论文信息 - Interpretation of creep behaviour of a 9Cr–Mo–Nb–V–N (T91) steel using threshold stress concept

Interpretation of creep behaviour of a 9Cr–Mo–Nb–V–N (T91) steel using threshold stress concept

AbstractThe creep behaviour and the microstructural evolution of a 9Cr–Mo–Nb–V (T91) steel were extensively evaluated by means of short term constant load creep tests and TEM analysis. Statistical analysis of the microstructural data revealed that the precipitated phases M23 C6 (where M is a metal, mainly Cr or Fe) and MX (where M is Nb or V, and X is C and/or N) were subject to coarsening during creep exposure. The coarsening law and its dependence on applied stress were identified, and the model was used to predict the magnitude of the Orowan stress at the time corresponding to the minimum creep rate. The minimum creep rate dependence on applied stress at 873 K was described by incorporating the threshold stress concept in a power law with stress exponent n = 5. In the resulting phenomenological model, the strengthening effect of the dispersed phases was thus expressed by a threshold stress proportional to the Orowan stress.

S. Spigarelli | E. Cerri | P. Bianchi | E. Evangelista

[1] I. Lifshitz,et al. The kinetics of precipitation from supersaturated solid solutions , 1961 .

[2] A. Kelly,et al. Strengthening methods in crystals , 1971 .

[3] M. Ashby,et al. Threshold stresses in materials containing dispersed particles , 1982 .

[4] R. Evans,et al. Creep behaviour of crystalline solids , 1985 .

[5] J. Čadek. Creep in metallic materials , 1988 .

[6] M. E. Kassner. A case for Taylor hardening during primary and steady-state creep in aluminium and type 304 stainless steel , 1990 .

[7] R. Uemori,et al. Role of a complex carbonitride of niobium and vanadium in creep strength of 9% Cr ferritic steels , 1991 .

[8] R. Uemori,et al. A complex carbonitride of niobium and vanadium in 9% Cr ferritic steels , 1991 .

[9] T. Takeda,et al. Dispersion strengthening high-Cr steels by forming “V-Wings” , 1992 .

[10] Fujio Abe,et al. The effect of tungsten on creep , 1992, Metallurgical and Materials Transactions A.

[11] J. Čadek,et al. Comment on “creep behavior of discontinuous SiCAl composites” , 1993 .

[12] J. Čadek,et al. An Analysis of a Set of Creep-Strain and Time-to-Creep Fracture Data for a SCR-1Mo-0.2V Steel , 1997 .

[13] Yong Li,et al. A comparison of the creep properties of an Al-6092 composite and the unreinforced matrix alloy , 1998 .