Korean Journal of Materials Research (한국재료학회지)

Materials Research Society of Korea (한국재료학회)
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The Effect of Cold-rolling on Microstructure and Transformation Behavior of Cu-Zn-Al shape Memory Alloy

냉간가공에 의한 CuZnAl계 현상기억합급의 결정립미세화와 특성평가

  • Lee, Sang-Bong (School of Materials and Metallurgical Engineering, Kum-oh National University of Technology) ;
  • Park, No-Jin (School of Materials and Metallurgical Engineering, Kum-oh National University of Technology)
  • 이상봉 (금오공과대학교 재료.금속공학부) ;
  • 박노진 (금오공과대학교 재료.금속공학부)
  • Published : 1999.03.01
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Abstract

In this study, cold-rolling and appropriate annealing was adopted for the grain refining of Cu-26.65Zn-4. 05Al-0.31Ti(wt%) shape memory alloy. For the cold deformation of this alloy the ducti1e $\alpha$-phase must be contained. After heat treatment at $550^{\circ}C$ the $(\alpha+$\beta)$-dual phase with 40vol.% $\alpha$-phase was obtained which could be rolled at room temperature. This alloy was cold rolled into a final thickness of 1.0mm with total reduction degrees of 70% and 90%. The rolled sheets were betanized at $800^{\circ}C$ for various times, then quenched into ice water. The grain size of co]d rolled samples were $60~80\mu\textrm{m}$ which is much smaller comparing with the hot-rolled samples. And the 90% rolled sample showed smaller grain size than the case of the 70% rolled one. The small grain size had influence on the phase transformation temperatures and stabilization of the austenitic phases.

본 연구는 냉간가공과 열처리를 통해 Cu-26.65Zn-4.05Al-0.31Ti(wt%) 형상기억합금의 결정립을 미세화하기 위한 목적으로 수행하였다. 냉간가공을 위하여는 α-상이 가능한 많이 존재하는 (α+β)-조직을 가져야 하는데, 이는 550℃에서 열처리함으로써 얻었고, 최종두께 1mm로 냉간압연하였다. 총 압연율은 70%와 90%이었다. 냉간압연한 판재를 800℃에서 가열 후 급랭함으로써 형상기억특성을 갖는 상으로 변태시켰으며, 이 대 결정립크기를 측정한 결과, 열간압연한 경우보다 냉간압연과 열처리를 한 경우의 결정립이 월등히 작아졌음을 보여주었다. 냉간압연과 열처리를 한 경우에는 냉간압연 변형율이 큰 경우가 결정립이 더 작아지는 경향을 보였다. 또한 결정립크기가 작아짐에 따라 변태온도가 저하되었으며 오스테나이트상이 더 안정하게 되었음을 확인할 수 있었다. In this study, cold-rolling and appropriate annealing was adopted for the grain refining of Cu-26.65Zn-4. 05Al-0.31Ti(wt%) shape memory alloy. For the cold deformation of this alloy the ducti1e α-phase must be contained. After heat treatment at 550℃ the (α+β)-dual phase with 40vol.% α-phase was obtained which could be rolled at room temperature. This alloy was cold rolled into a final thickness of 1.0mm with total reduction degrees of 70% and 90%. The rolled sheets were betanized at 800℃ for various times, then quenched into ice water. The grain size of co]d rolled samples were 60∼80 ㎛ which is much smaller comparing with the hot-rolled samples. And the 90% rolled sample showed smaller grain size than the case of the 70% rolled one. The small grain size had influence on the phase transformation temperatures and stabilization of the austenitic phases.

Keywords

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