1. bookVolumen 62 (2018): Edición 4 (December 2018)
Detalles de la revista
License
Formato
Revista
eISSN
1804-1213
Primera edición
03 Apr 2012
Calendario de la edición
4 veces al año
Idiomas
Inglés
Acceso abierto

Influence of hydrate formation and wall shear stress on the corrosion rate of industrial pipeline materials

Publicado en línea: 25 Jan 2019
Volumen & Edición: Volumen 62 (2018) - Edición 4 (December 2018)
Páginas: 121 - 128
Detalles de la revista
License
Formato
Revista
eISSN
1804-1213
Primera edición
03 Apr 2012
Calendario de la edición
4 veces al año
Idiomas
Inglés

1. Stetsiuk, S. M. Otsinka vplyvu dotychnykh napruzhen ta yikh pulsatsii na propusknu zdatnist hazoprovodu. Rozvidka ta rozrobka naftovykh i hazovykh rodovyshch2013, 2, 72-78.Search in Google Scholar

2. Mazur M. Matematychne modeliuvannia vnutrishnotrubnoi korozii truboprovodiv pid diieiu hazohidrativ. Visnyk TNTU2014, 76 (4), 88-102.Search in Google Scholar

3. di Caprio, D., Vautrin-Ul, C., Stafiej, J., Saunier, J., Chaussé, A., Féron, D. and Badiali, J.P. Morphologyof Corroded Surfaces: Contribution of Cellular Automaton Modelling. Corrosion Science2011, 53 (1), 418–425.10.1016/j.corsci.2010.09.052Search in Google Scholar

4. Estupinan-Lopez, F.H. Almeraya-Calderon, F., Bautista Margulis, R.G., Zamora, M.A.B., MartínezVillafane1, A., Ch., J.U. and Gaona-Tiburcio, C. Transient Analysis of Electrochemical Noise for 316 and Duplex 2205 Stainless Steels under Pitting Corrosion. Int. J. Electrochem. Sci.2011, 6, 1785–1796.Search in Google Scholar

5. van Hunnik E.W.J., Pots B.F.M., Hendriksen E.L.J.A. The formation of protective FeCO3 corrosion product layers in CO2 corrosion. Proceedings of conference NACE CORROSION 1996. Paper No. 006.Search in Google Scholar

6. Nesic, S, Xiao, Y. and Pots, B.F.M. A Quasi 2-D Localized Corrosion Model. Proceedings of conference NACE CORROSION 2004. Paper No. 04628.Search in Google Scholar

7. Obanijesu E.O., Akindeju M.K., Pareek V. and Tade M.O. Modeling the Natural Gas Pipeline Internal Corrosion Rate as a Result of Hydrate Formation. Elsevier 21st European Symposium on Computer-Aided Process Engineering. (Part B), 1160-1164.10.1016/B978-0-444-54298-4.50011-8Search in Google Scholar

8. Soares C.G and Garbatov Y. Reliability of Maintained, Corrosion Protected Plate Subjected to Non-linear Corrosion and Compressive Loads. Marine Structures1999, 12 (6), 425-446.10.1016/S0951-8339(99)00028-3Search in Google Scholar

9. Qin S and Cui W. Effect of Corrosion Models on the Time-Dependent Reliability of Steel Plated Elements. Marine Structures2003, 16 (1), 15-34.10.1016/S0951-8339(02)00028-XSearch in Google Scholar

10. Paik J. L., Hwang J. and Park Y. A Time-Dependent Corrosion Wastage Model for the Structures of Single and Double Hull Tankers and FSOs and FPSOs. Marine Technology2003, 40 (3), 201-217.10.5957/mt1.2003.40.3.201Search in Google Scholar

11. Ivanov L., Spencer J. and Wang G. Probabilistic Evaluation of Hull Structure Renewals for Aging Ships. Proceedings of the 8th International Marine Design Conference (IMDC) 2003. 5-8 May. Athens, Greece, 393-406.Search in Google Scholar

12. Wang W. and Free M.L. Prediction and Measurement of Mild Steel Corrosion Inhibition by Alkyl Pyridinium Chloride and Alkyl Trimethyl Ammonium Bromide Surfactants in Acidic Chloride Media. Anti-Corrosion Methods and Materials2003, 50 (3), 186-192.10.1108/00035590310471750Search in Google Scholar

13. Garbatov Y., Soares C.G., and Wang G. Non-linear Time Dependent Corrosion Wastage of Deck Plates of Ballast and Cargo Tanks of Tankers. Proceedings of the 24th International Conference on Offshore Mechanics and Arctic Engineering (ASME) 2005. Paper OMAE2005-67579.10.1115/OMAE2005-67579Search in Google Scholar

14. Soares C.G, Garbatov Y, Zayed A. and Wang G. Non-linear Corrosion Model for Immersed Steel Plates Accounting for Environmental Factors. Proceedings of Marine Technology Conference & Expo 2005. New Jersey. 193-211.10.5957/SMC-2005-D21Search in Google Scholar

15. Melchers R. Effect on Marine Immersion Corrosion of Carbon Content of Low Alloyed Steels. Corrosion Science2003, 45 (11), 2609-2625.10.1016/S0010-938X(03)00068-4Search in Google Scholar

16. NORSORK STANDARD. CO2 Corrosion Rate Calculation Model. Norwegian Technological Standards Institute. Oscarsgt. 20. Majorstural. NORWAY.Search in Google Scholar

17. Mohyaldin M. E., Elkhatib N., Ismail M.C. Coupling NORSOK CO2 corrosion prediction model with pipelines thermal/hydraulic models to simulate CO2 corrosion along pipelines. Journal of Engineering Science and Technology2011, 6 (6), 709 – 719.Search in Google Scholar

18. Nyborg, R. CO2 Corrosion Models for Oil and Gas Production Systems. Proceedings of conference NACE CORROSION 2010. Paper No. 10371.Search in Google Scholar

19. Mamaev V.A., Odisharia G.E., Semenov N.I., Tochigin A.A. Dvizhenie gazozhidkostnykh smesei v trubakh. Moskva: Nedra. 1978. p. 270.Search in Google Scholar

20. Rozrobka ta ekspluatatsiia hazovykh i hazokondensatnykh rodovyshch. Navchalnyi posibnyk. Ivano-Frankivsk:Nova Zoria. 2015. p. 288.Search in Google Scholar

21. de Waard C., Lotz U. and Williams D. E. Predictive model for CO2 corrosion engineering in wet natural gas pipeline. Corrosion1991, 47 (12), 976-985.10.5006/1.3585212Search in Google Scholar

Artículos recomendados de Trend MD

Planifique su conferencia remota con Sciendo