QI Huaiwei*,WU Xinyuan,WANG Liangbing,et al.祁怀伟*,吴心元,王亮兵,徐涛涛[J].Plating & Finishing,2021,(3):41-46.[doi:10.3969/j.issn.1001-3849.2021.03.009]
镀层和涂层的抗霉菌研究进展
- Title:
- 祁怀伟*,吴心元,王亮兵,徐涛涛
- 文献标志码:
- A
- 摘要:
- 霉菌及其新陈代谢产物严重影响着各种材料的性能与使用寿命,尤其是在大气环境中对镀层和涂层的腐蚀更为严重。本文介绍了影响霉菌生长的条件、因素及霉菌对金属材料的腐蚀过程,综述了目前对镀层和涂层防霉处理方法及其研究进展,并对防霉涂层的研究发展提出了建议。
- Abstract:
- Molds and their metabolites seriously affect the properties and service life of various materials, especially affect the corrosion of deposits and coatings in atmospheric environment. In this paper, the conditions and factors affecting the growth of mold were studied, the corrosion process of mold on metal materials was analyzed, and the methods and progress of anti-mildew on metal materials were summarized, we also proposed the suggestion for the development of anti-mildew coatings.
参考文献/References:
[1] 钱鸿昌. 超疏水表面技术在腐蚀防护领域中的研究进展[J]. 表面技术, 2015, 44(3):15-30.
Qian H C. Research progress of super-hydrophobic surface technology in the field of corrosion protection[J]. Surface Technology, 2015, 44(3) :15-30(in Chinese).
[2] 赵金榜. 发展前景灿烂的重防腐涂料[J]. 上海涂料, 2010, 48(5):23-25.
Zhao J B Heavy anticorrosive coatings with bright development prospects[J]. Shanghai Coatings, 2010, 48 (5):23-25(in Chinese).
[3] 胡梅, 陈逸君, 杨光雄. 涂料防腐防霉体系的构建及性能测试[J]. 上海涂料, 2007, 46(8):37-40.
Hu M, Chen Y J, Yang G X. Construction and performance test of coating anticorrosive and mildew-resistant system[J]. Shanghai Coatings, 2007, 46(8):37-40(in Chinese).
[4] 林宣益. 涂料用防腐剂和防霉防藻剂及发展[J]. 现代涂料与涂装, 2006, 1(创刊10周年特刊):54-60.
Lin X Y Preservatives and mildew and algae inhibitors for coatings and their development[J]. Modern Coatings and Coatings, 2006, 1(10th Anniversary Special Issue):54-60(in Chinese).
[5] 陈化南. 抗菌性金属表面处理技术之浅述[J]. 五金科技, 2008, 36(4):86-88.
Chen H N Brief introduction of antibacterial metal surface treatment technology[J]. Hardware Science and Technology, 2008, 36(4):86-88(in Chinese).
[6] 梁子原, 林燕顺, 叶德赞. 霉菌对金属材料腐蚀的研究[J]. 海洋学报(中文版), 1986, 8(2):251-254.
Liang Z Y, Lin Y SYe Dezan. Study on the corrosion of metal materials by mold[J]. Chinese Journal of Oceanography (Chinese version), 1986, 8(2):251-254(in Chinese).
[7] 汪学华. 自然环境试验技术[M]. 北京:航空工业出版社, 2003.
Wang X H. Natural environment test technology[M]. Beijing:Aviation Industry Press, 2003(in Chinese).
[8] 林应锐. 防霉与工业杀菌剂[M]. 北京:科学出版社, 1987.
Lin Y R Mildew and industrial fungicides[M]. Beijing:Science Press, 1987(in Chinese).
[9] 马振瀛. 实用防霉技术[M]. 上海:上海科学技术出版社, 1987.
Ma Z H. Practical anti-mold technology[M]. Shanghai:Shanghai Science and Technology Press, 1987(in Chinese).
[10] 井上真由美. 微生物灾害及其防止技术[M]. 上海:上海科学出版社, 1983.
Mayumi I. Microbial disaster and its prevention technology[M]. Shanghai:Shanghai Science Press, 1983(in Chinese).
[11] 李梅, 王庆瑞. 抗菌材料的发展及其应用[J]. 化工新型材料, 1998, 26(5): 8-11.
Li M, Wang Q R. Development and application of antibacterial materials[J]. New Chemical Materials, 1998, 26(5):8-11(in Chinese).
[12] 刘倩倩, 卢琳, 高歌. 大气环境中金属及其保护层霉菌腐蚀研究的进展[J]. 工程科学学报, 2017, 39(10): 1463-1469.
Liu Q Q, Lu L, Gao G. Research progress on mold and metal corrosion in atmospheric environment[J]. Journal of Engineering Science, 2017, 39(10):1463-1469(in Chinese).
[13] 董言治, 任建存, 刘振杰. 霉菌和微生物对舰船的腐蚀及其涂料防护研究[J]. 现代涂料与涂装, 2006, 特刊(7): 30-32.
Dong Y Z, Ren J C, Liu Z J. Corrosion of molds and microorganisms on ships and its coating protection[J]. Modern Paint and Coating, 2006, Special Issue(7):30-32(in Chinese).
[14] 朱武峰, 吴文海, 秦成. 舰载机液压系统霉菌综合环境试验研究[J]. 液压与气动, 2013, 11: 79-83.
Zhu W FWu W H, Qin C. Comprehensive environmental test research on mold of carrier-borne hydraulic system[J]. Hydraulic & Pneumatic, 2013, 11:79-83(in Chinese).
[15] 周振宇. 抗菌防霉调湿涂料的研制及其性能研究[D]. 湖南:湖南工业大学, 2017.
Zhou Z Y. Study on the development of antibacterial and mildew-resistant humidity-controlling coatings and their performance[D]. Hunan:Hunan University of Technology, 2017(in Chinese).
[16] 夏越美, 傅耘. 电子产品常用有机涂层防霉特性研究[J]. 装备环境工程, 2007, 4(2):32-35.
Xia Y M, Fu Y. Research on Anti-mildew Properties of Common Organic Coatings for Electronic Products[J]. Equipment Environmental Engineering, 2007, 4 (2):32-35(in Chinese).
[17] 陈丹明, 李明, 郑兴明. 霉菌对A04-60氨基烘干磁漆的侵蚀作用研究[J]. 腐蚀科学与防护技术, 2014, 26(1): 19-24.
Chen D M, Li M, Zheng X M. Study on the Erosion Effect of Mold on A04-60 Amino Drying Magnetic Lacquer[J]. Corrosion Science and Protetion Technology, 2014, 26(1):19-24(in Chinese).
[18] 王丽. 霉菌试验及其标准介绍[J]. 航空标准化与质量, 2001, 3: 38-42.
Wang L. Introduction of mold test and its standard[J]. Aviation Standardization and Quality, 2001, 3:38-42(in Chinese).
[19] 刘志雄. 抗菌防霉防腐阻燃一体化纳米涂层应用研究[J]. 表面技术, 2017, 46(11):77-82.
Liu Z X. Research on the application of antibacterial, mildewproof, anticorrosive and flame retardant integrated nano coatings[J]. Surface Technology, 2017, 46 (11):77-82(in Chinese).
[20] 高云鹏, 柴全微, 尹默. 船用防爆电机涂层结构研究[J]. 电气防爆, 2015, 2:21-24.
Gao Y P, Chai Q W, Yin M. Study on coating structure of marine explosion-proof motor[J]. Electrical Explosion Protection, 2015, 2:21-24(in Chinese).
[21] 董言治, 周晓东, 沈同圣. 舰船设备盐雾防护及实验技术研究进展[J]. 腐蚀科学与防护技术, 2004, 16(1):29-32.
Dong Y Z, Zhou X D, Shen T S. Research progress on salt spray protection and experimental technology of ship equipment[J]. Corrosion Science and Protection Technology, 2004, 16(1):29-32(in Chinese).
[22] 董言治, 尉志苹, 沈同圣. 高盐雾条件下舰船设备的腐蚀防护研究进展[J]. 现代涂料与涂装, 2003, 3:35-38.
Dong Y Z, Wei Z P, Shen T S. Research progress on corrosion protection of ship equipment under high salt fog conditions[J]. Modern Paint and Coating, 2003, 3:35-38(in Chinese).
[23] 张友兰, 李树华. 海洋环境条件对机载电子设备的影响[C]:1998电子产品防护技术研讨会, 中国江西庐山, 1998:85-91.
Zhang Y L, Li S H. Impact of marine environmental conditions on airborne electronic equipment[C]//1998 Seminar on Electronic Product Protection Technology, Lushan, Jiangxi, China, 1998:85-91(in Chinese) .
[24] 周家胜, 王慧, 周涛. 炮弹在海洋环境下适应性分析及对策[J]. 兵工自动化, 2017, 36(3):81-83.
Zhou J S, Wang H, Zhou T. Analysis on the Adaptability of Projectiles in the Marine Environment and the Countermeasures[J] .Ordnance Industry Automation, 2017, 36(3):81-83(in Chinese).
[25] 石娇, 曲彦平. 耐海洋环境中霉菌腐蚀有机涂层的研究[J]. 表面技术, 2011, 40(1):56-58.
Shi J, Qu Y P. Study on organic coatings resistant to mold corrosion in marine environment[J] .Surface Technology, 2011, 40(1):56-58(in Chinese).
[26] 陈丹明, 李明, 李维保. A04-60氨基烘干磁漆抗霉性能研究[J]. 装备环境工程, 2015, 12(2):25-29.
Chen D M, Li M, Li W B. A04-60 Study on Anti-mildew Properties of Amino Drying Magnetic Varnish[J]. Equipment Environmental Engineering, 2015, 12(2):25-29(in Chinese).
[27] 夏越美, 傅耘. 电子产品常用有机涂层防霉特性研究[J]. 装备环境工程, 2007, 4(2):32-35.
Xia Y M, Fu Y. Study on Anti-mildew Properties of Common Organic Coatings for Electronic Products[J]. Equipment Environmental Engineering, 2007, 4(2):32-35(in Chinese).
[28] 张颢, 黄永捷, 王文明. N-TiO_2涂料对甲醛降解与霉菌抑制的研究[J]. 中国环保产业, 2016, 2:25-27.
Zhang H, Huang Y J, Wang W M. Study on the degradation of formaldehyde and mold inhibition by N-TiO_2 coatings[J]. China Environmental Protection Industry, 2016, 2:25-27(in Chinese).
[29] 王政芳, 罗广建, 陈海生. 无机硅酸盐涂料的研制及应用[J]. 广州化学, 2014, 39(3):1-6.
Wang Z F, Luo G J, Chen H S. Development and Application of Inorganic Silicate Coatings[J]. Guangzhou Chemical Industry, 2014, 39(3):1-6(in Chinese).
[30] 原瑞霞. 电沉积法制备氧化亚铜及其防微生物附着研究[D]. 山东青岛:中国海洋大学, 2014.
Yuan R X. Preparation of Cuprous Oxide by Electrodeposition and Its Antimicrobial Adhesion[D]. Qingdao, Shandong:Ocean University of China, 2014(in Chinese).
[31] 盛国华. 日本开发金属镀膜抗菌技术[J]. 食品工业科技, 2002, 23(5):43.
Sheng G H. Japan develops antibacterial technology for metal coatings[J]. Science and Technology of Food Industry, 2002, 23(5):43(in Chinese).
[32] 赵立华, 段渝平. 高强度合金结构钢与高强度铝合金防护层的耐霉性研究[J]. 装备环境工程, 2015, 12(4):82-88.
Zhao L H, Duan Y P Study on the mildew resistance of the protective layer of high-strength alloy structural steel and high-strength aluminum alloy[J]. Equipment Environmental Engineering, 2015, 12(4):82-88(in Chinese).
[33] 夏玲玲. 新防护性镀层Zn-Ni(锌/镍)合金工艺研究[J]. 材料保护, 2013, 46(8):44-46.
Xia L L. Research on New Protective Coating Process of Zn-Ni (Zn / Ni) Alloy[J]. Materials Protection, 2013, 46(8):44-46(in Chinese).
[34] 谭生, 郭军红, 崔锦峰. 抗菌涂料的研究现状及发展趋势[J]. 中国涂料, 2011, 26(2):16-20.
Tan S, Guo J H, Cui J F. Research Status and Development Trend of Antibacterial Coatings[J]. China Coatings, 2011, 26(2):16-20(in Chinese).
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备注/Memo
收稿日期:2019-08-26
修回日期:2020-03-23
通信作者:祁怀伟,qihuaiwei105@126.com