms, etc., (b) Particles representing material phases in continua at the meso-, micro-and nano-scale and (c) Particles as a discretization unit in continua and discontinua in numerical methods such as Discrete Element Methods (DEM), Particle Finite Element Methods (PFEM), Molecular Dynamics (MD), and Smoothed Particle Hydrodynamics (SPH), to name a few.