Enhancing understanding of fracture mechanisms in brittle rocks under static and cyclic loads: Experimental insights and theoretical model

•The fatigue behavior of rocks is studied experimentally and theoretically.•A micromechanics-based model is developed to characterize the fatigue crack growth within rocks.•Theoretical model captures the classical three-stage damage evolution of rock fatigue. The present study investigates the fatig...

Full description

Saved in:
Bibliographic Details
Published in:Engineering fracture mechanics 2023-09, Vol.289, p.109426, Article 109426
Main Authors: Miao, Shuting, Pan, Peng-Zhi, Cao, Yangbing, Huo, Lei
Format: Article
Language:English
Subjects:
Acoustic emission
Damage evolution
Fatigue damage model
Stress intensity factor
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:•The fatigue behavior of rocks is studied experimentally and theoretically.•A micromechanics-based model is developed to characterize the fatigue crack growth within rocks.•Theoretical model captures the classical three-stage damage evolution of rock fatigue. The present study investigates the fatigue behavior of granite and red sandstone under coupled static and cyclic loading. Experimental results reveals a three-stage evolution trend for the deformation modulus, Young's modulus, peak strain, residual strain, dissipated energy as a function of the absolute cycle. Acoustic emission (AE) rate also exhibits a three-phase stage, including the initial phase, uniform velocity phase, and accelerated phase. To explain the mechanical responses and fracture mechanisms related to rock fatigue, this study built a micromechanics-based damage model that adopts a modified Paris law and considers both the effect of static stress and stress amplitude. The theoretical model successfully reflects the effect of static loading history and reproduces the three-stage evolution of residual strain during rock fatigue. The SIF deduced by the theoretical model exhibits a distinct behavior: it initially decreases during the first few cycles, stabilizes at a lower value, and subsequently undergoes a significant increase as it approaches the final cycles. The internal cause behind the three-stage evolution of crack growth rate, AE rate, and mechanical properties is attributed to subcritical crack growth during cyclic loading. Finally, the theoretical model successfully characterizes the effect of static stress and stress amplitude of cyclic loads on fatigue damage evolution.
ISSN:0013-7944
1873-7315
DOI:10.1016/j.engfracmech.2023.109426