Research Status and Development of Functional Powder Coatings

Abstract With the development of coatings field and the widening of coatings market, especially the tightening of national environmental protection policy, powder coatings have become an indispensable part of coatings because of its pollution-free, efficient and recyclable advantages. There are more and more kinds of powder coatings. According to the specific requirements of the application environment of powder coatings, many other types of powder coatings occur, such as hydrophobic powder coatings and high temperature resistant powder coatings, this paper briefly reviews the development of powder coatings at home and abroad. Combined with the reaction mechanism of powder coatings and the current research situation, it focuses on heavy anti-corrosion powder coatings, weather resistant powder coating, anti-bacterial powder coatings, high temperature resistant powder coatings, hydrophobic powder coatings and self-healing powder. Finally, the functional powder coatings are summarized in this paper, and the future development of functional powder coatings is prospected.

	Service

	Email this article
	Add to my bookshelf
	Add to citation manager
	Email Alert
	RSS
	Articles by authors
	Zhang Hui
	Yan Baowei
	Yang Shuai
	Huang Jinbao
	Cui Jixing
	Liu Wei
	Shao Yuanyuan
	Zhang Haiping
	Zhu Jingxu

Keywords： functional powder coating； heavy anti-corrosion； weather resistant； anti-bacterial； high temperature resistant； hydrophobic

Received 2019-09-19;

About author:

Cite this article:

Zhang Hui, Yan Baowei, Yang Shuai, Huang Jinbao, Cui Jixing, Liu Wei, Shao Yuanyuan, Zhang Haiping, Zhu Jingxu.Research Status and Development of Functional Powder Coatings[J] Chemcial Industry and Engineering, 2020,V37(2): 1-18

[1] 钟红, 南仁植. 粉末涂料与涂装的发展[C]//环保型涂料及涂装技术研讨会论文集. 2000 Zhong Hong, Nan Renzhi. Development of powder coatings and coatings[C]//China Chemical Industry Society Coatings Coating Committee. Proceedings of Environmentally Friendly Coatings and Coating Technology Seminar. Xiamen:China Chemical Industry Association, 2000(in Chinese)
[2] Bell G. Advances in powder coating technology for automotive applications[J]. Pigment and Resin Technology, 1997, 26(4):229-234
[3] 孙先良. 新型粉末涂料发展的新趋势[J]. 现代涂料与涂装, 2002, 5(2):12-15, 53 Sun Xianliang. Developing trend of new powder coati ngs[J]. Modern Paint and Finishing, 2002, 5(2):12-15, 53(in Chinese)
[4] Janardhanan S, Zvonkina I, Soucek M D. Powder coating technology[J]. Kirk-Othmer Encyclopedia of Chemical Technology, 2000:1-16
[5] 谢远伟,黄微波,伯忠维,等. 金属材料表面新型重防腐涂层研究进展及发展趋势[J]. 上海涂料, 2012, 50(5):40-43 Xie Yuanwei, Huang Weibo, Bo Zhongwei,et al. Research progress and development trend of new heavy-duty anti-corrosion coatings on metal materials[J]. Shanghai Coatings, 2012, 50(5):40-43(in Chinese)
[6] 曲颖. 国内外重防腐涂料现状及发展方向[J]. 化学工业, 2013, 31(8):25-34 Qu Ying. The present situation and developing direction of heavy-duty coating at home and abroad[J]. Chemical Industry,2013, 31(8):25-34(in Chinese)
[7] 王正岩. 我国粉末涂料市场现状及发展趋势[J]. 现代化工, 2003, 23(8):54-56 Wang Zhengyan. Current situation and development trend of powder coatings market in China[J]. Modern Chemical Industry, 2003, 23(8):54-56(in Chinese)
[8] 吴向平, 宁波,徐萍,等. 2017年中国粉末涂料行业年度报告[C]//2018中国粉末涂料与涂装年会. 成都:2018 Wu Xiangping, Ning Bo, Xu Ping, et al. 2017 Annual report of china powder coatings industry[C]//2018 Annual Meeting Of Powder Coatings&Finshing. Chengdu:2018(in Chinese)
[9] 李福志. 功能性粉末涂料的论证报告[C]//第十次全国环氧树脂应用技术学术交流会论文集. 上海, 2003 Li Fuzhi. Demonstration report of functional powder coating[C]//Proceedings of the 10th National Epoxy Resin Application Technology Academic Exchange Conference. Shanghai, 2003(in Chinese)
[10] Misev T, van der Linde R. Powder coatings technology:New developments at the turn of the century[J]. Progress in Organic Coatings, 1998, 34(1/2/3/4):160-168
[11] Radtke J, Stalder H, Tschuppert E, et al. New powder coating system for a furniture manufacturer[J]. JOT-International Surface Technology, 2011, 4(1):32-33
[12] 吴向平, 宁波, 郭滟, 等. 2015年度中国粉末涂料行业运行分析[J]. 涂料技术与文摘, 2017, 38(2):43-50, 55 Wu Xiangping, Ning Bo, Guo Yan,et al. Overview on powder coatings industry of China in 2015[J]. Coatings Technology & Abstracts, 2017, 38(2):43-50, 55(in Chinese)
[13] 孔凡厚, 张雷, 罗智明, 等. 防腐蚀涂料发展现状及进展[J]. 涂料技术与文摘, 2017, 38(6):54-58 Kong Fanhou, Zhang Lei, Luo Zhiming,et al. Progress in anticorrosive coatings[J]. Coatings Technology & Abstracts, 2017, 38(6):54-58(in Chinese)
[14] 潘玉霞, 王玫, 王志高, 等. 大气腐蚀环境对四川电网输变电设备腐蚀的影响研究[J]. 材料保护, 2018, 51(4):110-113, 129 Pan Yuxia, Wang Mei, Wang Zhigao,et al. Influence of atmospheric corrosive environment on corrosion of power transmission and transformation equipment in Sichuan power grid[J]. Materials Protection, 2018, 51(4):110-113, 129(in Chinese)
[15] Montemor M F. Functional and smart coatings for corrosion protection:A review of recent advances[J]. Surface and Coatings Technology, 2014, 258:17-37
[16] Schmidt R G, Bell J P. Epoxy adhesion to metals[M]//Epoxy Resins and Composites II. Berlin/Heidelberg:Springer-Verlag. doi:10.1007/bfb0017914
[17] Spyrou E. Powder coatings chemistry and technology[M]. Hannover, Germany:Vincentz Network, 2019
[18] 陈超, 王浩, 李效忠, 等. 一种高性能重防腐粉末涂料及制备方法和应用:CN, 104893493A[P]. 2015-09-09
[19] 朱继刚, 张喜民. 一种油井管纳米重防腐耐磨耐高温粉末涂料:CN, 201710154266.5[P]. 2017-06-23
[20] Samour C M, et al. Coated pipe and process for making same:US,4213486[P].1980-07-22
[21] Wei Y, Zhang L, Ke W. Comparison of the degradation behaviour of fusion-bonded epoxy powder coating systems under flowing and static immersion[J]. Corrosion science, 2006, 48(6):1449-1461
[22] Qian S, Cheng Y. Degradation of fusion bonded epoxy pipeline coatings in the presence of direct current interference[J]. Progress in Organic Coatings, 2018, 120:79-87
[23] Wei Y, Zhang L, Ke W. Evaluation of corrosion protection of carbon black filled fusion-bonded epoxy coatings on mild steel during exposure to a quiescent 3% NaCl solution[J]. Corrosion Science, 2007, 49(2):287-302
[24] Misev L, Schmid O, Udding-Louwrier S, et al. Weather stabilization and pigmentation of UV-curable powder coatings[J]. Journal of Coatings Technology, 1999, 71(891):37-44
[25] Ramezanzadeh B, Rostami M. The effect of cerium-based conversion treatment on the cathodic delamination and corrosion protection performance of carbon steel-fusion-bonded epoxy coating systems[J]. Applied Surface Science, 2017, 392:1004-1016
[26] Husain A, Al-Bahar S, Chakkamalayath J, et al. Differential scanning calorimetry and optical photo microscopy examination for the analysis of failure of fusion bonded powder epoxy internal coating[J]. Engineering Failure Analysis, 2015, 56:375-383
[27] Husain A, Chakkamalayath J, Al-Bahar S. Electrochemical impedance spectroscopy as a rapid technique for evaluating the failure of fusion bonded epoxy powder coating[J]. Engineering Failure Analysis, 2017, 82:765-775
[28] Luo S, Zheng Y, Li J, et al. Effect of curing degree and fillers on slurry erosion behavior of fusion-bonded epoxy powder coatings[J]. Wear, 2003, 254(3/4):292-297
[29] Shreepathi S, Bajaj P, Mallik B P. Electrochemical impedance spectroscopy investigations of epoxy zinc rich coatings:Role of Zn content on corrosion protection mechanism[J]. Electrochimica Acta, 2010, 55(18):5129-5134
[30] Arman S Y, Ramezanzadeh B, Farghadani S, et al. Application of the electrochemical noise to investigate the corrosion resistance of an epoxy zinc-rich coating loaded with lamellar aluminum and micaceous iron oxide particles[J]. Corrosion Science, 2013, 77:118-127
[31] Wang X, Chen S, Ding R, et al. A brief communication on the improved mechanism of graphene on zinc-rich coatings[J]. Int J Electrochem Sci, 2019, 14:353-356
[32] 田振宇, 李志刚, 瞿研. 锌烯重防腐涂料的发展现状与应用前景[J]. 涂料技术与文摘, 2015, 9:30-34 Tian Zhenyu, Li Zhigang, Qu Yan. Application of zinc/graphene composite heavy-duty anticorrosive coatings[J]. Coatings Technology & Abstracts, 2015, 9:30-34(in Chinese)
[33] 曾凡辉, 姜其斌. 复合铁钛粉改性环氧富锌重防腐涂料的研究[J]. 现代涂料与涂装, 2006, 9(9):12-13 Zeng Fanhui, Jiang Qibin. Study on zinc-rich heavy-duty epoxy coatings modified by iron oxide/titanium dioxide compound pigment[J]. Modern Paint & Finishing, 2006, 9(9):12-13(in Chinese)
[34] Shirehjini F T, Danaee I, Eskandari H, et al. Effect of nano clay on corrosion protection of zinc-rich epoxy coatings on steel 37[J]. Journal of Materials Science & Technology, 2016, 32(11):1152-1160
[35] Park S, Shon M. Effects of multi-walled carbon nano tubes on corrosion protection of zinc rich epoxy resin coating[J]. Journal of Industrial and Engineering Chemistry, 2015, 21:1258-1264
[36] Yun T H, Park J H, Kim J S, et al. Effect of the surface modification of zinc powders with organosilanes on the corrosion resistance of a zinc pigmented organic coating[J]. Progress in Organic Coatings, 2014, 77(11):1780-1788
[37] Hayatdavoudi H, Rahsepar M. A mechanistic study of the enhanced cathodic protection performance of graphene-reinforced zinc rich nanocomposite coating for corrosion protection of carbon steel substrate[J]. Journal of Alloys and Compounds, 2017, 727:1148-1156
[38] Lin S, Kamsler C, Argasinski K. Polyvinylidene fluoride weather resistant coating compositions including polymethyl methacrylate:US, 19990384123[P]. 2002-03-26
[39] 毛海荣, 祁黎, 张志勇, 等. 聚酯粉末涂料的大气暴露试验与人工加速试验研究[J]. 涂料工业, 2003, 33(12):49-52, 56 Mao Hairong, Qi Li, Zhang Zhiyong,et al. Study on weathering exposure and artificial weathering tests for polyester powder coatings[J]. Paint & Coatings Industry, 2003, 33(12):49-52, 56(in Chinese)
[40] 陈湘南. 氟聚合物涂料的开发动向[J]. 材料保护, 2000, 33(1):74-77 Chen Xiangnan.Developing trends of fluoropolymer coating[J]. Materiais Protection, 2000, 33(1):74-77(in Chinese)
[41] 马洪英. 户外低温固化粉末涂料用聚酯树脂的合成及其性能研究[D]. 南昌:南昌大学, 2013 Ma Hongying. Synthesis and application research of polyester resin for exterior low temperature curing powder coatings[D]. Nanchang:Nanchang University, 2013(in Chinese)
[42] 黄瑞安, 曹堃, 范宏, 等. 户外用耐候性粉末涂料的研究进展[J]. 功能高分子学报, 2001, 14(2):226-230 Huang Rui'an, Cao Kun, Fan Hong, et al. Novel development in outdoors powder coating[J]. Journal of Functional Polymers, 2001, 14(2):226-230(in Chinese)
[43] Takeshita Y, Handa T K, Kudo T. Improvement of weathering resistance for developed thermoplastic polyester powder coating for telecommunication plant[J]. Zairyo-to-Kankyo, 2010, 59(6):228-231
[44] 施奇武, 郭刚, 颜家振, 等. 耐候型聚酯粉末涂料的研究进展[J]. 工程塑料应用, 2008, 36(3):78-82 Shi Qiwu, Guo Gang, Yan Jiazhen,et al. Research advance in weather durable polyester powder coating[J]. Engineering Plastics Application, 2008, 36(3):78-82(in Chinese)
[45] Kim N S, Lee J H, Han K M, et al. Isolation and structural characterisation of a propoxyphenyl-linked thiohomosildenafil analogue found in a herbal product[J]. Food Additives & Contaminants:Part A, 2013, 30(10):1693-1700
[46] Harmuth C M. Polyvinyl chloride terpolymer powder coating composition:US, 4046728[P]. 1977-09-06
[47] 南仁植.粉末涂料与涂装技术[M]. 3版. 北京:化学工业出版社, 2014
[48] 黄之祥, 巩永忠. 氟碳粉末涂料的发展趋势[J]. 中国涂料, 2007, 22(4):19-20, 39
[49] Nobuhiko, Tsuda S. Powder coating composition containing vinylidene fluoride copolymer and methyl methacrylate copolymer:US, 6551708[P]. 2003-04-22
[50] 巩永忠, 陶冶. 建筑铝型材用氟碳粉末涂料的技术进展及应用展望[J]. 涂料工业, 2017, 47(11):63-68 Gong Yongzhong, Tao Ye. Technical progress and application of fluorocarbon powder coatings for construction aluminum profiles[J]. Paint & Coatings Industry, 2017, 47(11):63-68(in Chinese)
[51] 巩永忠, 黄之祥. 氟碳粉末涂料种类与性能关系浅述[J]. 现代涂料与涂装, 2006, 9(5):8-10, 21 Gong Yongzhong, Huang Zhixiang. Remark on therelationship between the categories and performances of fluoro-carbon powder coatings[J]. Modern Paint & Finishing, 2006, 9(5):8-10, 21(in Chinese)
[52] 巩永忠, 陶冶, 任环, 等. 浅析热固性氟碳粉末涂料在应用中常见问题与对策[J]. 现代涂料与涂装, 2014, 17(5):20-24 Gong Yongzhong, Tao Ye, Ren Huan,et al. A brief analysis of the application problems and countermeasures of the thermoset fluorocarbon powder coatings[J]. Modern Paint & Finishing, 2014, 17(5):20-24(in Chinese)
[53] 霍文波. 一种热固性氟碳粉末涂料及其制备方法:CN, 107129751A[P]. 2017-09-05
[54] Stark C J, Eward J M. Epoxidized polyester-based powder coating compositions:US, 19960596059[P]. 2000-06-13
[55] Kim W, Kim B J. Process for preparing acryl modified polyester resin for use in a powder coating and a powder coating composition containing the same:US, 5405910[P]. 1995-04-11
[56] Forsgren O Ø Y K A. Corrosion control through organic coatings[M]. 2^nd ed. FL Boca Raton:CRC Press,2006
[57] Li W, Franco D C, Yang M, et al. Investigation of the performance of ATH powders in organic powder coatings[J]. Coatings, 2019, doi:10.3390/coatings 9020110
[58] Feng Q, Wu J, Chen G, et al. A mechanistic study of the antibacterial effect of silver ions on Escherichia coli and Staphylococcus aureus[J]. Journal of Biomedical Materials Research, 2000, 52(4):662-668
[59] Frederick L, Cummings R E A. Antl-Microbial powder coatings:US, 6093407[P]. 2000-07-25
[60] Fang M, Chen J, Xu X, et al. Antibacterial activities of inorganic agents on six bacteria associated with oral infections by two susceptibility tests[J]. International Journal of Antimicrobial Agents, 2006, 27(6):513-517
[61] He J, Ma W, Tan S, et al. Study on surface modification of ultrafine inorganic antibacterial particles[J]. Applied Surface Science, 2005, 241(3/4):279-286
[62] Liau S Y, Read D C, Pugh W J, et al. Interaction of silver nitrate with readily identifiable groups:Relationship to the antibacterialaction of silver ions[J]. Letters in Applied Microbiology, 1997, 25(4):279-283
[63] Ghandour W, Hubbard J, Deistung J, et al. The uptake of silver ions by Escherichia coli K12:Toxic effects and interaction with copper ions[J]. Applied Microbiology and Biotechnology, 1988, doi:10.1007/bf00250412
[64] Luther E M, Koehler Y, Diendorf J, et al. Accumulation of silver nanoparticles by cultured primary brain astrocytes[J]. Nanotechnology, 2011, doi:10.1088/0957-4484/22/37/375101
[65] Foldbjerg R, Dang D A, Autrup H. Cytotoxicity and genotoxicity of silver nanoparticles in the human lung cancer cell line, A549[J]. Archives of Toxicology, 2011, 85(7):743-750
[66] Yeasmin R, Zhang H, Zhu J, et al. Pre-Treatment and conditioning of chabazites followed by functionalization for making suitable additives used in antimicrobial ultra-fine powder coated surfaces[J]. RSC Advances, 2016, 6(91):88340-88349
[67] Top A, Vlkü S. Silver, zinc, and copper exchange in a Na-clinoptilolite and resulting effect on antibacterial activity[J]. Applied Clay Science, 2004, 27(1/2):13-19
[68] Yoshihiro I, Makoto K, Ken-Ichiro M, et al. Light irradiation is a factor in the bactericidal activity of silver-loaded zeolite[J]. Chemical & Pharmaceutical Bulletin, 2008, 56(5):692-694
[69] Xu X, Ding H, Wang B. Preparation and performance of Ag⁺-Zn²⁺-zeolite antimicrobial and antibacterial plastic[J]. Advanced Materials Research, 2010, 96:151-154
[70] Ferreira L, Guedes J F, Almeida-Aguiar C, et al. Microbial growth inhibition caused by Zn/Ag-Y zeolite materials with different amounts of silver[J]. Colloids and Surfaces B:Biointerfaces, 2016, 142:141-147
[71] Martínez-Castañón G A, Niño-Martínez N, Loyola-Rodríguez J P, et al. Synthesis of silver particles with different sizes and morphologies[J]. Materials Letters, 2009, 63(15):1266-1268
[72] Paná?ek A, Kvítek L, Prucek R, et al. Silver colloid nanoparticles:Synthesis, characterization, and their antibacterial activity[J]. The Journal of Physical Chemistry B, 2006, 110(33):16248-16253
[73] Sharma S, Thakur M, Deb M. Synthesis of silver nanoparticles using N 1, N 2-diphenylbenzamidine by microwave irradiation method[J]. Journal of Experimental Nanoscience, 2007, 2(4):251-256
[74] Singh M, Sinha I, Mandal R. Role of pH in the green synthesis of silver nanoparticles[J]. Materials Letters, 2009, 63(3/4):425-427
[75] Venediktov E, Padokhin V. Synthesis of silver nanoclusters in starch aqueous solutions[J]. Russian Journal of Applied Chemistry, 2008, 81(11):2040-2042
[76] Li Y, Kim Y N, Lee E J, et al. Synthesis of silver nanoparticles by electron irradiation of silver acetate[J]. Nuclear Instruments and Methods in Physics Research Section B:Beam Interactions With Materials and Atoms, 2006, 251(2):425-428
[77] Long D, Wu G, Chen S. Preparation of oligochitosan stabilized silver nanoparticles by gamma irradiation[J]. Radiation Physics and Chemistry, 2007, 76(7):1126-1131
[78] Yin H, Yamamoto T, Wada Y, et al. Large-Scale and size-controlled synthesis of silver nanoparticles under microwave irradiation[J]. Materials Chemistry and Physics, 2004, 83(1):66-70
[79] Dutta P, Wang B. Zeolite-Supported silver as antimicrobial agents[J]. Coordination Chemistry Reviews, 2019, 383:1-29
[80] Kittler S, Greulich C, Diendorf J, et al. Toxicity of silver nanoparticles increases during storage because of slow dissolution under release of silver ions[J]. Chemistry of Materials, 2010, 22(16):4548-4554
[81] Xiu Z, Zhang Q, Puppala H L, et al. Negligible particle-specific antibacterial activity of silver nanoparticles[J]. Nano Letters, 2012, 12(8):4271-4275
[82] Lok C N, Ho C M, Chen R, et al. Silver nanoparticles:Partial oxidation and antibacterial activities[J]. Journal of Biological Inorganic Chemistry, 2007, 12(4):527-534
[83] 郁慧, 倪晰望, 郑文捷, 等. 纳米复合抗菌剂在粉末涂料中的应用[J]. 涂料工业, 2006, 36(8):55-57 Yu Hui, Ni Xiwang,Zheng Wenjie, et al. Application of nano-antibacterial agent in powder coatings[J]. Paint & Coatings Industry, 2006, 36(8):55-57(in Chinese)
[84] 喻倩. 用于金属制品表面的抗菌涂料及其制备方法:CN, 105778713A[P]. 2016-07-20
[85] Kuratsuji T, Shimizu H. Polyamide based antibacterial powder paint composition:US, 20030296458[P]. 2003-09-11
[86] Lapeyre A, Gancet C. Polyamide-Based powder and its use for obtaining an antibacterial coating:US, 20040001922[P]. 2005-08-04
[87] 赵广林, 濮建国, 仇亚波, 等. 耐高温粉末涂料[J]. 涂料工业, 2003, 33(5):21-23, 52 Zhao Guanglin, Pu Jianguo,Qiu Yabo, et al. Heat resistant powder coatings[J]. Paint & Coatings Industry, 2003, 33(5):21-23, 52(in Chinese)
[88] 江建明, 许国徽, 方敏辉, 等. 耐高温粉末涂料用聚酯及其制备方法:CN, 106244000A[P]. 2016-12-21
[89] 黄文, 苏捷, 林琳艺, 等. 一种耐高温粉末涂料及其制备方法:CN, 103214941A[P]. 2013-07-24
[90] Wang Z, Zhang L, Hu W, et al. Ultra-Heat resistant, adhesive and anticorrosive properties of poly(dimethylsiloxane) resin/furan coating[J]. Progress in Organic Coatings, doi:10.1016/j.porgcoat.2018.10.005
[91] 孙华强, 文佳军. 一种抗菌粉末涂料及其制备方法:CN, 107641428A[P]. 2018-01-30
[92] 马利强, 陈向阳. 一种高性能耐高温氟硅粉末涂料及其制备方法:CN, 106883693A[P]. 2017-06-23
[93] 曹建伟, 郎允祥. 一种韧性耐高温环氧粉末涂料:CN, 105820717A[P]. 2016-08-03
[94] Guo T, Xu G, Chen Y, et al. Effect of Ni20Cr alloy on infrared emissivity of inorganic silicate heat-resistant composite coatings[J]. Surface and Coatings Technology, 2016, 288:46-51
[95] ?erny' M, Chlup Z, Strachota A, et al. Rheological behaviour and thermal dilation effects of alumino-silicate adhesives intended for joining of high-temperature resistant sandwich structures[J]. Journal of the European Ceramic Society, 2017, 37(5):2209-2218
[96] Zhang B, Xu G, Liu C, et al. Low infrared emissivity of the Cr39Ni7C/inorganic silicate coatings with excellent heat-resistant[J]. Infrared Physics & Technology, 2018, 92:234-239
[97] Decker O H, Zhou W. Heat resistant powder coating composition having enhanced properties:AU, 20040215459[P]. 2004-09-10
[98] 王慧丽, 董亿政, 邵妃. 低TGIC用量的粉末涂料用耐高温聚酯树脂及其制备方法:CN, 105418901A[P]. 2016-03-23
[99] Editor P. Technology trends in the powder coating industry[J]. Focus on Powder Coatings, 2018, doi:10.1016/j.fopow. 2017.12.024
[100] Guo Z, Liu W, Su B. Superhydrophobic surfaces:From natural to biomimetic to functional[J]. Journal of Colloid and Interface Science, 2011, 353(2):335-355
[101] Tadanaga K, Katata N, Minami T. Super-Water-Repellent Al₂O₃ coating films with high transparency[J]. Journal of the American Ceramic Society, 2005, 80(4):1040-1042
[102] Wu R, Liang S, Pan A, et al. Fabrication of nano-structured super-hydrophobic film on aluminum by controllable immersing method[J]. Applied Surface Science, 2012, 258(16):5933-5937
[103] Sun M, Luo C, Xu L, et al. Artificial lotus leaf by nanocasting[J]. Langmuir, 2005, 21(19):8978-8981
[104] Badge I, Sethi S, Dhinojwala A. Carbon nanotube-based robust steamphobic surfaces[J]. Langmuir, 2011, 27(24):14726-14731
[105] Xu Q, Wang J, Smith I H, et al. Superhydrophobic and transparent coatings based on removable polymeric spheres[J]. J Mater Chem, 2009, 19(5):655-660
[106] Appelhans D, Gedan-Smolka M, Lehmann D. Get to (very) hydrophobic surfaces[J]. European coatings journal, 2004, (4):24-31
[107] 任华, 包秀群, 叶琳. 一种氟硅改性环氧树脂及其制备方法和一种粉末涂料:CN, 107936764A[P]. 2018-04-20
[108] Pan L, Dong H, Bi P. Facile preparation of superhydrophobic copper surface by HNO₃ etching technique with the assistance of CTAB and ultrasonication[J]. Applied Surface Science, 2010, 257(5):1707-1711
[109] 陈刚, 赵玉涛, 朱敏华, 等. 一种超疏水粉末涂料的制作方法:CN, 102925028A[P]. 2013-02-13
[110] Sheng X, Zhang J. Superhydrophobic behaviors of polymeric surfaces with aligned nanofibers[J]. Langmuir, 2009, 25(12):6916-6922
[111] Venkateswara Rao A, Kulkarni M M, Amalnerkar D P, et al. Superhydrophobic silica aerogels based on methyltrimethoxysilane precursor[J]. Journal of Non-Crystalline Solids, 2003, 330(1/2/3):187-195
[112] Mozumder M S, Zhang H, Zhu J. Mimicking lotus leaf:Development of micro-nanostructured biomimetic superhydrophobic polymeric surfaces by ultrafine powder coating technology[J]. Macromolecular Materials and Engineering, 2011, 296(10):929-936
[113] Peng C, Chen Z, Tiwari M K. All-Organic superhydrophobic coatings with mechanochemical robustness and liquid impalement resistance[J]. Nature Materials, 2018, 17(4):355-360
[114] Zhu J. Compositions and processes for producing durable hydrophobic and/or olephobic surfaces:US, 20100004373[P]. 2010-01-07
[115] 郑博凯. 基于粉末涂料的疏水涂层的制备和研究[D]. 天津:天津大学, 2017
[116] John T, Simpson B R D U. Superhydrophobic diatomaceous earth:US, 8216674[P]. 2012-07-10
[117] John T, Simpson C. Superhydrophobic powder coatings:US, 20140094540[P]. 2014-04-03
[118] Simpson J T, Hunter S R, Aytug T. Superhydrophobic materials and coatings:A review[J]. Reports on Progress in Physics, 2015, doi:10.1088/0034-4885/78/8/086501
[119] White S R, Sottos N, Geubelle P, et al. Autonomic healing of polymer composites[J]. Nature, 2001, doi:10.1038/35057232
[120] Kumar A, Stephenson L D, Murray J N. Self-Healing coatings for steel[J]. Progress in Organic Coatings, 2006, 55(3):244-253
[121] Zhang F, Ju P, Pan M, et al. Self-Healing mechanisms in smart protective coatings:A review[J]. Corrosion Science, 2018, 144:74-88
[122] Yabuki A. Particle-Induced damage and subsequent healing of materials:Erosion, corrosion and self-healing coatings[J]. Advanced Powder Technology, 2011, 22(3):303-310
[123] Deflorian F, Rossi S, Fedel M. Aluminium components for marine applications protected against corrosion by organic coating cycles with low environmental impact[J]. British Corrosion Journal, 2011, 46(3):237-244
[124] García S, Fischer H, Van Der Zwaag S. A critical appraisal of the potential of self healing polymeric coatings[J]. Progress in Organic Coatings, 2011, 72(3):211-221
[125] Zhou X, Li W, Zhu L, et al. Polymer-Silica hybrid self-healing nano/microcapsules with enhanced thermal and mechanical stability[J]. RSC Advances, 2019, 9(4):1782-1791
[126] Dubey R. Microencapsulation technology and applications[J]. Defence Science Journal, 2009, 59(1):82-95
[127] Chen T, Chen R, Jin Z, et al. Engineering hollow mesoporous silica nanocontainers with molecular switches for continuous self-healing anticorrosion coating[J]. Journal of Materials Chemistry A, 2015, 3(18):9510-9516
[128] 马衍轩, 张颖锐, 尹康樾, 等. 自修复微胶囊及其防护涂层应用研究进展[J]. 涂料工业, 2018, 48(11):54-62 Ma Yanxuan, Zhang Yingrui, Yin Kangyue, et al. Research progress of self-healing microcapsules and their application in anticorrosive coating[J]. Paint & Coatings Industry, 2018, 48(11):54-62(in Chinese)
[129] Puech C, Mangin d'Ouince V, Hallet L A M. Unité cognitivo-comportementale (UCC) de Corentin-Celton:évaluation à un an[J]. NPG Neurologie-Psychiatrie-Gériatrie, 2014, 14(83):252-254
[130] Hillewaere X K D, Teixeira R F A, Nguyen L T T, et al. Autonomous self-healing of epoxy thermosets with thiol-isocyanate chemistry[J]. Advanced Functional Materials, 2014, 24(35):5575-5583
[131] Koh E, Kim N K, Shin J, et al. Polyurethane microcapsules for self-healing paint coatings[J]. RSC Adv, 2014, 4(31):16214-16223
[132] de la Paz Miguel M, Ollier R, Alvarez V, et al. Effect of the preparation method on the structure of linseed oil-filled poly(urea-formaldehyde) microcapsules[J]. Progress in Organic Coatings, 2016, 97:194-202
[133] Meng L, Yuan Y, Rong M, et al. A dual mechanism single-component self-healing strategy for polymers[J]. Journal of Materials Chemistry, 2010, doi:10.1039/C0JM00268B
[134] Li G, Schenderlein M, Men Y, et al. Monodisperse polymeric core-shell nanocontainers for organic self-healing anticorrosion coatings[J]. Advanced Materials Interfaces, 2014, doi:10.1002/admi.201300019
[135] Andersson H M, Wilson G. Self-Healing systems for high-performance coatings[J]. PCI-Paint and Coatings Industry, 2012, 28-36
[136] Lim A T O, Cui C, Jang H D, et al. Self-Healing microcapsule-thickened oil barrier coatings[J]. Research, 2019, 2019:1-9