An Electrochemical Noise Study of the Pitting Process of X80 Pipeline Steel
摘 要
采用电化学噪声(Electrochemical Noise,EN)方法研究了X80管线钢在NaHCO3+NaCl溶液中亚稳态与稳态点蚀特征。结果表明:在含Cl-溶液中,当试样处于点蚀亚稳态,电位与电流噪声具有典型的快速下降或上升,缓慢恢复的暂态峰(Transient)特征,噪声电流峰平均宽约5~10 s,而噪声电位峰宽为100 s。随着腐蚀时间的延长,亚稳态点蚀噪声峰数量增多,亚稳态点蚀程度加剧;当点蚀由亚稳态发展到稳态初期,电流噪声峰恢复时间变长,与电位噪声峰寿命趋于一致;而随着稳态点蚀的发展,电位与电流峰出现的频率显著增加,电位与电流峰具有很好的相位同步性。
Abstract
The characters of metastable and stable pitting of X80 pipeline steel in NaHCO3 + NaCl aqueous solution were studied by electrochemical noise (EN). The results showed that in the solution containing Cl-,when the sample was in the condition of metastable pitting, noise current and noise potential patterns had a general characteristic of fast rise (or fast down) and slow recovery. The lasting time of noise current peak was 5-10 second in average, but the lasing time of noise potential peak was 100 second. The number of metastable pitting noise peaks increased with the increase of time. And the metastable pitting was promoted. When the pitting developed from metastable state to the initial stage of stable state, the recovery time of noise current peak became longer and was gradually close to the lifetime of noise potential peak. With the development of the stable pitting, the frequency of potential and current peak increased. There was phase synchronism existing between potential and current peak.
中图分类号 TG174 DOI 10.11973/fsyfh201607016
所属栏目 试验研究
基金项目 长庆油田油气当量上产5000万吨关键技术课题六(2011E-1306)
收稿日期 2015/9/2
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备注刘 伟(1985-),工程师,本科,主要从事油气田防腐蚀相关研究
引用该论文: LIU Wei,SUN Gangwei,LI Caibing,LI Xifeng,LIU Rui,LIU Qiao,YANG Bin. An Electrochemical Noise Study of the Pitting Process of X80 Pipeline Steel[J]. Corrosion & Protection, 2016, 37(7): 609
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参考文献
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【2】BERTOCCI U,HUET F. Noise analysis applied to electrochemical systems\[J\]. Corrosion,1995,51(2):131144.
【3】BUDEVSKI E,OBRETENOV W,BOSTANOV W,et al. Noise analysis in metal depositionexpectations and limits\[J\]. Electrochemical Acta,1989,34(8):10231029.
【4】刘晓方,王汉功,权高峰,等. 电化学系统噪声分析进展\[J\]. 腐蚀科学与防护技术,2001,13(2):101105.
【5】张鉴清,张昭,王建明,等. 电化学噪声的分析与应用I电化学噪声的分析原理\[J\]. 中国腐蚀与防护学报,2001,21(5):310320.
【6】ZHOU X Y,LVOV S N,WEI X J. Quantitative evaluation of general corrosion of type 304 stainless steel in subcritical and supercritical aqueous solutions via electrochemical noise analysis\[J\]. Corrosion Science,2002,44(8):841860.
【7】胡骞,邱于兵,郭兴蓬. Q235碳钢缝隙腐蚀的电化学噪声研究\[J\]. 电化学,2009,15(2):184188.
【8】胡会利,李宁,程瑾宁. 电化学噪声在腐蚀领域中的研究进展\[J\]. 腐蚀科学与防护技术,2007,27(2):114117.
【9】MARTINET S,DURAND R,OZIL P. Application of electrochemical noise analysis to the study of batteries state of charge determination and overcharge detection\[J\]. Journal Power Sources,1999,83(1):9399.
【10】赵茹,邓伟峰,宋诗哲. 304不锈钢管焊缝区碱性腐蚀的电化学噪声检测\[J\]. 化工学报,2008,59(5):12161222.
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