天然气管道环焊缝缺陷部位的腐蚀沉淀机理
Corrosion and deposition mechanism at position of defect in circumferential weld of gas pipeline
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摘要: 为了深入分析天然气管道的“梗阻”现象,采用金相法和能谱仪对靖边某气田典型的有大量沉积物管道进行了焊缝和沉积物结构及成分分析.结果表明,焊缝缺陷处的腐蚀和沉淀机理为管内发生CO2腐蚀、缝隙腐蚀和H2S腐蚀,产生了氧化物、氯化物和硫化物等腐蚀产物.随着腐蚀产物的逐渐堆积,其阻隔了管子材料与腐蚀性介质,使得腐蚀速率减慢,沉积物转为以粉尘为主.沉积物堆积到一定高度时,天然气的流向改变,管道顶部的腐蚀变为冲刷腐蚀,腐蚀速率加快,管道壁厚严重减薄,危害管道的正常安全运行.Abstract: Metallographic microscope and EDS (energy dispersive spectrometer) were used to investigate the reason which caused the pipe blockage of the gas field in Jingbian. Results showthat there are CO2 corrosion, H2S corrosion and crevice corrosion in the natural gas pipeline.The deposits are mainly corrosion products such as iron oxides, iron chlorides and iron sulfides at this stage. As the corrosion continues, the pipe and the fluid inside the pipe are separated by the compact corrosion products. The type of deposits transforms from corrosion products to dust as the corrosion rate drops. When the height of deposits reaches a certain value, the top of the pipe suffers from erosion corrosion because the flow direction of fluid inside the pipe changes. And the corrosion rate accelerates. The thickness of pipe is so thin that it endangers the safety operation of the pipeline.
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Keywords:
- welded joint /
- gas pipeline /
- corrosion mechanism /
- deposition mechanism
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[1] 郭永华, 刘 震, 王玉凤, 等. 天然气管道内粉尘物性分析方法探究[J]. 石油机械, 2012, 40(6): 101-105. Guo Yonghua, Liu Zhen, Wang Yufeng, et al. Research on the method for physical analysis of dust within gas pipeline[J]. China Petroleum Machinery, 2012, 40(6): 101-105. [2] Lee P J, Vítkovsky J P, Lambert M F, et al. Discrete blockage detection in pipelines using the frequency response diagram: numerical study[J]. Journal of Hydraulic engineering, 2008, 134(5): 658-663. [3] López D A, Pérez T, Simison S N. The influence of microstructure and chemical composition of carbon and low alloy steels in CO2 corrosion. a state-of-the-art appraisal[J]. Materials and Design, 2003, 24(8): 561-575. [4] 李云涛, 杜则裕, 陶勇寅, 等. X70管线钢硫化氢应力腐蚀[J]. 焊接学报, 2003, 24(3): 76-78, 86. Li Yuntao, Du Zeyu, Tao Yongyin, et al. Sulfide stress cracking of X70 pipeline steels[J]. Transactions of the China Welding Institution, 2003, 24(3): 76-78,86. [5] 徐连勇, 荆洪阳, 曹 军, 等. 管线钢焊接接头H2S应力腐蚀试验分析[J]. 焊接学报, 2010, 31(1): 12-16. Xu Lianyong, Jing Hongyang, Cao Jun, et al. H2S stress corrosion investigation of pipeline steel welded joints[J]. Transactions of the China Welding Institution, 2010, 31(1): 12-16. [6] 黄安国, 李志远, 余圣甫, 等. 低合金钢焊缝金属的腐蚀行为[J]. 焊接学报, 2005, 26(11): 30-34. Huang Anguo, Li Zhiyuan, Yu Shengfu, et al. Corrosion behavior of weld metal of low-alloy steel[J]. Transactions of the China Welding Institution, 2005, 26(11): 30-34. [7] 陈卓元, 张学元, 王凤平, 等. 二氧化碳腐蚀机理及影响因素[J]. 材料开发与应用, 1998, 13(5): 34-40. Chen Zhuoyuan, Zhang Xueyuan, Wang Fengping, et al. The mechanism and influence factors of CO2 corrosion[J]. Development and Application of Materials, 1998, 13(5): 34-40. -
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