Finite Element Analysis of Reinforcement Rocker Part Made from JAC780Y Steel Sheets

Aeksuwat Nakwattanaset; Surasak Suranuntchai

doi:10.4028/www.scientific.net/KEM.877.83

Paper Titles

Low-Cycle-Fatigue Properties of a 17-4 PH Stainless Steel Manufactured via Selective Laser Melting
p.55

Effect of Silane-Treated Wollastonite on Mechanical and Thermal Properties of 3D-Printed ABS via Fused Deposition Modeling
p.61

Silane-Treated Muscovite as Reinforcement for 3D-Printed ABS via Fused Deposition Modeling
p.67

Application of MIG Welding Process of Mild Steel Wire in Additive Manufacturing
p.73

Finite Element Analysis of Reinforcement Rocker Part Made from JAC780Y Steel Sheets
p.83

Welding Shape Control of Cross Member Backbone Assembly by Automatic Gas Metal Arc Yaskawa-MA1440 Type
p.90

Design and Simulation of Metal Oxide Gas Sensor for Breath Analyzer Application
p.96

Study of Ni²⁺/Ni³⁺ Redox Couple and Electrocatalytic Responses of Ni on Nitrogen-Doped Carbon for Urea Non-Enzymatic Detection
p.102

Effect of Antimony Trioxide and Carbon Black on the Mechanical Properties and Ablation Properties of Liner Insulation in Rocket Motors
p.108

HomeKey Engineering MaterialsKey Engineering Materials Vol. 877Finite Element Analysis of Reinforcement Rocker...

Finite Element Analysis of Reinforcement Rocker Part Made from JAC780Y Steel Sheets

Abstract:

The manufacturing industries for automotive parts aim to develop technologies for reducing vehicle weight in order to decrease fuel consumption. However, passive safety function for drivers and passengers must not be impaired or should be even improved. Therefore, advanced high strength steel sheet plays more and more important role in designing automotive components. Nowadays, prediction of formability for sheet metal stamping has high capability more than the past. The major challenge is springback prediction. Moreover, it assists in the tooling design to correctly compensate for springback. Especially in automotive production, springback effects have been generally exhibited distinct after forming process of the high strength steel sheets. The springback effect occurred in the deformed state of metal parts must be taken into account by designing any sheet metal panels. Then, the purpose of the present research is to investigate the springback phenomenon of an automotive part named Reinforcement Rocker RL made from an advanced high strength steel grade JAC780Y, after stamping. In addition, the tools design has been carried out. Finite Element (FE) program known as DYNAFORM (based on LS-DYNA solver), has been applied to analyze and improve the springback effect on such forming part. An anisotropic material model according to type 36 (MAT_036 3-PARAMETER_BARAT) was applied. The results obtained from simulations were compared with required parts in each section. Then, the die surface from compensation in 2nd step forming was modified to use. Finally, the simulation part was verified with the real stamping part. It was found that the finite element simulation showed high capability for prediction and compensation of springback in high strength steel sheets forming.

You might also be interested in these eBooks

Material and Manufacturing Technology XI

View Preview

Info:

Periodical:

Key Engineering Materials (Volume 877)

Pages:

83-89

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.877.83

Citation:

Cite this paper

Online since:

February 2021

Authors:

Aeksuwat Nakwattanaset, Surasak Suranuntchai*

Keywords:

Finite Element Analysis, JAC780Y Steel Sheets, Reinforcement Rocker Part, Springback, Stamping Dies Design

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

* - Corresponding Author

References

[1] World Auto Steel: Advanced High Strength Steel (AHSS) Application Guidelines Version 4.0,on http://www.worldautosteel.org.

Google Scholar

[2] U. Peter: High Stress for Stampers and Die Shops, Metal forming magazine, on http://www.Metalformingmagazine.com.

Google Scholar

[3] H. Takechi: Recent Progress in High Strength Steels for Automobile in Japan, on http://www.metal.citic.com/iwcm/UserFiles/img/cd/2005-HSLA-NB/HSLA-014.pdf.

Google Scholar

[4] M. TISZA, Advanced Materials in Sheet Metal Forming,, Key Engineering Materials, vol.581, 2014, pp.137-142.

DOI: 10.4028/www.scientific.net/kem.581.137

Google Scholar

[5] AutoSteel Partnership: High Strength Steel Stamping Design Manual, Michigan (2000).

Google Scholar

[6] A. Ali: Experimental & Numerical Study of Sidewall Curl in Advance High Strength Steel, Canada (2011).

Google Scholar

[7] M. Clarke, J. He and X. Zhu: A Real World Approach for using LS-DYNA to Achieve True Springback Compensation on AHSS Components During Forming, 7th European LS-DYNA Conference.

Google Scholar

[8] G. Chris, T. Dylan and F. Mark: Manufacturing Simulation of an Automotive Hood Assembly, 4th European LS-DYNA Conference.

Google Scholar

[9] S. Toros, A. Polat and F. Ozturk, Formability and springback characterization of TRIP800 advanced high strength steel,, Materials and Design, vol.41, 2012, p.298–305.

DOI: 10.1016/j.matdes.2012.05.006

Google Scholar

[10] 2015.1PAM-STAMP Manual, 2015 User's Guide.

Google Scholar

[11] F. Barlat and O. Richmond Prediction of tricomponent plane stress yield surfaces and associated flow and failure behaviour of strongly textured FCC polycrystalline sheets, Materials Science and Engineering, vol.91, 1987, p.15–29.

DOI: 10.1016/0025-5416(87)90494-0

Google Scholar

[12] LS-DYNA: Keyword User's Manual Version971 Volume 2: Material Models, Livermore Software Technology Corporation, Californial, USA (2007).

Google Scholar