Numerical Investigation on Laser-Assisted Flow Forming Process

Ling Yan Sun; Chao Yang

doi:10.4028/www.scientific.net/KEM.620.29

Paper Titles

Modeling and Optimization of Laser Direct Joining Process Parameters of Titanium Alloy and Carbon Fiber Reinforced Nylon Based on Response Surface Methodology
p.3

Modeling and Optimization of Mask Assisted Laser Transmission Micro Joining Process
p.10

Experimental Research on Laser Transmission Micro-Joining Based on the Mask
p.17

Molten Depth Modeling of Laser Transmission Welding Based on Temperature Distribution of Moving Point Heat Source
p.23

Numerical Investigation on Laser-Assisted Flow Forming Process
p.29

Impact Analysis of the Force Environment on the KDP Crystal Harmonic Loss Considering the Frame Surface Topography
p.35

Experimental Study of Laser Direct Joining of Metal and Carbon Fiber Reinforced Nylon
p.42

Study of Form Control Algorithm in Atmospheric Pressure Plasma Processing
p.49

Influence of Cracking Damage on Deflection Basin Test Data of FWD
p.55

HomeKey Engineering MaterialsKey Engineering Materials Vol. 620Numerical Investigation on Laser-Assisted Flow...

Numerical Investigation on Laser-Assisted Flow Forming Process

Abstract:

Recent years laser-assisted manufacturing techniques are increasingly the focus of the automotive and aerospace industry due to cost price, low energy efficiency and safety. Among these techniques is laser-assisted flow forming process that combines laser beam technology with conventional flow forming process. During forming the material undergoes a rapidly heating and cooling cycles with the irradiative action of the laser beam, which is quite different from the traditional process. A transient three-dimensional model was developed to investigate the influence of laser irradiation on the forming process, in which a user-defined function was created to overcome the problem of a moving Gaussian heating source. The result indicates that a ring-shaped temperature field is acquired when the heating source scans workpiece along a thread; the deformation area on the workpiece during forming is extensively and continuously heated by intense laser radiation and the thermally induced loss of material strength significantly increases the formability concerning the achievable material reduction rate and tool service life; the possibility of accuracy improvement by laser assistance has been investigated and an accuracy error decreases 10%-28.5%.

You might also be interested in these eBooks

Manufacturing Automation Technology and System I

View Preview

Info:

Periodical:

Key Engineering Materials (Volume 620)

Pages:

29-34

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.620.29

Citation:

Cite this paper

Online since:

August 2014

Authors:

Ling Yan Sun, Chao Yang

Keywords:

Flow Forming Process, Laser-Assisted Mechanical Forming, Numerical Simulation, Sheet Metal Forming

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

References

[1] Y. Akihide, O. Moriaki: JFE Technical Report, Vol. 4 (2004) No. 4, pp.1-7.

Google Scholar

[2] I. Akinobu, U. Masaki and I. Toru: JFE Technical Report, Vol. 18 (2013) No. 4, pp.96-102.

Google Scholar

[3] Metallic Material Trends Fort North American Light Vehicles on http: /www. autosteel. org.

Google Scholar

[4] F. Klocke and A. Demmer: Proceedings of the 6th ICTP (Nürnberg, Germany, September 19 - 24, 1999). Vol. II, pp.1031-1042.

Google Scholar

[5] J. Mazumder and W. M. Steen: Journal of Applied Physics, Vol. 51 (1980) No. 2, pp.941-947.

Google Scholar

[6] P. Wriggers: Computational Contact Mechanics (John Wiley & Sons Ltd, American, 2002).

Google Scholar

[7] R. Patwa and Y. C. Shin: International Journal of Machine Tools and Manufacture, Vol. 47 (2007) No. 1, pp.14-22.

Google Scholar

[8] L.Y. Sun, B.Y. Ye and S.H. Hao: Journal of South China University Of Technology (Nature edition), Vol. 38 (2010) No. 2, pp.49-54.

Google Scholar

[9] O. Abdulghani, M. Sobih and A. Youssef: Modeling and Numerical Simulation of Material Science, Vol. 3 (2013), pp.106-113.

Google Scholar

[10] J. Cheng and Y.L. Yao: Journal of Manufacturing Processes, Vol. 3 (2001) No. 1, pp.60-72.

Google Scholar