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Effect of annealing on the transformation and properties of TiNiCo AND TiNiTa shape memory alloys for medical applications

Identyfikatory
Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
Application for medicine of the shape memory alloys required presence of the one- or two-way shape memory effect or superelastic properties, which occur below the patient body temperature. The studied alloys were obtained by induction melting following by hot and cold working. The phase composition and course of the martensitic transformation and their characteristic temperatures of plates and wires, after thermomechanical treatments, were studied using the X-ray diffraction and differential scanning calorymetry (DSC). The B2-B19' and B19'-R-B2 transitions during heating and cooling were observed, respectively. The ageing causes that the martensitic transformation occurs in two steps: B2-R-B19' during cooling as well as heating. Combination of cold working and annealing or quenching with ageing of the semi-products leads to obtain shape memory effect, which occurs in required range of the temperature. The staples and clips with the shape memory effects, which act below the patient body temperature for joining of mandible bone fractures, for in vitro studies, have been prepared.
Rocznik
Strony
50--56
Opis fizyczny
Bibliogr. 12 poz., rys.
Twórcy
autor
autor
  • University of Silesia, Institute of Materials Science, Katowice, Poland
Bibliografia
  • 1. Duerig T. W., Pelton A. R., Stockel D. : The utility of superelasticity in medicine. Bio-Medical Materials and Engineering 6 (1996), pp. 255-266
  • 2. Pelton A. R, Stockel D., Duerig T.W. : Medical Uses of Nitinol. Materials Science Forum 327-328 (2000), p. 63-70.
  • 3. Pelton A. R., DiCello J., Miyazaki S.: Optimisation of processing and properties of medical grade Nitinol wire. Min Invas Ther & Allied Technol. 9 (1) (2000), pp. 107-118.
  • 4. Shabalovskaya S. A.: On the nature of the biocompatibility and on medical applications of NiTi shape memory and superelastic alloys. Bio-Medical Materials and Engineering 6 (1996), 267-289 12 (2002), p. 69.
  • 5. Shabalovskaya S. A.: Surface, corrosion and biocompatibility aspects of Nitinol as an implant material. Bio-Medical Materials and Engineering 12 (2002), p. 69109.
  • 6. Kishi Y., Yajima Z., Shimizu K., Morii K.: Effects of microstructure on mechanical fatigue crack growth characteristics of a Ti-Ni-Co shape memory alloy. Materials Science and Engineering A273-275 (1999), pp. 654-657.
  • 7. Eckelmeyer K. H.: The Effect of Alloying on the Shape Memory Phenomenon in Nitinol. Scripta Metallurgica 10 (1976), pp. 667-672.
  • 8. Yeung K. W. K., Cheung K. M. C., Lu W. W., Chung C. Y.: Optimization of thermal treatment parameters to alter austenitic phase transition temperature of NiTi alloy for medical implant. Materials Science and Engineering A 383 (2004), pp. 213-218.
  • 9. Cheng Y., Cal W., Li H. T., Zheng Y. F.: Surface modification of NiTi alloy with tantalum to improve its biocompatibility and radiopacity. Journal Material Science 41 (2006), pp. 4961-4964.
  • 10. Ma J. L., Wu K. H., Pu Z.: Microstructure and Transformation Behavior of Ni5oTi5o_XTaXAlloys. Materials Science Forum 327-328 (2000), pp. 179-182.
  • 11. Gong C. W., Wang Y. N., Yang D. Z.: Martensitic transformation of NisoTi45Tas shape memory alloy. Journal of Alloys and Compounds 419 (2006), pp. 61-65.
  • 12. Gong C. W., Wang Y. N., Yang D. Z.: Phase transformation and second phases in ternary Ni-Ti-Ta shape memory alloys. Materials Chemistry and Physics 96 (2006), pp. 183-187.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-article-BPG4-0028-0025
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