Current research and developing trend of MgO-C bricks

YAO Hua-bai; YAO Su-zhe; LUO Chang; CHEN Jun-hong; HOU Xin-mei; SUN Jia-lin

doi:10.13374/j.issn2095-9389.2018.03.001

Volume 40 Issue 3

Mar. 2018

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Article Navigation > Chinese Journal of Engineering > 2018 > 40(3): 253-268

YAO Hua-bai, YAO Su-zhe, LUO Chang, CHEN Jun-hong, HOU Xin-mei, SUN Jia-lin. Current research and developing trend of MgO-C bricks[J]. Chinese Journal of Engineering, 2018, 40(3): 253-268. doi: 10.13374/j.issn2095-9389.2018.03.001

Citation:

YAO Hua-bai, YAO Su-zhe, LUO Chang, CHEN Jun-hong, HOU Xin-mei, SUN Jia-lin. Current research and developing trend of MgO-C bricks[J]. Chinese Journal of Engineering, 2018, 40(3): 253-268. doi: 10.13374/j.issn2095-9389.2018.03.001

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Current research and developing trend of MgO-C bricks

doi: 10.13374/j.issn2095-9389.2018.03.001

1) School of Materials Science and Engineering, University of Science and Technology Beijing, Beijing 100083, China;
2) State Key Laboratory of Advanced Metallurgy, University of Science and Technology Beijing, Beijing 100083, China

Received Date: 2017-08-06

Abstract

Abstract

This paper summarizes current developments and ongoing research of MgO-C bricks, both at home and abroad, and especially analyzes antioxidant and low-carbon aspects. A future research direction regarding MgO-C bricks was proposed based on the discussion. Specifically, the property improvement of traditional MgO-C bricks through component optimization and structural design, the development of a new antioxidant, improvement of MgO-C bricks in low-carbon methods, and evaluation of corresponding properties, were proposed.
- MgO-C bricks,
- developing trend,
- low-carbon treatment,
- microstructure,
- antioxidant

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References(23)

References

[8]	Zhu T B, Li Y W, Jin S L, et al. Catalytic formation of one-dimensional nanocarbon and MgO whiskers in low carbon MgO-C refractories. Ceram Int, 2015, 41(3):3541
[19]	Behera S, Sarkar R. Effect of different metal powder anti-oxidants on N220 nano carbon containing low carbon MgO-C refractory:an in-depth investigation. Ceram Int, 2016, 42(16):18484
[21]	Benavidez E, Brandaleze E, Musante L, et al. Corrosion study of MgO-C bricks in contact with a steelmaking slag. Proc Mater Sci, 2015, 8:228
[24]	White H E. Electrically fused magnesia. J Am Ceram Soc, 1938, 21(6):216
[27]	Zhu T B, Li Y W, Jin S L, et al. Microstructure and mechanical properties of MgO-C refractories containing expanded graphite. Ceram Int, 2013, 39(4):4529
[28]	Zhu T B, Li Y W, Sang S B, et al. Effect of nanocarbon sources on microstructure and mechanical properties of MgO-C refractories. Ceram Int, 2014, 40(3):4333
[30]	Zhang S, Marriott N J, Lee W E. Thermochemistry and microstructures of MgO-C refractories containing various antioxidants. J Eur Ceram Soc, 2001, 21(8):1037
[32]	Gokce A S, Gurcan C, Ozgen S, et al. The effect of antioxidants on the oxidation behaviour of magnesia-carbon refractory bricks. Ceram Int, 2008, 34(2):323
[34]	Rymon-Lipinski T, Fichtner R, Benecke T. Study of the oxidation protection of MgO-C refractories by means of boron carbide. Steel Res Int, 1992, 63(11):493
[40]	Campos K S, Silva G F B L E, Nunes E H M, et al. The influence of B 4 C and MgB₂, additions on the behavior of MgO-C bricks. Ceram Int, 2012, 38(7):5661
[43]	Aneziris C G, Hubalkova J, Barabas R. Microstructure evaluation of MgO-C refractories with TiO₂-and Al-additions. J Eur Ceram Soc, 2007, 27(1):73
[49]	Wei G P, Zhu B Q, Li X C, et al. Microstructure and mechanical properties of low-carbon MgO-C refractories bonded by an Fe nanosheet-modified phenol resin. Ceram Int, 2015, 41(1):1553
[50]	Bag M, Adak S, Sarkar R. Study on low carbon containing MgO-C refractory:use of nano carbon. Ceram Int, 2012, 38(3):2339
[52]	Tamura S, Ochiai T, Takanaga S, et al. Nano-tech refractories-1. The development of the nano structural matrix//Proceedings of UNITECR. Osaka, 2003, 3:517
[55]	Bag M, Adak S, Sarkar R. Nano carbon containing MgO-C refractory:effect of graphite content. Ceram Int, 2012, 38(6):4909
[56]	Behera S, Sarkar R. Low-carbon magnesia-carbon refractory:use of N220 nanocarbon black. Int J Appl Ceram Technol, 2014, 11(6):968
[57]	Behera S, Sarkar R. Study on variation of graphite content in N220 nanocarbon containing low carbon MgO-C refractory. Ironmaking Steelmaking, 2016, 43(2):130
[60]	Fuchimoto H, Hokki T, Asano K. Evaluation of ultra low carbon magnesia-carbon bricks//47th International Colloquium on Refractories. Aachen, 2004:59
[63]	Hashemi B, Nemati Z A, Faghihi-Sani M A. Effects of resin and graphite content on density and oxidation behavior of MgO-C refractory bricks. Ceram Int, 2006, 32(3):313
[64]	Wang S J, Jing X L, Wang Y, et al. High char yield of aryl boron-containing phenolic resins:the effect of phenylboronic acid on the thermal stability and carbonization of phenolic resins. Polym Degrad Stab, 2014, 99:1
[65]	Matsuo Y, Tanaka M, Yoshitomi J, et al. Effect of the carbon nanofiber addition on the mechanical properties of MgO-C brick//Proceedings of UNITECR. Kyoto, 2011:11
[66]	Li L, Tang G S, He Z Y, et al. Influences of black carbon addition on mechanical performance of low-carbon MgO-C composite. J Iron Steel Res Int, 2010, 17(12):75
[67]	Jansen H. Bonding of MgO-C bricks by catalytically activated resin. Millennium Steel Int, 2007:95