基于3D-ILC脆性材料双共面与障碍内裂纹扩展特性
Fracture of impedimental crack and double coplanar cracks in brittle solid based on 3D-ILC
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摘要: 内裂纹是岩石等脆性材料的固有属性,裂纹间相互作用对材料断裂破坏特性影响巨大。以往研究多集中于表面裂纹或可简化为二维问题的穿透裂纹,对于三维内裂纹相互作用研究较少。基于3D-ILC,在不损伤试样表面的前提下生成内裂纹,对含障碍裂纹与不含障碍裂纹的试样开展拉伸试验,借助应力双折射效应定性观测应力分布,并开展数值模拟研究。结果表明:①基于3D-ILC的内裂纹相互作用规律显著,该技术为三维内裂纹相互融合、穿透问题的研究提供了手段;②竖直障碍裂纹破坏了双共面裂纹的应力分布,可以减小双共面裂纹靠近障碍裂纹尖端的应力集中;③竖直障碍裂纹对试样的起裂和破坏存在促进作用,使共面裂纹内侧起裂荷载降低10%,外侧起裂荷载降低2.5%,破坏荷载下降26.1%,含障碍裂纹试样的起裂荷载为破坏荷载的33.7%,不含障碍裂纹试样的起裂荷载为破坏荷载的41%;④竖直障碍裂纹不会改变试样的断裂模式,2种试样均呈现纯I型破坏特征,沿双共面裂纹所在的平面形成光滑的断裂面,断口表面存在一圈圈可表征裂纹扩展融合过程的弧纹;⑤竖直障碍裂纹会增强试样断裂时的应力释放,在障碍裂纹周围产生大量残余应力;⑥最大拉应力准则(MTS)可用于含障碍内裂纹扩展数值模拟,裂纹扩展路径以及裂纹尖端应力强度因子分布规律,与试验结果一致。Abstract: Three-dimensional internal crack is an inherent property of brittle materials such as rocks, which has a great influence on the fracture failure characteristics of materials.Most of the previous researches focused on surface cracks or penetrating cracks that could be simplified into two-dimensional problems.There are few studies on three dimensional internal crack interactions.Based on 3D-ILC,internal cracks were generated without damaging the sample surface.Then we carried out uniaxial tensile test for samples with and without impedimental crack.The stress distribution was observed qualitatively by means of the stress birefringence effect, and the numerical simulation was carried out at the same time.The results show that:① Internal cracks made by 3D-ILC can penetrate through each other, which lays a foundation for solving the problems of the fusion and penetration three-dimensional internal cracks in fracture mechanics.② The vertical impedimental crack destroys the stress distribution of the double coplanar crack, which can reduce the stress concentration of tips near the impedimental crack.③ The vertical impedimental crack can promote the crack initiation of samples, which cause the initiation load on the inner side of the coplanar crack decreased by 10% and the initiation load of lateral tip of coplanar crack decreased by 2.5%,the failure load decreased by 26.1%.The crack initiation load of the sample with the impedimental crack is 33.7% of the failure load, and the crack initiation load of the sample without the impedimental crack is 41% of the failure load.④ The impedimental crack does not change the fracture mode of the samples.Both samples show pure I type failure characteristics, and form smooth fracture surfaces along the plane where the double coplanar cracks are located.⑤ The impedimental crack will enhance the stress release during the fracture of the sample, and generate a large amount of residual stress around the impedimental crack.⑥ According to the maximum tensile stress criterion(MTS),the samples were simulated numerically, and we obtained the propagation process of cracks, the final failure pattern and the distribution rule of stress intensity factor at the crack tip, which was consistent with the test results.