Corrosion Protection Design of Safety-Related DCS Cabinet

doi:10.16183/j.cnki.jsjtu.2019.S1.001

Abstract

Abstract: In order to control the corrosion occurred in steel materials which are often used in the safety-related DCS cabinets operating in the severe atmospheric corrosion environment, the key technologies of corrosion protection design to meet the life requirement are explored in this paper. Firstly, the design progress of anti-corrosive coating system for cabinet with steel structure as main material is analyzed. The coatings with their characteristics and the coating systems, which are often used under the corrosivity category C4 and high durability, are listed. Besides, the attention of avoiding common problems such as galvanic corrosion, crevice corrosion and stress corrosion during structure design, process and material selection is summarized, aiming at the specific structure prone to corrosion and the position where coating protection cannot be taken according to design requirement. Through the summary of key anti-corrosion design principles such as coating system and design consideration, the reference for the anti-corrosion design of DCS cabinet is provided.

Key words: cabinet; corrosion protection; coating system; design consideration

CLC Number:

TG 174

YANG Rui,LIU Mingxing,WU Xiao,WANG Dongwei,CHEN Wei. Corrosion Protection Design of Safety-Related DCS Cabinet[J]. Journal of Shanghai Jiaotong University, 2019, 53(Sup.1): 1-6.

References

［1］贺红彦, 刘纯斌, 张春雷.核电站DCS安全级机柜防腐涂层的探究［J］.涂料工业, 2013, 43(02): 10-13. HE Hongyan, LIU Chunbin, ZHANG Chunlei. The exploration of anticorrosive paint for DCS safety cabinet in nuclear power plant［J］. Paint & Coatings Industry, 2013, 43(02): 10-13. ［2］田杰棠.借鉴国外经验发展内陆核电［J］.国防科技工业, 2006(04): 44-47. TIAN Jietang. Learn from foreign experience to develop inland nuclear power［J］. Defense Science & Technology Industry, 2006(04): 44-47. ［3］戈进飞.电子设备的防腐结构设计综述［J］.舰船电子工程, 2015, 35(06): 146-153. GE Jinfei. Overview of structure design for anticorrosive treatment in electronic equipment［J］. Ship Electronic Engineering, 2015, 35(06): 146-153. ［4］史青华.重力法高速镀锌工艺参数对镀层影响的研究［D］.沈阳: 东北大学, 2014. SHI Qinghua. Study on influence of electroplating process parameters on coating by gravity method［D］. Shenyang: Northeastern University, 2014. ［5］肖艳.粉末静电喷涂工艺及其应用特点［J］.汽车与配件, 2014(23): 73-76. XIAO Yan. Electrostatic powder spraying process and its application characteristics［J］. Automobile & Parts, 2014(23): 73-76. ［6］姜智锐, 陈卫, 刘永亮, 等. 核电厂安全级仪控系统电气设备喷漆防护性能研究［J］.核标准计量与质量, 2016(03): 35-38. JIANG Zhirui, CHEN Wei, LIU Yongliang, et al. Study on painting protection performance of electrical equipment in safety-related I&C system of nuclear power plant［J］. Nuclear Standard Measurement and Quality, 2016(03): 35-38. ［7］肖珺.飞机结构腐蚀防护和控制研究［J］.科技创新与应用, 2014(01): 33-34. XIAO Jun. Research on corrosion protection and control of aircraft structure［J］. Technology Innovation and Application, 2014(01): 33-34. ［8］BSEN ISO 12944. Paints and varnishes—Corrosion protection of steel structures by protective paint systems［S］. 2nd ed. Switzerland: International Organization for Standardization, 2017/2018. ［9］刘丽芸, 潘杰, 王晓, 等.我国核电专用涂料的应用及发展趋势［J］.上海涂料, 2015, 53(01): 31-33. LIU Liyun, PAN Jie, WANG Xiao, et al. Application and development trend of special coatings for nuclear power in China［J］. Shanghai Coatings, 2015, 53(01): 31-33. ［10］刘聪, 唐其环, 王莞, 等.ISO 9223-2012 标准碳钢大气腐蚀速率预测方程在我国典型地区的适用性研究［J］.装备环境工程, 2017, 14(10): 74-77. LIU Cong, TANG Qihuan, WANG Wan, et al. Applicability of atmospheric corrosion rate predication equation for carbon steel of standard ISO 9223-2012 in typical areas of China［J］. Equipment Environment Engineering, 2017, 14(10): 74-77. ［11］黄湘鹏, 陆敏.海洋环境中雷达表面涂层的现状及分析［J］.雷达与对抗, 2015, 35(01): 58-64. HUANG Xiangpeng, LU Min. Status quo and analysis of radar surface coatings in marine environment［J］. Radar & ECM, 2015, 35(01): 58-64. ［12］穆山, 李军念, 王玲, 等.海洋大气环境金属防护涂层技术与工艺研究［J］.装备环境工程, 2012, 9(02): 81-84. MU Shan, LI Junnian, WANG Ling, et al. Corrosion protection coating technologies of metal in marine atmosphere［J］. Equipment Environment Engineering, 2012, 9(02): 81-84. ［13］王晓, 雷剑, 郭年华, 等.我国船壳漆的发展概况［J］.上海涂料, 2011, 49(03): 30-33. WANG Xiao, LEI Jian, GUO Nianhua, et al. Development status domestic hull paint［J］. Shanghai Coatings, 2011, 49(03): 30-33. ［14］毛蕾蕾.涂料在钢结构防腐中的应用［J］.上海涂料, 2012, 50(09): 34-36. MAO Leilei. The application of coatings in steel structure anticorrosion［J］. Shanghai Coatings, 2012, 50(09): 34-36. ［15］张文毓. 电偶腐蚀与防护的研究进展［J］.全面腐蚀控制, 2018, 32(12): 51-56. ZHANG Wenyu. Research progress of galvanic corrosion and protection［J］. Total Corrosion Control, 2018, 32(12): 51-56. ［16］陈兴伟, 吴建华, 王佳, 等. 电偶腐蚀影响因素研究进展［J］. 腐蚀科学与防护技术, 2010, 22(4): 363-366. CHEN Xingwei, WU Jianhua, WANG Jia, et al. Progress in research on factors influencing galvanic corrosion behavior［J］. Corrosion Science and Protection Technology, 2010, 22(4): 363-366. ［17］国防科学技术工业委员会.金属镀覆层和化学覆盖层选择原则与厚度系列: GJB/Z 594A-2000 ［S］. 北京: 国防科学技术工业委员会, 2000. Commission of Science, Technology and Industry for National Defence. Selection principle and thickness series for metallic and chemical coatings: GJB/Z 594A-2000［S］. Beijing: Commission of Science, Technology and Industry for National Defence, 2000. ［18］邱成悌, 赵惇殳, 蒋全兴.电子设备结构设计原理［M］.南京: 东南大学出版社, 2002. QIU Chengti, ZHAO Dunshu, JIANG Quanxing. Principle of electronic equipment structure design［M］. Nanjing: Southeast University Press, 2002. ［19］汪金奇. 铁道车辆缝隙腐蚀和腐蚀控制［J］.现代涂装, 2013, 16(08): 56-58. WANG Jinqi. Crevice corrosion and corrosion control of railway vehicle［J］. Modern Paint and Finishing, 2013, 16(08): 56-58. ［20］杨万均, 肖敏, 张燕, 等.舰面电子设备机柜防护失效分析与对策研究［J］.装备环境工程, 2012, 09(06): 83-87. YANG Wanjun, XIAO Min, ZHANG Yan, et al. Failure analysis and countermeasure study of protection for warship electronic equipment cabinet［J］. Equipment Environment Engineering, 2012, 09(06): 83-87.

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