PSI - Issue 36

Halyna Krechkovska et al. / Procedia Structural Integrity 36 (2022) 334–341 Halyna Krechkovska, Volodymyr Kulyk, Volodymyr Vira et al. / Structural Integrity Procedia 00 (2021) 000 – 000

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Hredil 2 , 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. Hredil 3 , M, Krechkovskа, H, Student, O., Tsyrulnyk, O., 2020. Brittle fracture manifestation in gas pipeline steels after long term operation. Procedia Structural Integrity 28, 1204 – 1211. Kosarevych, R. Ya., Student, O. Z., Svirs’ka, L. M., Rusyn, B. P., Nykyforchyn, H. M., 2013. Computer analysis of characteris tic elements of fractographic images. Materials Science 48 (4), 474 – 481. Krechkovs'ka 1 , 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, 701 – 711. Krechkovs’ka 2 , H. V, Student, O. Z., Kutnyi, A., I., Nykyforchyn, H. M., Sydor, P. Ya., 2015. Brittle-fracture resistance of the metal of hyperboloid gridshell Shukhov tower. Materials Science 50, 4. 578 – 584. Krechkovs’ka 3 , 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, 566 – 571 Krechkovs’ka 4 , H. V., Tsyrul’nyk O. T., Student O. Z., 2019. In-service degradation of mechanical characteristics of pipe steels in gas mains. Strength of Materials 51 (3), 406 – 417. Krechkovs’ka 5 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 Krechkovska 6 , H., Hredil, M., Student, O., 2021. Structural and fractographic features of gas pipeline steel degradation. Book Chapter: Lecture Notes in Civil Engineering 102. 45 – 59. Kryzhanivs’kyi, E. І., Nykyforchyn, H. M., 2011. Specific features of hydrogen-induced corrosion degradation of steels of gas and oil pipelines and oil storage reservoirs. Materials Science 47(2), 127 – 136. Lesiuk, G., Correia, J.A.F.O., Krechkovska, H.V., .Jesus, A.M.P., Student, O., 2021. Case studies: Structural, fractographic and mechanical aspects of the steels degradation of the hyperboloid gridshell towers. Structural Integrity 15, 95 – 125. Maruschak, P. O., Danyliuk, I. M., Bishchak, R. T., Vuherer, T., 2014. Low temperature impact toughness of the main gas pipeline steel after long-term degradation. Cent. Eur. J. Eng 4, 408 – 415. Nechaev Yu.S. 2008. Metallic materials for the hydrogen energy industry and main gas pipelines: complex physical problems of aging, embrittlement, and failure. Uspekhi Fizicheskikh Nauk 51(7), 681 – 697. Nykyforchyn 1 , H. M., Banakhevych, Yu. V., Mytsyk, A. B., Kostiv, V. V. 2016. The role of in-service degradation of gas mains steels in loss of their integrity. Oil and Gas Power Engineering 2(26), 35 – 40. Nykyforchyn 2 , H., Tsyrulnyk, O., Zvirko, O., Krechkovska, H., 2019. Non-destructive evaluation of brittle fracture resistance of operated gas pipeline steel using electrochemical fracture surface analysis . Engineering Failure Analysis 104, 617 – 625. Nykyforchyn 3 , H., Tsyrulnyk, O., Zvirko, O., Hredil, M., 2020. Role of hydrogen in operational degradation of pipeline steel. Procedia Structural Integrity 28, 896 – 902. Nykyforchyn 4 , H., Zvirko, O., Dzioba, I., Krechkovska, H., Hredil, M., Tsyrulnyk, O., Student, O., Lipiec, S., Pala, R., 2021. Аssessment of operational degradation of pipeline steels. Materials 14, 3247 – 3262. Ohaeri, E., Eduok, U., Szpunar , J., 2018. Hydrogen related degradation in pipeline steel: A review. Int. J. Hydrogen Energy 43, 14584 – 14617. Okipnyi, I., Poberezhny, L., Zapukhlia, V., Hrytsanchuk, A., Poberezhna, L., Stanetsky, A., Kravchenko, V., Rybitskyi, I., 2020. Impact of long term operation on the reliability and durability of transit gas pipelines. Stroj. Casopis 70, 115 – 126. Orynyak, I.V., Zarazovskii, М.N. , Bogdan, A.V., 2015. A Method for the Evaluation of the Critical Temperature of Brittleness with Regard for the Spread of the Experimental Data on Impact Toughness. Materials Science 51(1), 23 – 36. Ostash 1 , O. P., Andreiko, I. M., Kulyk, V. V., Vavrukh, V. I., 2013. Influence of braking on the microstructure and mechanical behavior of railroad wheel steels. Materials Science 48(5). 569 – 574. Ostash 2 , O. P., Panasyuk, V. V., Andreiko, I. M., Chepil, R. V., Kulyk V. V., Vira, V. V., 2007. Methods for the construction of the diagrams of fatigue crack-growth rate of materials. Materials Science 43(4). 479 – 491. Rykavets, Z. M., Bouquerel, J., Vogt, J.-B., Duriagina, Z. A., Kulyk, V. V., Tepla, T. L., Bohun L. I., Kovbasyuk T. M., 2019. Investigation of the microstructure and properties of trip 800 steel subjected to low-cycle fatigue. Progress in Physics of Metals 20(4), 620 – 633. 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., Nykyforchyn, H. M., Kurnat, I. M., 2019. Fractographic criterion of attainment of the critical technical state by carbon steels. Materials Science 55(2), 160 – 167. Tsyrulnyk 1 O. T., Nykyforchyn H. M., Zvirko O. I., Petryna D. Yu., 2004. Embrittlement of the steel of an oil-trunk pipeline. Materials Science 2, 302 – 304. Tsyrulnyk 2 O. T., Slobodyan Z. V., Zvirko O. I., Hredil’ M. I., Nykyforchyn H. M., Gabetta G., 2008. Influence of operation of Kh52 steel on corrosion processes in a model solution of gas condensate. Materials Science 5, 619 – 629. Zurnadzhy, V. I., Efremenko, V. G., Petryshynets, I., Shimizu, K., Brykov, M. N., Kushchenko, I. V., Kudin, V. V., 2020. Mechanical properties of carbide-free lower bainite in complex-alloyed constructional steel: Effect of bainitizing treatment parameters. Kovove Mater 58, 129 – 140. Zvirko, O.I., Kret, N.V., Tsyrulnyk, O.T., Vengrynyuk, T. P., 2018. Influence of textures of pipeline steels after operation on their brittle fracture resistance. Materials Science 54(3), 400 – 405.