基于DIC技术的煤样裂隙发育特征及应变演化规律分析

doi:10.11799/ce202302018

摘要/Abstract

摘要： 为了深入分析煤样单轴压缩下裂隙发育特征及应变演化规律，采用数字图像相关技术(DIC)分别获得试验过程中试件裂隙场、应变场的全程图像和数据，研究结果表明：试件应变演化与裂隙发育具有潜在的联系，裂隙发育处往往存在明显的应变集中现象，在弯曲裂隙中，当其张开程度较大时，受垂直压应力影响，诱导反方向的水平变形，出现裂隙闭合，以及垂直应变剧增、水平应变剧减等现象。当裂隙张开或扩展时，最大主应变增大，同时会出现明显的应变集中现象|当裂隙闭合时，最大主应变减小，应变集中程度也随之减小|最大主应变方向与裂隙张开方向基本一致，与裂隙扩展延伸方向基本垂直。试件加载后期，裂隙快速发育，而此后也表现出多处局部应变快速集中现象。当试件裂隙瞬间产生或破坏时，最大主应变方向也会发生较大变化，该试验结果可作为试件破坏预警的前兆信息之一。

Abstract: In order to deeply analyze the characteristics of crack development and strain evolution of coal samples under uniaxial compression, digital speckle technology was used to obtain the full-process images and data of the crack field and strain field of the specimen during the test. The global cracks development and strain evolution process of the specimen are analyzed, and the internal relationship between strain evolution and crack development is obtained. Based on this, the key cracks of the specimen are selected, the development of local cracks is further analyzed, and the evolution characteristics of the local horizontal strain, vertical strain, maximum principal strain field and the direction of the maximum principal strain with the acquisition frame are clarified. The results show that: the strain evolution of the specimen is potentially related to the development of cracks. There is often obvious strain concentration in the development of cracks, and there will be concentrated distribution of horizontal strain and vertical strain at the inclined or curved cracks. And the horizontal strain concentration is relatively large. In a curved crack, When the degree of opening is large, it is affected by the vertical compressive stress, which tends to produce large vertical deformation, and induce horizontal deformation in the opposite direction. There will be phenomena such as crack closure, sharp increase in vertical strain, and sharp decrease in horizontal strain. When the crack opens or expands, the maximum principal strain increases, and at the same time, there will be obvious strain concentration; When the crack is closed, the maximum principal strain decreases and the strain concentration also decreases; The direction of maximum principal strain is basically the same as the crack opening direction, and is basically perpendicular to the crack propagation direction. In addition, when the acquisition frame reaches 89% of the failure frame of specimen, the specimen's cracks develop rapidly, and thereafter, it also shows rapid concentration of local strains. And when the specimen cracks are generated or destroyed instantaneously, the maximum principal strain direction will also change greatly. The test results can be used as one of the precursors of the specimen failure early warning.

中图分类号:

TD315

尚宇琦, 熊钰, 孔德中, 等. 基于DIC技术的煤样裂隙发育特征及应变演化规律分析[J]. 煤炭工程, 2023, 55(2): 98-104.

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