A lower bound damage-based finite element simulation of stretch flange forming of Al–Mg alloys

Cliff Butcher; Zengtao Chen; Michael Worswick

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A lower bound damage-based finite element simulation of stretch flange forming of Al–Mg alloys

机译：Al-Mg合金拉伸凸缘成形的基于损伤下界的有限元模拟

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Numerical simulation of stretch flange forming of Al–Mg sheet AA5182 was performed using the upper and lower bound constitutive models of Gurson–Tvergaard–Needleman (GTN) and Sun and Wang, respectively. Stress and strain-controlled nucleation rules are adopted for both models. The lower bound model of Sun and Wang has been extended to include the void coalescence criterion of Tvergaard and Needleman to form the so-called Sun–Tvergaard–Needleman (STN) model. Upper and lower bound formability predictions are combined to create a predictive formability band as actual formability lies between these limits. The resulting formability predictions are compared with experimental results and an appropriate void nucleation stress and strain suggested.

机译：分别使用Gurson-Tvergaard-Needleman（GTN）和Sun和Wang的上限和下限本构模型对Al-Mg薄板AA5182的拉伸凸缘成形进行了数值模拟。两种模型均采用应力和应变控制的成核规则。 Sun和Wang的下界模型已扩展到包括Tvergaard和Needleman的空隙合并准则，从而形成了所谓的Sun-Tvergaard-Needleman（STN）模型。当实际可成形性介于这些限制之间时，将上限和下限可成形性预测结合起来以创建可预测的可成形性带。将所得的可成形性预测与实验结果进行比较，并提出适当的空隙形核应力和应变。

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来源
《International Journal of Fracture》 |2006年第4期|289-298|共10页
作者
Cliff Butcher; Zengtao Chen; Michael Worswick;
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作者单位

Department of Mechanical Engineering University of New Brunswick Fredericton NB E3B 5A3 Canada;

Department of Mechanical Engineering University of New Brunswick Fredericton NB E3B 5A3 Canada;

Department of Mechanical and Mechatronics Engineering University of Waterloo Waterloo ON N2L 3G1 Canada;

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正文语种 eng
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关键词
Stretch flange; Lower bound; Predictive formability band; Sheet metal forming; Ductile fracture;

机译：拉伸法兰;下限;可预测成形带;金属板成形;韧性断裂;

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1. A lower bound damage-based finite element simulation of stretch flange forming of Al-Mg alloys [J] . Cliff Butcher, Zengtao Chen, Michael Worswick International Journal of Fracture . 2006,第3a4期

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2. Effect of micro-alloying elements on the stretch-flangeability of dual phase steel [J] . Jewoong Lee, Seok-Jae Lee, Bruno C.De Cooman Materials Science and Engineering . 2012,第Feba28期

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4. Finite Element Simulation and Control Method on Springback of Stretch Flanging in Rubber Forming [C] . Lei Chen, Yingwei Liu, Shanliang Li 2010 International Conference on Digital Manufacturing and Automation . 2010

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A lower bound damage-based finite element simulation of stretch flange forming of Al–Mg alloys

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