The Role of Cohesive Strength and Separation Energy for Modeling of Ductile Fracture

T. Siegmund, W. Brocks
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引用次数: 48

Abstract

Barenblatt's idea of modeling the crack process zone by means of a cohesive zone has attracted considerable attention for predicting ductile crack growth. The model allows separation of the energy necessary for material separation from global plastic work. This has been a key problem in ductile fracture when searching for reasons for the geometry dependence of crack growth resistance curves. When using cohesive zone models, the correct determination of the cohesive zone material parameters is of eminent importance. In the past these parameters-the cohesive strength and the separation energy-were assumed to be material constants. However, micromechanical considerations show that this assumption is only an approximation in the case of ductile fracture. Here, the underlying mechanisms of void nucleation, growth, and coalescence are dependent on the stress triaxiality. This effect is accounted for in the new constitutive equation for cohesive zone models as presented here. In this new "triaxiality-dependent cohesive zone model," the cohesive material properties are taken to be dependent on the stress triaxiality in the solid element adjacent to the cohesive element. For low triaxiality, low values of cohesive strength and large values of the separation energy are observed; the opposite holds true for cases of high triaxiality. Ductile crack growth in a mild steel under quasistatic loading was investigated. The results from the use of the triaxiality-dependent cohesive zone model are compared to those of the Gurson-Tvergaard-Needleman (GTN) model as well as to the cohesive zone model with constant material parameters. The dissipation rate is shown to be a favorable measure for the characterization of the crack growth resistance. It allows the description of both the (global) plastic dissipation and the (local) work of fracture.
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黏结强度和分离能在塑性断裂建模中的作用
Barenblatt用黏合区来模拟裂纹过程区的想法在预测韧性裂纹扩展方面引起了相当大的关注。该模型允许从全球塑料工作中分离出材料分离所需的能量。在寻找裂纹扩展阻力曲线几何依赖性的原因时,这一直是韧性断裂中的一个关键问题。在使用黏结区模型时,黏结区材料参数的正确确定至关重要。过去,这些参数——内聚强度和分离能——被认为是材料常数。然而,微观力学的考虑表明,这种假设只是一个近似的韧性断裂的情况下。在这里,空洞成核、生长和聚并的潜在机制取决于应力三轴性。这种影响是在新的本构方程的粘聚区模型,在这里提出。在这个新的“triaxiality-dependent软熔带模式,”聚合材料属性被依赖于应力三维固体元素毗邻凝聚力元素。低三轴性时,黏结强度较低,分离能较大;高三轴性的情况正好相反。研究了一种低碳钢在准静态载荷作用下的延性裂纹扩展。将三轴相关黏聚带模型的计算结果与Gurson-Tvergaard-Needleman (GTN)模型以及恒定材料参数黏聚带模型的计算结果进行了比较。耗散率是表征裂纹扩展阻力的有利指标。它允许描述(整体)塑性耗散和(局部)断裂功。
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