PSI - Issue 36

Halyna Krechkovska et al. / Procedia Structural Integrity 36 (2022) 43–50

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Halyna Krechkovska, Viktor Sylovanyuk, Oleksandra Student et al. / Structural Integrity Procedia 00 (2021) 000 – 000

Hredil, M., Krechkovska, H., Student, O., Kurnat, I., 2019. Fractographic features of long term operated gas pipeline steels fracture under impact loading. Procedia Structural Integrity 21, 166 – 172. Krechkovs’ka 1 , H.V., 2016. Fractographic signs of the mechanisms of transportation of hydrogen in structural steels. Materials Science 51(4), 509 – 513. Krechkovs’ka 2 , H. V, Student, O. Z., 2017. Determination of the degree of degradation of steels of steam pipelines according to their impact toughness on specimens with different geometries of notches. Materials Science 52(4), 566 – 571. Krechkovs’ka 3 , H. V., Student, O. Z., Nykyforchyn, H. M. 2019. Diagnostics of the engineering state of steam pipeline of thermal power plants by the hardness and crack resistance of steel. Materials Science 54(5), 627 – 637. Krechkovs'ka 4 , G. V., 2008. Structural changes in exploitation of steam power plant pipeline 15Kh1M1F-type steel concerning with shut downs of power units. Metallofizika i Noveishie Tekhnologii 30, Is. Spec. 701 – 711. Lesiuk 1 , G., Smolnicki, M., Rozumek, D., Krechkovska, H., Student, O., Correia, J, Jesus, A., 2020. Study of the fatigue crack growth in long term operated mild steel under mixed-mode (I + II, I + III) loading conditions. Materials 13. 160 – 171. Lesiuk 2 , G., Correia, J.A.F.O., Krechkovska, H.V., Jesus, A.M.P., Student O., 2021. Degradation theory of long term operated materials and structures. Springer: Structural Integrity 15. 205. Maruschak P., Baran D., Sorochak A., Bischak R., Iasnii V., 2012. Cyclic crack resistance and micro-mechanisms fracture of 25Cr1Mo1V steel. Strength of Materials 4(418), 88 – 98. Maruschak, P., Vorobel, R., Student, O., Ivasenko, I., Krechkovska, H., Berehulyak, O., Mandziy, T., Svirska, L., Prentkovskis, O., 2021. Estimation of fatigue crack growth rate in heat-resistant steel by processing of digital images of fracturesurfaces. Metals 11, 1776. Murakami 1 , Y., Usuki, H., 1989. Prediction of fatigue strength of high-strength steels based on statistical evaluation of inclusion size. Trans. Jpn. Soc. Mech. Eng., A. 55 (510), 213 – 221. Murakami 2 , Y., 2002. Metal fatigue effect of small defects and n onmetallic inclusionsions. Elsevier, 369 р. Nazarov, S.A., 1997. Invariant integrals in the Leonov-Panasyuk-Dugdale model of a crack. J Appl Mech Tech Phys 38, 784 – 791. Nykyforchyn, H.M., Student , O.Z., Krechkovs’ka, H.V., Markov, A.D., 2010. Evaluation of the influence of shutdowns of a technological process on changes in the in-service state of the metal of main steam pipelines of thermal power plants. Materials Science 46(2). 177 – 189. Ostash, O. P., Kondyr, A. I., Vol'demarov, O. V., Hladysh, P. V., Kurechko, M. V., 2009. Structural microdamageability of steels of the steam pipelines of thermal power plants. Materials Science 45(3). 340 – 349. Robson 1 , J.D., Bhadeshia, H.K.D.H., 1997. Modelling Precipitation Sequences in Power Plant Steels. Part 1: Kinetic Theory. Materials Science and Technology 13, 631 – 639. Robson 2 , J.D., Bhadeshia, H.K.D.H., 1996. Kinetics of Precipitation in Power Plant Steels. Calphad 20(4), 447. Pietryka, I., Lisak, J. 2010. The identification of carbide phases by XRD analysis as the method of assess the extent of the steel damage after long time in service. Archives of Foundry Engineering. 10(3), 283 – 288. Romaniv, O. M., Nykyforchyn, H. M., Dzioba, I. R.,.Student, O. Z., Lonyuk, B. P, 1998. Effect of damage in service of 12Kh1MF steam-pipe steel on its crack resistance characteristics. Materials Science 34(1), 110 – 114. Sidorenko, V. M., Fedorov, V. V., Barabash, L. V., Pokhmurskii, V. I., 1978. Acceleration of self-diffusion processes in metals under the influence of dissolved hydrogen. Materials Science 13(6). 607 – 610. Smiyan, О.D., Student, О.Z. , 2021. Fractographic signs of gigacycle fatigue and hydrogenation of heat-resistant steels after long-term operation. Materials Science. Strang, A., Vodarek, V., 1996. Z phase formation in martensitic 12CrMoVNb steel. Mater Sci Technol 12, 552. Student 1 , O. Z., Krechkovs’ka , H. V., 2012. Anisotropy of the mechanical properties of degraded 15Kh1M1F steel after its operation in steam pipelines of thermal power plants Materials Science 47(5), 590 – 597. Student 2 , O.Z., Krechkovs’ka , H.V, Palashchuk, T.E., Hladkyi, Ya.М., 2018. Influence of the Long- Term Operation of 12Kh1МF Steel of the Bends of Main Steam Pipelines of Thermal Power Plants on Its Mechanical Properties. Materials Science 53(4), 460 – 467. Student 3 , О. Z., Krechkovs’ka, H. V., Nykyforchyn, H. М., Kurnat, І. М., 2019. F ractographic criterion of attainment of the critical technical state by carbon steels. Materials Science 55 (2), 160 – 167. Student 4 , O.Z., 1998. Accelerated method for hydrogen degradation of structural steel. Material Science. 34 (4), 497 – 507. Vytvytskiy, P.M., 1970. Elastic-plastic equilibrium of a plate with a periodic system of slits. Reports. USSR Academy of Sciences. Ser. A. 6., 524 – 527. Yasniy, O., Pyndus, Yu., Iasnii, V., Lapusta, Y., 2017. Residual lifetime assessment of thermal power plant superheater header. Engineering Failure Analysis 82., 390 – 403. Yasniy 1 , P.V., Maruschak, P.O., Panin, S.V., Bischak, R.T., Vuherer, T., Ovechkin, B.B., Panin, V.E., 2011. Temperature effect on impact fracture of 25CrlMolV ferrite-pearlite steel. Physical Mesomechanics 14 (3-4), 185 – 194. Yasniy 2 , P.V., Okipnyi, I.B., Maruschak, P.O., Panin, S.V., Konovalenko, I.V., 2013. Crack tip strain localisation on mechanics of fracture of heat resistant steel after hydrogenation, Theoretical and Applied Fracture Mechanics 63-64, 63 – 68. Yasniy 3 , P.V., Okipnyi, I.B., Maruschak, P.O., Bishchak, R.T., Sorochak, A.P., 2011. Toughness and failure of heat resistant steel before and after hydrogenation, Theoretical and Applied Fracture Mechanics 56(2), 63 – 67. Hu, Z.-F., 2012. Heat-resistant steels, microstructure evolution and life assessment in power plants. In: Thermal Power Plants. Ed. Mohammad Rasul. InTech 10, 195 – 226. Zvirko, O. I, Кryzhanivskyi, E.I, Nykyforchyn, H. М. , Krechkovska, H.V., 2021. Methods for the Evaluation of Corrosion-Hydrogen Degradation of Steels of Oil-and-Gas Pipelines. Materials Science 56, 585 – 592.