Failure characteristics of two porous sandstones subjected to true triaxial stresses: Applied through a novel loading path

Ma, Xiaodong; Rudnicki, John W.; Haimson, Bezalel C.

doi:10.1002/2016jb013637

Cited by 79 publications

(24 citation statements)

References 51 publications

(153 reference statements)

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“…Moreover, a growing number of in situ stress measurements have indicated that axisymmetric stress conditions (like the ones applied in conventional triaxial tests) are rare in the Earth's crust. 81,88,89 Thus, conventional triaxial testing does not faithfully replicate typical crustal stress conditions (where σ 1 ≥ σ 2 ≥ σ 3 ). This constitutes the necessity of exploring the deformation and failure characteristics of flawed specimens under true triaxial compression.…”

Section: Crack Initiation and Growth In Flawed Rocks Under Triaxial Compressionmentioning

confidence: 99%

Compression‐induced crack initiation and growth in flawed rocks: A review

Zhou

Zhang

Yang

et al. 2021

Fatigue Fract Eng Mat Struct

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Section: Crack Initiation and Growth In Flawed Rocks Under Triaxial Compressionmentioning

confidence: 99%

Compression‐induced crack initiation and growth in flawed rocks: A review

Zhou

Zhang

Yang

et al. 2021

Fatigue Fract Eng Mat Struct

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“…Since all the three principal stresses vary during the loading and unloading of the specimen, the octahedral shear stress τ oct in Equation ( 3) is used to generalize the strength characteristic of the specimen [33]:…”

Section: Characteristics Of Strength and Deformationmentioning

confidence: 99%

Influence of Three-Dimensional Stress Field Variation on Fracture Evolution Characteristics of a Roof

Shi

Cai

et al. 2020

Geofluids

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Excavation disturbance on the dynamic variation of the three-dimensional stress field is the main cause for the dynamic disasters of the surrounding rock mass of the roof. The stress condition in the surrounding rock mass of the roof during entry excavation and its impact on entry stability are systemically studied in this study. It is found that the surrounding rock mass of the roof is mainly influenced by the combined effect of the stress unloading and stress transference induced by entry excavation. A servo-controlled true triaxial material testing system is used to conduct the true triaxial loading and unloading experiments of rocks under different stress paths. The influence of different stress paths, especially the variation of the principal stress direction, on the mechanical characteristics and fracture characteristics of rocks is investigated. The results indicate that the variation of the principal stress direction has a significant impact on the macroscopic fracture characteristics of the rock. The main macroscopic fracture plane of the rock highly depends on the intermediate principal stress. The fracture evolution of the roof rock mass during entry excavation is analyzed. The results show that the change of the three-dimensional stress field induces the formation of complex fracture networks in the surrounding rock mass of the roof. The roof is likely to dislocate horizontally and collapse. The corners of the entry are seriously damaged. Based on the above findings, a support scheme is proposed to maintain the stability of a gob-side entry. The field experience suggests that the support scheme can achieve good results.

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“…This leaves the prediction of the structural behavior and performance of sandstone as a significant challenge. Consequently, mechanical properties and failure patterns of sandstone have been the common research focus of various disciplines integrating mechanics, material science, and engineering [6,7].…”

Section: Introductionmentioning

confidence: 99%

Prediction of Fracture Damage of Sandstone Using Digital Image Correlation

et al. 2020

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Featured Application: A non-contact digital image correlation technique is used to predict sandstone failure. Failure strain for the tested sandstone is estimated to be around 0.004. Finite element analysis verifies the accuracy of prediction results based on experiments.Abstract: Investigation on the deformation mechanism of sandstone is crucial to understanding the life cycle patterns of pertinent infrastructure systems considering the extensive adoption of sandstone in infrastructure construction of various engineering systems, e.g., agricultural engineering systems. In this study, the state-of-the-art digital image correlation (DIC) method, which uses classical digital photography, is employed to explore the detailed failure course of sandstone with physical uniaxial compression tests. Four typical points are specifically selected to characterize the global strain field by plotting their corresponding strain-time relationship curves. Thus, the targeted failure thresholds are identified. The Hill-Tsai failure criterion and finite element simulation are then used for the cross-check process of DIC predictions. The results show that, though errors exist between the experimental and the theoretical values, overall, they are sufficiently low to be ignored, indicating good agreement. From the results, near-linear relationships between strain and time are detected before failure at the four chosen points and the failure strain thresholds are almost the same; as low as 0.004. Failure thresholds of sandstone are reliably determined according to the strain variation curve, to forecast sandstone damage and failure. Consequently, the proposed technology and associated information generated from this study could be of assistance in the safety and health monitoring processes of relevant infrastructure system applications.

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Failure characteristics of two porous sandstones subjected to true triaxial stresses: Applied through a novel loading path

Cited by 79 publications

References 51 publications

Compression‐induced crack initiation and growth in flawed rocks: A review

Compression‐induced crack initiation and growth in flawed rocks: A review

Influence of Three-Dimensional Stress Field Variation on Fracture Evolution Characteristics of a Roof

Prediction of Fracture Damage of Sandstone Using Digital Image Correlation

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