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Simulating the Mechanical Response of Titanium Alloys Through the Crystal Plasticity Finite Element Analysis of Image-Based Synthetic Microstructures

机译：用图像合成微结构的晶体塑性有限元分析模拟钛合金的力学响应

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Micromechanical crystal plasticity finite element simulations of the response of synthetic titanium microstructures are carried out with the goal of quantifying the effect of microstructure on mechanical properties. Two separate materials are studied: (1) an alpha-Beta Ti-6Al-4V material and (2) a highly- textured, rolled lpha Ti-3Al-2.5V sheet material. Performing accurate finite element analyses begins with accurate image-based characterization of the morphological and crystallographic features of the materials at the microstructural scale. Then, statistically equivalent representative 3D microstructures are built and meshes are generated for crystal plasticity based finite element method (CPFEM) analysis. For the Ti-3Al-2.5V material, experimental results from the displacement controlled mechanical testing of dog bone shaped, rolled specimens are used for the calibration of elastic parameters as well as anisotropic crystal plasticity parameters. The inspection of micrographs of the rolled material showed elongated grain shapes which led to the updating of the crystal plasticity model to include grain aspect ratio dependence on the Hall-Petch size effect an update of a previous size effect model which assumed spherical grains. Model validation is achieved by comparing load controlled experimental results with simulated creep results. For the Ti- 6Al-4V material, the robust and validated analysis tool is used to perform sensitivity analyses and a quantitative understanding of how individual microstructural parameters affect the mechanical response properties of the alloy is developed. Functional dependencies are proposed that directly connect the metal's microstructural features to creep response, yield strength response, and tensile response.

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Thomas, J.;
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年度 2012
页码 1-103
总页数 103
原文格式 PDF
正文语种 eng
中图分类工业技术;
关键词
Crystallography ; Finite element analysis ; Plastic properties ; Titanium ; Accuracy ; Alloys ; Anisotropy ; Aspect ratio ; Calibration ; Control ; Creep ; Crystals ; Displacement ; Inspection ; Materials ; Mechanical properties ; Mesh ; Metals ; Microstructure ; Models ; Morphology ; Parameters ; Response ; Scale ; Sensitivity ; Simulation ; Tensile properties ; Test and evaluation ; Theses ; Tools ; Validation ; Yield strength;

机译：晶体学;有限元分析;塑性;钛;精度;合金;各向异性;纵横比;校准;控制;蠕变;晶体;位移;检验;材料;机械性能;网格;金属;微观结构;模型;形态学;参数;响应;尺度;灵敏度;模拟;拉伸性能;测试和评估;论文;工具;验证;屈服强度;

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1. A three-dimensional cellular automata-crystal plasticity finite element model for predicting the multiscale interaction among heterogeneous deformation, DRX microstructural evolution and mechanical responses in titanium alloys [J] . Li Hongwei, Sun Xinxin, Yang He International Journal of Plasticity . 2016,第Null期

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2. Effects of subgrain size and static recrystallization on the mechanical performance of polycrystalline material: A microstructure-based crystal plasticity finite element analysis [J] . Fengbo Han, Bin Tang, Hongchao Kou, 自然科学进展（英文版） . 2015,第001期

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Simulating the Mechanical Response of Titanium Alloys Through the Crystal Plasticity Finite Element Analysis of Image-Based Synthetic Microstructures

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