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Materials at High Temperatures Volume 37, 2020 - Issue 5
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Research Article

Modelling of rupture ductility of metallic materials over wide ranges of temperatures and loading conditions, part II: comparison with strain energy-based approach

Yukio TakahashiCentral Research Institute of Electric Power Industry, Tokyo, JapanCorrespondence[email protected]
Pages 340-350 | Received 09 Apr 2020, Accepted 12 Jul 2020, Published online: 13 Aug 2020

References

  • Takahashi Y. Modelling of rupture ductility of metallic materials for a wide range of temperature and loading conditions, Part I: development of basic model. Mater High Temp. (to be published).
  • e.g. Spindler MW. The multiaxial and uniaxial creep ductility of Type. 304 steel as a function of stress and strain rate. Mater High Temp. 2004;21:47–54.
  • Takahashi Y, Dogan B, Gandy B Systematic evaluation of creep-fatigue life prediction methods for various alloys. Proceedings of the ASME 2009 Pressure Vessels & Piping Conference; 2009; Prague, Czech Republic. p. PVP2009–77990. also published in J Press Vessel Tech, 2013;135:061204-1-10.
  • Takahashi Y, Gandy D Creep-fatigue behavior of Grade 92 steel and its predictability. Proceedings of the ASME 2011 Pressure Vessels & Piping Division Conference; 2011; Baltimore, Maryland, USA. p. PVP2011–57976.
  • Takahashi Y, Parker J, Gandy D Creep-fatigue interaction in Grade 92 steel and its predictability. Advances in Materials Technology for Fossil Power Plants: Proceedings from the Seventh International Conference; ASM International; 2014; Hawaii, USA. p. 667–678.
  • Payten WM, Dean DW, Snowden KU. A strain energy density method for the prediction of creep–fatigue damage in high temperature components. Mater Sci Eng A. 2010;527:1920–1925.
  • Skelton RP. The energy density exhaustion method for assessing the creep-fatigue lives of specimens and components. Mater High Temp. 2013;30(3):183–201.
  • Payten WM, Dean DW, Snowden KU. Analysis of creep ductility in a ferritic martensitic steel using a hybrid strain energy technique. J Mater Sci Tech. 2016;32:695–704.
  • Wang R-Z, Zhang X-C, Tu S-T, et al. A modified strain energy density exhaustion model for creep–fatigue life prediction. Int J Fatigue. 2016;90:12–22.
  • Takahashi Y. Unified constitutive modeling of three alloys under a wide range of temperature. Int J Press Vess Piping. 2019;172:166–179.
  • Takahashi Y. Study on creep-fatigue evaluation procedures for high-chromium steels—Part I: test results and life prediction based on measured stress relaxation. Int J Press Vess Piping. 2008;85:406–422.
  • Takahashi Y, Shibamoto H, Inoue K. Long-term creep rupture behavior of smoothed and notched bar specimens of low-carbon nitrogen-controlled 316 stainless steel (316FR) and their evaluation. Nucl Engng Design. 2008;238:310–321.

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