Fractographic Regularities in Fatigue Failure of 17Mn1Si Steel

Pavlo Maruschak; Sergey Panin; Ilya Vlasov; Iryna Danyliuk; Roman Bishchak

doi:10.4028/www.scientific.net/AMR.1040.230

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HomeAdvanced Materials ResearchAdvanced Materials Research Vol. 1040Fractographic Regularities in Fatigue Failure of...

Fractographic Regularities in Fatigue Failure of 17Mn1Si Steel

Abstract:

Using the scanning electron microscopy data the main regularities of the fatigue crack propagation in the 17Mn1Si steel were studied. Based on fracture surface observation and analysis one can testify that the transition of the leading role of deformation and failure from the lower structural level to the higher one has the ordered pattern.

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Periodical:

Advanced Materials Research (Volume 1040)

Pages:

230-235

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.1040.230

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Online since:

September 2014

Authors:

Pavlo Maruschak, Sergey Panin, Ilya Vlasov, Iryna Danyliuk, Roman Bishchak

Keywords:

Failure Analysis, Fatigue, Fracture, Gas Pipeline, Structure

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References

[1] P. Maruschak, L. Poberezhny, T. Pyrig, Fatigue and brittle fracture of carbon steel of gas and oil pipelines, Transport, 28 (2013) 270-275.

DOI: 10.3846/16484142.2013.829782

Google Scholar

[2] Y. Kondo, Prediction of fatigue crack initiation life based on pit growth, Corrosion, 45 (1989) 7-11.

DOI: 10.5006/1.3577891

Google Scholar

[3] G.S. Chen, K.C. Wan, M. Gao, R.P. Wei, T.H. Flournoy, Transition from pitting to fatigue crack growth - modeling of corrosion fatigue crack nucleation in a 2024-T3 aluminum alloy, Materials Science and Engineering A, 219 (1996) 126-132.

DOI: 10.1016/s0921-5093(96)10414-7

Google Scholar

[4] V.S. Ivanova, Discreteness and self-similarity of failure in stable fatigue crack growth, Strength of Materials, 14 (1983) 675-684.

DOI: 10.1007/bf00767610

Google Scholar

[5] T.F. Elsukova, V.E. Panin, Fatigue failure mechanism of polycrystalline materials at the mesoscopic level, Russian Physics Journal 39 (1996) 534-547.

DOI: 10.1007/bf02437018

Google Scholar

[6] V.E. Panin, V.E. Egorushkin, L.S. Derevyagina, E.E. Deryugin, Nonlinear wave processes of crack propagation in brittle and brittle-ductile fracture, Physical Mesomechanics 16 (2013) 183-190.

DOI: 10.1134/s1029959913030016

Google Scholar

[7] H.M. Nykyforchyn, Effect of hydrogen on the kinetics and mechanism of fatigue crack growth in structural steels, Materials Science, 33 (1997) 504-515.

DOI: 10.1007/bf02537547

Google Scholar

[8] L.R. Botvina, M.R. Tyutin, Formation of a cascade of plastic zones under cyclic loading of low-carbon steels, Doklady Physics, 52 (2007) 674-676.

DOI: 10.1134/s1028335807120087

Google Scholar

[9] I.B. Okipnyi, P.O. Maruschak, O. Prentkovskis Structural-hierarchical mechanism of cracking of reactor steel after preliminary thermomechanical loading, Proc. of 9-th Int. Conf. «Mechatronic Systems and Materials», 1-3 July, Vilnius, Lithuania, 2013, 188.

DOI: 10.4028/www.scientific.net/ssp.220-221.720

Google Scholar