International Journal of Environmental Monitoring and Analysis
Volume 3, Issue 5, October 2015, Pages: 373-376
Received: Dec. 3, 2015;
Published: Dec. 3, 2015
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Chen Liu, Environmental Protection and Energy Saving Center, China Waterborne Transport Research Institute, Beijing, China
The marine organism attaching to the ship hull would slow down the ship and increasing fuel consumption. In order to prevent the problem, anti-fouling paints are used to coat the bottoms of ships. At the same time, the harmful environmental effects of these paints such as tributyltin have been recognized. The International Convention on the Control of Harmful Anti-fouling Systems on Ships was adopted by the IMO in 2001 to prohibit the use of harmful organotins in anti-fouling paints used on ships. As the invention entered into force internationally, the most important work is to develop new material to replace the traditional coating. In this work, we summarize the development of anti-fouling paints all over the world and introduce the progress of the latest research.
Development of Anti-fouling Coating Using in Marine Environment, International Journal of Environmental Monitoring and Analysis.
Vol. 3, No. 5,
2015, pp. 373-376.
Coneski P. N., Weise N. K., Fulmer P. A., et al. Development and evaluation of self-polishing urethane coatings with tethered quaternary ammonium biocides [J]. Progress in Organic Coatings, 2013, 76: 1376-1386.
Fabrice A., Fabienne F., Karine R, et al. Development of hybrid anti-fouling paints [J]. Progress in Organic Coatings, 2015, 87: 10-19.
Lin C. H., Yeh Y. H., Lin W. C., et al. Novel silicone hydrogel based on PDMS and PEGMA for contact lens application [J]. Colloids and Surfaces B: Biointerfaces, 2014, 123: 986-994.
Marceaux S., Bressy C. Development of polyorganosilazane–silicone marine coatings [J]. Progress in Organic Coatings, 2014, 77: 1919-1928.
Gui T. J. Preparation and Characterization of the Organic Silicone/Fluorine Antifouling Coatings with Low Surface Energy [D]. Ocean University of China, 2008.
Qiu W. G. Investigation of marine antifouling coatings based on silicones [D]. Dalian Maritime University, 2011.
Martinelli E, Suffredini M, Galli G, et al. Amphiphilic block copo-lymer/poly (dimethylsiloxane) (PDMS) blends and nanocompos-ites for improved fouling-release [J]. Biofouling, 2011, 27(5): 529-541.
Chen M., Ding F., Xu L., et al. Low surface energy anti-fouling coatings based on nano- SiO2/fluorine-silicon modified acrylic resin [J]. Paint & Coatings Industry, 2010, 2010, 40(5): 11-15.
Tsoukatou M, Marechal JP, Hellio Cetal. Evaluation of the activity of the sponge metabolites avarol and avarone and their synthetic derivatives against fouling micro-and macro organisms [J]. Molecules, 2007, 12: 1022-1034.
Gao M. Extraction and performance study of antifouling compounds produced by marine microorganism and microalgae [D]. Ocean University of China, 2014.
Qian P. Y., Xu Y. and Fusetani N. Natural products as anti-fouling compounds: recent progress and future perspectives. Biofouling, 2010, 26(2): 223–234.
Shi H. W., Liu F. C., Wang Z. Y., et al. Research Progress ofCorrosion-resisting Paints for Marine Application [J]. CORROSION SCIENCE AND PROTECTION TECHNOLOGY, 2010, 22 (1): 43-46.
Xu Q, et al. Evaluation of toxicity of capsaicin and zosteric acid and their potential application as antifoulants [J]. Environ Toxicol, 2005, 20: 467-474.
Fischer. Marine organism repellent covering for Protection of underwater objects and method of applying same [P]. US005226380A, 1993-07-13.
Yan X. F., Yu L. M. and Jiang X. H. Synthesis of acrylamides containing capsaicin derivative and their bacteriostatic activity and antifouling capability [J]. Periodical of Ocean University of China, 2013, 43: 64-67.
Fu Z. Y., Wang Q., Jia L. N., et al. The synthesis and application of isothiazolone derivativatives for recent decade [J]. Materials Review, 2012, 291-296.
Shi H., Shi J. G., Chen X. L., et al. Application in marine antifouling coating [J]. Polymer Bulletin, 2011, 01: 65-70.