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INFLUENCE OF TEMPERATURE AND LOADING PROGRAM ON THE FATIGUE LIFE OF STEEL P91

Stanisław Mroziński
Stanisław Mroziński
 and 
Michał Piotrowski
Michał Piotrowski
   | Dec 31, 2013
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Published Online: Dec 31, 2013
Page range: 93 - 98
DOI: https://doi.org/10.2478/ama-2013-0017
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1. ASTM E606-92: Standard Practice for Strain -Controlled Fatigue.Search in Google Scholar

2. Byrne J., Kan N. Y. K. (1999), Hussey I.W., Harrison G.F.: Influence of sub-surface defects on low-cycle fatigue life in a gas turbine disc alloy at elevated temperature, International Journal of Fatigue, 21, 195-206Search in Google Scholar

3. Fatemi A., Yang L. (1998), Cumulative Fatigue Damage and Life Prediction Theories: A Survey of the State of the Art for Homogeneous Materials, International Journal of Fatigue, 20, 9-34.10.1016/S0142-1123(97)00081-9Search in Google Scholar

4. Junak G., Cieśla M. (2010), Low cycle life at graded load for steel in power generators, Energetyka, 21, 74-77 (in Polish).Search in Google Scholar

5. Junak G., Cieśla M. (2011), Effect of graded loads on low cycle durability of steel P91 i P92 used in power generation, Inżynieria materiałowa, 32, 5, 862-867 (in Polish).Search in Google Scholar

6. Junak G., Cieśla M. (2011), Low-cycle fatigue of P91 and P92 steels used in the power engineering industry, Archives of Materials Science and Engineering, vol. 48 nr 1, 19-24.Search in Google Scholar

7. Manson S. S., Halford G. R. (1986), Re-Examination of Cumulative Fatigue Damage Analysis - an Engineering Perspective, Engineering Fracture Mechanics, 25(5/6), 539-571.10.1016/0013-7944(86)90022-6Search in Google Scholar

8. Miner M. A. (1945), Cumulative Damage in Fatigue, Transactions of the American Society of Mechanicals Engineers Journal of Applied Mechanics, 67, 159-164.10.1115/1.4009458Search in Google Scholar

9. Mroziński S. (2011), The influence of loading program on the course of fatigue damage cumulation, Journal of Theoretical and Applied Mechanics, 49, 1, 83-95.Search in Google Scholar

10. Mroziński S., Skocki R. (2012), Influence of temperature on the cyclic properties of martensitic cast steel, Materials Science Forum, Vol. 726, 150-155.Search in Google Scholar

11. Nagesha A., Valsan M., Kannan R., Bhanu Sankara Rao K., Mannan S.L. (2002), Influence of temperature on the low cycle fatigue behaviour of a modified 9Cr-1 Mo ferritic steel, International Journal of Fatigue, 24, 1285-1293.10.1016/S0142-1123(02)00035-XSearch in Google Scholar

12. Nagode M., Zingsheim M. (2004), An online algorithm for temperature influenced fatigue life estimation: strain-life approach, International Journal of Fatigue, 26, 155-161.10.1016/S0142-1123(03)00108-7Search in Google Scholar

13. Palmgren A. (1924), Die Lebensdauer von Kugellagem Verfahrenstechnik, Berlin, 68, 339-341.Search in Google Scholar

14. Szala J., Fatigue damage summation hypothesis, University ATR in Bydgoszcz (in Polish).Search in Google Scholar

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