[[1] 9th Report of the European Gas Pipeline Incident Data Group (period 1970 – 2013) https://www.egig.eu/startpagina/$61/$156]Search in Google Scholar
[[2] Prinz, W. “AC induced corrоsion on cathodically protected pipelines”, UK Corrosion 92, vol.1, pp. 503 – 514, 1992.]Search in Google Scholar
[[3] Stalder, F. “Pipelines failures”, Materials Science Forum 247, pp. 139 – 146, 1997.10.4028/www.scientific.net/MSF.247.139]Search in Google Scholar
[[4] Wakelin, R. G. “AC corrosion – case histories, test procedures, and mitigation“ / R. G. Wakelin, R. A. Gummow, S. M. Segall // Conference: Corrosion 98, San Diego CA, USA, Paper number 565, pp. 316 – 324, 1998]Search in Google Scholar
[[5] Heim, G., Peez G. “The influence of alternating current on buried and cathodically protected high pressure gas pipelines”, Gas-Erdgas 133 (3), 1992.]Search in Google Scholar
[[6] Ragault I. “AC corrosion induced by VHV electrical lines on polyethylene coated steel gas pipelines”, Corrosion 98, NACE, paper n°557, 1998.]Search in Google Scholar
[[7] Induced AC Interference, Corrosion & Mitigation Prepared for NACE / Pipeliners Joint Meeting Atlanta, GA April 8, 2013 Bryan Evans, Vice President, Corrosion & Integrity Solutions Grayson, GA., 2013.]Search in Google Scholar
[[8] Wakelin, R.G., Sheldon, C. “Investigation and Mitigation of AC Corrosion on a 300 mm Diameter Natural Gas Pipeline,” CORROSION 2004, Paper No. 04205 (Houston, TX: NACE International, 2004), 2004.]Search in Google Scholar
[[9] Neilsen, L. V., Neilsen, K. V., Baumgarten B., Breuning-Madsen H., Cohn, P., Rosenburg H. “AC-Induced Corrosion in Pipelines: Detection, Characterisation, and Mitigation”, CORROSION 2004, Paper No. 04211 (Houston, TX: NACE International, 2004), 2004.]Search in Google Scholar
[[10] Peabody A. W. “Control of Pipeline Corrosion”, NACE, Second Edition, p. 374, 2001.]Search in Google Scholar
[[11] The CEOCOR Booklet, “AC corrosion on cathodically protected pipelines. Guidelines for risk assessment and mitigation measures”, APCE, p. 44., 2001.]Search in Google Scholar
[[12] “Guide on the influence of high voltage AC power systems on metallic pipelines”, CIGRE Working Group 36.02, 1995.]Search in Google Scholar
[[13] Maruschak, P., Poberezny, L., Prentkovskis, O., Bishchak, R., Sorochak, A., Baran, D. “Physical and mechanical aspects of corrosion damage of distribution gas pipelines after long-term operation”, Journal of failure analysis and prevention 18(3), pp. 562 – 567, 2018. DOI: 10.1007/s11668-018-0439-z10.1007/s11668-018-0439-z]Open DOISearch in Google Scholar
[[13] HOST 9.602-2005 «Edynaya systema zashchyty ot korrozyy y starenyya. Konstruktsiyi pidzemni. Zahal’ni vymohy do zakhystu vid korroziyi ».- 55 s. [In Ukrainian]]Search in Google Scholar
[[14] BN-85/2320-01 Rurociągi stalowe układane w ziemi. Określanie zagrojenia korozyjnego, 1985.]Search in Google Scholar
[[15] PN-90/E-05030/01 Ochrona przed korozją. Elektrochemiczna ochrona katodowa. Metalowe konstrukcje podziemne. Wymagania i badania, 1990.]Search in Google Scholar
[[16] PN-EN 12954:2004 Ochrona katodowa konstrukcji metalowych w gruntach lub w wodach. Zasady ogólne i zastosowania dotyczące rurociągów.]Search in Google Scholar
[[17] CEN/TS 15280, “Evaluation of a.c. corrosion likelihood of buried pipelines - Application to cathodically protected pipelines”, Technical Specification, CEN - European Committee for Standardization, 2006.]Search in Google Scholar
[[18] Poberezhny, L., Maruschak, P., Hrytsanchuk, A., Mischuk, B., Draganovska, D., & Poberezhna, L. “Impact of AC current density on material corrosion of distribution pipelines”, Koroze a ochrana materialu 61(5), pp. 178 – 184, 2017. DOI: 10.1515/kom-2017-002310.1515/kom-2017-0023]Open DOISearch in Google Scholar
[[19] Kryzhanivs’kyi, E. I., Hrabovs’kyi, R. S., Fedorovych, I. Y., Barna, R. A. “Evaluation of the Kinetics of Fracture of Elements of a Gas Pipeline after Operation”, Materials Science 51(1), pp. 7 – 14, 2015.10.1007/s11003-015-9804-1]Search in Google Scholar
[[20] Tsyrul’nyk, O. T., Nykyforchyn, H. M., Petryna, D. Y., Dz’oba, I. M. “Hydrogen degradation of steels in gas mains after long periods of operation”, Materials Science 43(5), pp. 708 – 717, 2007.10.1007/s11003-008-9010-5]Search in Google Scholar
[[21] Speight, J. G. “Lange’s handbook of chemistry”, (Vol. 1, p. 242). New York: McGraw-Hill. 2005.]Search in Google Scholar
[[22] Tsyrul’nyk, O. T., Nykyforchyn, H. M., Zvirko, O. I., & Petryna, D. Y. “Embrittlement of the steel of an oil-trunk pipeline”, Materials Science 40 (2), pp. 302 – 304, 2004.10.1007/s11003-005-0018-9]Search in Google Scholar
[[23] Kryzhanivskyy YE. I. “Korroziyno-vodneva dehradatsiya hazotransportnykh system” / YE. I. Kryzhanivskyy, H. M. Nykyforchyk // Naukovi zapysky. - 2013. - Vyp. 41 (1). - pp. 148 – 153, 2013. [In Ukrainian]]Search in Google Scholar
[[24] Uorf, R.A. “Otsinka korroziynoyi aktyvnosti seredovyshch Salymskykh naftovykh rodovyshch z tochky zoru mozhlyvostey vyklykaty sulfidne rozshcheplennya promyslovykh truboprovodiv ta obladnannya” / R.A. Uorf, A.B. Kychenko // Praktyka protykorrozyonnoyi zakhystu. - 2012. - № 1 (63). - pp. 42 – 49, 2012. [In Russian]]Search in Google Scholar
[[25] Moi, S. C., Pal, P. K., Bandyopadhyay, A., Rudrapati, R. “Determination of Tungsten Inert Gas Welding Input Parameters to Attain Maximum Tensile Strength of 316L Austenitic Stainless Steel” Journal of Mechanical Engineering – Strojnícky časopis 68 (3), pp. 231 – 248, 2018. DOI: 10.2478/scjme-2018-003710.2478/scjme-2018-0037]Open DOISearch in Google Scholar
[[26] Kumar, N., Mukherjee, M., Bandyopadhyay, A. “Study on laser welding of austenitic stainless steel by varying incident angle of pulsed laser beam”, Optics & Laser Technology 94, pp. 296 – 309, 2017. DOI: 10.1016/j.optlastec.2017.04.00810.1016/j.optlastec.2017.04.008]Open DOISearch in Google Scholar
[[27] Valkovič V., Jančo R., Frydrýšek K. “The effect of landslide on gas pipeline”, Journal of Mechanical Engineering – Strojnícky časopis, 66 (2), pp. 95 – 100, 2016. DOI:10.1515/scjme-2016-002310.1515/scjme-2016-0023]Open DOISearch in Google Scholar
