MgO-ZrO2耐火骨料的制备及其抗热震行为
[1] ZHANG W X, HUANG A, ZOU Y S, et al. Corrosion modeling of magnesia aggregates in contact with CaO-MgO-SiO2 slags[J]. J Am Ceram Soc, 2020, 103: 2128-2136.
[2] ZHU T B, LI Y W, JIN S L, et al. Microstructure and mechanical properties of MgO-C refractories containing graphite oxide nanosheets (GONs)[J]. Ceram Int, 2013, 39(3): 3017-3025.
[3] SAHAA A, SINGHC S K, GHOSHA A, et al. Studies on synthesis and properties of magnesia refractory aggregates prepared from Indian magnesite through plasma fusion[J]. Ceram Int, 2015, 41(2): 2876-2883.
[4] CHEN L G, SHUANG L L, JONES P T, et al. Identification of magnesia-chromite refractory degradation mechanisms of secondary copper smelter linings[J]. J Eur Ceram Soc, 2016, 36(8): 2119-2132.
[5] JIN E D, YU J K, WEN T P, et al. Fabrication of high-density magnesia using vacuum compaction molding[J]. Ceram Int, 2018, 44(6): 6390-6394.
[6] LIU J H, FU Z Y, WANG W M, et al. Ultra-high heating rate densification of nanocrystalline magnesia at high pressure and investigation on densification mechanisms[J]. J Eur Ceram Soc, 2014, 34(12): 3095-3102.
[7] GU Q, ZHAO F, LIU X H, et al. Preparation and thermal shock behavior of nanoscale MgAl2O4 spinel-toughened MgO-based refractory aggregates[J]. Ceram Int, 2019, 45(9): 12093-12100.
[8] GRUBER D, SISTANINIA M, FASCHING C, et al. Thermal shock resistance of magnesia spinel refractories-Investigation with the concept of configurational forces[J]. J Eur Ceram Soc, 2016, 36(16): 4301-4308.
[9] GU Q, LIU G Q, LI H X, et al. Synthesis of MgO-MgAl2O4 refractory aggregates for application in MgO-C slide plate[J]. Ceram Int, 2019, 45(18): 24768-24776.
[10] 薛宗伟, 李心慰, 栾旭, 等. 纳米氧化锆对氧化镁陶瓷抗热震性的影响[J]. 材料导报, 2019, 33(10): 1630-1633. XUE Zongwei, LI Xinwei, LUAN Xu, et al. Mater Rev (in Chinese), 2019, 33(10): 1630-1633.
[11] 张海萍, 汪厚植, 顾华志, 等. 提高镁质浇注料抗热震性的研究[J]. 耐火材料, 2002, 36(1): 53-54. ZHANG Haiping, WANG Houzhi, GU Huazhi, et al. Refractories (in Chinese), 2002, 36(1): 53-54.
[12] MAHATO S, PRATIHAR S K, BEHERA S K. Fabrication and properties of MgO-C refractories improved with expanded graphite[J]. Ceram Int, 2014, 40(10): 16535-16542.
[13] ABOLHASSAN N. Facile and scalable synthesis of uniform MgO/carbon black nano-admixture for microstructural and mechanical property improvement of magnesia-carbon refractory bricks[J]. Ceram Int, 2016, 42(16): 18031-18036.
[14] GHOSH A, SARKAR R, MUKHERJEE B, et al. Effect of spinel content on the properties of magnesia-spinel composite refractory[J]. J Eur Ceram Soc, 2004, 24(7): 2079-2085.
[15] AKSELA C, RAND B, RILEY F L, et al. Thermal shock behaviour of magnesia spinel composites[J]. J Eur Ceram Soc, 2004, 24(8):2839-2845.
[16] DAS R R, NAYAK B B, ADAK S. Influence of nanocrystalline MgAl2O4 spinel addition on the properties of MgO-C refractories[J]. Adv Manuf Processes, 2012, 27(3): 242-246.
[17] GHASEMI-KAHRIZSANGI S, DEHSHEIKH H G, BOROUJERDNIA M. Effect of micro and nano-Al2O3 addition on the microstructure and properties of MgO-C refractory ceramic composite[J]. Mater Chem Phys, 2016, 189: 230-236.
[18] DUDCZIG S, VERES D, ANEZIRIS C G, et al. Nano and micrometer additions of SiO2, ZrO2 and TiO2 in fine grained alumina refractory ceramics for improved thermal shock performance, [J]. Ceram Int, 2012, 38(3): 2011-2019.
[19] CHEN M, LU C Y, YU J K, Improvement in performance of MgO-CaO refractories by addition of nano-sized ZrO2[J]. J Eur Ceram Soc, 2007, 27(16): 4633-4638.
[20] PENG C H, LI N, HAN B Q. Influence of microporous magnesia-rich spinel aggregates on properties of low Carbon MgO-C refractories[J]. Chinas Refract, 2010, 19(1): 12-15.
[21] CHAI J L, ZHU Y B, SHEN T L, et al. Assessing fracture toughness in sintered Al2O3-ZrO2(3Y)-SiC ceramic composites through indentation technique [J]. Ceram Int, 2020, 46(17): 27143-27149.
[22] MOHAN S K, SARKAR R. Effect of ZrO2 addition on MgAl2O4 spinel from commercial grade oxide reactants[J]. Ceram Int, 2016, 42(8): 10355-10365.
[23] LIAO N, Q B F, NATH M, et al. Effects of nano ZrO2 content on the comprehensive properties of BN-SiC composites [J]. J Alloys Compd, 2020, 813: 152180.
[24] GU Q, MA T, ZHAO F, et al. Enhancement of the thermal shock resistance of MgO-C slide plate materials with the addition of nano-ZrO2 modified magnesia aggregates[J]. J Alloys Compd, 2020, 847: 156339.
[25] SNIEZEK E, SZCZERBA J, STOCH P, et al. Structural properties of MgO-ZrO2 ceramics obtained by conventional sintering, arc melting and field assisted sintering technique[J]. Mater Des, 2016, 99: 412-420.
[26] KUSIOROWSKI R. MgO-ZrO2 refractory ceramics based on recycled magnesia-carbon bricks[J]. Constr Build Mater, 2020, 231: 117084.
[27] PATIL R N, SUBBARAO E C. Axial thermal expansion of ZrO2 and HfO2 in the range room temperature to 1400 ℃[J]. J Appl Crystallogr, 2010, 2(6): 281-288.
[28] 戴斌煜, 陈同彩, 商景利, 等. 氧化镁和氧化铈复合部分稳定氧化锆泡沫陶瓷的显微结构[J]. 硅酸盐学报, 2007, 35(2): 192-196. DAI Binyu, CHEN Tongcai, SHANG Jingli, et al. J Chin Ceram Soc, 2007, 35(2): 192-196.
[29] HE X. L, YE F, ZHANG H J, et al. Effect of Sm2O3 content on microstructure and thermal conductivity of spark plasma sintered AlN ceramics[J]. J Alloys Compd, 2009, 482(1-2): 345-348.
[30] MEDVEDEV P G, LAMBREGTS M J, Meyer M K. Thermal conductivity and acid dissolution behavior of MgO-ZrO2 ceramics for use in LWR inert matrix fuel[J]. J Nucl Mater, 2006, 349(1-2): 167-177.
[31] LIN L Z, YOUNG J P, LIN G, et al. Enhancement of the thermal shock resistance of transparent Y2O3 ceramics by reducing the content of sintering additive[J]. Ceram Int, 2018, 44(14): 17522-17525.
糜瑶, 徐义彪, 李亚伟, 桑绍柏, 王庆虎, 朱天彬, 廖宁, 戴亚洁. MgO-ZrO2耐火骨料的制备及其抗热震行为[J]. 硅酸盐学报, 2021, 49(12): 2760. MI Yao, XU Yibiao, LI Yawei, SANG Shaobai, WANG Qinghu, ZHU Tianbin, LIAO Ning, DAI Yajie. Preparation and Thermal Shock Behavior of MgO-ZrO2 Refractory Aggregates[J]. Journal of the Chinese Ceramic Society, 2021, 49(12): 2760.