• Title of article

    Microstructure of warm rolling and pearlitic transformation of ultrafine-grained GCr15 steel

  • Author/Authors

    Sun، نويسنده , , Jun-Jie and Lian، نويسنده , , Fu-Liang and Liu، نويسنده , , Hong-Ji and Jiang، نويسنده , , Tao and Guo، نويسنده , , Sheng-Wu and Du، نويسنده , , Linxiu and Liu، نويسنده , , Yong-Ning، نويسنده ,

  • Issue Information
    روزنامه با شماره پیاپی سال 2014
  • Pages
    8
  • From page
    291
  • To page
    298
  • Abstract
    Pearlitic transformation mechanisms have been investigated in ultra-fine grained GCr15 steel. The ultrafine-grained steel, whose grain size was less than 1 μm, was prepared by thermo-mechanical treatment at 873 K and then annealing at 923 K for 2 h. Pearlitic transformation was conducted by reheating the ultra-fine grained samples at 1073 K and 1123 K for different periods of time and then cooling in air. Scanning electron microscope observation shows that normal lamellar pearlite, instead of granular cementite and ferrite, cannot be formed when the grain size is approximately less than 4(± 0.6) μm, which yields a critical grain size for normal lamellar pearlitic transformations in this chromium alloyed steel. The result confirms that grain size has a great influence on pearlitic transformation by increasing the diffusion rate of carbon atoms in the ultra-fine grained steel, and the addition of chromium element doesnʹt change this pearlitic phase transformation rule. Meanwhile, the grain growth rate is reduced by chromium alloying, which is beneficial to form fine grains during austenitizing, thus it facilitating pearlitic transformation by divorced eutectoid transformation. Moreover, chromium element can form a relatively high gradient in the frontier of the undissolved carbide, which promotes carbide formation in the frontier of the undissolved carbide, i.e., chromium promotes divorced eutectoid transformation.
  • Keywords
    ultrafine grained steel , Pearlitic transformation , Granular cementite , Divorced eutectoid transformation
  • Journal title
    Materials Characterization
  • Serial Year
    2014
  • Journal title
    Materials Characterization
  • Record number

    2269606