Corrosion Science and Technology

The Corrosion Science Society of Korea (한국부식방식학회)
권호 표지

Effects of W Contents in Co Matrix of the Thermal Sprayed WC-Co on the Corrosion Behavior in Molten Zinc

  • Published : 2007.08.01
Download PDF
⟨ Previous Next ⟩

Abstract

This study sought to investigate the reaction of Co-binder containing tungsten with molten zinc. Four kinds of Co-W alloys (pure, 10%W, 20%W, 30%W) were prepared using the powder metallurgy method. The specimens were immersion-tested in molten pure zinc baths at $460^{\circ}C$. To evaluate the corrosion property in molten zinc, the weight loss of the specimen was measured after the immersion tests at different immersion times (10~300 min.). Co-10%W alloys, compared with pure cobalt, showed no effect of tungsten addition on the reaction rate in molten zinc. The relationship between the weight loss and the square root of immersion period represents a straight line in both pure cobalt and Co-10%W alloy. The Co-Zn reaction layer in Co- 1O%W alloy consists of $\gamma2$, $\gamma1$, $\gamma$ and ($\beta1$ phases. The rate of weight loss significantly increases and the weight loss behavior is not well accord with the linear relationship as the tungsten content in the Co-W alloy increases. The $\beta1$ layer was not formed on the Co-20%W alloy and neither was a stable Co-Zn intermetallic compound layer found on the Co-30%W alloy. The main cause of increase in reaction rate with increasing tungsten content is related with the instability of the Co-Zn reaction phases as seen on micro-structural analysis.

Keywords

References

  1. M. Nakagawa, J. Sakai, T. Ohgouchi, and H. Ohkoshi, Tetsu to Hagane, 81, 989 (1995) https://doi.org/10.2355/tetsutohagane1955.81.10_995
  2. M. Sawa, J. Oohori, Processing of International Thermal Spray Conference '95, p.37, Kobe, Japan (1995)
  3. H. Nakahira, Y. Harada, and K. Tani, Proc. ATTAC' 88, p.73, Osaka, Japan (1988)
  4. H. Nakahira, Y. Harada, T. Doi, Y. Takatani, and T. Tomita, J. High Temp. Soc., 16, 317 (1990)
  5. D. Horstmann, Proc. 6th Inter. Conf. on H.D.G., p.319, London, ZDA (1962)
  6. D. Horstmann and F. Peters, Proc. 9th Inter. Conf. on H.D.G., p.75, London, ZDA (1971)
  7. H. Koga, Y Uchiyama, and T. Aki, J. Jpn. Inst. Met., 42, 136 (1978)
  8. T. Tomita, Y. Takatani, Y. Kobayashi, Y. Harada, and H. Nakahira, ISIJ International, 33, 982 (1993)
  9. K. Tani, T. Tomita, Y. Kobayashi, Y. Takatani, and Y. Harada, ISIJ International, 34, 822 (1994)
  10. B. G. Seong, S. Y. Hwang, M. C. Kim, and K. Y. Kim, J. Kor. Inst. Met. & Mater., 38, 488 (2000)
  11. B. G. Seong, S. Y. Hwang, M. C. Kim, and K. Y. Kim, Surface and Coatings Technology, 138, 101 (2001) https://doi.org/10.1016/S0257-8972(00)01145-2
  12. B. G. Seong, S. H. Kwon, K. Y. Kim, and K. A. Lee, TMS 2007, p.17, Orlando, Florida, USA, Feb. 25 Mar. 2 (2007)
  13. A. Hoffman and R. Mohs, Metall, 28, 661 (1974)
  14. T. B. Massalski, Binary Alloy Phase Diagrams, 2nd edition, Co-W, ASM Int. (1990)
  15. T. B. Massalski, Binary Alloy Phase Diagrams, 2nd edition, Co-Zn, ASM Int. (1990)
  16. K. Yajima and T. Yamaguchi, Powder Metall. International, 14, 90 (1982)
  17. M. R. Rijnders and F. J. J. van Loo, Scripta Metall. et Mater., 32, 1931 (1995)
  18. C. Xiaaming, J. Xinchang, and H. Wenxiang, Proc. of environmental & energy efficient heat treatment tech., p.250, Beijing, China, Sept. 15-17 (1993)
  19. W. Hadge, R. M. Evans, and A. F. Haskins, Trans. AIME, 203, 824 (1955)