We present a survey of works devoted to the investigation of the fatigue fracture of steels under the conditions of transverse shear. Numerous methods aimed at the determination of the characteristics of cyclic crack resistance of structural steels of different strength classes are analyzed. The analysis of the results of investigations enables us to make a conclusion about the necessity of improvement of the available methods and development of new methods for the construction of the kinetic diagrams of fatigue fracture with regard for the influence of friction of the lips of fatigue cracks on the stress intensity factor K II and the elimination of stresses in the vicinity of the crack tip.
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References
RD 50-260-81. Methodical Recommendation. Strength Analyses and Tests in Mechanical Engineering. Methods for Mechanical Tests of Metals. Determination of the Characteristics of Crack-Growth Resistance (Fracture Toughness) under Cyclic Loading [in Russian], Izd. Standartov, Moscow (1983).
V. T. Troshchenko, V. V. Pokrovskii, and A. V. Prokopenko, Crack Resistance of Metals under Cyclic Loading [in Russian], Naukova Dumka, Kiev (1987).
V. V. Panasyuk (editor), Fracture Mechanics and Strength of Materials, Vol. 4: О. N. Romaniv, S. Ya. Yarema, G. N. Nikiforchin, et al., Fatigue and Cyclic Crack Resistance of Structural Materials [in Russian], Naukova Dumka, Kiev (1990).
I. O. Vakulenko, V. H. Anofriev, M. A. Hryshchenko, and O. P. Perkov, Defects of Railroad Wheels [in Ukrainian], Vyd. Makovets’kyi, Dnipropetrovs’k (2009).
E. L. Sheinman, “Defects of rails. Review of foreign publications,” Put’ Putev. Khoz., No. 3, 29–32 (2007).
V. V. Panasyuk, О. P. Ostash, О. P. Datsyshyn, et al., “Service life of railroad wheels of high-strength steel,” in: Problems of the Service Life and Safety of Operation of Structures, Buildings, and Machines [in Ukrainian], Paton Institute of Electric Welding, Kyiv (2009), pp. 659–663.
M. O. Wang, R. H. Hu, C. F. Qian, and J. C. M. Li, “Fatigue crack growth under mode II loading,” Fatig. Fract. Eng. Mater. Struct., 18, No. 12, 1443–1454 (1995).
Ya. L. Ivanyts'kyi, S. T. Shtayura, Т. M. Lenkovs‘kyi, and Yu. V. Mol’kov, “Determination of the parameters of crack resistance for 17G1S steel under transverse shear,” Fiz.-Khim. Mekh. Mater., 49, No. 5, 73–78 (2013); English translation: Mater. Sci., 49, No. 5, 637–643 (2013).
S. H. Song and J. M. Lee, “Mode II fatigue crack behavior in compact tension shear specimen,” Key Eng. Mater., 297–300, 1592–1597 (2005).
P. E. Bold, M. W. Brown, and R. J. Allen, “Shear mode crack growth and rolling contact fatigue,” Wear, 144, Nos. 1–2, 307–317 (1991).
Y. Murakami, C. Sakae, and S. Hamada, “Mechanism of rolling contact fatigue and measurement of ∆K IIth for steels,” in: J. H. Beynon, M. W. Brown, Lindley, et al. (editors), Engineering Against Fatigue, A. A. Balkema Publ., Rotterdam (1999), pp. 473–485.
C. Pinna and V. Doquet, “The preferred fatigue crack propagation mode in M250 maraging steel loaded in shear,” Fatig. Fract. Eng. Mater. Struct., No. 22, 173–183 (1999).
A. Otsuka, Y. Fujii, and K. Maeda, “A new testing method to obtain mode II fatigue crack growth characteristics of hard materials,” Fatig. Fract. Eng. Mater. Struct., 27, No. 3, 203–212 (2004).
A. K. Hellier and K. Zarrabi, “On the mode II fatigue threshold for mild steel,” Int. J. Fract., 167, No. 2, 267–272 (2011).
J. Pokluda, B. Trattnig, C. Martinschitz, and R. Pippan, “Straightforward comparison of fatigue crack growth under modes II and III,” Int. J. Fatigue, No. 30, 1498–1506 (2008).
M. Liu and S. Hamada, “Measurement of effective stress intensity factor range of mode II fatigue crack propagation,” Procedia Eng., No. 10, 1949–1954 (2011).
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Translated from Fizyko-Khimichna Mekhanika Materialiv, Vol. 50, No. 3, pp. 29–37, May–June, 2014.
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Lenkovs’kyi, Т.M. Determination of the Characteristics of Cyclic Crack Resistance of Steels Under Transverse Shear (A Survey). Mater Sci 50, 340–349 (2014). https://doi.org/10.1007/s11003-014-9725-4
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DOI: https://doi.org/10.1007/s11003-014-9725-4