基于变形增量的红砂岩单轴加载破坏短临预报方法研究

doi:10.3724/1000-6915.jrme.2024.0877

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摘要以红砂岩单轴压缩实验为基础，采用数字散斑相关方法，基于岩石材料破坏的物理不稳定性表达，研究红砂岩在单轴加载条件下应变增量的变化趋势，建立基于应变增量的红砂岩单轴加载破坏短临预报方法。主要结论为：（1）基于岩石材料破坏的物理不稳定性，建立岩石加载破坏全过程的应力–应变增量表达式，并将岩石加载破坏全过程应变增量分为3个阶段。（2）依据岩石泊松比参数确定变形增量d?与应力增量d?夹角变化阈值，并统计得到其绝对值超过阈值的采集点数量、最大值和平均值3个指标。这3个指标参数曲线均呈现波动变化趋势，说明岩石试件在加载过程中处于不断受载调整的循环往复状态。（3）建立关键变化节点时间与总破坏时间的对应关系，实现了对岩石加载破坏时间的多阶段预报。（4）标示出不同时刻对应超过阈值采集点的位置、数值大小及方向，并画出其影响范围线，影响范围线均出现在岩石破坏裂隙周边区域，能够一定程度上反映出岩石破坏裂隙的发展变化状态。（5）引入调整系数K，建立能量预测公式，调整系数K取值为1.5～2.5。

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	许海亮
	袁舜鑫
	宋义敏
	安栋
	张润泽
	刘玉欣

关键词 ：岩石力学, 数字散斑, 增量原理, 单轴压缩

Abstract：Based on uniaxial compression experiments of red sandstone and employing the digital speckle correlation method, this study investigates the variation trends of strain increment under uniaxial loading conditions through physical instability characterization of rock material failure, establishing a short-term imminent prediction method for red sandstone failure under uniaxial loading based on strain increment. The main conclusions are as follows：(1) Through physical instability analysis of rock material failure, a stress-strain increment expression for the complete rock loading failure process was established, categorizing the strain increment during rock loading failure into three distinct stages. (2) The threshold value for angular variation between deformation increment d? and stress increment d? was determined based on Poisson?s ratio parameter, with three statistical indicators of quantity, maximum value, and average value of measurement points exceeding the threshold all exhibiting fluctuating variation patterns, indicating the cyclic adjustment state of rock specimens during loading. (3) A temporal correlation between critical change node time and total failure time was established, achieving multi-stage prediction of rock loading failure time. (4) Delineated action boundary lines drawn based on the position, magnitude, and direction of threshold-exceeding measurement points at different times consistently appeared in proximity to rock failure cracks, demonstrating partial reflection of the development state of rock fracture propagation. (5) An energy prediction formula with adjustment coefficient K was developed, where K values range from 1.5 to 2.5.

Key words： rock mechanics digital speckle incremental principle uniaxial compression

引用本文:

许海亮，袁舜鑫，宋义敏，安栋，张润泽，刘玉欣. 基于变形增量的红砂岩单轴加载破坏短临预报方法研究[J]. 岩石力学与工程学报, 2025, 44(7): 1800-1807.
XU Hailiang, YUAN Shunxin, SONG Yimin, AN Dong, ZHANG Runze, LIU Yuxin. Strain increment-based short-term prediction method for uniaxial compressive failure in red sandstone. , 2025, 44(7): 1800-1807.

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https://rockmech.whrsm.ac.cn/CN/10.3724/1000-6915.jrme.2024.0877 或 https://rockmech.whrsm.ac.cn/CN/Y2025/V44/I7/1800

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