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Периклазовые малоуглеродистые огнеупоры


https://doi.org/10.17073/1683-4518-2024-11-10-12

Полный текст:




Аннотация

Исследована технологическая и экономическая целесообразность производства оксидоуглеродистых огнеупоров с низким содержанием углерода. Представлены результаты разработки, производства и промышленных испытаний периклазовых малоуглеродистых огнеупоров в шлаковом поясе сталеразливочных ковшей.


Об авторах

Е. Б. Лаишевцев
LCC PKK Technoline / Yingkou Xinshengda Magnesium Industry Co., Ltd
Россия


Shi Shenglong
LCC PKK Technoline / Yingkou Xinshengda Magnesium Industry Co., Ltd
Китай


К. Г. Земляной
ФГАОУ ВО «Уральский федеральный университет»
Россия
к. т. н.


Список литературы

1. Ewais, E. M. M. Carbon based refractories / E. M. M. Ewais // J. Ceram. Soc. Jpn. ― 2004. ― Vol. 112, № 10. ― Р. 517‒532.

2. Sugita, K. Historical overview of refractory technology in the steel industry / K. Sugita // Nippon Steel Tech. Report. ― 2008. ― Vol. 98. ― P. 8‒17.

3. Kwong, K. S. Recycling practices of spent MgO‒C refractories / K. S. Kwong, J. P. Bennett // J. Miner. Mater. Charact. Eng. ― 2002. ― № 01. ― Р. 69‒78. https://doi.org/10.4236/jmmce.2002.12005.

4. Peng, Х. The progress of low-carbon MgO‒C composite study / X. Peng, L. Li, D. Peng // Refractories. ― 2003. ― Vol. 37, № 6. ― Р. 355‒357.

5. Boquan, Z. Current situation and development of low carbon magnesia-carbon materials research / Z. Boquan, Z. Wenjie, Y. Yashuang // Refractories. ― 2006. ― Vol. 40, № 1. ― Р. 90‒95.

6. Tamura, S. Nano-tech refractories-1: the development of nano structured matrix, in : Proceedings of the 8th UNITECR-03, Osaka, Japan, 19–22 October, 2003 / S. Tamura, T. Ochiai, S. Takanaga [et al.]. ― P. 517‒520.

7. Conejo, A. N. Recycling MgO‒C refractory in electric arc furnaces / A. N. Conejo, R. G. Lule, F. Lopéz, R. Rodriguez // Resour. Conserv. Recycl. ― 2006. ― Vol. 49. ― P. 14‒31. https://doi.org/10.1016/j.resconrec.2006.03.002.

8. Chatterjee, S. Continual improved performance MgO‒C refractory for BOF, in: UNITECR 09 / S. Chatterjee, R. Eswaran. ― 2009.

9. Tassot, P. New concepts for steel ladle linings, in : UNITCER 07 / P. Tassot, F. Etinne, J. Wang, P. Atkinson. ― 2007. ― P. 462.

10. Xuejun, Y. The influence of nanometer carbon black on the mechanical properties of phenolic resin / Y. Xuejun, Q. Zheming, H. Liangquan // Process. Aircraft. Mater. ― 2003. ― Vol. 33, № 4. ― Р. 34‒38.

11. Xianhui, L. The optimization of characterization and preparation on nanometer carbon blacks / L. Xianhui, W. Chifei // Process. Technol. Nano. Mater. ― 2005. ― № 2 (5). ― Р. 47–49.

12. Takanaga, S. Nano-Tech. refractories-3: develop ment of MgO-rimmed MgO‒C brick, in : Proceedings of the 9th UNITECR-2005, Orlando, FL, USA, November 8‒11 / S. Takanaga, Y. Fujiwara, M. Hatta. ― 2005.

13. Matsui, T. Characteristics and applications of nano tech magnesia carbon bricks, in: Proceedings of the 9th UNITECR 2005, Orlando, FL, USA, November 8‒11, 2005 / T. Matsui, T. Goto, Y. Yamada, N. Taki. ― 2005.

14. Fujiwara, Y. Development of nano tech MgO‒C brick. Pt. 1. Application of nano technology to matrix / Y. Fujiwara, K. Namba, S. Takanaga // J. Tech. Assoc. Refract. Jpn. ― 2004. ― Vol. 24, № 3. ― P. 210.

15. Hatta, M. Development of nano tech MgO‒C brick. Pt. 3. MgO‒C brick with nano structural matrix / M. Hatta, K. Namba, S. Takanaga // J. Tech. Assoc. Refract. Jpn. ― 2004. ― Vol. 24, № 3. ― P. 212.

16. Liu, B. Effects of nanometer carbon black on performance of low-carbon MgO‒C composites / B. Liu, J.Sun, G. Tang, K. Liu, L. Li, L. Liu // J. Iron Steel Res. Int. ― 2010. ― Vol. 17, № 10. ― Р. 75‒78.

17. Ochiai, T. Development of refractories by applying nano technology / T. Ochiai // J. Tech. Assoc. Refract. Jpn. ― 2005. ― Vol. 25, № 1. ― Р. 4‒11.

18. Lin, L. Effects of dispersion and content of nanometer carbon on mechanical performance of low carbon MgO‒C materials, in: Proceedings of the 11th UNITECR-09, Salvador, Brazil, October 13‒16 / L. Lin, T. Guangsheng, H. Zhiyong [et al.]. ― 2009.

19. Bag, M. Nano carbon containing MgO‒C refractory: effect of graphite content / M. Bag, S. Adak, R. Sarkar // Ceram. Int. ― 2012. ― Vol. 38. ― P. 4909‒4914. https:// doi.org/10.1016/j.ceramint.2012.02.082.

20. Maldhure, A. V. In-situ development of carbon nanotubes network and graphitic carbon by catalytic modification of phenolic resin binder in Al2O3‒MgO‒C refractories / A. V. Maldhure, A. V. Wankhade // J. Asian Ceram. Soc. ― 2017. ― № 5. ― Р. 247‒254. https://doi.org/10.1016/j.jascer.2017.04.010.

21. Zhu, T. Formation of nanocarbon structures in MgO‒C refractories matrix: influence of Al and Si additives / T. Zhu, Y. Li, S. Sang, Z. Xie // Ceram. Int. ― 2016. ― Vol. 42. ― P. 18833‒18843. https://doi.org/10.1016/j.ceramint.2016.09.029.

22. Aneziris, C. G. Microstructure evaluation of MgO‒C refractories with TiO2 and Al-additions / C. G. Aneziris, J. Hubálková, R. Barabás // J. Eur. Ceram. Soc. ― 2007. ― Vol. 27, № 1. ― Р. 73–78, https://doi.org/10.1016/j.jeurceramsoc.2006.03.001.

23. Bag, M. Study on low carbon containing MgO‒C refractory: use of nano carbon / M. Bag, S. Adak, R. Sarkar // Ceram. Int. ― 2012. ― Vol. 38. ― P. 2339‒2346. https://doi.org/10.1016/j.ceramint.2011.10.086.

24. Wei, G. Microstructure and mechanical properties of low-carbon MgO‒C refractories bonded by an Fe nanosheet-modified phenol resin / G. Wei, B. Zhu, X. Li, Z. Ma // Ceram. Int. ― 2015. ― Vol. 41. ― P. 3541‒3548.

25. Zhao, M. Catalytic graphitization of phenolic resin / M. Zhao, H. Song // J. Mater. Sci. Technol. ― 2011. ― Vol. 27. ― P. 266‒270. https://doi.org/10.1016/S1005-0302(11)60060-1.

26. Zhu, B. Q. Preparation and growth mechanism of carbon nanotubes via catalytic pyrolysis of phenol resin / B. Q. Zhu, G. P. Wei, X.C. Li [et al.] // Mater. Res. Innov. ― 2014. ― Vol. 18. ― P. 267‒272. https://doi.org/10.1179/1433075X13Y.0000000125.

27. Oya, A. Catalytic graphitization of a phenolic resin carbon by nickel (-100 pm): selective gasification of three resultant components as studied by SEM / A. Oya, S. Jikihara, S. Otani // Fuel. ― 1983. ― Vol. 62. ― P. 50‒55.

28. Zhu, T. Catalytic formation of one-dimensional nanocarbon and MgO whiskers in low carbon MgO‒C refractories / T. Zhu, Y. Li, S. Jin [et al.] // Ceram. Int. ― 2015. ― Vol. 41. ― P. 3541‒3548. https://doi.org/10.1016/j.ceramint.2014.11.017.

29. Talabi, S. I. Catalytic graphitization of novolac resin for refractor y applications / S. I. Talabi, A. P. Luz, A. A. Lucas [et al.] // Ceram. Int. ― 2018. ― Vol. 44. ― P. 3816‒3824.

30. Rastegar, H. Catalytic graphitization behavior of phenolic resins by addition of in situ formed nano-Fe particles / H. Rastegar, M. Bavand-vandchali, A. Nemati, F. Golestani-Fard // Phys. E: Low-Dimens. Syst. Nanostruct. ― 2018. ― Vol. 101. ― P. 50‒61. https://doi.org/10.1016/j.physe.2018.03.013.


Дополнительные файлы

Для цитирования: Лаишевцев Е.Б., Shenglong S., Земляной К.Г. Периклазовые малоуглеродистые огнеупоры. Новые огнеупоры. 2024;(11):10-12. https://doi.org/10.17073/1683-4518-2024-11-10-12

For citation: Laishevtsev E.B., Shenglong S., Zemlyanoi K.G. Periclase low carbon refractories. NOVYE OGNEUPORY (NEW REFRACTORIES). 2024;(11):10-12. (In Russ.) https://doi.org/10.17073/1683-4518-2024-11-10-12

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ISSN 1683-4518 (Print)