The possibility of obtaining low-cement low-carbon periclase concretes with various ultrafine carbonaceous components is studied. It is shown that it is possible to obtain periclase-carbon concrete containing up to 1 wt.% ground waste from production of high-modulus graphite fiber. With an increase in carbon waste content from 1 to 5%, the water requirement of the mixture increases (from 6.25 to 10%), which leads to a reduction in concrete indices. It is established that slag resistance of the developed periclase-carbon objects is comparable with that of ordinary periclase-carbon products.
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References
A. A. Boikova and K. A. Zvyagin, «The Use of refractory castables in the ferrous metallurgy,» Refract. Ind. Ceram., 44(5), 285 – 288 (2003).
K. Furuta, I. Furusato, and I. Takita, «Development of castables for teeming ladle in Japan,» Proceedings of the 2nd International Symposium on Refractories, Oct. 30 – Nov. 02, Beijing, China (2019).
N. Li, H. Li, and Y. Wei, «Influence of calcium aluminate cement in magnesia castable on total oxygen content of interstitial free steel,» Brit. Ceram. Trans., 103, 139 – 142 (2004).
M. Rigaud ; Ed. by F. Golestani-Fard, «Trends in the steel industry and development of new refractory materials» Proc. of Tehran International Conf. on Refract., Tehran, Iran (2004).
N. M. Khalil, M. M. S. Wahsh, E. M. M. Ewais, et al., «Improvement of mullite and magnesia-based refractory castables through addition of nanospinel powder,» Int. J. Appl. Ceram. Technol., 10, 655 – 670 (2013).
M. Rigaud, S. Palco, and N. Znou, «Alumina and magnesia- based castables containing graphite comparison,» Iron & Steelmaker, October, 45 – 51 (2002).
Yasumasa Fukushima, Yoko Miyamoto, Tadakimi Kiyoda, et al., «Properties of castables with carbon-containing aggregate, Dzairyo tî Pu-rosesu, 20, 168 (2007).
S. Tamura, T. Ochiai, S. Takanaga, et al., «Nano-tech. refractories- 1: the development of the nanostructural matrix,» Proceedings of UNITECR’03 (2003).
M. Bag, S. Adak, and R. Sarkar, «Nano carbon containing MgO–C refractory: effect of graphite content,» Ceram. Int., 38, 4909 – 4914 (2012).
T. B. Zhu, Y.W. Li, M. Luo, et al., «Microstructure and mechanical properties of MgO–C refractories containing graphite oxide nanosheets (GONs),» Ceram. Int. 39, 3017 – 3025 (2013).
T. B. Zhu, Y. W. Li, S. B. Sang, et al., «Effect of nanocarbon sources on microstructure and mechanical properties of MgO–C refractories,» Ceram. Int., 40, 4333 – 4340 (2014).
T. B. Zhu, Y. W. Li, S. B. Sang, and Z. P. Xie, «Fracture behavior of low carbon MgO–C refractories using the wedge splitting test,» J. Eur. Ceram. Soc., 37, No. 4, 1789 – 1797 (2017).
I. D. Kashcheev, K. G. Zemlyanoi, A. R. Khafizova, and D. V. Kuznetsov, «Study of the possibility of preparing low-cement magnesia concretes,» Refract. Ind. Ceram., 59(5), 549 – 551 (2018).
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Translated from Novye Ogneupory, No. 5, pp. 113 – 115, May, 2023
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Khafizova, A.R., Kashcheev, I.D. & Zemlyanoi, K.G. Effect of Carbon Component Form on Periclase-Carbon Concrete Properties. Refract Ind Ceram 64, 296–298 (2023). https://doi.org/10.1007/s11148-024-00841-5
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DOI: https://doi.org/10.1007/s11148-024-00841-5