Modelling the Brittle-Ductile Transition Temperature of Irradiated A508-3 Steel With CPFEM

Volume 15: Student Paper Competition Pub Date : 2022-08-08 DOI:10.1115/icone29-90986

P. Lin, J. Nie, Meidan Liu

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Abstract

Crystal Plasticity Finite Element Model (CPFEM) is the powerful tool to bridge the meso-scale and marco-scale and study the mechanical properties of metals systematically. In this paper, crystal plasticity theory coupling with irradiation effect is proposed. Note that it is based on density of dislocation and irradiation-induced full-absorption and partial-absorption dislocation loop and their interaction between each other. Then the model is numerically implemented in UMAT on ABAQUS platform. Secondly, A508-3 steel, the typical BCC crystal material, has specific brittle-ductile transition. The cleavage failure probability theory model (CFPTM) which assumes that the failure probability of specimen depends on its Cauthy stress filed is presented. The tensile tests for A508-3 steel are simulated by CPFEM in a combination of CFPTM to obtain the brittle-ductile transition temperature (BDTT). Results show that failure probability for specimen increases with increasing strain and decreasing temperature. In terms of BDTT, the numerical and experimental result are in close agreement whether there is under irradiation condition or not. Furthermore, the obvious irradiation embrittlement phenomenon is observed.

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辐照A508-3钢脆性-韧性转变温度的CPFEM模拟

晶体塑性有限元模型(CPFEM)是连接细观尺度和宏观尺度，系统研究金属力学性能的有力工具。本文提出了结合辐照效应的晶体塑性理论。注意，它是基于位错密度和辐照诱导的全吸收和部分吸收位错环以及它们之间的相互作用。然后在ABAQUS平台的UMAT中对该模型进行了数值实现。其次，A508-3钢是典型的BCC晶体材料，具有特定的脆-韧转变。提出了假定试样的破坏概率取决于试样的自然应力场的解理破坏概率理论模型。采用CPFEM和CFPTM相结合的方法对A508-3钢的拉伸试验进行了模拟，得到了A508-3钢的脆-韧转变温度。结果表明:试样的破坏概率随应变的增大和温度的降低而增大;对于BDTT，无论是否存在辐照条件，数值结果与实验结果都非常吻合。此外，还观察到明显的辐照脆化现象。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Volume 15: Student Paper Competition

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