Investigation on directional rock fracture mechanism under instantaneous expansion from the perspective of damage mechanics: A 3-D simulation

IF 4.3 3区 材料科学 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC
Shan Guo , Seokwon Jeon , Quan Zhang , Manchao He , Jianning Liu , Chao Wang , Qun Sui
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Abstract

With developments in geotechnical engineering, directional rock-breaking technology has been applied in large quantities. As a novel non-explosive rock-breaking technology, Instantaneous Expansion with a Single Crack (IESC) has been studied and applied to some extent in the past few years. IESC uses expansion gas to fracture rock mass in the predetermined direction by a special energy-gathering tube, which has the advantages of high safety, strong directional ability, and easy to operate. At present, there is a lack of in-depth investigation on the directional fracture mechanism of rock under the action of IESC. According to damage mechanics, the fundamental reason for rock fracture is due to the initiation, expansion, and penetration of internal cracks. In this study, a 3-D numerical model based on the theory of progressive failure is established to study the directional rock fracture mechanism of IESC, while a Conventional Expansion (CE) model without energy-gathering tube is established for comparative research. The maximum tensile stress criterion and unified strength criterion are used to identify damage failure of the element. The evolution processes of four key parameters are simulated, the types and degrees of tensile/compressive damage of the unit are analyzed, which aims to decipher the model's directional fracture mechanism under IESC loading. The established 3-D numerical models are validated by comparing with experimental results. The research results can contribute to further understanding the directional rock fracture mechanism of IESC and provide a theoretical basis for the application of IESC in the field.

从损伤力学角度研究瞬时膨胀下的定向岩石断裂机制三维模拟
随着岩土工程的发展,定向破岩技术得到了大量应用。作为一种新型的非爆炸性破岩技术,单裂缝瞬时膨胀技术(IESC)在过去几年中得到了一定程度的研究和应用。单裂缝瞬时膨胀破岩技术是利用膨胀气体通过特殊的集能管使岩体按预定方向破裂,具有安全性高、定向能力强、操作简便等优点。目前,对 IESC 作用下岩石定向断裂机理还缺乏深入研究。根据损伤力学,岩石断裂的根本原因是内部裂缝的产生、扩展和渗透。本研究建立了基于渐进破坏理论的三维数值模型来研究 IESC 作用下岩石的定向断裂机理,同时建立了不含集能管的常规膨胀(CE)模型进行对比研究。采用最大拉应力准则和统一强度准则来识别该元件的破坏失效。模拟了四个关键参数的演变过程,分析了单元的拉伸/压缩损伤类型和程度,旨在破解模型在 IESC 载荷作用下的定向断裂机理。通过与实验结果对比,验证了所建立的三维数值模型。研究成果有助于进一步理解 IESC 的定向岩石断裂机理,为 IESC 在野外的应用提供理论依据。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
7.20
自引率
4.30%
发文量
567
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