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A Study Of Phase Transformation In Shape Memory Alloy Cual9fe4

Author

Listed:
  • Nguyen Duong Nam

    (Viet Nam Maritime University, Hai Phong City, Viet Nam.)

  • Vu Anh Tuan

    (Viet Nam Maritime University, Hai Phong City, Viet Nam.)

  • Nguyen Hai Yen

    (Viet Nam Maritime University, Hai Phong City, Viet Nam.)

  • Dao Van Lap

    (Viet Nam Maritime University, Hai Phong City, Viet Nam.)

  • Pham Mai Khanh

    (School of Material Science and Engineering, Ha Noi University of Science and Technology, Ha Noi City, Viet Nam.)

Abstract

Microstructure and phase transformation in shape memory alloy Cu-Al (Fe addition: 9% Al, 4 % Fe) were investigated in this study. It is a material capable of restoring its original shape when impacted by a reasonable temperature or cyclic stress and production cost is not too expensive. In many years, shape memory alloys (SMA) based on Cu – Fe is considered to be very attractive to industrial and biomedical applications such as cardiovascular, orthopedic, surgery and production of spare parts and jigs. Original alloy exists β martensite and only exists 〖α^’〗_1 (3R)+ 〖β’〗_1(9R) + 〖γ^’〗_(1 ) (2H) which is finely dispersed homogenously in microstructure after finishing shape memory transformation. Shape memory rate obtained 6%-24% corresponding to each deformation angle before the experiment. Phase transformation between these two phases during deformation as well as the heating-cooling process which create the basis for the unique properties of the alloy.

Suggested Citation

  • Nguyen Duong Nam & Vu Anh Tuan & Nguyen Hai Yen & Dao Van Lap & Pham Mai Khanh, 2019. "A Study Of Phase Transformation In Shape Memory Alloy Cual9fe4," Journal of Mechanical Engineering Research & Developments (JMERD), Zibeline International Publishing, vol. 42(2), pages 72-75, March.
  • Handle: RePEc:zib:zjmerd:v:42:y:2019:i:2:p:72-75
    DOI: 10.26480/jmerd.02.2019.72.75
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    References listed on IDEAS

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