Study of the Effect of Low Cycle Fatigue on the Parameters of Fracture Mechanics Using Speckle Interferometry

Evolution of the parameters of fracture mechanics at different stages of low cycle damage is analyzed. The developed approach is based on processing the results of optical interferometric measurements of the deformation response to a small increment of the crack length. Three consecutive symmetrical notches are used to simulate the process of fatigue crack propagation through the zone of accumulated damage induced by low cycle fatigue. The magnitude of tangential component of the displacement measured at several points on the edge of the notch using speckle-inter-ferometry is an input experimental data. The first four coefficients of the Williams series solution are used to determine the stress intensity factor (SIF) and T-stress values. The values of crack opening, SIF and T-stress for cracks of different lengths are obtained at a fixed number of preliminary loading cycles N_c = 0, 100, 1000, 1800, 2500, and 3300. The dependences of the parameters of fracture mechanics for the cracks of fixed length on N_c number which illustrate a process of fatigue damage accumulation are constructed.

low-cyclic fatigue, stress intensity factor, T-stress, method of successively increasing crack length (crack compliance method), speckle-interferometry, малоцикловая усталость, коэффициент интенсивности напряжений, Т-напряжения, метод последовательного наращивания длины трещины, электронная спекл-интерферометрия

1. Osgood C. C. Fatigue Design. 2nd edition. - Oxford, U.K.: Pergamon Press, 1982. - 606 p.

2. Махутов H. А. Деформационные критерии разрушения и расчет элементов конструкций на прочность. - М.: Машиностроение, 1981. -271 с.

3. Collins J. A. Failure of Materials in Mechanical Design: Analysis, Prediction, Prevention, 2nd edition. - NY, Chichester, Brisbane, Toronto, Singapure: John Wiley & Sons, 1993. - 672 p.

4. Воробьев А. З., Олькин Б. И., Стебенев В. Н. Сопротивление усталости элементов конструкций. - М.: Машиностроение, 1990. - 240 с.

5. Makhutov N., Matvienko Yu., Chernyakov S. A unified methodological approach to calculation analysis of the stages of nucleation and growth of low-cycle fatigue cracks / Materials Science. 1993. Vol. 29. N2. P. 109-114.

6. Chiang F.-P. Moiré and speckle methods applied to elastic-plastic fracture studies. In: Experimental Techniques in Fracture mechanics, 3rd edition / Edited by J. S. Epstein. - NY: VCH, 1993. P. 291 - 325.

7. Post D., Han B., Ifju P. High Sensitivity Moiré. Experimental Analysis for Mechanics and Materials. - Berlin: Springer Verlag, 1994. - 444 p.

8. Shchepinov V. P., Pisarev V. S., Novikov S. A., Balalov V. V., Odintsev I. N., Bondarenko M. M. Strain and Stress Analysis by Holographic and Speckle Interferometry. - Chichester: John Wiley, 1996. - 483 p.

9. Lee C., Chao Y. J., Sutton M. A., Peters W. H., Ranson W. E. Determination of plastic strains at notches by image-processing methods / Experimental Mechanics. 1989. Vol. 29. N 2. P. 214 - 220.

10. Steckenrider J., Wagner J. Computed speckle decorrelation (CSD) for the study of fatigue damage / Optics & lasers in Engineering. 1995. Vol. 22.N1. P. 3-15.

11. Diaz E. V., Kaufmann G. H., Armas A. E., Galizzi G. E. Optical measurement of the plastic zone size in a notched metal specimen subjected to low-cycle fatigue / Optics & lasers in Engineering. 2001. Vol. 35. N6. P. 325 -333.

12. Diaz E. V., Armas A. E., Kaufmann G. H., Galizzi G. E. Fatigue damage accumulation around a notch using a digital image measurement system / Experimental Mechanics. 2004. Vol. 44. N 3. P. 241 - 246.

13. Lopez-Crespo P., Burguete R. L., Patterson E. A., Shterenlikht A., Withers P. J., Yates J. R. Study of a crack at a fastener hole by digital image correlation / Experimental Mechanics. 2009. Vol. 49. N 4. P. 551 - 559.

14. Писарев В. С., Матвиенко Ю. Г., Одинцев И. Н. Определение параметров механики разрушения при малом приращении длины трещины / Заводская лаборатория. Диагностика материалов. 2012. Т. 78. №4. С. 45-51.

15. Matvienko Y. G., Pisarev V. S., Eleonsky S. I., Chernov A. V. Determination of fracture mechanics parameters by measurements of local displacements due to crack length increment / Fatigue & Fracture of Engineering Materials & Structures. 2014. Vol. 37. N 12. P. 1306 - 1318.

16. Digital Speckle Pattern Interferometry and Related Techniques / P. Rastogi (editor). -West Sussex: John Wiley, 2001. - 384 p.

17. Williams M. L. On the stress distribution at the base of a stationary crack / ASME Journal of Applied Mechanics. 1957. Vol. 24. N 1. P. 109-114.

18. Yates J. R., Zanganeh M., Tai Y. H. Quantifying crack tip displacement fields with DIC / Engineering Fracture Mechanics. 2010. Vol. 77. N 11. P. 2063 - 2076.

19. Pisarev V. S., Odintsev I. N., Apalkov A. A., Chernov A. V. Role of high-quality interference fringe patterns for the residual stress deter mination by the hole-drilling method / Visualization of Mechanical Processes. 2011. Vol. 1. N 1. DOI: 10.1615/VisMechProc.v1.i1.40.

20. Справочник по коэффициентам интенсивности напряжений: В 2-х томах. Т. 1 / Пер. с англ.; под ред. Ю. Мураками. - М.: Мир, 1990. - 448 с.

21. Писарев В. С., Городниченко В. И., Гришин В. И. Объемное деформированное состояние в растягиваемой полосе с отверстием по данным экспериментального, расчетного и комбинированного методов / Ученые записки ЦАГИ. 1989. Т. 20. № 5. С. 67 - 75.

22. Сиратори М., Миёси Т., Мацусита X. Вычислительная механика разрушения. - М.: Мир, 1986. - 334 с.