Damage and hardening evolution characteristics of sandstone under multilevel creep–fatigue loading

IF 3.9 2区 工程技术 Q3 ENERGY & FUELS
Zhang Bichuan, Liang Yunpei, Zou Quanle, Ning Yanhao, Kong Fanjie
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Abstract

During the operation of artificial underground structures, the surrounding rock experiences fatigue and creep damage caused by several types of disturbances under long-term constant loading. To quantify the mechanical response of sandstone under creep–fatigue loading, a damage–hardening evolution model based on the linear superposition concept is proposed. In the model, coupling is applied to represent the synergistic effect of creep and fatigue. Creep–fatigue tests of sandstone specimens are conducted under multilevel loading. The damage and hardening effects of sandstone under creep–fatigue loading are complex. Hardening is the dominant effect under low creep–fatigue loads, and damage is the dominant effect under high creep–fatigue loads. The strength of the rock specimens undergoes increasing and decreasing trends under this loading path, and the evolution of the Mohr–Coulomb envelope is discussed. The proposed model can be used to describe the test data and the evolution of the creep–fatigue process. With increasing creep–fatigue number, the acoustic emission amplitude, energy, and cumulative counts increase. However, the amplitude is more sensitive than the energy, indicating that it is more suitable for describing creep–fatigue loading. Furthermore, the peak frequencies of the AE signals are mostly distributed in the 0–15 kHz, 15–30 kHz, 30–45 kHz, and 45–55 kHz regions. The signal proportion in the 45–55 kHz zone decreases with the creep–fatigue number. However, other frequency zones increase with the creep–fatigue number. This phenomenon illustrates that the crack scale of the specimens increases with the creep–fatigue number.

Abstract Image

多级蠕变疲劳加载下砂岩的损伤和硬化演变特征
在人工地下结构的运行过程中,围岩在长期恒定荷载作用下会受到多种扰动引起的疲劳和蠕变损伤。为了量化砂岩在蠕变-疲劳荷载作用下的力学响应,提出了一个基于线性叠加概念的损伤-硬化演化模型。在该模型中,耦合被用来表示蠕变和疲劳的协同效应。在多级加载下对砂岩试样进行了蠕变-疲劳试验。砂岩在蠕变-疲劳加载下的损伤和硬化效应非常复杂。在低蠕变疲劳载荷下,硬化是主要效应,而在高蠕变疲劳载荷下,损伤是主要效应。在这种加载路径下,岩石试样的强度经历了上升和下降的趋势,并讨论了莫尔-库仑包络的演变。提出的模型可用于描述试验数据和蠕变疲劳过程的演变。随着蠕变疲劳次数的增加,声发射的振幅、能量和累积次数都会增加。然而,振幅比能量更敏感,这表明它更适合描述蠕变疲劳加载。此外,AE 信号的峰值频率主要分布在 0-15 kHz、15-30 kHz、30-45 kHz 和 45-55 kHz 区域。45-55 kHz 区域的信号比例随着蠕变疲劳次数的增加而降低。然而,其他频率区则随着蠕变疲劳数的增加而增加。这一现象说明试样的裂纹尺度随着蠕变疲劳数的增加而增大。
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来源期刊
Geomechanics and Geophysics for Geo-Energy and Geo-Resources
Geomechanics and Geophysics for Geo-Energy and Geo-Resources Earth and Planetary Sciences-Geophysics
CiteScore
6.40
自引率
16.00%
发文量
163
期刊介绍: This journal offers original research, new developments, and case studies in geomechanics and geophysics, focused on energy and resources in Earth’s subsurface. Covers theory, experimental results, numerical methods, modeling, engineering, technology and more.
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