Citations (35)
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Read on this site (11)
Yukio Takahashi. (2020) Modelling of rupture ductility of metallic materials for wide ranges of temperatures and loading conditions, part I: development of basic model. Materials at High Temperatures 37:6, pages 357-369.
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Yukio Takahashi. (2020) Modelling of rupture ductility of metallic materials over wide ranges of temperatures and loading conditions, part II: comparison with strain energy-based approach. Materials at High Temperatures 37:5, pages 340-350.
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R. P. Skelton. (2017) Deformation, diffusion and ductility during creep – continuous void nucleation and creep-fatigue damage. Materials at High Temperatures 34:2, pages 121-133.
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Stuart Holdsworth. (2017) Creep ductility of 1CrMoV rotor steel. Materials at High Temperatures 34:2, pages 99-108.
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A. Pineau & S. D. Antolovich. (2015) High temperature fatigue: behaviour of three typical classes of structural materials. Materials at High Temperatures 32:3, pages 298-317.
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R. P. Skelton. (2013) The energy density exhaustion method for assessing the creep-fatigue lives of specimens and components. Materials at High Temperatures 30:3, pages 183-201.
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Mikolaj Lukaszewicz, Nigel J. Simms, Tomasz Dudziak & John R. Nicholls. (2012) Characterisation of oxide scales developed on high temperature resistant alloys in pure steam environments. Materials at High Temperatures 29:3, pages 210-218.
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Stuart Holdsworth. (2011) Creep-fatigue interaction in power plant steels. Materials at High Temperatures 28:3, pages 197-204.
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M.W. Spindler. (2008) Effects of dwell location on the creep-fatigue endurance of cast Type 304L. Materials at High Temperatures 25:3, pages 187-196.
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M. W. Spindler. (2007) An improved method for calculation of creep damage during creep–fatigue cycling. Materials Science and Technology 23:12, pages 1461-1470.
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E. Mazza, S. R. Holdsworth & R.P. Skelton. (2004) Characterisation of the creep-fatigue behaviour of a 1CrMoV turbine steel. Materials at High Temperatures 21:3, pages 119-128.
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Articles from other publishers (24)
Tianyu Zhang, Xiaowei Wang, Xianxi Xia, Yong Jiang, Xiancheng Zhang, Liguo Zhao, Anish Roy, Jianming Gong & Shantung Tu. (2023) A robust life prediction model for a range of materials under creep-fatigue interaction loading conditions. International Journal of Fatigue 176, pages 107904.
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Shengde Zhang & Yukio Takahashi. (2023) Creep-fatigue life and damage evaluation under various strain waveforms for Ni-based Alloy 740H. International Journal of Fatigue 176, pages 107833.
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Le Xu, Run-Zi Wang, Yu-Chen Wang, Lei He, Takamoto Itoh, Ken Suzuki, Hideo Miura & Xian-Cheng Zhang. (2023) Microstructural evolutions and life evaluation of non-proportional creep-fatigue considering loading path and holding position effects. Materials Characterization 204, pages 113209.
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Jingwei Zhang, Jie Li, Jingyi Zan, Zijian Guo & Kanglin Liu. (2022) A Creep Constitutive Model, Based on Deformation Mechanisms and Its Application to Creep Crack Growth. Metals 12:12, pages 2179.
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Le XU, Run-Zi WANG, Ji WANG, Lei HE, Takamoto ITOH, Hideo MIURA, Xian-Cheng ZHANG & Shan-Tung TU. (2022) On multiaxial creep–fatigue considering the non-proportional loading effect: Constitutive modeling, deformation mechanism, and life prediction. International Journal of Plasticity 155, pages 103337.
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J. Eaton-Mckay, K. Yan, M.D. Callaghan & E. Jimenez-Melero. (2022) Creep deformation phenomena in near-surface carburised layers of 316H stainless steels. Materials Science and Engineering: A 842, pages 143029.
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Raheeg Ragab, Jonathan Parker, Ming Li, Tao Liu, Andy Morris & Wei Sun. (2022) Requirements for and challenges in developing improved creep ductility-based constitutive models for tempered martensitic CSEF steels. Journal of Materials Research and Technology 17, pages 3337-3360.
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J. Eaton-Mckay, K. Yan, M.D. Callaghan & E. Jimenez-Melero. (2022) Creep performance of carburized 316H stainless steel at 550 °C. Journal of Nuclear Materials 558, pages 153329.
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Dawei Ji, Xianming Hu, Zuopeng Zhao, Xu Jia, Xuteng Hu & Yingdong Song. (2021) Stress Rupture Life Prediction Method for Notched Specimens Based on Minimum Average Von Mises Equivalent Stress. Metals 12:1, pages 68.
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Hermann Riedel, Gerhard Maier & Heiner Oesterlin. (2021) A lifetime model for creep-fatigue interaction with applications to the creep resistant steel P92. International Journal of Fatigue 150, pages 106308.
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Xiao-Cheng Zhang, Jian-Guo Gong, Fu-Hai Gao & Fu-Zhen Xuan. (2021) An Improved Creep-Fatigue Life Model Involving the Cyclic Softening/Hardening and Stress Relaxation Effect. Journal of Pressure Vessel Technology 143:4.
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Warwick Payten. (2019) A reassessment of the multiaxial ductility C* creep crack growth equation based on the strain energy integral of the HRR singular field terms. Engineering Fracture Mechanics 217, pages 106530.
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Stuart Holdsworth. (2019) Creep-Ductility of High Temperature Steels: A Review. Metals 9:3, pages 342.
Crossref
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E.A. Hares, M. Mostafavi, R. Bradford & C.E. Truman. (2018) The effect of creep strain rate on damage accumulation in Type 316H austenitic stainless steel. International Journal of Pressure Vessels and Piping 168, pages 132-141.
Crossref
Crossref
Jing-Dong Hu, Fu-Zhen Xuan & Chang-Jun Liu. (2018) A void growth model of multiaxial power-law creep rupture involving the void shape changes. International Journal of Mechanical Sciences 144, pages 723-730.
Crossref
Crossref
Yu-Cai Zhang, Wenchun Jiang, Shan-Tung Tu, Xian-Cheng Zhang & You-Jun Ye. (2017) Creep crack growth behavior analysis of the 9Cr-1Mo steel by a modified creep-damage model. Materials Science and Engineering: A 708, pages 68-76.
Crossref
Crossref
Sunil Goyal, K. Laha & A. K. Bhaduri. (2016) Response of Triaxial State of Stress to Creep Rupture Life and Ductility of 316 LN Austenitic Stainless Steel. Journal of Materials Engineering and Performance 26:2, pages 752-763.
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Jian-hua Pan, Zhi-cao Fan & Ning-sheng Zong. (2016) Research on weld cracking of TP321H stainless steel pipeline under elevated temperature. International Journal of Pressure Vessels and Piping 148, pages 1-8.
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Jian-Feng Wen, Shan-Tung Tu, Fu-Zhen Xuan, Xue-Wei Zhang & Xin-Lin Gao. (2016) Effects of Stress Level and Stress State on Creep Ductility: Evaluation of Different Models. Journal of Materials Science & Technology 32:8, pages 695-704.
Crossref
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Jian-Feng Wen & Shan-Tung Tu. (2014) A multiaxial creep-damage model for creep crack growth considering cavity growth and microcrack interaction. Engineering Fracture Mechanics 123, pages 197-210.
Crossref
Crossref
Stefan HolmströmRami PohjaWarwick Payten. (2014) Creep-Fatigue Interaction Models for Grade 91 Steel. Materials Performance and Characterization 3:2, pages 20130054.
Crossref
Crossref
Warwick M. Payten, Ken U. Snowden & David W. Dean. (2013) Effects of Prior Stress Relaxation on the Prediction of Creep Life Using Time and Strain Based Methods. Journal of Pressure Vessel Technology 135:4.
Crossref
Crossref
Stuart Holdsworth. (2010) Advances in the assessment of creep data during the past 100 years. Transactions of the Indian Institute of Metals 63:2-3, pages 93-99.
Crossref
Crossref
Stuart Holdsworth. (2008) The European Creep Collaborative Committee (ECCC) Approach to Creep Data Assessment. Journal of Pressure Vessel Technology 130:2.
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