A Novel Martensitic Stainless Steel Material for CO2 Corrosion Environment

被引:0
|
作者
Sang, Pengfei [1 ]
Luo, Wei [1 ]
Li, Wenzhe [1 ]
Wang, Chuanlei [1 ]
Chen, Ye [1 ]
Zhou, Lang [1 ]
Ma, Zihan [1 ]
Wang, Du [1 ]
Duan, Yunqi [1 ]
机构
[1] PetroChina Southwest Oil & Gas Field Co, Engn Technol Res Inst, Chengdu 610017, Peoples R China
来源
PROCESSES | 2024年 / 12卷 / 12期
关键词
trace alloy elements; new type martensitic stainless steel; corrosion resistance; 13CrU; 13CrS; MECHANICAL-PROPERTIES; HIGH-TEMPERATURE; MICROSTRUCTURE; TI; BEHAVIOR;
D O I
10.3390/pr12122912
中图分类号
TQ [化学工业];
学科分类号
0817 ;
摘要
The novel martensitic stainless steel 13CrU was developed based on 13CrS by adding trace alloying elements, such as Mo, Ni, and Ta. This study compares the mechanical and corrosion resistance properties of the two martensitic stainless steels to assess the effect of these alloying elements on 13CrU's performance. Experimental results show that increasing Mo by 0.67 wt% and Ni by 1.13 wt% improves the yield strength of 13CrU by 11.6% compared to 13CrS. The addition of Ta enhances the corrosion resistance of 13CrU beyond that of 13CrS. Overall, the addition of trace alloying elements significantly improves the mechanical properties of 13CrU and enhances its resistance to CO2 corrosion.
引用
收藏
页数:18
相关论文
共 50 条
  • [21] Study on corrosion behavior of steel for oil well in HT/HP CO2 corrosion environment
    Li, Jing
    Sun, Dongbai
    Yang, Dejun
    Yan, Milin
    Lu, Minxu
    Zhao, Guoxian
    Kang T'ieh/Iron and Steel (Peking), 2001, 36 (06): : 48 - 51
  • [22] Effect of Salt Concentration on the Corrosion Behavior of Carbon Steel in CO2 Environment
    Zeng, Zhipeng
    Lillard, R. S.
    Cong, Hongbo
    CORROSION, 2016, 72 (06) : 805 - 823
  • [23] Effect of typical ions on the corrosion behavior of carbon steel in CO2 environment
    Gu T.
    Tang D.
    Wang Z.
    Chen H.
    Xie H.
    Natural Gas Industry, 2019, 39 (07) : 106 - 112
  • [24] Effect of Fe ion concentration on corrosion of carbon steel in CO2 environment
    Rogowska, M.
    Gudme, J.
    Rubin, A.
    Pantleon, K.
    Ambat, R.
    CORROSION ENGINEERING SCIENCE AND TECHNOLOGY, 2016, 51 (01) : 25 - 36
  • [25] Corrosion and stress corrosion cracking behavior of 316L austenitic stainless steel in high H2S–CO2–Cl− environment
    Jinhui Ding
    Lei Zhang
    Dapeng Li
    Minxu Lu
    Junpeng Xue
    Wen Zhong
    Journal of Materials Science, 2013, 48 : 3708 - 3715
  • [26] Effect of Microstructure on the Corrosion Performance of 5% Cr Steel in a CO2 Environment
    Wu, Tao
    Wu, Huibin
    Niu, Gang
    Li, Tao
    Sun, Ruiyan
    Gu, Yang
    Yuan, Rui
    CORROSION, 2018, 74 (07) : 757 - 767
  • [27] Flow-accelerated corrosion behavior of 13Cr stainless steel in a wet gas environment containing CO2
    Yong Li
    Min-dong Chen
    Jian-kuan Li
    Long-fei Song
    Xin Zhang
    Zhi-yong Liu
    InternationalJournalofMineralsMetallurgyandMaterials, 2018, 25 (07) : 779 - 787
  • [28] Flow-accelerated corrosion behavior of 13Cr stainless steel in a wet gas environment containing CO2
    Yong Li
    Min-dong Chen
    Jian-kuan Li
    Long-fei Song
    Xin Zhang
    Zhi-yong Liu
    International Journal of Minerals, Metallurgy, and Materials, 2018, 25 : 779 - 787
  • [29] Effect of temperature on the corrosion behavior of 13Cr stainless steel under a high CO2 partial pressure environment
    Institute for Advanced Materials and Technology, University of Science and Technology Beijing, Beijing
    100083, China
    Gongcheng Kexue Xuebao, 11 (1463-1468):
  • [30] Flow-accelerated corrosion behavior of 13Cr stainless steel in a wet gas environment containing CO2
    Li, Yong
    Chen, Min-dong
    Li, Jian-kuan
    Song, Long-fei
    Zhang, Xin
    Liu, Zhi-yong
    INTERNATIONAL JOURNAL OF MINERALS METALLURGY AND MATERIALS, 2018, 25 (07) : 779 - 787
12345