High-Speed Sinter-Forging of Annular Ring Component

S. Singh; A. K. Jha; S. Kumar

doi:10.6180/jase.2007.10.1.03

High-Speed Sinter-Forging of Annular Ring Component

S. Singh This email address is being protected from spambots. You need JavaScript enabled to view it.¹, A. K. Jha² and S. Kumar¹

¹Department of Production Engineering, Birla Institute of Technology Mesra, Ranchi–835 215, Jharkhand, India
²Department of Mechanical Engineering, Institute of Technology, Banaras Hindu University, Varanasi–221 005, U.P., India

Received: June 24, 2005
Accepted: December 21, 2005
Publication Date: March 1, 2007

Download Citation: ||https://doi.org/10.6180/jase.2007.10.1.03

ABSTRACT

The forging of sintered metal powder preforms is currently arousing interest in many parts of the world as an economic method of producing components from metal powders. The present investigation has been undertaken with a view to analyze the high-speed axi-symmetric sinter-forging of annular ring component by upper bound method taking barreling into consideration. The exponential velocity field and strain rates have been derived using compatibility equation formulated from suitable yield criterion for sintered porous preforms. The average die load has been estimated based on energy dissipated in form of internal deformation, interfacial friction losses and inertia forces. The effect of die velocity on inertia energy has been critically studied using inertia factor. The relationship between interfacial frictional stress and other process variables are illustrated. The interaction of various parameters during high-speed sinter-forging of ring component are discussed and presented graphically also. It is believed that the study will be useful for the assessment high-speed forging of sintered materials.

Keywords: Sinter-Forging, High-Speed, Upper Bound, Annular Ring, Die-Velocity

REFERENCES

[1] Cull, G. W., “Mechanical and Metallurgical Properties of Powder Forging,” Powder Metallurgy, Vol. 13, p. 156 (1970).
[2] Shivpuri, R., “Past Development and Future Trends in the Rotary or Orbital Forging Process,” J. Mater. Shaping Technology, Vol. 6, pp. 5571 (1988).
[3] Singh, S., “Sintered Preforms Adds Better Value to Aerospace Components,” J. of Aerospace Engineering, I. E. (I), Vol. 82, pp. 16 (2001).
[4] Jha, A. K. et. al., “Production of Sinter-Forged Components,” J. of Materials Process. Tech., Vol. 41, pp. 143169 (1994).
[5] Sutradhar, G., “Cold Forging of Sintered Polygonal Discs,” J. of Prod. Engg., I. E. (I), Vol. 76, pp. 148152 (1995).
[6] Jha, A. K. et. al., “Dynamic Effects during High-Speed Sinter-Forging Process,” Int. J. of Mach. Tools & Manuf., Vol. 36, p. 1109 (1996).
[7] Singh, S. et. al., “Analysis of Dynamic Effects during High-Speed Forging of Sintered Preforms,” J. of Materials Process. Tech., Vol. 112, pp. 5362 (2001).
[8] Singh, S. et. al., “An Energy Analysis during Forging of Sintered Truncated Conical Preform at High-Speed,” Tamkang J. of Sci. and Engg., Vol. 7, pp. 227236 (2004).
[9] Jha, A. K. et. al., “Forging of Metal Powder Preforms,” Int. J. of Mach. Tool Design & Res., Vol. 23, p. 210 (1996).
[10] Jha, A. K. et. al., “Investigations into the High-Speed Forgings of Sintered Copper Powder Strips,” J. of Materials Process. Tech., Vol. 71, p. 394 (1997).
[11] Tabata, T. and Masaki, M., “A Yield Criterion for Porous Metals and Analysis of Axial Compression of Porous Discs,” Memories of Osaka Institute of Technology, Series-B, Science and Technology, Vol. 22, p. 45 (1978).
[12] Jha, A. K. et. al., “Compatibility of Sintered Materials during Cold Forging,” Int. J. of Materials & Product Tech., Vol. 9, pp. 281299 (1994).
[13] Sahoo, S. K. et. al., “Forging of a Truncated Cone: An Upper Bound Analysis,” Proc. of the 20th All India M.T.D.R. Conference, pp. 414420 (2003).
[14] Rooks, B. W., “The Effect of Die Temperature on Metal Flow and Die Wear during High-Speed Hot Forging,” Proc. of the 15th Int. MTDR Conference, p. 487 (1974).
[15] Avitzur, B., Metal Forming Processes and Analysis, McGraw Hill, New York, U.S.A. (1968).
[16] Agrawal, M. et. al., “High-Speed Forging of Hollow Metal Powder Preforms,” J. of Prod. Engg., I. E. (I), Vol. 80, pp. 815 (1999).