Understanding formability of extra-deep drawing steel at elevated temperature using finite element simulation

Swadesh Kumar Singh; rnK. Mahesh; rnApurv Kumar; rnM. Swathi

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Understanding formability of extra-deep drawing steel at elevated temperature using finite element simulation

机译：使用有限元模拟了解超深拉伸钢在高温下的可成形性

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Deep drawing involves conversion of flat thin sheet metal blanks into parts of desired shape. Although applications of deep drawing processes at elevated temperatures (warm forming) have not yet been used effectively nowadays, it is clear that it is going to be a very important manufacturing application in the future. Warm deep drawing process of circular blanks is investigated using a 20 T hydraulic press and a finite element model coupled with thermal analysis. The present work is aimed to investigate the limiting draw ratio (LDR) and the coefficient of friction of extra-deep drawing (EDD) steels at room temperature and at 200 ℃. Simulation and experimental results showed an increase in the LDR as the temperature increases and the coefficient of friction was estimated by comparing the simulation and experimental load-displacement curve. Finite element simulation results were in good agreement with the experimental results.

机译：深冲涉及将扁平的薄金属板坯料转变成所需形状的零件。尽管如今在高温下（热成型）深冲工艺的应用尚未得到有效利用，但是很明显，它将在将来成为非常重要的制造应用。使用20 T液压机和有限元模型以及热分析研究了圆形毛坯的热深拉伸过程。本工作旨在研究室温和200℃下极限拉伸比（LDR）和超深拉伸（EDD）钢的摩擦系数。仿真和实验结果表明，随着温度的升高，LDR会增加，并且通过比较仿真和实验载荷-位移曲线可以估算出摩擦系数。有限元模拟结果与实验结果吻合良好。

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《Materials & design》 |2010年第9期|P.4478-4484|共7页
作者
Swadesh Kumar Singh; rnK. Mahesh; rnApurv Kumar; rnM. Swathi;
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Dept. of Mechanical Engineering, GRIET, Bachupally, Hyderabad, AP 500 072, India;

Dept. of Metallurgy and Materials Engineering, IIT Madras, Chennai 600 036, India;

Dept of Mechanical Engineering, IIT Madras, Chennai 600 036, India;

Dept. of Mechanical Engineering, JNTUH, Hyderabad, AP 500 072, India;

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1. Research on Finite Element Simulation of Direct Redrawing Process of Extra Deep Drawing (EDD) Steel at Elevated Temperatures [J] . Kalavala Sai Kiran Reddy American Journal of Mechanical and Materials Engineering . 2017,第1期

机译：高温下超深拉伸（EDD）钢直接再拉伸过程的有限元模拟研究
2. Finite element simulation on deep-drawing process of magnesium alloy sheet at elevated temperatures [J] . Shi-Hong Zhang, Kun Zhang, Chuan-Fu Yu, International Journal of Vehicle Design . 2005,第1a2期

机译：镁合金板材高温拉伸过程的有限元模拟
3. Analysis and simulation on fracture of structural steel at elevated temperatures based on extended finite element method [J] . Cai Wenyu, Jiang Jian, Li Guo-Qiang Fire Safety Journal . 2021,第Mara期

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4. 2D finite-element modelling of stainless steel cold-formed RHS subjected to elevated temperatures [C] . O. Salem, O. El-Husseiny, E. Matar, Tubular structures XIV . 2012

机译：高温下不锈钢冷弯RHS的2D有限元建模
5. Finite element modal formulation for panel flutter at hypersonic speeds and elevated temperatures. [D] . Cheng, Guanfeng. 2002

机译：在超音速和高温下，面板颤振的有限元模态公式。
6. Modelling of the material flow of Nd-Fe-B magnets under high temperature deformation via finite element simulation method [O] . Yen-Ju Chen, Yen-I Lee, Wen-Cheng Chang, 2017

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7. Mechanical properties of various concrete after high temperature exposure Mechanical property of various types of concrete after high temperature exposure is investigated. Considering compressive strength requirement for a vertical element in high rise building, concrete specimens with various design strengths of 35, 80, 100, and 150 MPa were tested. Particularly, the influence of incorporated steel fiber on fire resistance is of interest in this study. Experimental results show that the fire resistance depends on the design strength and steel fiber content. Normal strength concrete (NSC) of a design strength of 35 MPa or high performance concrete (HPC) of 80-100 MPa does not spall when exposed to 100-400 °C of temperature. However, an explosive spalling occurs at 300 °C when the HPCs contain 1 vol. of steel fiber. Ultra-high performance concrete (UHPC) of a design strength of 150 MPa and 1.5 vol. of steel fiber also shows dramatic spalling at 300 °C. The experimental results found in this study can contribute to a better understanding of the behaviors of HPC and UHPC under fire and the role of steel fiber on the fire resistance. [O] . 2017

机译：研究了高温暴露后各种混凝土高温曝光机械性能各种混凝土的机械性能。考虑到高层建筑中垂直元件的抗压强度要求，测试了35,80,100和150MPa各种设计强度的混凝土试样。特别是，在这项研究中，掺入钢纤维对耐火性的影响。实验结果表明，耐火性取决于设计强度和钢纤维含量。在暴露于100-400°C的温度时，80-100MPa的设计强度为35MPa或高性能混凝土（HPC）的正常强度混凝土（NSC）不会击落。然而，当HPC含有1体积的钢纤维的百分比时，爆炸性剥落发生在300℃。超高性能混凝土（UHPC）的设计强度为150 MPa和1.5 Vol。钢纤维的百分比也显示出300℃的剧烈剥落。本研究中发现的实验结果可以有助于更好地了解在火灾中的HPC和UHPC的行为以及钢纤维对耐火性的作用。

Understanding formability of extra-deep drawing steel at elevated temperature using finite element simulation

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