Crystal plasticity model for creep and relaxation deformation of OFP copper

IF 1 4区材料科学 Q4 MATERIALS SCIENCE, MULTIDISCIPLINARY

Materials at High Temperatures Pub Date : 2023-11-06 DOI:10.1080/09603409.2023.2278232

Tom. Andersson, Matti. Lindroos, Rami. Pohja, Abhishek. Biswas, Supriya. Nandy, Janne. Pakarinen, Juhani. Rantala

引用次数: 0

Abstract

We demonstrate a dislocation density-based crystal plasticity (CP) model approach for simulating mesoscale deformation and damage. The existing CP framework is extended to be compatible with the oxygen-free phosphorous copper microstructure that is the focus of this study. The key aim is to introduce relevant plastic deformation mechanisms and to develop a failure model capable of depicting creep damage in the material. The effect of local variations in material is evaluated, and the model response is compared with experiments and characterisation. The basis of this work is CP material modelling, including grain orientation and size, obtained using electron backscatter diffraction and experimental test data of real relaxation test specimens. This will yield a realistic description of texture and grain shape and, ultimately, accurate stress–strain response at the microstructural level for further evaluation of performance with respect to material creep(−fatigue) damage.

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OFP铜蠕变松弛变形的晶体塑性模型

我们展示了一种基于位错密度的晶体塑性(CP)模型方法，用于模拟中尺度变形和损伤。现有的CP框架被扩展为与无氧磷铜微观结构兼容，这是本研究的重点。主要目的是介绍相关的塑性变形机制，并开发一种能够描述材料蠕变损伤的失效模型。评估了材料局部变化的影响，并将模型响应与实验和表征进行了比较。本工作的基础是利用电子背散射衍射和真实弛豫试样的实验测试数据获得的CP材料模型，包括晶粒取向和尺寸。这将产生对纹理和晶粒形状的真实描述，并最终在微观结构水平上准确地进行应力应变响应，从而进一步评估材料蠕变(-疲劳)损伤的性能。

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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来源期刊

Materials at High Temperatures 工程技术-材料科学：综合

CiteScore

1.90

自引率

15.40%

发文量

审稿时长

>12 weeks

期刊介绍： Materials at High Temperatures welcomes contributions relating to high temperature applications in the energy generation, aerospace, chemical and process industries. The effects of high temperatures and extreme environments on the corrosion and oxidation, fatigue, creep, strength and wear of metallic alloys, ceramics, intermetallics, and refractory and composite materials relative to these industries are covered. Papers on the modelling of behaviour and life prediction are also welcome, provided these are validated by experimental data and explicitly linked to actual or potential applications. Contributions addressing the needs of designers and engineers (e.g. standards and codes of practice) relative to the areas of interest of this journal also fall within the scope. The term ''high temperatures'' refers to the subsequent temperatures of application and not, for example, to those of processing itself. Materials at High Temperatures publishes regular thematic issues on topics of current interest. Proposals for issues are welcomed; please contact one of the Editors with details.