Transactions of Materials Processing (소성∙가공)

The Korean Society for Technology of Plasticity and materials processing (한국소성∙가공학회)
권호 표지
DOI QR코드

DOI QR Code

A Study on the Superplasticity of Zn-Al Alloy using Dynamic Materials Model

동적재료모델을 이용한 Zn-Al 합금의 초소성 변형거동 연구

  • 정재용 (강릉원주대학교 금속재료공학과) ;
  • 하태권 (강릉원주대학교 금속재료공학과) ;
  • 장영원 (포항공과대학교 신소재공학과)
  • Published : 2009.07.01
Download PDF
⟨ Previous Next ⟩

Abstract

Superplastic deformation behavior of a Zn-0.3 wt.% Al was investigated. Grain sizes of $1{\mu}m$ and $10{\mu}m$ were obtained by a thermomechanical treatment. A series of load relaxation and tensile tests were conducted at various temperatures ranging from RT ($24^{\circ}C$) to $200^{\circ}C$. A large elongation of 1400% was obtained at room temperature in the specimens with the grain size of $1{\mu}m$. In the case of specimens with the grain size of $10{\mu}m$, relatively lower elongation at room temperature was obtained and, as the temperature increases above $100^{\circ}C$, a high elongation of about 400 % has been obtained at $200^{\circ}C$ under the strain rate of $2{\times}10^{-4}/s$. Dynamic materials model (DMM) has been employed to explain the contribution from GBS of Zn-Al alloy. Power dissipation efficiency for GBS was evaluated as above 0.4 and found to be very close to the unity as strain rate decreased and temperature increased, suggesting that GBS could be regarded as Newtonian viscous flow.

Keywords

References

  1. K. A. Padmanabhan, G. J. Davis, 1980, Superplasticity, Springer-Verag, p. 133
  2. O. D. Sherby, J. Wadsworth, 1982, Deformation, Processing, & Structure, G. Krauss(Eds.) ASM Mat. Sci. Seminar, St Louis, p. 355
  3. J. W. Edington, K. N. Melton, C. P. Cutler, 1976, Superplasticity, Prog. Mater. Sci., Vol. 21, p. 61 https://doi.org/10.1016/0079-6425(76)90005-0
  4. T. K. Ha, H. C. Shin, Y. W. Chang, 1997, An Internal Variable Approach to Superplastic Deformation Behavior of Pb-Sn Eutectic Alloy, Journal of Korean Institute of Metals and Materials, Vol. 35, p. 191
  5. C. Van Riet, P. De Meester, 1985, Cavitation in a Dilute Superplastic Zn-0.5%Al Alloy - A Cascade Mechanism for Cavity Generation, Scripta Metall., Vol. 19, p. 795 https://doi.org/10.1016/0036-9748(85)90194-2
  6. T. K. Ha, J. R. Son, W. B. Lee, C. G. Park, Y. W. Chang, 2001, Superplastic Deformation Behavior of a Fine-Grained Zn-0.3wt.%Al Alloy at Room Temperature, Mater. Sci. Eng., Vol. A307, p. 98
  7. Y. V. R. K. Prasad, H. L. Gegel, S. M. Doraivelu, J. C. Malas, J. T. Morgan, K. A. Lark, D. R. Barker, 1984, Modeling of Dynamic Material Behavior in Hot Deformation: Forging of Ti-6242, Metall. Trans., Vol. 15A, p. 188 https://doi.org/10.1007/BF02664902
  8. Y. V. R. K. Prasad, T. Seshacharyulu, 1998, Processing Maps for Hot Working of Titanium Alloys, Mater. Sci. Eng., Vol. A243, p. 8 https://doi.org/10.1016/S0921-5093(97)00782-X
  9. A. K. S. Kalyan Kumar, 1987, Criteria for predicting metallurgical instabilities in processing (M.Sc Eng. Thesis, Indian Institute of Science, Bangalore, India)
  10. E. W. Hart, 1979, Stress Relaxation Testing, A. Fox (Ed.), ASTM Special Technical Publication 676, Baltimore, p. 5
  11. T. K. Ha, Y. W. Chang, 1998, An Internal Variable Approach to Structural Superplasticity, Acta Materialia, Vol. 46, p. 2741 https://doi.org/10.1016/S1359-6454(97)00473-4