Influence of pitting corrosion on fatigue and corrosion fatigue of ship structures. Part I. Pitting corrosion of ship structures

• Autorzy: Jakubowski M.
• Języki publikacji: EN

Abstrakty

EN

The present paper is a literature survey focused on a specific kind of corrosion, i.e. pitting corrosion and its influence on fatigue of ship and offshore steels. Mechanisms of a short- and long-term pitting corrosion in marine environment have been described including pit nucleation and growth phases. Some models of pit growth versus time of exposure have been presented. Some factors which influence the pit growth rate have been discussed briefly

• Wydawca: -
• Czasopismo: Polish Maritime Research
• Rocznik: 2014
• Tom: 21
• Numer: 1
• Opis fizyczny: p.62-69,fig.,ref.

Twórcy

autor

Jakubowski M.

• Faculty of Ocean Engineering and Ship Technology, Gdansk University of Technology, Narutowicza 11/12, 80-952 Gdansk, Poland

Bibliografia

• 1. Domański A., Birn J.: Corrosion of ships and their prevention (in Polish). Wydawnictwo Morskie, Gdańsk, 1970,
• 2. Melchers R.E.: Development of new applied models for steel corrosion in marine applications including shipping. SAOS, 2008, Vol.3, No.2, pp.135-144.
• 3. Shi P., Mahadevan S.: Probabilistic corrosion fatigue life prediction. 8th ASCE Specialty Conference: Probabilistic Mechanics and Structural Reliability. 2000
• 4. Zhang R., Mahadevan S.: Reliability based reassessment of corrosion fatigue life. Structural Safety, 2001, Vol.23, pp.77-91.
• 5. Butler G., Stretton P., Beynon J.G.: Initiation and growth of pits on high purity iron and its alloys with chromium and copper in neutral chloride solution. British Corrosion Journal, 1972, Vol.7. July, pp. 168-173.
• 6. Wang Q.Y., Kawagoishi N., Chen Q.: Effect of pitting corrosion on very high cycle fatigue behaviour. Scripta Materialia 2003, Vol.49, pp.711-716.
• 7. Wranglen G.: Pitting and sulphide inclusions in steel. Corrosion Science, 1974, Vol.14, pp.319-349.
• 8. Melchers R.E.: Pitting corrosion of mild steel in marine immersion environment – Part 1: Maximum pit depth. Corrosion, 2004, Vol.60, No. 9, pp.824-836.
• 9. Melchers R.E.: Pitting corrosion under marine anaerobic conditions – Part 1: Experimental observations. 2006, Vol.62, No. 11, pp.981-988.
• 10. Akid R., Dmytrakh I.M., Gonzales-Sanchez J.: Fatigue damage accumulation: the role of corrosion on the early stages of crack development. Corrosion Engineering, Science and Technology, 2006, Vol.41, No.4, pp.328-335.
• 11. Nakai T., Matsushita H., Yamamoto N., Arai H.: Effect of pitting corrosion on local strength of hull structural members. Class NK Technical Bulletin, 2005, pp.29-49.
• 12. Ishihara S., Saka S., Nan Z.Y., Goshima T., Sunada S.: Prediction of corrosion fatigue lives of aluminium alloy on the basis of corrosion pit growth law. Fatigue & Fracture of Engineering Materials & Structures, 2006, Vol.29, pp.472-480.
• 13. Novokshchenov V.: Brittle fracture of prestressed bridge steel exposed to chloride-bearing environment by corrosiongenerated hydrogen. Corrosion, 1994, Vol.50, No.6, pp.477-484.
• 14. Biezma M.V., Rio-Cologne B.: Influence of various marine conditions on corrosion behaviour of AISI C1118 steel. Inżynieria Materiałowa (Material Engineering), 2001, Vol. 22, No.4, pp.227-230.
• 15. Linder J., Blom R.: Development of a method for corrosion fatigue life prediction of structurally loaded bearing steel. Corrosion, 2001, Vol. 57, No.5, pp.404-412.
• 16. Kumakura Y., Takanashi M., Fuji A., Kitagawa M., Ojima M., Kobayashi Y.: Fatigue strength of coated steel plate in seawater. Proc. Ninth Int. Offshore and Polar Engineering Conference, Brest, France, May 30 – June 4, 1999, Vol.4, pp. 108-113.
• 17. Kawai S., Kasai K.: Considerations of allowable stress of corrosion fatigue (focused on the influence of pitting). Fatigue & Fracture of Engineering Materials & Structures, 1985, Vol.8, pp.115-127.
• 18. Wang Y., Wang Y., Huang X. Cui W.: A simplified maximum pit depth model of mild and low alloy steels in marine immersion environment. Journal of Ship Mechanics, 2008, Vol.6, No.1, pp.401-417.
• 19. Kobzaruk K.A.V., Marichev V.A.: Corrosion and corrosion fatigue resistance of steels in real marine environment and in laboratory (in Russian). Physical Chemical Mechanics of Materials,1981, Vol.16, No 2, pp.15-21.
• 20. Melchers R.E.: Pitting corrosion under marine anaerobic conditions – Part 2: Statistical representation of maximum pit depth, 2006, Vol.62, No 12, pp.1074-1081.
• 21. Salvarezza R.C., Videla H.A.: Passivity breakdown of mild steel in seawater in the presence of sulphate reducing bacteria. Corrosion, 1980, Vol.36, No.10, pp.550-554.
• 22. Matoba M., Yamamoto N., Watanabe T., Umino M.: Effect of corrosion and its protection on hull strength (1st report) (in Japanese). J. Society of the Naval Architects of Japan, 1994, Vol.175, pp.271-280.
• 23. Nakai T., Matsushita H., Yamamoto N.: Effect of pitting corrosion on the ultimate strength of steel plates subjected to in-plane compression and bending. J. Marine Science and Technology, 2006, pp.52-64.
• 24. Wang Y, Wu X., Zhang Y., Huang X., Cui W.: Pitting corrosion model of mild and low-alloy steel in marine environment – Part 2: The shape of corrosion pit (in Chinese). Journal of Ship Mechanics, 2007, Vol.11, No.5.
• 25. Yuasa M, Watanabe T.: Fatigue strength of corroded weld joints. Class NK Technical Bulletin, 1996, Vol.14, pp.51-61.
• 26. Matsushita H., Nakai T., Yamamoto N.: A study on static strength of corroded fillet welded joints for ship structures (in Japanese). J. Society of the Naval Architects of Japan, 2004, Vol. 195, pp.291-297.
• 27. Cui N., Qiao L.J., Luo J.L., Chiovelli S.: Pitting of carbon steel with banded microstructures in chloride solutions. British Corrosion Journal, 2000, Vol.35.
• 28. Boukerrou A., Cottis R.A.: Crack initiation in the corrosion fatigue of structural steels in salt solutions. Corrosion Science, 1993, Vol.35, pp.577-585.
• 29. Miller K.J., Akid R.: The application of microstructural Fracture Mechanics to various metal surface states. Proc. Royal Society A ?, 1996, Vol. 452, pp. 1411-1432.
• 30. Konda N., Suzuki S., Tada N., Kho Y., Kazushige A., Watanabe E., Yamamoto M and Yaima H.: Effect of microstructure on fatigue properties of steel in seawater – development of steels for high resistance to fatigue in ships, Part 2. J. Soc. Naval Architects of Japan, 2001, Vol.191, pp.229-237.
• 31. Dolley E.J., Lee B., Wei R.P.: The effect of pitting corrosion on fatigue life. Fatigue & Fracture of Engineering Materials & Structures, 2000, Vol.23, pp.555-560.
• 32. Sankaran K.K., Perez R., Jata K.V.: Effect of pitting corrosion on the fatigue behaviour of aluminium alloy 7075-T6: Modelling and experimental studies. Materials Science and Engineering, 2001, Vol. A 297, pp223-229.

Identyfikatory

DOI

10.2478/pomr-2014-0009