Grain-based coupled thermo-mechanical modeling for stressed heterogeneous granite under thermal shock

IF 8.2 1区 工程技术 Q1 ENGINEERING, CIVIL
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Abstract

Microscopic damage and macroscopic mechanical properties of granite under the coupling effect of thermal load and initial stress are crucial considerations for the safe construction of underground geo-energy engineering. However, visualizing real-time micro-crack processes in rocks under high-temperature and high-pressure conditions using the current experimental techniques remains challenging. In this study, a numerical method is developed to analyze the thermally induced damage in heterogeneous granite under the coupled influence of initial stress and thermal loading. A biaxial thermo-mechanical grain-based model considering real mineral distribution is established based on digital image processing technology, the grain-based modeling method, and heat conduction theory. The microscopic parameters are calibrated and the effectiveness of the model is verified based on thermal shock and uniaxial compression experiments. The thermal destruction mechanism of granite under initial stress from a microscopic perspective was unveiled for the first time. During the thermal shock process, the stress within the rock does not remain constant at the initial stress value. Instead, it changes continuously with the progression of heat conduction. The impact of the initial stress on the thermally induced cracks is relatively minor. Cooling causes more damage to the rock than heating during thermal shock. The intragranular cracks of quartz consistently outnumber other intragranular or intergranular cracks during thermal shock. The initial stress and thermal shock damage enhance and weaken the biaxial peak strength of granite, respectively. The weakening effect of thermal shock on the peak strength becomes more pronounced at a higher initial stress. These research findings and proposed research techniques contribute to the management and optimization of underground geo-energy engineering.
热冲击下受力异质花岗岩的基于晶粒的热机械耦合建模
在热负荷和初始应力的耦合作用下,花岗岩的微观损伤和宏观力学性能是地下地质能源工程安全施工的关键因素。然而,利用现有的实验技术对岩石在高温高压条件下的微裂缝过程进行实时可视化仍然具有挑战性。本研究开发了一种数值方法,用于分析在初始应力和热负荷耦合影响下,异质花岗岩中的热诱导损伤。基于数字图像处理技术、基于晶粒的建模方法和热传导理论,建立了考虑真实矿物分布的双轴热机械晶粒模型。基于热冲击和单轴压缩实验,校准了微观参数并验证了模型的有效性。首次从微观角度揭示了花岗岩在初始应力作用下的热破坏机理。在热冲击过程中,岩石内部的应力并不会保持恒定的初始应力值。相反,它随着热传导的进行而不断变化。初始应力对热裂缝的影响相对较小。在热冲击过程中,冷却比加热对岩石造成的破坏更大。在热冲击过程中,石英的粒内裂缝始终多于其他粒内或粒间裂缝。初始应力和热冲击破坏分别增强和削弱了花岗岩的双轴峰值强度。当初始应力较大时,热冲击对峰值强度的削弱作用更加明显。这些研究成果和建议的研究技术有助于地下地质能源工程的管理和优化。
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来源期刊
Underground Space
Underground Space ENGINEERING, CIVIL-
CiteScore
10.20
自引率
14.10%
发文量
71
审稿时长
63 days
期刊介绍: Underground Space is an open access international journal without article processing charges (APC) committed to serving as a scientific forum for researchers and practitioners in the field of underground engineering. The journal welcomes manuscripts that deal with original theories, methods, technologies, and important applications throughout the life-cycle of underground projects, including planning, design, operation and maintenance, disaster prevention, and demolition. The journal is particularly interested in manuscripts related to the latest development of smart underground engineering from the perspectives of resilience, resources saving, environmental friendliness, humanity, and artificial intelligence. The manuscripts are expected to have significant innovation and potential impact in the field of underground engineering, and should have clear association with or application in underground projects.
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