Microsimulation Study on Energy Release and Rock Block Ejection Force of Granite under Different Unloading Conditions

Wang, Xinyuan; Yin, Yanchun; Xing, Minglu; Zhang, Dongdong; Yang, Chen; Wang, En-Chao

doi:10.3389/feart.2022.909371

Cited by 2 publications

(1 citation statement)

References 36 publications

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“…A coal burst is a dynamic failure phenomenon driven by energy. Therefore, it is better to reveal the essential characteristics of coal bursts by studying the energy evolution law [20][21][22][23]. In the research on the stiffness theory of coal bursts, limited by the test methods, the research on the energy parameters in the current stage is less and generally only involves the analysis of the storage and release of elastic strain energy in the two states of the peak strength point and post-failure [19].…”

Section: Introductionmentioning

confidence: 99%

Simulation Research on Energy Evolution and Supply Law of Rock–Coal System under the Influence of Stiffness

Yin

Tang

et al. 2023

Sustainability

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The energy supply effect caused by the stiffness difference between roofs and sidewalls is an important factor that induces strain coal bursts. In order to quantitatively reveal the energy supply mechanism of strain coal bursts, this paper first establishes a coal burst energy model of the rock–coal system and proposes the calculation formula of coal burst kinetic energy considering supply energy and the stiffness ratio of rock to coal. Then the whole energy evolution law of the rock–coal system with different stiffness ratios is researched by using the numerical simulation method, and the whole process is divided into three stages. With the decrease in the stiffness ratio, the elastic strain energy of the coal changes little, while its kinetic energy is negatively correlated with the stiffness ratio in a power function. Meanwhile, the elastic strain energy and kinetic energy of the rock have power function relations with the stiffness ratio, too. When the rock–coal system is fractured, the kinetic energy of the coal comes from the release of elastic strain energy from the coal and the energy supplied from the rock. The energy supply rate is between 22% and 35% when the stiffness ratio changes from 3.0 to 0.5, and they show a linear relationship, while the supplied energy has a negative power function relationship with the stiffness ratio.

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Section: Introductionmentioning

confidence: 99%

Simulation Research on Energy Evolution and Supply Law of Rock–Coal System under the Influence of Stiffness

Yin

Tang

et al. 2023

Sustainability

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Coevolving edge rounding and shape of glacial erratics: the case of Shap granite, UK

Carling

2024

Earth Surf. Dynam.

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Abstract. The size distributions and the shapes of detrital rock clasts can shed light on the environmental history of the clast assemblages and the processes responsible for clast comminution. For example, mechanical fracture due to the stresses imposed on a basal rock surface by a body of flowing glacial ice releases initial “parent” shapes of large blocks of rock from an outcrop, which then are modified by the mechanics of abrasion and fracture during subglacial transport. The latter processes produce subsequent generations of shapes, possibly distinct in form from the parent blocks. A complete understanding of both the processes responsible for block shape changes and the trends in shape adjustment with time and distance away from the source outcrop is lacking. Field data on edge rounding and shape changes of Shap granite blocks (dispersed by Devensian ice eastwards from the outcrop) are used herein to explore the systematic changes in block form with distance from the outcrop. The degree of edge rounding for individual blocks increases in a punctuated fashion with the distance from the outcrop as blocks fracture repeatedly to introduce new fresh unrounded edges. In contrast, block shape is conservative, with parent blocks fracturing to produce self-similar “child” shapes with distance. Measured block shapes evolve in accord with two well-known models for block fracture mechanics – (1) stochastic and (2) silver ratio models – towards one or the other of these two attractor states. Progressive reduction in block size, in accord with fracture mechanics, reflects the fact that most blocks were transported at the sole of the ice mass and were subject to the compressive and tensile forces of the ice acting on the stoss surfaces of blocks lying against a bedrock or till surface. The interpretations might apply to a range of homogeneous hard rock lithologies.

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Microsimulation Study on Energy Release and Rock Block Ejection Force of Granite under Different Unloading Conditions

Cited by 2 publications

References 36 publications

Simulation Research on Energy Evolution and Supply Law of Rock–Coal System under the Influence of Stiffness

Simulation Research on Energy Evolution and Supply Law of Rock–Coal System under the Influence of Stiffness

Coevolving edge rounding and shape of glacial erratics: the case of Shap granite, UK

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