Journal of Korea Foundry Society (한국주조공학회지)

Korea Foundry Society (한국주조공학회)
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In-situ Synthesis and Investment Casting of Titanium Matrix (TiC+TiB) Hybrid Composites

Ti기 (TiC+TiB) 하이브리드 복합재료 반응생성합성 및 정밀주조

  • Sung, Si-Young (Department of Advanced Materials Engineering, Sungkyunkwan University) ;
  • Park, Keun-Chang (Department of Advanced Materials Engineering, Sungkyunkwan University) ;
  • Lee, Sang-Hwa (Department of Metallurgical Engineering, Donga University) ;
  • Kim, Young-Jig (Department of Advanced Materials Engineering, Sungkyunkwan University)
  • 성시영 (성균관대학교 신소재공학과) ;
  • 박근창 (성균관대학교 신소재공학과) ;
  • 이상화 (동아대학교 금속공학과) ;
  • 김영직 (성균관대학교 신소재공학과)
  • Published : 2004.06.20
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Abstract

The aim of the present work is to investigate the possibility of in-situ synthesis and net-shape forming of the titanium matrix (TiC+TiB) hybrid composites using a casting route. From the scanning electron microscopy, electron probe micro-analyzer, X-ray diffraction and thermodynamic calculations, the spherical TiC and needle like TiB reinforced hybrid titanium matrix composites could be obtained in-situ by the conventional melting and casting route between titanium and $B_4C$. No melt-mold reaction occurred between the titanium matrix (TiC+TiB) hybrid composites and the SKK mold, since the mold is consisted with interstitial and substitutional metal-mold reaction products. Not only the sound in-situ synthesis but also the economic net-shape forming of the titanium matrix (TiC+TiB) hybrid composites could be possible by the conventional casting route.

Keywords

References

  1. P. R. Smith and F. H. Froes : Journal of Metals, 'Develop-ments Titanium Metal Matrix Composites", 36(3) (1984) 19-26
  2. L. Guozhen, Z. Quanpu and D. Ju : Titanium '95, 'The Research and Development ofTMCs', (1995) 2704-2713
  3. S. Ranganath : J. Mater. Sci., 'A review on particulate-reinforced titanium matrix composites', 32 (1997) 1-16
  4. F. H. Froes, H. Friedrich, J. Kiese and D. Bergoint : Journal of Metals, 'Titanium in the Family Automative : The Cost Challenge', 56(2) (2004) 40-44
  5. C. M. Ward-Close, L. Chandrasekaran, J.G. Robertson, S. P. Godfrey and D.P. Murgatroyde : Mater. Sci. Eng. A, "Advances in the fabrication of titanium metal matrix com-posite', A263 (1999) 314-318
  6. B. V. R. Bhat, J. Subrarnanyam and V. V. B. Prasad: Mater. Sci. Eng. A, 'Preparation of Ti-TiB-TiC & TI-TIB composites by in-situ reaction hot pressing', A325 (2002) 126-130
  7. J. J. Moore and H. J. Feng : Prog. Mater. Sci., 'Combustion synthesis of advanced materials : Part II. Classification, application and modelling', 29 (1995) 275-316
  8. S. Ranganath, M. Vijayakumar and 1. Subrahmanyam : Mater. Sci. Eng. A, 'Combustion-assisted synthesis of Ti-TIB-TIC composite via the casting route', A149 (1992) 253-257
  9. X. Zhang, W. Lu, D. Zhang and R. Wu : Scripta Materailia, 'In situ technique for synthesizing (TiB+TiC)ffi composites', 41(1) (1999) 39-46 https://doi.org/10.1016/S1359-6462(99)00087-1
  10. E. Zhang, S. Zeng and B. Wang: J. of Mater. Pro. Tech.,'Preparation and microstructure of in situ particle reinforced titanium matrix alloy", 125-126 (2002) 103-109
  11. M. W. Chase, C. A. Davies, J. R. Downey, D. 1. Frurip, R. A. McDonald and A. N. Syverud : JANAF Thermochemical Tables, American Chemical Society and American Institute of Physics (1985) 256-1818
  12. S. Y. Sung, M. H. Kang, M. G. Kim and Y. J. Kim : Proceedings of the 1st Korea-Japan Conference for Young Foundry Engineers, "Influence of AI contents on alpha-case formation of Ti-AI alloys", Edited by S.M.Lee, K.Ogi and T.W.Nam, (2003) 61-64
  13. M. J. Donachie Jr. : TItanium-A technical guide, 2nd ASM International (2000) 39-45