Microstructure control for high strength 9Cr ferritic–martensitic steels

Abstract Ferritic–martensitic (F–M) steels with 9 wt.%Cr are important structural materials for use in advanced nuclear reactors. Alloying composition adjustment, guided by computational thermodynamics, and thermomechanical treatment (TMT) were employed to develop high strength 9Cr F–M steels. Samples of four heats with controlled compositions were subjected to normalization and tempering (N&T) and TMT, respectively. Their mechanical properties were assessed by Vickers hardness and tensile testing. Ta-alloying showed significant strengthening effect. The TMT samples showed strength superior to the N&T samples with similar ductility. All the samples showed greater strength than NF616, which was either comparable to or greater than the literature data of the PM2000 oxide-dispersion-strengthened (ODS) steel at temperatures up to 650 °C without noticeable reduction in ductility. A variety of microstructural analyses together with computational thermodynamics provided rational interpretations on the strength enhancement. Creep tests are being initiated because the increased yield strength of the TMT samples is not able to deduce their long-term creep behavior.

[1]  M. Tamura,et al.  A new approach to improve creep resistance of high Cr martensitic steel , 2011 .

[2]  Gerhard Inden,et al.  Design of martensitic/ferritic heat-resistant steels for application at 650 °C with supporting thermodynamic modelling , 2008 .

[3]  A. Pineau,et al.  High-temperature mechanical properties improvement on modified 9Cr―1Mo martensitic steel through thermomechanical treatments , 2010 .

[4]  Kouichi Maruyama,et al.  Strengthening Mechanisms of Creep Resistant Tempered Martensitic Steel , 2001 .

[5]  Mark H. Anderson,et al.  Corrosion of austenitic and ferritic-martensitic steels exposed to supercritical carbon dioxide , 2011 .

[6]  John P. Shingledecker,et al.  Oxide dispersion-strengthened steels: A comparison of some commercial and experimental alloys , 2005 .

[7]  R. Klueh,et al.  Development of new nano-particle-strengthened martensitic steels , 2005 .

[8]  Todd R. Allen,et al.  Microstructure tailoring for property improvements by grain boundary engineering , 2008 .

[9]  R. Klueh Reduced-activation steels: Future development for improved creep strength , 2008 .

[10]  Yukio Tomita,et al.  Microstructural Evolution during Creep Test in 9Cr–2W–V–Ta Steels and 9Cr–1Mo–V–Nb Steels , 2001 .

[11]  Fujio Abe,et al.  Creep-strengthening of steel at high temperatures using nano-sized carbonitride dispersions , 2003, Nature.

[12]  L. Tan,et al.  Corrosion behavior of 9-12% Cr ferritic-martensitic steels in supercritical water , 2010 .

[13]  N. Saunders,et al.  CALPHAD : calculation of phase diagrams : a comprehensive guide , 1998 .

[14]  Fujio Abe,et al.  Creep-resistant Steels , 2008 .

[15]  P. Maziasz,et al.  Effect of thermomechanical treatment on 9Cr ferritic–martensitic steels , 2013 .

[16]  James I. Cole,et al.  Materials Challenges for Generation IV Nuclear Energy Systems , 2008 .

[17]  R. Viswanathan,et al.  Advanced heat resistant steels for power generation : Conference proceedings 27-29 April 1998 San Sebastian, Spain , 1999 .

[18]  Gary S. Was,et al.  The relationship between hardness and yield stress in irradiated austenitic and ferritic steels , 2005 .

[19]  K. Chawla,et al.  Mechanical Behavior of Materials , 1998 .

[20]  H. Bhadeshia,et al.  Design of new Fe-9CrWV reduced-activation martensitic steels for creep properties at 650 C , 2004 .

[21]  K. Sridharan,et al.  Effect of thermomechanical processing on grain boundary character distribution of a Ni-based superalloy , 2007 .