Abstract
Pre-existing cracks and associated filling materials cause the significant heterogeneity of natural rocks and rock masses. The induced heterogeneity changes the rock properties. This paper targets the gap in the existing literature regarding the adopting of artificial neural network approaches to efficiently and accurately predict the influences of heterogeneity on the strength of 3D-printed rocks at different strain rates. Herein, rock heterogeneity is reflected by different pre-existing crack and filling material configurations, quantitatively defined by the crack number, initial crack orientation with loading axis, crack tip distance, and crack offset distance. The artificial neural network model can be trained, validated, and tested by finite 42 quasi-static and 42 dynamic Brazilian disc experimental tests to establish the relationship between the rock strength and heterogeneous parameters at different strain rates. The artificial neural network architecture, including the hidden layer number and transfer functions, is optimized by the corresponding parametric study. Once trained, the proposed artificial neural network model generates an excellent prediction accuracy for influences of high dimensional heterogeneous parameters and strain rate on rock strength. The sensitivity analysis indicates that strain rate is the most important physical quantity affecting the strength of heterogeneous rock.
Highlights
Natural rocks typically have substantial heterogeneity in terms of containing preexisting flaws at multiple scales resulting from a variety of geological processes
The current study aims to investigate the artificial neural network (ANN) application in establishing the relationship between the rock strength and rock heterogeneous factors at different strain rates
The entire dataset is used to evaluate the accuracy of the predicted peak load by the ANN approach
Summary
Natural rocks typically have substantial heterogeneity in terms of containing preexisting flaws at multiple scales resulting from a variety of geological processes. The heterogeneity makes alternations to rock mechanical strength, further affecting the deformation behaviors and failure patterns upon loading [1,2]. To a certain degree, almost all rock-related engineering projects include structure constructions in rock masses, which involve pre-existing opening cracks [3,4]. Stress concentration may occur around the pre-existing flaws, which triggers crack coalescence and ultimate failure [5,6]. These opening flaws are usually naturally filled with different fine-grained materials due to weathering or joint shearing [7]. As a rate-dependent material, the heterogeneous rock mechanical strength is highly related to the strain rate [10]
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