Experimental study on fracture and fragmentation characteristics of laminated rocks under impact loading
Ding Deng, Yuling Li, Lianjun Guo, Gaofeng Liu, Jiawei Hua

TL;DR
This study examines how the orientation of rock layers affects how rocks break and release energy when impacted, which is important for engineering safety.
Contribution
The study reveals how lamination orientation influences energy dissipation, crack propagation, and fragmentation in laminated rocks under impact loading.
Findings
Lamination angle significantly affects energy dissipation characteristics of rocks.
Oblique lamination orientations lead to complex damage modes and large-scale crack propagation.
AE b-values confirm that diagonal laminations increase structural instability and damage.
Abstract
Laminated rock bodies are prevalent in engineering applications, making the investigation of their damage characteristics and evolution patterns under impact loading critical for ensuring engineering safety. Despite this importance, the relationship between energy dissipation and the crushing mode of laminated rock bodies remains underexplored, particularly regarding the influence of lamination orientation on their dynamic response. To bridge this scientific gap, this study conducts rock impact tests in the presence of various lamination angles (0°, 30°, 60°, and 90°) and employs digital image correlation (DIC) technology alongside acoustic emission (AE) monitoring and fracture sieve analysis to systematically examine how lamination orientation affects energy dissipation patterns, crack propagation behavior, and fragmentation characteristics in rocks. The results indicate that the…
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Taxonomy
TopicsRock Mechanics and Modeling · Nonlocal and gradient elasticity in micro/nano structures · Calcium Carbonate Crystallization and Inhibition
