Effect of initial blank temperature in hot press forming towards 22MnB5 springback failure

Authors

  • C. H. Ng Advance Forming Research Group (AFRG), Faculty of Mechanical and Manufacturing Engineering, Universiti Tun Hussein Onn Malaysia
  • C. F. Lai Advance Forming Research Group (AFRG), Faculty of Mechanical and Manufacturing Engineering, Universiti Tun Hussein Onn Malaysia
  • S. N. M. Yahaya Advance Forming Research Group (AFRG), Faculty of Mechanical and Manufacturing Engineering, Universiti Tun Hussein Onn Malaysia
  • S. Shamsudin Advance Forming Research Group (AFRG), Faculty of Mechanical and Manufacturing Engineering, Universiti Tun Hussein Onn Malaysia
  • S. N. A. S. Ahmad Faculty of Mechanical Engineering, Universiti Malaysia Pahang
  • F. Sharrifuddin Hot Press Forming Department, Miyazu (M) Sdn Bhd Phone: +6074537651; Fax: +6074536337

DOI:

https://doi.org/10.15282/jmes.13.2.2019.25.0422

Keywords:

Hot Press Forming, Ultra High Strength Boron Steel, Springback, ANSYS Workbench

Abstract

The springback failure of ultra-high strength boron steel (22MnB5) in hot press forming (HPF) process was characterized under bending and membrane conditions. Hot press forming for U–shaped parts with ultra-high strength boron steel were experimented and simulated to study the effect of initial blank temperatures on springback failure in the automotive industry. The results specify the various preheated temperature of 22MnB5 blank effect toward springback occurrences with reference to hot press forming dies design. ANSYS Workbench was used to verify finite element (FE) simulations of the processes in order to consolidate the knowledge of springback. The validated numerical simulation model were used in analyzing the stress and strain distributions along the formed part in the FE models, it was found that the springback angle was related in averaging value throughout quenching, regardless of the forming conditions. Springback failure mainly caused dimension deviation in hot press form parts due to the impact of thermal restoring moments and quenching rate of hot press forming process.

References

Merklein M, Wieland M, Lechner M, Bruschi S, Ghiotti A. Hot stamping of boron steel sheets with tailored properties: a review. Journal of Materials Processing Technology. 2016;228:11–24.

Ng CH, Yahaya SN, Lai CF, Grote KH. Reviews on the Forming Process of Heat Treatable Aluminium Alloys. International Journal of Integrated Engineering. 2018;10:74–9.

Zhao K, Chang Y, Hu P, Wu Y. Influence of rapid cooling pretreatment on microstructure and mechanical property of hot stamped AHSS part. Journal of Materials Processing Technology. 2016;228:68–75.

Venturato G, Novella M, Bruschi S, Ghiotti A, Shivpuri R. Effects of Phase Transformation in Hot Stamping of 22MnB5 High Strength Steel. Procedia Engineering. 2017;183:316-21.

Bardelcik A, Salisbury CP, Winkler S, Wells MA, Worswick MJ. Effect of cooling rate on the high strain rate properties of boron steel. International Journal of Impact Engineering. 2010;37(6):694–702.

Mulyana T, Rahim EA, Yahaya SNM. The influence of cryogenic supercritical carbon dioxide cooling on tool wear during machining high thermal conductivity steel. Journal of Cleaner Production. 2017;164:950–62.

Tisza M. Recent development trends in sheet metal forming. International Journal of Microstructure and Materials Properties. 2013;8(1/2):125–40.

Aziz N, Aqida SN. Optimization of quenching process in hot press forming of 22MnB5 steel for high strength properties for publication in. IOP Conference Series: Material Science and Engineering. 2013;50(1).

Edmonds D V, He K, Rizzo FC, De Cooman BC, Matlock DK, Speer JG. Quenching and partitioning martensite—A novel steel heat treatment. Material Science and Engineering A. 2006;438:25–34.

Pourboghrat F, Chu E. Springback in plane strain stretch/draw sheet forming. International Journal of Mechanical Sciences. 1995;37(3):327–41.

Chen K, Lin JP, Lv MK, Wang LY. Advanced High Strength Steel Sheet Forming and Springback Simulation. In: Advanced Materials Research. Trans Tech Publications; 2010. p. 200–3.

Billur E, Makine B. Challenges in Forming Advanced High Strength Steels. Proceedings of New Developments in Sheet Metal Forming. 2012; 285-304 .

Abdullah SA, Buang MS, Saedon J, Abdullah H. Design Parameters Selection of Springback Effect in Air-V Bending Using Taguchi Approach On Advance High Strength Steel-DP590. Jurnal Teknologi. 2015;76:69–73.

Adnan AF, Abdullah AB, Samad Z. Study of springback pattern of non-uniform thickness section based on V-bending experiment. Journal of Mechanical and Sciences. 2017;11(3):2845–55.

Ouakdi EH, Louahdi R, Khirani D, Tabourot L. Evaluation of springback under the effect of holding force and die radius in a stretch bending test. Materials & Design. 2012;35:106–12.

Panthi SK, Hora MS, Ahmed M. Artificial neural network and experimental study of effect of velocity on springback in straight flanging process. 2016;23:159-164.

Subramonian S, Altan T, Campbell C, Ciocirlan B. Determination of forces in high speed blanking using FEM and experiments. Journal of Material Processing Technology. 2013;213(12):2184–90.

Thipprakmas S, Komolruji P. Analysis of bending mechanism and spring-back characteristics in the offset Z-bending process. The International Journal of Advanced Manufacturing Technology. 2016;85(9–12):2589–96.

Zhou J, Wang BY, Lin JG, Fu L, Ma WY. Forming defects in aluminum alloy hot stamping of side-door impact beam. Transactions of Nonferrous Metal Society of China. 2014;24(11):3611–20.

Xing ZW, Bao J, Yang YY. Numerical simulation of hot stamping of quenchable boron steel. Materials Science and Engineering: A. 2009;499(1–2):28–31.

Trzepiecinski T, Lemu HG. Effect of Computational Parameters on Springback Prediction by Numerical Simulation. Metals (Basel). 2017;7(9):380.

Sulaiman AS. Finite element modelling and characterisation of springback and drawability in aluminium-based alloy. University of Birmingham; 2005.

Trzepiecinski T, Lemu HG. Prediction of springback in V-die air bending process by using finite element method. In: MATEC Web of Conferences, p. 3023; 2017.

Buang MS, Abdullah SA, Saedon J. Effect of die and punch radius on springback of stainless steel sheet metal in the air v-die bending process. Journal of Mechanical Engineering and Sciences . 2015;8:1322–31.

Güler H. Investigation of usibor 1500 formability in a hot forming operation. Mater Sci. 2013;19(2):144–6.

Hu P, Ying L, He B. Hot Stamping Advanced Manufacturing Technology of Lightweight Car Body. 2017;19–45.

Karbasian H, Tekkaya AE. A review on hot stamping. Journal of Materials Processing Technology. 2010;210(15):2103–18.

Tisza M. Hot Forming of Boron Alloyed Manganese Steels. In: Materials Science Forum, p. 25–30; 2017.

Altan T, Tekkaya AE. Sheet metal forming: fundamentals. Asm International; 2012.

Mori K, Bariani PF, Behrens BA, Brosius A, Bruschi S, Maeno T, et al. Hot stamping of ultra-high strength steel parts. CIRP Annals - Manufacturing Technology. 2017;66(2):755–77.

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Published

2019-06-28

How to Cite

[1]
C. H. Ng, C. F. Lai, S. N. M. Yahaya, S. Shamsudin, S. N. A. S. Ahmad, and F. Sharrifuddin, “Effect of initial blank temperature in hot press forming towards 22MnB5 springback failure”, J. Mech. Eng. Sci., vol. 13, no. 2, pp. 5137–5149, Jun. 2019.

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