For Libraries For Publication Open Access Downloads About Us Contact Us
Paper Titles
Study on Surface Roughness Transformation during Metal Rolling
p.2517
Antifouling Stainless Steel Surface: Competition between Roughness and Surface Energy
p.2523
Improving Releasability of Mold Materials for IC Encapsulation Using Epoxy Compounds
p.2529
Preliminary Study on the Fretting Wear Reliability of an Annular Nuclear Fuel
p.2535
Effect of Surface Hard Layer and Forging Conditions on the Resistance of Plastic Deformation of Hot Forging Tools
p.2540
Superhydrophobic RTV Silicone Rubber Coatings on Anodized Aluminium Surfaces
p.2546
Laser Cladding of Nickel Alloy with Ceramic Nanopowder on Steel as Coating in Corrosive Media
p.2552
Oxidation Resistance and Self Hardening of CrAlN/BN Nanocomposite Coatings
p.2559
Mechanical Properties Enhancement of High Reliability Metallic Materials by Laser Shock Processing
p.2565

Effect of Surface Hard Layer and Forging Conditions on the Resistance of Plastic Deformation of Hot Forging Tools

Article Preview

Abstract:

Tool damages including plastic deformation and wear are affected by forging load, thermal load and frictional slide applied to tool surface. Plastic deformation of forging tools proceeds in the tool corer owing to elevated temperature, high contact pressure and severe frictional slide. Hard layers on the tool surface increase plastic deformation resistance and thermal resistance. The optimal design of hard layer structure reduces the tool damage and improves tool life. Temperature and equivalent strain of forging tools are influenced by friction shear factor, contact thermal conductance and contact time between the tool and the workpiece. At the friction shear factor of less than 0.4, equivalent strain of the tool is reduced. At the friction shear factor of approximately 0.4 or greater, equivalent strain increases sharply and concentrates in the vicinity of the surface hard layer. This tendency becomes more significant when the contact time between the tool and the workpiece increases. Equivalent strain is reduced by low workpiece temperature.

You might also be interested in these eBooks
THERMEC 2011 View Preview

Info:

Periodical:

Materials Science Forum (Volumes 706-709)

Pages:

2540-2545

DOI:

https://doi.org/10.4028/www.scientific.net/MSF.706-709.2540

Citation:

Cite this paper

Online since:

January 2012

Authors:

Akihiro Minami, Yoshihiro Tabaru, Yasuo Marumo, Li Qun Ruan, Hiroyuki Saiki

Keywords:

Forging, Surface Hard Layer, Tool Life, Tool Temperature

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

© 2012 Trans Tech Publications Ltd. All Rights Reserved

Share:

Citation:

References

[1] L. Cser, M. Geiger, K. Lange, J.A.G. Kals, M. Hansel: Proc. Instn. Mech. Engrs, 207(1982), 223.

Google Scholar

[2] H. Saiki, S. Shimizu, T. Matsuo: Proc. Int M.T.D.R., (1982) 405.

Google Scholar

[3] T.A. Dean, T.M. Silva: Trans. ASME, Journal of Engineering for Industry, 101(1976)385-390.

Google Scholar

[4] S.L. Semiatin, E.W. Collings, V.E. Wood, T. Altan: Trans. ASME, Journal of Engineering for Industry, 109(1987)49-57.

Google Scholar

[5] H.S. Carslaw, J.C. Jaeger: Condition of heat in solids (2nd Edition) , (1959).

Google Scholar

[6] M.A. Kellow, A.N. Bramley: Int. J. Mach. Tool Des. & Res., (1969), 239-260.

Google Scholar

[7] K. Lange, Meyer-Molkemper, H. , Gesenkschmieden, Springer Verlag, (1997).

Google Scholar

[8] S.S. Sadhal : Trans. ASME, J. Heat Transfer, 103(1981), 32-40.

Google Scholar

[9] Y.T. Im, ; Trans. ASME, J. Eng. Ind., 111(1981), 337-343.

Google Scholar

[10] T. Altan, S.L. Semiatin, E.W. Collings, Wood, V.E.: Trans. ASME, J. Eng. Ind., 109(1982), 49-57.

Google Scholar

[11] H. Saiki, A. Minami, H. Yagoura: Journal of the Japan Society Technology of Plasticity, 30-336(1989) 51-56.

Google Scholar

[12] H. Saiki, Y. Marumo, A. Minami, and T. Sonoi: Journal of Materials Processing Technology., 113 (2001) 22-27.

Google Scholar

[13] T. Wanheim, and N. Bay: Annals of CIRP, Vol. 27, 189-194(1978).

Google Scholar

[14] J.M. Challen and P.L.B. Oxley: Advanced Technology of Plasticity 1884, Vol. 1, 127-132(1984).

Google Scholar

[15] N. Bay, T. Wanheim, Advanced Technology of Plasticity 1990, 4(1990)1677-1691.

Google Scholar

[16] S. Sheu, L.G. Hector and O. Richmond: Trans. ASME, J. of Tribology, 120 (1998) 517-527.

Google Scholar

[17] K. Stein, A. Kapoor and N. Guillon: Advanced Technology of Plasticity 1999, 1(1999), 265-270.

Google Scholar

[18] H. Saiki and G. Ngaile: Intern. Symposium on Advanced Forming and Die Manufacturing Technology, 37-48(1999).

Google Scholar

[19] S. Stancu-Niederkom, U. Engel, M. Geiger: Journal of Materials Processing Technology, 45(1994)613-618.

Google Scholar

[20] S. Shida et al.: Journal of the Japan Society Technology of Plasticity, 10-103(1969), 610.

Google Scholar

© 2025 Trans Tech Publications Ltd. All rights are reserved, including those for text and data mining, AI training, and similar technologies. For open access content, terms of the Creative Commons licensing CC-BY are applied.
Scientific.Net is a registered trademark of Trans Tech Publications Ltd.