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Mechanical Behavior and Evolution of the Lamellar Microstructure of Alloy VT9 as a Function of the Ratio of Axial and Shear Components of Hot Deformation

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Abstract

Results of a study of the effect of hot deformation under isothermal conditions under bicomponent (twisting + stretching) proportional loading with various ratios of the axial and shear components of the deformation on the mechanical behavior and evolution of the initial coarse lamellar microstructure and crystallographic texture in alloy VT9 are presented. It is shown that the ratio of the axial and shear components of the deformation is responsible for the degree of localization of plastic yield of the material and the fullness and intensity of transformation of the lamellar microstructure into a globular microcrystalline microstructure in the functional zone of deformed specimens.

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Authors and Affiliations

  1. Ufa State Aircraft Engineering University, Ufa, Russia

    V. K. Berdin, M. V. Karavaeva, L. A. Syutina & S. K. Nurieva

  2. Institute for Problems of Superplasticity of Metals of the Russian Academy of Sciences, Ufa, Russia

    V. K. Berdin, M. V. Karavaeva, L. A. Syutina & S. K. Nurieva

Authors
  1. V. K. Berdin
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  2. M. V. Karavaeva
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  3. L. A. Syutina
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  4. S. K. Nurieva
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Berdin, V.K., Karavaeva, M.V., Syutina, L.A. et al. Mechanical Behavior and Evolution of the Lamellar Microstructure of Alloy VT9 as a Function of the Ratio of Axial and Shear Components of Hot Deformation. Metal Science and Heat Treatment 46, 54–60 (2004). https://doi.org/10.1023/B:MSAT.0000029602.74120.a1

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  • DOI: https://doi.org/10.1023/B:MSAT.0000029602.74120.a1

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