叶章基,陈珊珊,马春风,吴建华,张广照.新型环保海洋防污材料研究进展[J].表面技术,2017,46(12):62-70.
YE Zhang-ji,CHEN Shan-shan,MA Chun-feng,WU Jian-hua,ZHANG Guang-zhao.Development of Novel Environment-friendly Antifouling Materials[J].Surface Technology,2017,46(12):62-70
新型环保海洋防污材料研究进展
Development of Novel Environment-friendly Antifouling Materials
投稿时间:2017-06-09  修订日期:2017-12-20
DOI:10.16490/j.cnki.issn.1001-3660.2017.12.012
中文关键词:  海洋防污  自抛光  防污功能基团  主链降解  减阻  仿生材料
英文关键词:marine antifouling  self-polishing  antifouling functional groups  main-chain degradation  drag reduction  biomimetic materials
基金项目:“十三五”国家海洋经济创新发展示范项目(16CZB023SF12);海洋公益科研专项(201305016);福建省海洋生物资源开发利用协同创新中心产学研基金(FJMBIO1504)
作者单位
叶章基 1.华南理工大学,广州 510640;2.海洋腐蚀与防护重点实验室,福建 厦门 361101;3.厦门双瑞船舶涂料有限公司,福建 厦门 361101 
陈珊珊 厦门双瑞船舶涂料有限公司,福建 厦门 361101 
马春风 华南理工大学,广州 510640 
吴建华 1.海洋腐蚀与防护重点实验室,福建 厦门 361101;2.厦门双瑞船舶涂料有限公司,福建 厦门 361101 
张广照 华南理工大学,广州 510640 
AuthorInstitution
YE Zhang-ji 1. South China University of Technology, Guangzhou 510640, China; 2. Key Laboratory of Marine Corrosion and Protection, Xiamen 361101, China; 3. Xiamen Sunrui Ship Coating Co., Ltd, Xiamen 361101, China 
CHEN Shan-shan Xiamen Sunrui Ship Coating Co., Ltd, Xiamen 361101, China 
MA Chun-feng South China University of Technology, Guangzhou 510640, China 
WU Jian-hua 1. Key Laboratory of Marine Corrosion and Protection, Xiamen 361101, China; 2. Xiamen Sunrui Ship Coating Co., Ltd, Xiamen 361101, China 
ZHANG Guang-zhao South China University of Technology, Guangzhou 510640, China 
摘要点击次数:
全文下载次数:
中文摘要:
      简要论述了海洋防污材料的发展历史及其防污机理,评述了新型环保高性能海洋防污材料的最新研究进展。自有机锡自抛光防污涂料被禁用后,基于聚丙烯酸锌、聚丙烯酸铜和聚丙烯酸硅烷酯的无锡自抛光防污涂料得到了广泛应用。为进一步提升其防污性能和环保性能,接枝防污官能团防污材料、生物降解高分子基防污材料、主链降解型自抛光防污材料、减阻型防污材料以及仿生防污材料成为当今的研究热点。介绍了席夫碱、草甘膦、苯并异噻唑啉酮等几种防污官能团的接枝方法及其防污效果,指出这类方法可提高防污剂的利用率,使防污剂释放更平稳,但实用化还需解决防污剂接枝改性后防污能力下降以及合成工艺复杂等问题。重点介绍了生物降解高分子基防污材料,特别是主链降解-侧链水解型防污材料的结构和合成方法。由于该类可降解/水解树脂具有良好的力学性能和水解可调控性,所制备的防污涂料即使在静态下,防污剂也释放平稳,因此可用于开发新型主链降解型自抛光防污涂料,以提高涂层的静态防污长效性,具有良好的应用前景。还介绍了通过对高分子树脂改性等方法降低涂层水解后的表面粗糙度,该类防污涂层具有良好的减阻性能。最后介绍了仿生防污材料的研究进展。
英文摘要:
      Development history and antifouling mechanisms of marine antifouling materials were briefly reviewed, and the latest research progress of novel environmental-friendly antifouling materials was presented. After tributyltin-containing self-polishing copolymer (SPC) coatings were prohibited, copper, zinc and silyl acrylate polymers-based coatings have been widely used. In order to further improve the antifouling properties and environmental protection performance, research is now focusing on grafted antifouling functional group materials, biodegradable macromolecule-based antifouling materials, main chain degradable self-polishing antifouling materials, anti-drag antifouling materials and biomimetic antifouling materials. Grafting methods and antifouling effects of several antifouling functional groups such as Schiff base, glyphosate and benzisothiazolinone were introduced. It was pointed out that such methods could improve utilization ratio of antifoulant and gain a steady release rate of antifoulant. However, such problems as reduced antifouling capacity due to grafting modification and complex synthesis process should be solved to apply such methods. Moreover, structure and synthesis methods of biodegradable macromolecule-based antifouling materials, especially main chain degradable and side chain hydrolysable were introduced emphatically. As these hydrolysable/degradable resins exhibited good mechanical properties and hydrolysis controlled performance, the anti-fouling coatings as-prepared could release antifoulant steadily even in static state. Therefore, the resins could be used to develop novel main chain degradable self-polishing antifouling coatings, so as to improve durability of the coatings in static state, the resins had good application prospects. Methods of reducing surface roughness of the antifouling coatings after hydrolysis such as macromolecule resin modification were introduced as well. Such anti-fouling coatings exhibited good anti-drag resistance. Finally, the progress of biomimetic antifouling materials was introduced.
查看全文  查看/发表评论  下载PDF阅读器
关闭

关于我们 | 联系我们 | 投诉建议 | 隐私保护 | 用户协议

您是第19503089位访问者    渝ICP备15012534号-3

版权所有:《表面技术》编辑部 2014 surface-techj.com, All Rights Reserved

邮编:400039 电话:023-68792193传真:023-68792396 Email: bmjs@surface-techj.com

渝公网安备 50010702501715号