Post-mortem Microstructural Study of Aluminous Refractory Brick Used in Channels of Blast Furnaces

doi:10.19691/j.cnki.1004-4493.2023.01.008

China's Refractories ›› 2023, Vol. 32 ›› Issue (1): 40-43.DOI: 10.19691/j.cnki.1004-4493.2023.01.008

Previous Articles Next Articles

Post-mortem Microstructural Study of Aluminous Refractory Brick Used in Channels of Blast Furnaces

Ana Valéria de Sousa COSTA, Belmira Benedita de LIMA-KUHN, Antonio Renato BIGANSOLLI^*

Department of Chemical Engineering, Technology Institute, Federal Rural University of Rio de

Online:2023-03-15 Published:2023-03-22
Contact: *e-mail: bigansolli.arb@gmail.com
About author:Ana Valéria de Sousa COSTA graduated in Materials Engineering from UFRRJ, with experience in materials and metallurgical engineering.

Abstract

Abstract: Aluminous refractory materials with high alumina contents are widely used in the steel industry, and the higher the alumina content, the higher the working temperature. Properties such as high refractoriness and thermal shock resistance lead these refractory materials to be used as channel linings of blast furnaces, where they are exposed to the attack by slag, molten steel, working cycles and sudden temperature changes between 25 ℃ (room temperature) and 1 520 ℃ (the temperature of molten pig iron). In this work, microstructural changes in post-mortem aluminous refractory bricks were investigated by apparent porosity, X-ray diffraction analysis (XRD), Fourier transform infrared spectroscopy (FTIR), scanning electron microscopy, and X-ray dispersion energy spectrometry (SEM/EDS). The results showed an increase in the apparent porosity and the bulk density and the presence of the phases mullite, sillimanite, alumina, and quartz in the post-mortem brick. Calcium and magnesium were not detected in the microstructure of the post-mortem brick, indicating that slags did not corrode these refractory materials. Therefore, the microstructural changes that occurred in the post-mortem bricks must be due to thermal cycling. In the X-ray diffraction (XRD) test, mullite, sillimanite, quartz, and α-alumina phases were identified. These results indicate that the aluminous refractory was obtained from sillimanite. In infrared spectroscopy (FTIR) it was possible to identify the vibration bands referring to the Si-O and Al-O bonds. The increase in the porosity is a result of cracks caused by work cycles at high temperatures and the temperature gradient to which the refractory was subjected during use. Through the micrograph it was possible to identify the presence of acicular mullite. The absence of magnesium and calcium in the microanalysis results by energy dispersed X-ray spectrometry (EDS) indicates that there was no infiltration by slag or liquid iron. These results indicate that the microstructural changes that occurred in the post-mortem aluminous refractory were of a thermal nature.

Key words: aluminous refractories, steel industry, microstructural, blast furnace

Ana Valéria de Sousa COSTA, Belmira Benedita de LIMA-KUHN, Antonio Renato BIGANSOLLI. Post-mortem Microstructural Study of Aluminous Refractory Brick Used in Channels of Blast Furnaces[J]. China's Refractories, 2023, 32(1): 40-43.

References

[1] Bastos S.C. L. P., Santos F. D., Caldeira J. A. D. Evolution of performance of refractory lining for the slag line of steel ladles at Usiminas Ipatinga. Proceedings of the 43^rd Steelmaking Seminar-International, Ipatinga, Brazil, 2012: 179-190.
[2] Zemánek D, Lang K, Tvrdík L, Všianský D, Nevrivová L, Štursa P, Kovár P, KeršnerováL, Dvorák K. Development and properties of new mullite based refractory grog. Materials, 2021, 14(4): 779.
[3] Xin Yalou, Yin Hongfeng, Tang Yun, Yuan Hudie, Ren Xiaohu, Gao Kui, Wan Qifa, Liu Yuchi.Effect of alumina bubbles with and without Al₂O₃ coatings on the performance of lightweight Al₂O₃-MgAl₂O₄ refractories. International Journal of Applied Ceramic Technology, 2020(17): 2622-2628.
[4] Sobrosa F.Z. Desenvolvimento de matériais cerâmicos refratários com adição da sílica residual proveniente da queima da casca de arroz [Dissertation, in Portuguese].Federal University of Pampa.
[5] ABNT NBR 16661, 2017: Materiais refratários densos confor-mados-Determinação do volume aparente, volume aparente da parte sólida, densidade de massa aparente, densidade aparente da parte sólida, porosidade aparente e absorção.
[6] MATCH, 2018. Accessed August 28, 2018. . Accessed August 28, 2018. http://www.crystalimpact.com/match/videos.htm.
[7] Bozano D. F.Preparação e caracterização de cerâmica tipo mulita pelo processo sol-gel [Dissertation, in Portuguese]. São Paulo University, 1991.
[8] Callister W.D. Ciência e Engenharia de Materiais: Uma Introdução. John Wiley & Sons, Inc.,(Ed.)
[9] Maximina Romero, Isabel Padilla, Manuel Contreras, Aurora López-Delgado.Mullite-based ceramics from mining waste: a review. Minerals, 2002, 11(3): 332.
[10] Magliano, M. V. M., Pandolfelli V. C.2010. Mulitização em refratários utilizando diferentes fontes precursoras-revisão[in Portuguese]. Cerâmica, 56(340): 368-375.
[11] Sylvia M. Johnson, Joseph A.Pask. Role of impurities on formation of mullite from kaolinite and Al₂O₃-SiO₂ Mixtures. American Ceramic Society Bulletin, 1982, 61(8): 838-842.
[12] Andrade F.Comparativo entre tijolos MgO-C e dolomitico para aplicação no revestimento da panela para a fabricação de aços de construção mecânica [Dissertation, in Portuguese]. Federal University of Rio Grande do Sul, 2009.
[13] Oliveira M. R., Garcia G. C. R., Claudinei S., Resende W. S., Ribeiro S.2011. Efeito do tempo de sinterização de um concreto refratário com agregados de andaluzita nos módulos de ruptura e elástico[in Portuguese]. Proceedings of the 55º Congresso Brasileiro de Cerâmica, 1561-1572.

[1]	SUN Saiyang, MA Xiaoqing, WANG Xingwei, ZHAO Yong, ZHANG Ronghui, FEI Weibao. Erosion Mechanism of Al₂O₃-SiC Castables for Lining Maintenance in Blast Furnace Hearths [J]. China's Refractories, 2022, 31(2): 17-23.
[2]	LI Hengxu, CHE Yuman, ZHOU Zhe, WANG Qi, WANG Hongtao. Cooling Water Flow Rate Calculation for Hearth of Large Blast Furnaces [J]. , 2015, 24(2): 16-20.
[3]	LI Hengxu, CHE Yuman, ZHOU Zhe, WANG Qi, WANG Hongtao. Mathematical Model of Hearth and Bottom Erosion in Blast Furnace [J]. , 2014, 23(3): 19-26.
[4]	XU Guotao, LI Huaiyuan, CHEN Xilai, ZHANG Honglei. Environmental-friendly Ramming Materials for Mud Package and Taphole of Large-scaled Blast Furnaces [J]. , 2013, 22(4): 5-8.
[5]	XYU Guotao, WANG Yue, ZHOU Wangzhi. Technical Questions in Castables Innovation for Main Iron Trough in Large-scaled [J]. , 2013, 22(3): 12-17.
[6]	XU Guotao, WANG Yue, HE Mingsheng. Development of Anhydrous Taphole Clay for Blast Furnace [J]. China's Refractories, 2011, 20(1): -.
[7]	LIANG Yibing, FENG Yunkang, LIANG Xiangrong. Development & Application of Taphole Clay for 4 350 m3 Blast Furnace [J]. China's Refractories, 2009, 18(4): -.
[8]	LI Xianming, LI Yong, KANG Huarong. Development and Application of Al2O3-Si3N4 Refractories Used in Blast Furnace [J]. China's Refractories, 2008, 17(3): -.
[9]	LIU Jiehua，ZHANG Xiaohui, SHEN Keyin, WANG Jing. A Glimpse of Iron and Steel Industry of China in Recent Years [J]. China's Refractories, 2006, 15(4): -.
[10]	XU Guotao, ZHANG Honglei, CHEN Huasheng. Application of Sol Self-Clean Bond Al2O3-SiC-C Castable for Iron Runner [J]. China's Refractories, 2006, 15(3): -.
[11]	CHAI Junlan. Technology Development of Refractories for Iron Making in China [J]. China's Refractories, 2005, 14(4): -.
[12]	LIN Binyin. Sillimanite, Kyanite and Andalusite in China and Their Applications Part II: Their Applications in Refractories to Improve Resistances to Creep and Thermal Shock [J]. China's Refractories, 2005, 14(2): -.
[13]	LI Tingshou,ZHOU Ningsheng,SU Tiansen. Highlights of Recent Advances in Refractories for Iron and Steel Industry in China [J]. China's Refractories, 2003, 12(2): -.
[14]	LIU Xiongzhang,ZHAO Huimin,CAO Hongfa. Development of Anti-creep Andalusite Based Bricks for Blast Furnace Stove [J]. China's Refractories, 2003, 12(2): -.
[15]	SU Tiansen. Clean Production of Steel and Refractories in China's Steel Industry [J]. China's Refractories, 2002, 11(3): -.

China's Refractories

Post-mortem Microstructural Study of Aluminous Refractory Brick Used in Channels of Blast Furnaces

PDF

Knowledge

Abstract

Cite this article

share this article

References

Related Articles 15

Recommended Articles

Metrics

Comments