水压试验对管线内腐蚀的影响

doi:10.3969/j.issn.1006-8805.2023.01.007

石油化工设备技术 ›› 2023, Vol. 44 ›› Issue (1): 35-38，44.doi: 10.3969/j.issn.1006-8805.2023.01.007

水压试验对管线内腐蚀的影响

周吉锋¹，朱环环²，袁海娜³

1. 山东博兴实华天然气有限公司,山东滨州 256500；
2. 山东滨农科技有限公司，山东滨州 256600；
3. 延长石油股份有限公司，陕西延安 717600

收稿日期:2022-10-13 接受日期:2022-12-31 出版日期:2023-01-15 发布日期:2023-03-16
通讯作者: 崔铭伟 E-mail:1156600657@qq.com
作者简介:周吉锋，男，2013年毕业于中国石油大学（华东）化工机械专业，工学学士，主要从事燃气输配气研究工作，现任项目经理,工程师。
基金资助:
国家自然科学基金项目(No. 51006123)，音速喷嘴中气液两相流临界分配特性及相分离控制理论资助资助。

The Influence of Hydraulic Testing on Corrosion in Pipeline

Zhou Jifeng¹, Zhu Huanhuan², Yuan Haina³

1. Shandong Boxing Shihua Natural Gas Co., Ltd., Binzhou, Shandong, 256500;
2. Shandong Binnong Technology Co., Ltd., Binzhou, Shandong, 256600;
3. Yanchang Petroleum Co., Ltd., Yan'an, Shaanxi, 717600

Received:2022-10-13 Accepted:2022-12-31 Online:2023-01-15 Published:2023-03-16
Contact: Cui Mingwei E-mail:1156600657@qq.com

摘要/Abstract

摘要： 为获得水压试验对管线内腐蚀的影响规律、做好腐蚀防护措施、提高水压试验安全性，对水压试验稳压失效的管材采用扫描电镜和XRD分析手段，分析研究了水压试验泄漏点附近管材表面显微组织、腐蚀产物以及局部腐蚀截面特点。结果表明：管材表面存在较严重局部腐蚀和管线轴向裂纹是造成水压试验稳压失效的双重原因；水压试验管道内壁腐蚀产物主要是较稳定的γ-Fe₂O₃、α-Fe(OH)₂，同时还存在少量不稳定的腐蚀中间产物γ-Fe(OH)₂，因其保护性差，导致管道底部仍处于活性腐蚀阶段；水压试验管道内壁腐蚀产物膜存在内层、中间、外层结构，外层组织松散、不稳定、保护性差，中间层多为较稳定的α-Fe(OH)₂，内层氧含量较高，与金属基体之间结合较紧密，多为非常稳定的γ-Fe₂O₃；外层、中间和内层之间存在缝隙，易产生缝隙腐蚀导致严重的局部腐蚀。

关键词: 水压试验, 局部腐蚀, 轴向裂纹, 腐蚀产物膜, 三层结构

Abstract: In order to obtain the influence laws of hydraulic testing on the corrosion in the pipeline, take good measures for corrosion protection and improve the safety of hydraulic testing, scanning electron microscope and XRD analysis methods are adopted to analyze the tube that has failed in the hydraulic testing. The microstructure, corrosion products and local corrosion cross sections of the pipe surface near the leakage point of hydraulic testing are analyzed and studied. The results show that the existence of more serious local corrosion on the surface of the pipe and axial cracks in the pipeline are the two causes for the failure of pressure stabilizing during the hydraulic testing; the corrosion products of the inner wall of the hydraulic test pipe are mainly stable γ-Fe₂O₃, α-Fe(OH)₂, and there is also a small amount of unstable corrosion intermediate product γ-Fe(OH)₂ with poor protection, causing the bottom of the pipeline to be still in active corrosion phase; the inner wall of the hydraulic testing pipeline corrodes the material film in the inner, middle, and outer layers; the outer layer is loose, unstable, and poorly protected; the middle layer is mostly a relatively stable α-Fe(OH)₂, and the inner layer has a higher oxygen content; the binding between the metal matrix is relatively close, and it is mostly very stable γ-Fe₂O₃; there's a gap between the outer layer, the middle layer and the inner layer, which is prone to crevice corrosion and leads to severe local corrosion.

Key words: hydraulic testing, local corrosion, axial crack, corrosion production film, three layer structure

周吉锋，朱环环，袁海娜. 水压试验对管线内腐蚀的影响[J]. 石油化工设备技术, 2023, 44(1): 35-38，44.

Zhou Jifeng, Zhu Huanhuan, Yuan Haina. The Influence of Hydraulic Testing on Corrosion in Pipeline[J]. Petro-chemical Equipment Technology, 2023, 44(1): 35-38，44.

参考文献

［1］董绍华. 全球油气管道完整性技术与管理的最新进展与中国管道的对策[C]//.2006年全国失效分析与安全生产高级研讨会论文集. 油气储运,2006:37-56.
［2］ The American Society of Mechanical Engineers, ASME B 31.8, Gas Transportation and Distribution Piping Systems[S]. New York: 2003: 98-101.
［3］ The American Society of Mechanical Engineers, ASME B 31.4, Pipeline Transportation Systems for Liquid Hydrocarbons and Other Liquids[S]. New York: 2002: 82-84.
［4］ Det Norske Vertitas, Rules for Submarine Pipeline Systems[S]. Oslo: 1981: 46-48.
［5］ Det Norske Vertitas, Offshore Standard DNV-OS-F101 Submarine Pipeline Systems[S]. Oslo: 2007: 117-118.
［6］国家技术监督局. 钢制压力容器GB 150—1998[S]. 北京: 中国标准出版社, 1998: 16-18.
［7］ Gen, June. Design and Engineering Practice used by Companies of the Royal Dutch/Shell Group[M]. Technical Specification Hydrostatic Pressure Testing of New Pipelines, October 1993: 23-29.
［8］中华人民共和国工业和信息化部. 长输油气管道站场布置规范SH/T 3169—2012[S]. 北京:石油工业出版社,2012.
［9］国家能源局. 输送钢管静水压爆破试验方法SY/T 5992—2012[S]. 北京: 石油工业出版社,2012.
［10］辽宁省建设厅. 建筑给水排水及采暖工程施工质量验收规范: GB 50242—2002[S]. 北京:中国建筑工业出版社,2002.
［11］POURBAIX, M. Atlas of Electrochemical Equilibria in Aqueous Solutions[M]. Houston：NACE International, 1974: 117-119.
［12］JONES, D R H. Engineering materials 3: Materials failure analysis-case studies and design implications[J]. Materials & Design, 1994,15, 115-116.
［13］ RUGGERI R T, Beck, T R. An Analysis of Mass Transfer in Filiform Corrosion[J]. Corrosion,1983.39: 452-465.
［14］Shreir, L L, Jarman R A, Burstein, G T. Corrosion Control[M]. Oxford, U.K. Butterworth Heinemann, 1994: 15-19.
［15］曹楚南. 腐蚀电化学原理(第三版)[M]. 北京: 化学工业出版社,2008: 128-133.

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水压试验对管线内腐蚀的影响

The Influence of Hydraulic Testing on Corrosion in Pipeline

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