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Abstrakty
The article presents an accelerated method for fatigue limit calculation which makes use of constant temperature increase rate observed in the middle time interval of specimen fatigue loading. The examination was performed on specimens prepared from drawn rods made of corrosion resistant austenitic steel X5CrNi18-10 (1.4301) subjected to rotating bending. For comparison purposes, the fatigue limit was also calculated with the aid of the Staircase method, using 30 specimens and assuming the base number of cycles equal to 10・106. Three specimens were used for accelerated examination during which their temperature was measured with the aid of the thermographic camera CEDIP Silver 420M (FLIR SC 5200). The applied loads were gradually increased until specimen damage took place. Based on the analysis of temperature changes during specimen loading, the average rate of temperature increase at successive loading stages was assessed. The obtained results were then approximated using the 2-nd order curve and its minimal value was assumed as corresponding to the fatigue limit. The performed statistic test has revealed that the fatigue limit calculated in the above way does not differ substantially from that determined using the Staircase method.
Słowa kluczowe
Czasopismo
Rocznik
Tom
Strony
64--69
Opis fizyczny
Bibliogr. 24 poz., rys., tab.
Twórcy
autor
- UTP University of Science and Technology, Faculty of Mechanical Engineering, Department Laboratory for Research on Materials and Structures, 7 Kaliskiego Street, 85-796 Bydgoszcz, Poland
Bibliografia
- 1. Kozak, J., Gorski, Z.: Fatigue strength determination of ship structural joints. Part I. Polish Maritime Research, No. 2(69), Vol. 18, 28–36 (2011).
- 2. Szala, G.: Comments on linear summation hypothesis of fatigue failures. Polish Maritime Research, No. 3(83), Vol. 21, 77–85 (2014).
- 3. Skibicki, D.: Experimental verification of fatigue loading nonproportionality model. Journal of Theoretical and Applied Mechanics, 45, 2, 337–348 (2007).
- 4. Skibicki, D.: Multiaxial fatigue life and strength criteria for non-proportional loading. Materials Testing, 48, 3, 99–102 (2006).
- 5. Dixon, W.J.: The Up-and-Down Method for Small Samples. Journal of the American Statistical Association, 60, 312, 967–978 (1965).
- 6. Dixon, W.J., Mood, A.M.: A Method for Obtaining and Analyzing Sensitivity Data. Journal of the American Statistical Association, 43, 241, 109–126 (1948).
- 7. Collins, J.A.: Failure of materials in mechanical design - analysis, prediction, prevention. John Wiley & Sons, New York (1993).
- 8. Radaj, D.: Design and analysis of fatigue resistant welded structures. Abington, Woodhead Publishing (1990).
- 9. Szala, J.: Application of programmed fatigue tests to evaluating fatigue limit. Mechanika Teoretyczna I Stosowana, 3, 26, 523–539 (1988) - in Polish.
- 10. Lipski, A.: Determination of Fatigue Limit by Locati Method using S-N Curve Determined by Means of Thermographic Method. Solid State Phenomena, 223, 362–373 (2014).
- 11. Lipski, A.: Impact of the Strain Rate during Tension Test on 46Cr1 Steel Temperature Change. Key Engineering Materials, 598, 133–140 (2014).
- 12. Lipski, A., Boroński, D.: Use of Thermography for the Analysis of Strength Properties of Mini-Specimens. Materials Science Forum, 726, 156–161 (2012).
- 13. Lipski, A., Lis, Z.: Temperature Changes Induced by the Portevin-Le Chatelier (PLC) Effect during Tensile Test Based on the Example of CuZn37 Brass. Solid State Phenomena, 224, 238–243 (2014).
- 14. Kaleta, J., Błotny, R., Harig, H.: Energy Stored In A Specimen Under Fatigue Limit Loading Conditions. Journal Of Testing And Evaluation, 19, 4, 326-333 (1991).
- 15. Audenino, A.: Correlation between thermography and internal damping in metals. International Journal of Fatigue, 25, 4, 343–351 (2003).
- 16. Doudard, C., Calloch, S., Hild, F., Roux, S.: Identification of heat source fields from infrared thermography: Determination of “self-heating” in a dual-phase steel by using a dog bone sample. Mechanics of Materials, 42, 1, 55–62 (2010).
- 17. Lipski, A., Skibicki, D.: Variations of the Specimen Temperature Depending on the Pattern of the Multiaxial Load – Preliminary Research. Materials Science Forum, 726, 162–168 (2012).
- 18. La Rosa, G., Risitano, A.: Thermographic methodology for rapid determination of the fatigue limit of materials and mechanical components. International Journal of Fatigue. 22, 1, 65–73 (2000).
- 19. Luong, M.P.: Infrared thermographic scanning of fatigue in metals. Nuclear Engineering and Design, 158, 2-3, 363–376 (1995).
- 20. Luong, M.P.: Fatigue limit evaluation of metals using an infrared thermographic technique. Mechanics of Materials, 28, 1, 155–163 (1998).
- 21. Cura, F., Curti, G., Sesana, R.: A new iteration method for the thermographic determination of fatigue limit in steels. International Journal of Fatigue, 27, 4, 453–459 (2005).
- 22. Galietti, U., Palumbo, D., De Finis, R., Ancona, F.: Fatigue limit evaluation of martensitic steels with thermal methods. The 12th International Conference of Quantitative Infrared Thermography, QIRT, Bordeaux (2014).
- 23. Li, X.D., Zhang, H., Wu, D.L., Liu, X., Liu, J.Y.: Adopting lock-in infrared thermography technique for rapid determination of fatigue limit of aluminum alloy riveted component and affection to determined result caused by initial stress. International Journal of Fatigue, 36, 1, 18–23 (2012).
- 24. Kordatos, E.Z., Dassios, K.G., Aggelis, D.G., Matikas, T.E.: Rapid evaluation of the fatigue limit in composites using infrared lock-in thermography and acoustic emission. Mechanics Research Communications, 54, 14–20 (2013).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-cc841ddd-21e0-434b-b339-154b5b096367