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Abstract

The deformations and failure life ratios, obtained from creep damage analyses using a ‘unit cell’ model, are used to describe the ‘bulk’ anisotropic creep behaviour of a 9CrMoNbV weld metal. The model consists of a columnar region and a weaker equiaxed (fine-grained and coarse-grained) region, and is based on the assumption that the structure of the weld metal has a regular geometric pattern. The creep damage analyses were conducted using a single-variable Kachanov type damage law, for which the material constants are based on experimental data. The bulk material ‘uniaxial’ creep rupture lives in the three principal directions were investigated taking account of the effects of the length to width ratio of the unit cell, the material property mismatch for the two regions, and the volume fraction of the columnar region. Results from the analyses indicate that the predicted failure modes are the same as those observed in an experimental study of the weld metal.

Keywords

creep anisotropy 9CrMoNbV weld metal damage analysis unit cell model

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References

Wolstenholme

A. A.

Transverse cracking and creep ductility of 2CrMo weld metals. Conference on

Trends in Steels and Consumables for Welding, The Welding Institute, Abingdon, London UK, 1978.

Stout

R. D.

Weldability of steels, 4th edition, 1987 (Welding Research Council, New York).

Hyde

T. H.

Sun

Agyakwa

P. A.

Shipway

P. H.

Williams

J. A.

Anisotropic creep and fracture behaviour of a 9CrMoNbV weld metal at 650 °C

Anisotropic behaviour of damaged materials (Eds Skrzypek

J. J.

Ganczarski

) 2002, Chapter 9, pp. 295–316 (Springer-Verlag, Berlin).

Easterling

Introduction to the physical metallurgy of welding, 1992 (Butterworth/Heinemann, London).

Agyakwa

P. A.

Creep and microstructural development in P91 weldments at elevated temperature. PhD Thesis, University of Nottingham, 2004.

Hyde

T. H.

Sun

A unit cell approach to the analysis of the anisotropic creep behaviour of a 9CrMoNbV weld metal. Proceedings of ECCC Creep Conference on

Creep and Fractures in High Temperature Components — Design and Life Assessments Issues, London, 12-14 September 2005, pp. 499–509.

Evans

G. M.

Bailey

Metallurgy of basic weld metal, 1997 (Woodhead Publishing, Cambridge), 432 pp.

Brett

S. J.

The creep strength of weak thick section modified 9Cr forgings. Baltica V Conference on

Condition and Life Management for Power Plants, vol. 1, VTT Manufacturing Technology, Porvoo, Finland, June 2001, pp. 35–44.

Hayhurst

D. R.

Creep rupture under multi-axial states of stress

J. Mech. Phys. Solids, 1972, 20, 381–390.

10.

ABAQUS Version 6.3, Hibbitt, Karlsson and Sorenson Inc., 2002.

11.

Hyde

T. H.

Sun

Becker

A. A.

Creep crack growth in welds: A damage mechanics approach to predicting initiation and growth of circumferential cracks

Int. J. Pres. Ves. Piping, 2001, 78, 765–771.

12.

Hyde

T. H.

Sun

Becker

A. A.

Assessment of the use of finite element creep steady-state stresses for predicting the creep life of welded pipes. In Proceedings of Fourth International Conference on

Computational Structures Technology, 1998 (Ed. BHV Topping ) (Civil-Comp Press, Edinburgh), pp. 247–251.

13.

Reed

R. C.

Bhadeshia

H. K.D.H.

A simple model for multipass steel welds

Acta Metall. Mater., 1994, 42 (11), 3663–3678.

A Study of Anisotropic Creep Behaviour of a 9CrMoNbV Weld Metal Using Damage Analyses with a Unit Cell Model

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