<p>This study explored phase transformations and thermal expansion coefficients in 9%Cr steels; P91 and P92 base metals, and P91 welds, on heating to 1000&#xa0;°C. Neutron powder diffraction was employed to determine transformation temperatures, lattice parameters, and phase fractions. Austenite onset (A<sub>c1</sub>) and completion (A<sub>c3</sub>) temperatures were 800–805&#xa0;°C and 885–890&#xa0;°C for P91 base metal, and 814–816&#xa0;°C and 928–930&#xa0;°C for P92. The weld metals&#xa0;were evaluated in the as-welded condition. At room temperature, weld metals contained ferrite, martensite, and residual austenite. Residual austenite in weld 1 was retained on heating until fresh austenite formed at 765–770&#xa0;°C, whereas in weld 2 it disappeared at 655–660&#xa0;°C. The A<sub>c1</sub> and A<sub>c3</sub> temperatures of weld 2 were 815–820&#xa0;°C and 920–922&#xa0;°C. P92 transformed at lower temperatures and thermal expansion during the α-BCC-to-austenite transformation than P91. Weld 1 showed higher transformation temperatures and expansion than the base metal. Dilatometry measured transition temperatures of 817&#xa0;°C and 880&#xa0;°C for P91 base metal, and 836&#xa0;°C and 923&#xa0;°C for P92. As-welded curve exhibited multiple transitions between 697–904&#xa0;°C. Calorimetry showed endothermic α-ferrite-to-austenite transitions with A<sub>c1</sub> and A<sub>c3</sub> at 824&#xa0;°C and 874&#xa0;°C for P91 base metal, 839&#xa0;°C and 893&#xa0;°C for P92, and 831&#xa0;°C and 876&#xa0;°C for weld 1. This study demonstrates the advantages of integrating neutron diffraction, dilatometry, and calorimetry to improve transformation analysis in 9%Cr steels; neutron diffraction measured A<sub>c1</sub> up to 20&#xa0;°C lower than dilatometry, indicating current post-weld heat treatment temperature ranges may be insufficiently conservative. Residual austenite in weld metal and its behaviour on heating may also influence weld heat-treatment response.</p>

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Comparison of α-ferrite to ɣ-austenite transformations in 9%Cr steel alloys measured by neutron powder diffraction, dilatometry, and differential scanning calorimetry

  • Zeldah N. Sentsho,
  • Pieter G. H. Pistorius,
  • Andrew M. Venter,
  • James R. Hester,
  • Helen E. Maynard-Casely

摘要

This study explored phase transformations and thermal expansion coefficients in 9%Cr steels; P91 and P92 base metals, and P91 welds, on heating to 1000 °C. Neutron powder diffraction was employed to determine transformation temperatures, lattice parameters, and phase fractions. Austenite onset (Ac1) and completion (Ac3) temperatures were 800–805 °C and 885–890 °C for P91 base metal, and 814–816 °C and 928–930 °C for P92. The weld metals were evaluated in the as-welded condition. At room temperature, weld metals contained ferrite, martensite, and residual austenite. Residual austenite in weld 1 was retained on heating until fresh austenite formed at 765–770 °C, whereas in weld 2 it disappeared at 655–660 °C. The Ac1 and Ac3 temperatures of weld 2 were 815–820 °C and 920–922 °C. P92 transformed at lower temperatures and thermal expansion during the α-BCC-to-austenite transformation than P91. Weld 1 showed higher transformation temperatures and expansion than the base metal. Dilatometry measured transition temperatures of 817 °C and 880 °C for P91 base metal, and 836 °C and 923 °C for P92. As-welded curve exhibited multiple transitions between 697–904 °C. Calorimetry showed endothermic α-ferrite-to-austenite transitions with Ac1 and Ac3 at 824 °C and 874 °C for P91 base metal, 839 °C and 893 °C for P92, and 831 °C and 876 °C for weld 1. This study demonstrates the advantages of integrating neutron diffraction, dilatometry, and calorimetry to improve transformation analysis in 9%Cr steels; neutron diffraction measured Ac1 up to 20 °C lower than dilatometry, indicating current post-weld heat treatment temperature ranges may be insufficiently conservative. Residual austenite in weld metal and its behaviour on heating may also influence weld heat-treatment response.