用ΔJ法评价疲劳裂纹扩展

Jia Li, O. Ancelet, Alexandre Double, S. Chapuliot
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摘要

对大型铸造件进行疲劳裂纹扩展分析,以评估其在使用寿命期间可能发生的缺陷演变。这些部件承受机械载荷和热载荷。由于它们的厚度高,温度随厚度的变化可能是显著的。因此,传统的疲劳裂纹扩展弹性分析可能过于保守。为了考虑塑性的影响,在有限元软件SYSTUS中实现了ΔJ疲劳裂纹扩展评价方法[9]。本工作将使用四分之一循环法[11](或ASME规范中的二次屈服法)来计算热瞬态和机械载荷下的ΔJ值。在三维弹塑性有限元计算中,提出了两种创建虚拟单调递增加载的策略。通过与有限元软件CAST3M[10]和RSE-M[3]简化ΔKcp方法进行比较,验证数值格式的结果。
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Evaluation of Fatigue Crack Propagation by ΔJ Approach
An analysis of fatigue crack growth is required for large cast components to evaluate the possible defect evolution during the service life. These components are subjected to both mechanical loading and thermal loading. Due to their high thickness, temperature variations through the thickness can be significant. Thus, a conventional elastic analysis of fatigue crack propagation could be over conservative. In order to take into account the effect of plasticity, the ΔJ approach of fatigue crack propagation evaluation is implemented in FE software SYSTUS [9]. The quarter of cycle method [11] (or twice-yield method in ASME code) will be used in this work to calculate ΔJ values under both thermal transient and mechanical loadings. Two strategies will be proposed to create the virtual monotonically increasing loading in 3D elastic–plastic FE calculations. The result in terms of numerical scheme will be validated by comparing with FE software CAST3M [10] and the RSE-M [3] simplified ΔKcp method.
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