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通过物理混合将自制的石墨烯分散液与双组分水性环氧树脂制备成石墨烯环氧树脂。用扫描电镜(SEM)考察了石墨烯在水溶液中的分散情况。通过极化曲线、交流阻抗谱和中性盐雾试验探讨了含0.5%石墨烯的E44水性环氧涂层(0.5%G-E44)在模拟海水溶液中的隔水和耐腐蚀性能并与纯环氧涂层 E44进行比较。结果表明:石墨烯在水溶液中分散良好,其在水性环氧树脂中层层叠加,形成了致密的物理隔绝层,减缓了水分子在涂层中的扩散速率,拥有较好的隔水性能。E44和0.5%G-E44涂层在浸泡初期的Fick扩散系数分别为5.56×10?9 cm2/s和1.61×10?11 cm2/s。添加石墨烯明显提高了水性环氧树脂涂层的防护效果,自腐蚀电流密度减小,涂层电阻和电荷转移电阻增大,200 h中性盐雾试验后涂膜平整,无明显腐蚀。

A graphene–epoxy resin was prepared by physical blending home-made aqueous dispersion of graphene and two-component waterborne epoxy resin. The dispersed graphene in aqueous solution was analyzed by scanning electron microscopy. The water isolation and corrosion resistance of the waterborne epoxy coating doped with 0.5%graphene (0.5%G-E44) in simulated seawater were studied by polarization curve measurement, electrochemical impedance spectroscopy (EIS), and neutral salt spray (NSS) test, and compared with that of untreated E44 epoxy coating. The results indicated that graphene is dispersed well in the solution and presents good water-isolating performance, which is overlapped layer by layer in the waterborne epoxy resin, forming a dense physical isolation layer and thus slowing down the diffusion rate of water molecules in the coating. Fick diffusion coefficients of E44 and 0.5%G-E44 immersed in simulated seawater at early stage are 5.56 × 10?9 cm2/s and 1.61 × 10?11 cm2/s, respectively. The protection performance of waterborne epoxy coating is obviously improved by adding grapheme, as shown by the decreasing of self-corrosion current density and the increasing of coating resistance and charge transfer resistance. The coating features a level and smooth surface after 200 h NSS test without distinct corrosion.

参考文献

[1] ZHAO X;LIU S;HOU B R .A comparative study of neat epoxy coating and nano ZrO2/epoxy coating for corrosion protection on carbon steel[J].Applied Mechanics and Materials,2014,599/601:3-6.
[2] ZHAO Xia,LIU Shuan,WANG Xiutong,HOU Baorong.Surface modification of ZrO2 nanoparticles with styrene coupling agent and its effect on the corrosion behaviour of epoxy coating[J].中国海洋湖沼学报(英文版),2014(05):1163-1171.
[3] Guo-min Wu;Zhen-wu Kong;Jian Chen;Shu-ping Huo;Gui-feng Liu .Preparation and properties of waterborne polyurethane/epoxy resin composite coating from anionic terpene-based polyol dispersion[J].Progress in Organic Coatings: An International Review Journal,2014(2):315-321.
[4] Gao, J.;Lv, H.;Zhang, X.;Zhao, H. .Synthesis and properties of waterborne epoxy acrylate nanocomposite coating modified by MAP-POSS[J].Progress in Organic Coatings: An International Review Journal,2013(10):1477-1483.
[5] Wegmann A. .CHEMICAL RESISTANCE OF WATERBORNE EPOXY/AMINE COATINGS[J].Progress in Organic Coatings: An International Review Journal,1997(1/4):231-239.
[6] LIU M;MAO X H;ZHU H et al.Water and corrosion resistance of epoxy-acrylic-amine waterborne coatings:Effects of resin molecular weight,polar group and hydrophobic segment[J].Corrosion Science,2013,75:106-113.
[7] Sahu, S.C.;Samantara, A.K.;Seth, M.;Parwaiz, S.;Singh, B.P.;Rath, P.C.;Jena, B.K..A facile electrochemical approach for development of highly corrosion protective coatings using graphene nanosheets[J].Electrochemistry communications,2013:22-26.
[8] DONG Y H;LIU QQ;ZHOU Q .Corrosion behavior of Cu during graphene growth by CVD[J].Corrosion Science,2014,89:214-219.
[9] SUN W;WANG L D;WU T T et al.Synthesis of low-electrical-conductivity graphene/pernigraniline composites and their application in corrosion protection[J].CARBON,2014,79:605-614.
[10] LI Y Y;YANG Z Z;QIU H X et al.Self-aligned graphene as anticorrosive barrier in waterborne polyurethane composite coatings[J].Journal of Materials Chemistry A,2014,2(34):14139-14145.
[11] CHANG K C;HSU M H;LU H I et al.Room-temperature cured hydrophobic epoxy/graphene composites as corrosion inhibitor for cold-rolled steel[J].CARBON,2014,66:144-153.
[12] 刘栓,赵霞,孙虎元,孙立娟,曹琨.纳米TiO2改性的环氧树脂涂层的防腐蚀性能[J].材料保护,2014(01):11-13.
[13] 刘栓,赵霞,孙虎元,孙立娟,曹琨.纳米二氧化钛改性环氧涂层的交流阻抗谱研究[J].电镀与涂饰,2013(10):61-64.
[14] SUN H Y;LIU S;SUN L J .A comparative study on the corrosion of galvanized steel under simulated rust layer solution with and without 3.5wt%NaCl[J].International Journal of Electrochemical Science,2013,8(03):3494-3509.
[15] Shuan Liu;Huyuan Sun;Lijuan Sun;Huiji Fan .Effects of pH and Cl~- concentration on corrosion behavior of the galvanized steel in simulated rust layer solution[J].Corrosion Science: The Journal on Environmental Degradation of Materials and its Control,2012(Dec.):520-527.
[16] 赵霞,刘栓,侯保荣.改性纳米ZrO2/环氧涂层的耐蚀性能研究[J].腐蚀科学与防护技术,2014(05):436-440.
[17] 孙晓华,高瑾,郭为民,程文华,李晓刚.海水温度对深海用环氧涂层防护性能的影响[J].北京科技大学学报,2011(05):570-574.
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