Material modeling for multistage tube hydroforming process simulation.

机译：用于多级管液压成型过程仿真的材料建模。

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The Aerospace industries of the 21st century demand the use of cutting edge materials and manufacturing technology. New manufacturing methods such as hydroforming are relatively new and are being used to produce commercial vehicles. This process allows for part consolidation and reducing the number of parts in an assembly compared to conventional methods such as stamping, press forming and welding of multiple components. Hydroforming in particular, provides an endless opportunity to achieve multiple crosssectional shapes in a single tube. A single tube can be pre-bent and subsequently hydroformed to create an entire component assembly instead of welding many smaller sheet metal sections together. The knowledge of tube hydroforming for aerospace materials is not well developed yet, thus new methods are required to predict and study the formability, and the critical forming limits for aerospace materials.;In order to have a better understanding of the formability and the mechanical properties of aerospace materials, a novel online measurement approach based on free expansion test is developed using a 3D automated deformation measurement system (AramisRTM) to extract the coordinates of the bulge profile during the test. These coordinates are used to calculate the circumferential and longitudinal curvatures, which are utilized to determine the effective stresses and effective strains at different stages of the tube hydroforming process.;In the second step, two different methods, a weighted average method and a new hardening function are utilized to define accurately the true stress-strain curve for post-necking regime of different aerospace alloys, such as inconel 718 (IN 718), stainless steel 321 (SS 321) and titanium (Ti6Al4V). The flow curves are employed in the simulation of the dome height test, which is utilized for generating the forming limit diagrams (FLDs).;Then, the effect of stress triaxiality, the stress concentration factor and the effective plastic strain on the nucleation, growth and coalescence of voids are investigated through a new user material for burst prediction during tube hydroforming. A numerical procedure for both plasticity and fracture is developed and implemented into 3D explicit commercial finite element software (LS-DYNA) through a new user material subroutine. The FLDs and predicted bursting pressure results are compared to the experimental data to validate the models.;Finally, the new user material model is used to predict the bursting point of some real tube hydroforming parts such as round to square and round to V parts. Then, the predicted bursting pressure results are compared to the experimental data to validate the models in real and multistep tube hydroforming processes.

机译：21世纪的航空航天业要求使用最先进的材料和制造技术。诸如液压成形的新制造方法是相对较新的，并且被用于生产商用车辆。与传统方法（例如冲压，冲压成型和焊接多个组件）相比，此过程可实现零件固结并减少装配中零件的数量。特别地，液压成形为在单个管中获得多个横截面形状提供了无限的机会。可以预弯单个管，然后液压成形以形成整个组件，而不是将许多较小的钣金件焊接在一起。航空航天材料的管液压成形的知识尚未得到很好的发展，因此需要新的方法来预测和研究航空航天材料的可成形性以及关键的成形极限。为了更好地理解可成形性和机械性能针对航空航天材料，使用3D自动变形测量系统（AramisRTM）开发了基于自由膨胀测试的新颖在线测量方法，以在测试过程中提取凸起轮廓的坐标。这些坐标用于计算周向和纵向曲率，用于确定管液压成型过程不同阶段的有效应力和有效应变。第二步，两种不同的方法，加权平均法和新的硬化法利用函数，可以准确地定义不同航空航天合金（如因科镍合金718（IN 718），不锈钢321（SS 321）和钛（Ti6Al4V））的颈缩后状态的真实应力-应变曲线。流动曲线用于圆顶高度测试的仿真中，用于生成成形极限图（FLD）。然后，应力三轴性，应力集中系数和有效塑性应变对成核，生长的影响通过一种新的用户材料研究孔洞的聚结，以预测管材液压成形期间的爆裂。通过新的用户材料子例程，开发了可塑性和断裂的数值程序，并将其实施到3D显式商业有限元软件（LS-DYNA）中。将FLD和预测的爆破压力结果与实验数据进行比较，以验证模型。最后，使用新的用户材料模型来预测某些真实的管液压成型零件的爆破点，例如，圆角到圆角和圆角到V形零件。然后，将预测的爆破压力结果与实验数据进行比较，以验证实际和多步管液压成型过程中的模型。

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作者
Saboori, Mehdi.;
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作者单位

Ecole de Technologie Superieure (Canada).;

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授予单位 Ecole de Technologie Superieure (Canada).;
学科 Mechanical engineering.;Aerospace engineering.
学位 D.Eng.
年度 2015
页码 192 p.
总页数 192
原文格式 PDF
正文语种 eng
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1. The effect of tube material, microstructure, and heat treatment on process responses of tube hydroforming without axial force [J] . A. Fatemi, M. R. Morovvati, F. R. Biglari The International Journal of Advanced Manufacturing Technology . 2013,第1a4期

机译：管材料，微观结构和热处理对无轴向力的管液压成形工艺响应的影响
2. Part 2:Analytical modeling of regular planar polygon tube hydroforming as a special case of symmetric multi-nose tube hydroforming [J] . Bandar Alzahrani, Gracious Ngaile Journal of Manufacturing Processes . 2013,第2期

机译：第2部分：作为对称多鼻管液压成形的特例的规则平面多边形管液压成形的分析模型
3. Experimental characterization and inverse constitutive parameters identification of tubular materials for tube hydroforming process [J] . Temim Zribi, Ali Khalfallah, Hedi BelHadjSalah Materials & design . 2013,第auga期

机译：管材液压成型工艺的管状材料的实验表征和逆本构参数辨识
4. Tube and Sheet Hydroforming-Advances in Material Modeling, Tooling and Process Simulation [C] . T. Altan, H. Palaniswamy, Y. Aue-u-Ian International Conference on Sheet Metal; 20050405-08; Erlangen-Nuremberg(DE) . 2005

机译：管和板的液压成型-材料建模，工装和工艺仿真方面的进展
5. Process Control Modeling and Real-Time Error Compensation in Tube Hydroforming. [D] . Kilonzo, Obadiah Mutisya. 2010

机译：管液压成型中的过程控制建模和实时误差补偿。
6. A value-added multistage utilization process for the gradient-recovery tin iron and preparing composite phase change materials (C-PCMs) from tailings [O] . Zijian Su, Yikang Tu, Xijun Chen, -1

机译：梯度回收锡铁并从尾矿制备复合相变材料（C-PCM）的增值多级利用工艺
7. Material modeling for multistage tube hydroforming process simulation [O] . Saboori Mehdi 2015

机译：多级管液压成形过程模拟的材料建模

Material modeling for multistage tube hydroforming process simulation.

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