氧化还原去污对敏化304L不锈钢腐蚀性能的影响
Effect of Oxidation Reduction Decontamination on Corrosion Performance of Sensitized 304L Stainless Steel
摘 要
采用失重试验、扫描电子显微镜观察、晶间腐蚀试验研究了敏化304L不锈钢经过碱性高锰酸钾氧化-抗坏血酸还原(AP-A)、酸性高锰酸钾氧化-抗坏血酸还原(NP-A)、酸性高锰酸钾氧化-抗坏血酸和乙二胺四乙酸还原(NP-AE)和酸性高锰酸钾氧化-草酸还原(NP-O)等4种去污工艺清洗后的耐蚀性。结果表明:敏化304L不锈钢经NP-A和NP-O去污工艺清洗后单位面积质量损失较多,其次是NP-AE,经AP-A工艺清洗后试样单位面积质量损失最少。与AP-A和NP-AE去污工艺相比,采用NP-A和NP-O去污清洗工艺清洗后试样表面的微孔更多。碱性高锰酸钾清洗液对304L不锈钢的腐蚀作用弱于酸性高锰酸钾清洗液对304L不锈钢的。草酸和抗坏血酸还原剂对不锈钢的腐蚀相当。敏化304L不锈钢经过4种去污工艺清洗后都未发生晶间腐蚀。
高锰酸钾
晶间腐蚀
氧化还原去污
304L stainless steel
potassium permanganate
intergranular corrosion
oxidation reduction decontamination
Abstract
The corrosion resistance of sensitized 304L stainless steel after four kinds of decontamination processes such as alkaline potassium permanganate oxidation-ascorbic acid reduction (AP-A), acidic potassium permanganate oxidation-ascorbic acid reduction (NP-A), acid potassium permanganate oxidation-ascorbic acid and ethylenediaminetetraacetic acid reduction (NP-AE) and acidic potassium permanganate oxidation-oxalic acid reduction (NP-O) was investigated by weight loss test, scanning electron microscope observation and intergranular corrosion test. The results show that the mass loss of sensitized 304L stainless steel per unit area after cleaning by NP-A and NP-O decontamination processes was more, followed by NP-AE, and the mass loss per unit area of the sample after cleaning by AP-A process was the least. Compared with AP-A and NP-AE decontamination processes, the surface of the sample was more microporous after cleaning by NP-A and NP-O decontamination cleaning processes. The corrosion effect of alkaline potassium permanganate cleaning solution on 304L stainless steel was less than that of acidic potassium permanganate cleaning solution. Oxalic acid and ascorbic acid reducing agents were equivalent to corrosion of stainless steel. The sensitized 304L stainless steel did not undergo intergranular corrosion after being cleaned by four decontamination processes.
中图分类号 TG172 DOI 10.11973/fsyfh-201811002
所属栏目 试验研究
基金项目 中广核集团公司资助项目(3100029195)
收稿日期 2016/3/28
修改稿日期
网络出版日期
作者单位点击查看
引用该论文: SONG Lijun,LI Xinmin,LIU Bin,ZHU Haijian. Effect of Oxidation Reduction Decontamination on Corrosion Performance of Sensitized 304L Stainless Steel[J]. Corrosion & Protection, 2018, 39(11): 820
共有人对该论文发表了看法,其中:
人认为该论文很差
人认为该论文较差
人认为该论文一般
人认为该论文较好
人认为该论文很好
参考文献
【1】DESHON J. Corrosion and corrosion product release rates of PWR primary system materials a research assessment[R]. California:Electric Power Research Institute,TR-1018719,2009.
【2】DESHON J,MCGURK J C. Corrosion product transport model for PWR primary circuit applications[R]. California:Electric Power Research Institute,TR-1015023,2007.
【3】MCELRATH J. Pressurized water reactor primary water chemistry guidelines volume 1,revision 7[R]. California:Electric Power Research Institute,TR-3002000505,2014.
【4】PRIYA A R S,MURALIDHARAN S,VELMURUGAN S,et al. Corrosion inhibitor for the chemical decontamination of primary coolant systems of nuclear power plants[J]. Materials Chemistry and Physics,2008,110(2/3):269-275.
【5】顾景智,杨茂春,陈德淦,等. 大亚湾核电站辐射源项控制的实践[J]. 辐射防护,2004,24(3/4):227-232.
【6】陈忠宇,张勇. 秦山核电站大修期间辐射源项分析[J]. 辐射防护,2009,29(2):65-71.
【7】BALAJI V,TRIPATHI V S,KENY S J,et al. Studies on the process development for the chemical decontamination of stainless-steel systems:novel observations[J]. Industrial & Engineering Chemistry Research,2006,45(13):4461-4470.
【8】PETTIT P J,LESURF J E,STEWART W B,et al. Decontamination of the douglas point reactor by the CAN-DECON process[J]. Materials Performance,1980,19(1):34-45.
【9】WANG M T. Corrosion evaluation of the PNS CITROX process for chemical decontamination of BWR structural materials[R]. California:Electric Power Research Institute,NP-4687,1986.
【10】BRADBURY D,SEGAL M G,SELLERS R M,et al. Development of LOMI chemical decontamination technology[R]. California:Electric Power Research Institute,NP-3177,1983.
【11】SWAN T,SEGAL M G,WILLIAMS W J,et al. LOMI decontamination reagents and related oxidation processes[R]. California:Electric Power Research Institute,NP-5522M,1987.
【2】DESHON J,MCGURK J C. Corrosion product transport model for PWR primary circuit applications[R]. California:Electric Power Research Institute,TR-1015023,2007.
【3】MCELRATH J. Pressurized water reactor primary water chemistry guidelines volume 1,revision 7[R]. California:Electric Power Research Institute,TR-3002000505,2014.
【4】PRIYA A R S,MURALIDHARAN S,VELMURUGAN S,et al. Corrosion inhibitor for the chemical decontamination of primary coolant systems of nuclear power plants[J]. Materials Chemistry and Physics,2008,110(2/3):269-275.
【5】顾景智,杨茂春,陈德淦,等. 大亚湾核电站辐射源项控制的实践[J]. 辐射防护,2004,24(3/4):227-232.
【6】陈忠宇,张勇. 秦山核电站大修期间辐射源项分析[J]. 辐射防护,2009,29(2):65-71.
【7】BALAJI V,TRIPATHI V S,KENY S J,et al. Studies on the process development for the chemical decontamination of stainless-steel systems:novel observations[J]. Industrial & Engineering Chemistry Research,2006,45(13):4461-4470.
【8】PETTIT P J,LESURF J E,STEWART W B,et al. Decontamination of the douglas point reactor by the CAN-DECON process[J]. Materials Performance,1980,19(1):34-45.
【9】WANG M T. Corrosion evaluation of the PNS CITROX process for chemical decontamination of BWR structural materials[R]. California:Electric Power Research Institute,NP-4687,1986.
【10】BRADBURY D,SEGAL M G,SELLERS R M,et al. Development of LOMI chemical decontamination technology[R]. California:Electric Power Research Institute,NP-3177,1983.
【11】SWAN T,SEGAL M G,WILLIAMS W J,et al. LOMI decontamination reagents and related oxidation processes[R]. California:Electric Power Research Institute,NP-5522M,1987.
相关信息
