Numerical simulation for creep age forming of aluminium alloy 7050 saddle-shaped part

机译：铝合金7050鞍形部件蠕变年龄成型数值模拟

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Unified creep-ageing constitutive equations for aluminium alloy 7050 (AA7050) determined from experimental data were implemented into the finite element (FE) code, ABAQUS, through the user-defined subroutine, CREEP, for creep age forming (CAF) process modelling. The outer contour and yield strength of a saddle-shaped component were predicted, and the accuracy of FE prediction was analysed with experimental results. The research results show that, stress relaxation and creep deformation occur mainly in the early stage of the CAF process. A close agreement has been achieved between the simulation results and measurement data for the formed shape. More than 90% of the area has a surface gap less than 0.5 mm, and the relative error of the yield strength is between -1.18% and +7.22%, which prove the validity of the numerical computation.

机译：从实验数据确定的铝合金7050（AA7050）的统一蠕变构成方程被实施到有限元（FE）代码，ABAQU，通过用户定义的子程序蠕变，用于蠕变年龄形成（CAF）过程建模。预测鞍形部件的外轮廓和屈服强度，用实验结果分析了Fe预测的精度。研究结果表明，压力松弛和蠕变变形主要发生在CAF过程的早期阶段。在形成形状的模拟结果和测量数据之间实现了密切的协议。该区域的超过90％的表面间隙小于0.5mm，屈服强度的相对误差介于-1.18％和+ 7.22％之间，证明了数值计算的有效性。

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《International Conference on the Technology of Plasticity》|2018年|800 p.|共6页
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Fenggong Lyu; Xia Huang; Yuansong Zeng;
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中图分类工程塑性力学、工程弹性力学;
关键词
aluminium alloy 7050; creep age forming; constitutive model; numerical simulation; springback; yield strength;

机译：铝合金7050;蠕变年龄形成;本构模型;数值模拟;回弹;屈服强度;

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专利

1. Experimental studies and FEM analysis on the creep age forming for aluminium alloy 7050 [J] . Xia Huang, Yuansong Zeng, Pentao Gai Materials science forum . 2014,第期

机译：7050铝合金蠕变时效成形的实验研究与有限元分析
2. Constitutive modelling of creep-ageing behaviour of peak-aged aluminium alloy 7050 [J] . Yo-Lun Yang1a, Aaron C. L. Lam1, Zhusheng Shi1, MATEC Web of Conferences . 2015,第2015期

机译：峰值时效铝合金7050蠕变时效行为的本构模型
3. Constitutive modelling of creep-ageing behaviour of peak-aged aluminium alloy 7050 [J] . Yo-Lun Yang1a, Aaron C. L. Lam1, Zhusheng Shi1, MATEC Web of Conferences . 2015,第2015期

机译：峰值时效铝合金7050蠕变时效行为的本构模型
4. Numerical simulation for creep age forming of aluminium alloy 7050 saddle-shaped part [C] . Fenggong Lyu, Xia Huang, Yuansong Zeng International Conference on the Technology of Plasticity . 2018

机译：铝合金7050鞍形部件蠕变年龄成型数值模拟
5. Systematic Analysis of the Advantages of Stationary Shoulder Friction Stir Welding in Joining High Strength Aluminium Alloy AA7050-T7651 [D] . Wu, Hao. 2017

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7. Numerical simulation for creep age forming of aluminium alloy 7050 saddle-shaped part [O] . Lyu, F, Huang, X, Zeng, Y, 2017

机译：7050铝合金鞍形件蠕变时效成形数值模拟
8. EFFECTS OF CRACK PLANE ORIENTATION TRANSITIONS ON FLIGHT SIMULATION FATIGUE CRACK PROPAGATION IN A HIGH STRENGTH ALUMINIUM ALLOY (7050) [R] . R. J. H. Wanhill, L. Schra 1978

机译：裂纹面取向转变对高强度铝合金飞行模拟疲劳裂纹扩展的影响（7050）

Numerical simulation for creep age forming of aluminium alloy 7050 saddle-shaped part

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