Corrosion Behavior of Low-Alloy Pipeline Steel with 1% Cr Under CO2 Condition

doi:10.1007/s40195-015-0255-3

金属学报英文版 ›› 2015, Vol. 28 ›› Issue (6): 739-747.DOI: 10.1007/s40195-015-0255-3

收稿日期:2014-08-20 修回日期:2014-11-18 出版日期:2015-03-20 发布日期:2015-07-23

Corrosion Behavior of Low-Alloy Pipeline Steel with 1% Cr Under CO₂ Condition

Zhen-Guang Liu¹, Xiu-Hua Gao¹(), Chi Yu², Lin-Xiu Du¹, Jian-Ping Li¹, Ping-Ju Hao³

(1)The State Key Lab of Rolling and Automation, Northeastern University, Shenyang, 110819, China
(2)School of Resource and Material, Northeastern University at Qinhuangdao, Qinhuangdao, 066100, China
(3)Mechanical and Electrical Engineering, Shijiazhuang Vocational College for Scientific and Technical Engineering, Shijiazhuang, 050800, China

Received:2014-08-20 Revised:2014-11-18 Online:2015-03-20 Published:2015-07-23

摘要/Abstract

Abstract:

Carbon dioxide corrosion behavior of low-alloy pipeline steel with 1% Cr exposed to CO₂-saturated solution was investigated by immersion experiment. SEM, EDX, TEM, EPMA and XRD were utilized to investigate the microstructure, corrosion morphologies, corrosion phases and elements distribution of corrosion scale. The results demonstrate that the microstructure of tested steel consists of ferrite and carbides. During the corrosion process, ferrite dissolves preferentially, leaving carbide particles behind. The residual carbide particles may promote the nucleation of FeCO₃ crystal. The phase comprising of the inner layer is Cr compound, and the one of the outer layer is FeCO₃. The formation process of corrosion scale can be illustrated as follows: Firstly, a thin scale consisting of thin inner layer and outer layer is formed, which represents poor corrosion resistance; then, the inner layer changes little, once it has been formed, and the outer layer becomes thick and compact, which demonstrates that a fine corrosion resistance is obtained. The chemical elements of chromium and molybdenum accumulate in the inner layer of corrosion scale. The corrosion behavior of low-alloy steel based on microstructure and morphology characterization is also discussed.

Key words: Carbon, dioxide, Low-alloy, steel, Corrosion, behavior, Microstructure

. [J]. 金属学报英文版, 2015, 28(6): 739-747.

Zhen-Guang Liu, Xiu-Hua Gao, Chi Yu, Lin-Xiu Du, Jian-Ping Li, Ping-Ju Hao. Corrosion Behavior of Low-Alloy Pipeline Steel with 1% Cr Under CO₂ Condition[J]. Acta Metallurgica Sinica (English Letters), 2015, 28(6): 739-747.

图/表 9

Fig. 1 Microstructure morphologies of the tested steel: a, b FESEM image; b magnified image of the marked area in a; c EDX analysis result of the marked position in a; d, e TEM images

Fig. 2 Macroscopic morphologies of the surface of samples after immersion for different time: a 24 h; b 48 h; c 96 h; d 192 h

Fig. 3 Microscopic morphology and EDX results of the corrosion products: a microscopic morphology; b EDX result of position A; c EDX result of position B

Fig. 4 Surface microscopic morphologies of the corrosion products at different immersion time, and the insets are magnified images: a 24 h; b 48 h; c 96 h; d 192 h

Fig. 5 Microscopic morphologies of the corroded sample surface after the corrosion products removed with different immersion time: a 24 h; b 48 h; c 96 h; d 192 h

Fig. 6 Cross-sectional micrographs of the sample after different time immersions (S substrate, E epoxy, I inner layer, O outer layer): a 24 h; b 48 h; c 96 h; d 192 h

Fig. 7 Element distribution maps of the sample with different immersion time: a 24 h; b 48 h; c 192 h

Fig. 8 XRD patterns took from the surfaces of the sample after immersion for different time: a 24 h; b 48 h; c 96 h; d 192 h

Fig. 9 Corrosion kinetics curves of the sample: a mass loss versus time; b corrosion rate versus time

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Corrosion Behavior of Low-Alloy Pipeline Steel with 1% Cr Under CO₂ Condition

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