Slag corrosion-resistance mechanism of lightweight magnesia-based refractories under a static magnetic field

被引:0
|
作者
Zou, Yongshun [1 ]
Huang, Ao [1 ]
Wang, Runfeng [1 ]
Fu, Lvping [1 ]
Gu, Huazhi [1 ]
Li, Guangqiang [1 ]
机构
[1] The State Key Laboratory of Refractories and Metallurgy, Wuhan University of Science and Technology, Wuhan,Hubei,430081, China
来源
Corrosion Science | 2020年 / 167卷
关键词
Magnesia;
D O I
暂无
中图分类号
学科分类号
摘要
Slag corrosion resistance of lightweight magnesia-based refractories with micro/nano-sized pores under a static magnetic field is investigated. They exhibited excellent slag resistance under static magnetic field of 8.5 mT with an isolation layer composed of solid phases formed at the refractory/slag interface. The static magnetic field generated a magnetic brake effect that suppressed the infiltrating flow of the molten slag and decreased the dissolution rate of MgO grains. Moreover, it also limited the thickness of the isolation layer by reducing the extent of the refractory-slag interaction, which can be applied to further improve the slag resistance of refractories. © 2020 Elsevier Ltd
引用
收藏
相关论文
共 50 条
  • [31] Corrosion-Resistance Mechanism of TC4 Titanium Alloy under Different Stress-Loading Conditions
    Wang, Xin-Yu
    Zhu, Shi-Dong
    Yang, Zhi-Gang
    Wang, Cheng-Da
    Wang, Ning
    Zhang, Yong-Qiang
    Yu, Feng-Ling
    MATERIALS, 2022, 15 (13)
  • [32] Corrosion related static electric and magnetic field of ships based on mixed modeling
    Chen, Cong
    Gong, Shen-Guang
    Li, Ding-Guo
    Harbin Gongye Daxue Xuebao/Journal of Harbin Institute of Technology, 2010, 42 (03): : 495 - 499
  • [33] Local corrosion mechanism of SiO2-based refractories caused by slag movement near solid-liquid-gas interface in different slag systems
    Yuan, Zhang-fu
    Xie, Shan-shan
    Yu, Xiang-tao
    Zhang, Yan-gang
    Wang, Rong-yue
    TRANSACTIONS OF NONFERROUS METALS SOCIETY OF CHINA, 2019, 29 (09) : 1975 - 1982
  • [34] The effect of phase formation during use on the chemical corrosion of magnesia-chromite refractories in contact with a non-ferrous PbO-SiO2 based slag
    Scheunis, L.
    Mehrjardi, A. Fallah
    Campforts, M.
    Jones, P. T.
    Blanpain, B.
    Jak, E.
    JOURNAL OF THE EUROPEAN CERAMIC SOCIETY, 2014, 34 (06) : 1599 - 1610
  • [35] Corrosion mechanism and research progress of metal pipeline corrosion under magnetic field and SRB conditions: a review
    Wang, Yuxin
    Wang, Guofu
    Xie, Fei
    Wu, Ming
    Zhou, Yi
    Liu, Fugang
    Cheng, Longsheng
    Du, Mingjun
    CORROSION REVIEWS, 2024, 42 (02) : 203 - 223
  • [36] WEAR AND CORROSION-RESISTANCE OF FE-N BASED MICROGRAIN SOFT-MAGNETIC THIN-FILMS
    KATORI, K
    OHMORI, H
    SHOJI, M
    HAYASHI, K
    IEEE TRANSACTIONS ON MAGNETICS, 1994, 30 (02) : 331 - 336
  • [37] CORROSION-RESISTANCE OF NICKEL-BASED ALLOYS UNDER STRESS IN HIGH-TEMPERATURE, HIGH CHLORIDE ENVIRONMENTS
    PESSALL, N
    LIU, CT
    JOURNAL OF THE ELECTROCHEMICAL SOCIETY, 1976, 123 (08) : C248 - C248
  • [38] In situ investigation of atmospheric corrosion behavior of copper under thin electrolyte layer and static magnetic field
    Yu, Xueyong
    Wang, Zehua
    Lu, Zihan
    MICROELECTRONICS RELIABILITY, 2020, 108 (108)
  • [39] Research on the static magnetic field related with corrosion and anticorrosion of ships based on the electric dipole model
    Chen, Cong
    Gong, Shen-Guang
    Li, Ding-Guo
    Binggong Xuebao/Acta Armamentarii, 2010, 31 (01): : 113 - 118
  • [40] Influence of the Treatment in the Magnetic Field on Corrosion Resistance of the Amorphous Alloys Based on Iron and Cobalt
    Gertsyk, O. M.
    Kovbuz, M. O.
    Boychyshyn, L. M.
    Borysyuk, A. K.
    Kulyk, Yu. O.
    Kotur, B. Ya.
    METALLOFIZIKA I NOVEISHIE TEKHNOLOGII, 2012, 34 (05): : 643 - 650
12345