Understanding a new wrinkling behavior of annular grooved panel during flexible free incremental sheet forming

IF 6.7 2区 材料科学 Q1 ENGINEERING, INDUSTRIAL
Zhidong Chang , Mei Yang , Yongbing Li , Jun Chen
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Abstract

Wrinkling behavior of sheet metal by inappropriate process parameters and the resultant variation of thickness and microstructure during incremental sheet forming (ISF) have significant impact on forming stability and geometric profile. The wrinkling-related mechanism is yet to be well understood, which make it difficult to effectively control wrinkling defects during ISF. In the present work, the wrinkling behavior and related mechanism of a typical annular grooved panel are investigated during a novel flexible free ISF process. Experiments demonstrate that during this ISF process, the sheet material sequentially undergoes 4 deformation modes: contacting state under plane strain condition, contracting state with only elastic deflection, thickening state under uniaxial compression condition, and wrinkling state where the circumferential compressive stress exceeds the critical wrinkling stress. The evolution of these deformation modes is dominantly caused by the increasing of edge contraction and circumferential stress, which are induced by the bending moment from the forming tool and auxiliary sheets. Based on the mechanism, an analytical model is developed to predict the wrinkling behavior, by which the corresponded sheet thickness, bending moment, circumferential compressive stress and critical wrinkling stress during the wrinkling process could be comprehensively calculated. Experimental results validate that the analytical model can accurately predict the wrinkling behavior under different process parameters, material properties and auxiliary sheet materials. Through microstructural characterization, numerical simulation and analytical modeling, the influence of process parameter and material property on wrinkling behavior is systematically investigated, along with the variation of sheet thickness and microstructure under different wrinkling modes. This work enhance a deep understanding of wrinkling behavior during ISF process, thereby providing effective methods for process optimization and quality improvement.
了解柔性自由增量板材成型过程中环形槽板的新起皱行为
在增量板材成形(ISF)过程中,不适当的工艺参数会导致板材起皱,由此产生的厚度和微观结构变化会对成形稳定性和几何轮廓产生重大影响。与起皱相关的机理尚待深入了解,因此很难在 ISF 过程中有效控制起皱缺陷。在本研究中,我们研究了一种新型柔性自由 ISF 工艺中典型环形沟槽面板的起皱行为和相关机理。实验证明,在 ISF 过程中,板材会依次经历 4 种变形模式:平面应变条件下的接触状态、仅有弹性挠度的收缩状态、单轴压缩条件下的增厚状态以及周向压应力超过临界起皱应力的起皱状态。这些变形模式的演变主要是由成型工具和辅助板材的弯矩引起的边缘收缩和周向应力增加造成的。根据这一机理,建立了预测起皱行为的分析模型,从而可以全面计算起皱过程中相应的板材厚度、弯矩、周向压应力和临界起皱应力。实验结果验证了该分析模型能准确预测不同工艺参数、材料特性和辅助板材材料下的起皱行为。通过微观结构表征、数值模拟和分析模型,系统地研究了工艺参数和材料特性对起皱行为的影响,以及不同起皱模式下板材厚度和微观结构的变化。这项研究加深了对 ISF 工艺中起皱行为的理解,从而为工艺优化和质量改进提供了有效方法。
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来源期刊
Journal of Materials Processing Technology
Journal of Materials Processing Technology 工程技术-材料科学:综合
CiteScore
12.60
自引率
4.80%
发文量
403
审稿时长
29 days
期刊介绍: The Journal of Materials Processing Technology covers the processing techniques used in manufacturing components from metals and other materials. The journal aims to publish full research papers of original, significant and rigorous work and so to contribute to increased production efficiency and improved component performance. Areas of interest to the journal include: • Casting, forming and machining • Additive processing and joining technologies • The evolution of material properties under the specific conditions met in manufacturing processes • Surface engineering when it relates specifically to a manufacturing process • Design and behavior of equipment and tools.
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