A Functional Coefficients Version of a Generalized Orr–Sherby–Dorn Creep Model: An Application to 2.25Cr

A Functional Coefficients Version of a Generalized Orr–Sherby–Dorn Creep Model: An Application to 2.25Cr–1Mo Steel

Published:2024-06-08 Issue:8 Volume:55 Page:2811-2824
ISSN:1073-5623
Container-title:Metallurgical and Materials Transactions A
language:en
Short-container-title:Metall Mater Trans A

Author:

Evans M.

Abstract

AbstractIt is important to be able to predict the creep life of materials used in power plants. This paper illustrates the inadequacies of the Orr–Sherby–Dorn (OSD) creep model in achieving this aim for 2.25Cr–1Mo steel. This failure is explained in terms of non-constant model parameters—which in turn is the result of changing creep mechanisms. The paper introduces a semi-parametric estimation procedure for a variant of the OSD model (a structural coefficients version) that can be used to deal with such changing creep mechanisms while maintaining the structure of the model and consequently producing more reliable long-term predictions compared to the unmodified OSD model and the recently introduced LOESS technique. For 2.25Cr–1Mo steel, it was found that the model parameters varied in line with changing creep mechanisms, but in a modified way compared to that already suggested in the literature for this material. The models used suggested that with diminishing stress and increasing temperature, dislocation creep within the crystal structure morphs into grain boundary dislocation motion and finally Nabarro-Herring creep.

Publisher

Springer Science and Business Media LLC

Link

https://link.springer.com/content/pdf/10.1007/s11661-024-07437-1.pdf

Reference19 articles.

1. S. R. Holdsworth and G. Merckling: ECCC developments in the assessment of creep-rupture data. In: Proceedings of the Sixth International Charles Parsons Conference on Engineering Issues in Turbine Machinery, Power Plant and Renewables, Trinity College, Dublin, 16–18 September 2003.

2. F.R. Larson and J.A. Miller: Trans. ASME, 1952, vol. 174, p. 5.

3. S. S. Manson, and A. M. Haferd: A linear time-temperature relation for extrapolation of creep and stress-rupture data. NACA Technical Note 2890; National Advisory Committee for Aeronautics: Cleveland, 1953. Materials 2017, 10, 1190 29 of 30 15.

4. J. E. Dorn and L. A. Shepherd: What we need to know about creep. In: Proceedings of the STP 165 symposium on the effect of cyclical heating and stressing on metals at elevated temperatures, Chicago, 17 June 1954.

5. F.C. Monkman and N.J. Grant: Proc. Am. Soc. Test. Mater., 1956, vol. 56, pp. 593–620.