Prediction of Strain Gradient Hardening During Microextrusion

SUNAL AHMET PARASIZ; BRAD L. KINSEY

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Prediction of Strain Gradient Hardening During Microextrusion

机译：微挤压过程中应变梯度硬化的预测

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A new formulation is presented to predict the strain distribution through the thickness of the workpiece during forward extrusion. By using shear components, a new model is established to estimate the geometrically necessary dislocation density, which is found to increase with a decrease in the initial and final specimen diameters and an increase in the die angle. Also, strain gradient hardening during forward microextrusion is predicted according to the calculated geometrically necessary dislocation (GND) density. It is found that to experience a significant amount of strain gradient hardening, the diameter of the material should be on the order of 400μm or less.

机译：提出了一种新的公式来预测正向挤压过程中贯穿工件厚度的应变分布。通过使用剪切分量，建立了一个新的模型来估算几何上必要的位错密度，发现该位错密度随初始和最终试样直径的减小以及模具角的增大而增加。此外，根据计算出的几何必要位错（GND）密度，可以预测正向微挤压过程中的应变梯度硬化。发现要经历大量的应变梯度硬化，材料的直径应在400μm或更小的数量级。

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《Materials and Manufacturing Processes》 |2010年第9期|共8页
作者
SUNAL AHMET PARASIZ; BRAD L. KINSEY;
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正文语种 eng
中图分类工程材料学;
关键词
Analytical model; Extrusion; Microforming; Strain gradient hardening;

机译：分析模型挤压成形应变梯度硬化;
入库时间 2022-08-18 11:31:36

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1. 上限分析法预测棒材在挤压过程中的中心开裂缺陷 [J] . Amir PARGHAZEH, Heshmatollah HAGHIGHAT 中国有色金属学报（英文版） . 2016,第011期
2. 上限分析法预测棒材在挤压过程中的中心开裂缺陷 [J] . Amir PARGHAZEH, Heshmatollah HAGHIGHAT 中国有色金属学报：英文版 . 2016,第011期
3. Prediction of Strain Gradient Hardening During Microextrusion [J] . Sunal Ahmet Parasiza amp, Brad L. Kinseya* Materials and Manufacturing Processes . 2010,第8期

机译：微挤压过程中应变梯度硬化的预测
4. Tailoring a gradient nanostructured age-hardened aluminum alloy using high-gradient strain and strain rate [J] . Pingwei Xu, Hongyun Luo, Zhiyuan Han, Materials & design . 2015,第Nova15期

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机译：应变硬化和应变率硬化

Prediction of Strain Gradient Hardening During Microextrusion

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