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Composites: Mechanics, Computations, Applications: An International Journal
ESCI SJR: 0.193 SNIP: 0.497 CiteScore™: 0.39

ISSN 印刷: 2152-2057
ISSN オンライン: 2152-2073

Composites: Mechanics, Computations, Applications: An International Journal

DOI: 10.1615/CompMechComputApplIntJ.v1.i2.40
pages 169-189

SOLUTION OF THE COUPLED THERMOELECTROMECHANICAL PROBLEM FOR A ROD MADE FROM A SHAPE MEMORY ALLOY WITHIN THE FRAMEWORK OF THE THEORY OF NONLINEAR DEFORMATION OF THESE MATERIALS

A. A. Movchan
Federal Governmental Budgetary Scientific Institution "Institute of Applied Mechanics", Russian Academy of Sciences, Moscow, Russia
Kyaw Thu Ya
Moscow Aviation Institute (State Technical University), Moscow, Russia

要約

The problem on direct martensite transformation in a rod made from a shape-memory alloy (SMA) subjected to the action of a constant stress and cooled through its ends has been solved within the framework of the nonlinear model of deformation of SMA, as well as the reverse transformation of this rod heated by passing an electric current.

参考

  1. Kravchenko, Yu.. D., Likhachev, V. A., Rasov, A. I., Trusov, S. N., and Cherniavsky, A. G., The use of shape memory alloys in space building.

  2. Razov, A. I. and Chernyavskii, A. G., Application of shape memory alloys in space technology: past and future. Mechanisms of deformation and destruction of promising materials.

  3. Movchan, A. A. and Movchan, I. A., One-dimensional micromechanical model of nonlinear deformation of shape memory alloys on direct and reverse thermoelastic transformations.

  4. Movchan, A. A. and Movchan, I. A., Model of nonlinear deformation of shape memory alloys in active processes of direct transformation and structural transition.

  5. Movchan, A. A. and Mishustin, I. V., Thermodynamic analysis of the mechanical behavior of shape memory alloys.

  6. Movchan, A. A. and Mishustin, I. V., Thermodynamic description of the nonlinear deformation of shape memory alloys.

  7. Movchan, A. A. and Nyunt, Soe, Thermodynamic description of the behavior of shape memory alloys with the aid of the additive Gibbs potential.

  8. Movchan, A. A. and Mishustin, I. V., Analysis of nonadditive supplements to the Gibbs potential of a shape memory alloy.

  9. Uhil, J., Mahesh, K. K., and Kumura, K. J., Electrical resistivity and strain recovery studies on the effect of thermal cycling under constant stress on R-phase in TiNi shape memory alloy.


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