Tool Wear in Sheet Metal Stamping

Wen Yi Yan; Michael P. Pereira; Bernard F. Rolfe

doi:10.4028/www.scientific.net/AMR.421.750

Paper Titles

A Probe into the Interesting Design of Products
p.728

Collaborative Work Heterogeneous Data Sharing and Application Based on Petri Net
p.732

Numerical Simulation of Acoustic Field for the Miniature Cylindrical Transducer with a Rectangular Hole
p.739

An Error Compensation Method for Structural Responses and Sensitivities
p.743

Tool Wear in Sheet Metal Stamping
p.750

Development of Small-Efficient Tool for Ultrasonic Reactor
p.754

Structural Parameters Optimization of Excavator Working Device Based on Mining Process
p.759

Conceptual Design for Degreasing Pill Machine Based on TRIZ
p.764

Driving Force and Process Model of Technological System Evolution
p.770

HomeAdvanced Materials ResearchAdvanced Materials Research Vol. 421Tool Wear in Sheet Metal Stamping

Tool Wear in Sheet Metal Stamping

Abstract:

This paper discusses our recent research on wear at the die radius in sheet metal stamping. According to wear theory, contact pressure and sliding distance are the two dominant factors in determining sliding wear. We applied the finite element analysis to accurately quantify the contact pressure and sliding distance at the die radius in sheet metal stamping. The results were then applied to analyze sliding wear at the die radius. We found that a typical two-peak steady-state contact pressure response exists during a channel forming process. The steady-state contact pressure response was preceded by an initial transient response, which produced extremely large and localized contact pressures. We proposed a method to numerically quantify the sliding distance, which was applied to examine the contact sliding distance at the die radius. Correlating the contact pressure and sliding distance, a new insight into the wear/galling that occurs at the die radius in sheet metal stamping was gained. The results show that the region close to zero degrees on the die radius is likely to experience the most wear, with the identified transient stage contributing to a large proportion of the total wear.

You might also be interested in these eBooks

View Preview

Info:

Periodical:

Advanced Materials Research (Volume 421)

Pages:

750-753

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.421.750

Citation:

Cite this paper

Online since:

December 2011

Authors:

Wen Yi Yan, Michael P. Pereira, Bernard F. Rolfe

Keywords:

Contact Pressure, Sheet Metal Stamping, Sliding Distance, Wear

Export:

RIS, BibTeX

Price:

Permissions:

Request Permissions

References

[1] S. K. Rhee: Wear 16 (1970), p.431.

Google Scholar

[2] R. G. Bayer: Wear 162-164 (1993), p.913.

Google Scholar

[3] J. F. Archard: J. Appl. Phys. 24 (1953), p.981.

Google Scholar

[4] W. Yan, E. P. Busso and N. P. O'Dowd: Proc. R. Soc. Lond. A. 456 (2000), p.2387.

Google Scholar

[5] W. Yan: J Mater. Sci. Eng. A. 427 (2006), p.348.

Google Scholar

[6] M.P. Pereira, W. Yan, B.F. Rolfe: Wear 265 (2008), p.1687.

Google Scholar

[7] M.P. Pereira, J.L. Duncan, W. Yan, B.F. Rolfe: J. Mater. Process. Technol. 209 (2009), p.3532.

Google Scholar

[8] M.P. Pereira, W. Yan, B.F. Rolfe: Wear 268 (2010), p.1275.

Google Scholar

[9] O. Sandberg, P.-Å. Bustad, B. Carlsson, M. Fällström and T. Johansson, in: Pro. Int. Conf. Recent Adv. in Man. & Use of Tools & Dies and Stamping of Steel Sheets, 2004, p.151.

Google Scholar

[10] T. Skåre and F. Krantz: Wear 255 (2003), p.1471.

Google Scholar

[11] K. Hanaki and K. Kato: Adv. Technol. Plasticity. 1 (1984), p.581.

Google Scholar