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Jianbo Sun, C. Sun, Xueqiang Lin, Xiangkun Cheng, Huifeng Liu (2016)
Effect of Chromium on Corrosion Behavior of P110 Steels in CO2-H2S Environment with High Pressure and High TemperatureMaterials, 9
(2012)
Electrochemical corrosion behaviour of carbon steel under dynamic high pressure H 2 S / CO 2 environment ”
C. Sun, Jiankuan Li, S. Shuang, Hongbo Zeng, Jingli Luo (2018)
Effect of defect on corrosion behavior of electroless Ni-P coating in CO2-saturated NaCl solutionCorrosion Science, 134
B. Beidokhti, A. Dolati, A. Koukabi (2009)
Effects of alloying elements and microstructure on the susceptibility of the welded HSLA steel to hydrogen-induced cracking and sulfide stress crackingMaterials Science and Engineering A-structural Materials Properties Microstructure and Processing, 507
T. Jin, Zhiyong Liu, Y. Cheng (2010)
Effect of non-metallic inclusions on hydrogen-induced cracking of API5L X100 steelInternational Journal of Hydrogen Energy, 35
D. López, T. Perez, S. Simison (2003)
The influence of microstructure and chemical composition of carbon and low alloy steels in CO2 corrosion. A state-of-the-art appraisalMaterials & Design, 24
Effect of H 2 S and CO 2 corrosion of carbon steel in acidic solutions ”
(2005)
Standard Test Method: Laboratory Testing of Metals for Resistance to Sulfide Stress Cracking and Stress Corrosion Cracking in H2S Environments
(2011)
Hydrogen induced cracking and sul fi de stress cracking ”
Yoon-Seok Choi, S. Nešić, S. Ling (2011)
Effect of H2S on the CO2 corrosion of carbon steel in acidic solutionsElectrochimica Acta, 56
Qianlin Wu, Z. Zhang, Xiaoming Dong, Jian-chun Yang (2013)
Corrosion behavior of low-alloy steel containing 1% chromium in CO2 environmentsCorrosion Science, 75
S. Koh, B. Yang, KyooYoung Kim (2004)
Effect of Alloying Elements on the Susceptibility to Sulfide Stress Cracking of Line Pipe SteelsCorrosion, 60
Y. Zheng, B. Brown, S. Nešić (2014)
Electrochemical Study and Modeling of H2S Corrosion of Mild SteelCorrosion, 70
(2009)
Sul fi de stress cracking resistance of API - X 100 high strength low alloy steel ”
(2009)
Effects of alloying elements and microstructure on the susceptibility of the welded HSLA steel to hydrogen - induced cracking and sul fi de stress cracking
I. Peñalva, G. Alberro, G. Legarda, B. Riccardi (2012)
Interaction of Copper Alloys with Hydrogen
Chengshuang Zhou, Shuqi Zheng, Chang-feng Chen, G. Lu (2013)
The effect of the partial pressure of H2S on the permeation of hydrogen in low carbon pipeline steelCorrosion Science, 67
W. He, O. Knudsen, S. Diplas (2009)
Corrosion of stainless steel 316L in simulated formation water environment with CO2–H2S–Cl−Corrosion Science, 51
(2009)
Corrosion of stainless steel 316 L in simulated formation water environment with CO 2H 2 SCl ”
(2014)
The electrochemical behaviour of 316 L austenitic stainless steel in Cl containing environment under different H 2 S partial pressures ”
G. Zhang, Y. Zeng, Xingpeng Guo, F. Jiang, D. Shi, Zhenyu Chen (2012)
Electrochemical corrosion behavior of carbon steel under dynamic high pressure H2S/CO2 environmentCorrosion Science, 65
H. Abrams (1983)
MiCon 82 : optimization of processing, properties, and service performance through microstructural control : a symposium sponsored by ASTM Committee E-4 on Metallography, Houston, Tex., 18-19 Jan. 1982
Shaoqiang Guo, Lining Xu, Lei Zhang, W. Chang, Min-xu Lu (2012)
Corrosion of alloy steels containing 2% chromium in CO2 environmentsCorrosion Science, 63
Jinhui Ding, Lei Zhang, Min-xu Lu, Jing Wang, Zhibin Wen, Wenhui Hao (2014)
The electrochemical behaviour of 316L austenitic stainless steel in Cl− containing environment under different H2S partial pressuresApplied Surface Science, 289
V. Venegas, F. Caleyo, J. González, T. Baudin, J. Hallen, R. Penelle (2005)
EBSD study of hydrogen-induced cracking in API-5L-X46 pipeline steelScripta Materialia, 52
Y. Sui, C. Sun, Jianbo Sun, Baolin Pu, W. Ren, Weiming Zhao (2017)
Stability of an Electrodeposited Nanocrystalline Ni-Based Alloy Coating in Oil and Gas Wells with the Coexistence of H2S and CO2Materials, 10
S. Golovanenko, V. Zikeev, E. Serebryanaya, L. Popova (1978)
Effect of alloying elements and structure on the resistance of structural steels to hydrogen embrittlementMetal Science and Heat Treatment, 20
H. Kang, J. Yoo, J. Park, Soon-Tae Ahn, N. Kang, Kyung-mox Cho (2012)
Effect of nano-carbide formation on hydrogen-delayed fracture for quenching and tempering steels during high-frequency induction heat treatmentMaterials Science and Engineering A-structural Materials Properties Microstructure and Processing, 543
M. Al-Mansour, A. Alfantazi, M. Elboujdaini (2009)
Sulfide stress cracking resistance of API-X100 high strength low alloy steelMaterials & Design, 30
P. Bai, H Zhao, Shuqi Zheng, Chang-feng Chen (2015)
Initiation and developmental stages of steel corrosion in wet H2S environmentsCorrosion Science, 93
D. Sponseller, R. Garber, J. Straatmann (1983)
Effect of Microstructure on Sulfide-Stress-Cracking Resistance of High-Strength Casing Steels
(2003)
The in fl uence of microstructure and chemical composition of carbon and low alloy steels in CO 2 corrosion ”
X. Lei, Hongyan Wang, F. Mao, Junping Zhang, Mifeng Zhao, Anqing Fu, Yaorong Feng, D. Macdonald (2018)
Electrochemical behaviour of martensitic stainless steel after immersion in a H 2 S-saturated solutionCorrosion Science, 131
This paper aims to evaluate the sulfide stress cracking (SSC) resistance of L80 casing steels with different alloying chemistries (e.g. Ti-B and Mn-Cr-Mo) by correlating the reduction in area ratio with the mechanical property, inclusion and carbide.Design/methodology/approachSSC tests were conducted in 5.0 Wt.% sodium chloride and 0.5 Wt.% acetic acid solution saturated with H2S using constant load tensile method. The microstructure and fracture morphology of the steel were observed using scanning electron microscope. The inclusion and carbide were identified by energy dispersive spectroscopy and auger electron microscope.FindingsAmong all the testing steels, electric resistance welding (ERW) L80-0.5Mo steel demonstrates the highest SSC resistance because of its appropriate mechanical properties, uniform microstructure and low inclusion content. The SSC resistance of L80 steels generally decreases with the rising yield strength. The fracture mode of steel with low SSC resistance is jointly dominated by transgranular and intergranular cracking, whereas that with high SSC resistance is mainly transgranular cracking. SSC is more sensitive to inclusions than carbides because the cracks are easier to be initiated from the elongated inclusions and oversized oxide inclusions, especially the inclusion clusters. Unlike the elongated carbide, globular carbide in the steel can reduce the negative effect on the SSC resistance. Especially, a uniform microstructure with fine globular carbides favors a significant improvement in SSC resistance through precluding the cracking propagation.Originality/valueThe paper provides the new insights into the improvement in SSC resistance of L80 casing steel for its application in H2S environment through optimizing its alloying compositions and microstructure.
Anti-Corrosion Methods and Materials – Emerald Publishing
Published: Aug 9, 2019
Keywords: Sulfide stress cracking; Fracture mode; Inclusion; Carbide; L80 casing steel
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