[1] 钟香崇.展望新一代优质高效耐火材料[J].耐火材料,2003,37(1):1-10.
[2] 赵三团,王威,徐俊.CaO耐火材料的抗水化研究进展[J].耐火材料,2005,39(5):364-367+370.
[3] 于秋月.MgO-CaO耐火材料抗水化性能研究进展[J].有色矿冶,2018,34(2):39-42.
[4] 徐殿利.我国耐火材料行业发展思考——“十二·五”回顾与“十三·五”展望[J].耐火材料,2016,50(6):401-406.
[5] 王学达,陈树江,张红鹰,等.镁钙耐火材料对钢水的净化作用[J].耐火材料,2004,38(2):88-90.
[6] 王明广.不锈钢冶炼用镁钙质耐火材料研究[D].鞍山:辽宁科技大学,2012.
[7] 王杰曾.水泥窑用耐火材料的现状与展望[J].中国建材科技,2001(2):34-37.
[8] FUBINI B,BOLIS V,BAILES M,et al.The reactivity of oxides with water vapor[J].Solid State Ionics,1989,32-33:258-272.
[9] 梁永和,吴芸芸,沈伟英.氧化钙砂表面改性及其抗水化性能研究[J].武汉科技大学学报(自然科学版),2008,31(3):247-249.
[10] 王宏联,崔庆阳,薛群虎,等.MgO-CaO耐火材料性能研究进展[J].耐火材料,2010,44(1):67-70+74.
[11] 魏耀武,李楠,陈晓霞.MgO-CaO系耐火材料的研究与应用[J].武汉科技大学学报(自然科学版),2007,30(2):141-144.
[12] SALOMÃO R,ARRUDA C C,KAWAMURA M A.A systemic investigation on the hydroxylation behavior of caustic magnesia and magnesia sinter[J].Ceramics International,2015,41(10):13998-14007.
[13] CHEN S J,CHEN G R,CHENG J J,et al.Effect of additives on the hydration resistance of materials synthesized from the magnesia-calcia system[J].Journal of the American Ceramic Society,2000,83(7):1810-1812.
[14] GHOSH A,TRIPATHI H S.Sintering behaviour and hydration resistance of reactive dolomite[J].Ceramics International,2012,38(2):1315-1318.
[15] 吴占德,杨杨.超高温煅烧制备优质镁钙砂及其性能研究[J].耐火与石灰,2018,43(6):1-8.
[16] 陈旭峰,王杰曾,李懋强.白云石烧结的试验研究[J].耐火材料,1995,29(2):83-87.
[17] 张汪年,邓宁,李养良,等.岩峰白云石二步煅烧制备镁钙砂[J].耐火材料,2011,45(6):420-423.
[18] 吴俊银.二步煅烧法合成镁钙砂的研究[J].甘肃冶金,2007,29(6):20-22.
[19] 陈树江,程继健,田凤仁.合成MgO-CaO砂的CO2表面处理[J].耐火材料,1998,32(2):92-93,96.
[20] CHEN M,WANG N,YU J K,et al.A.Effect of porosity on carbonation and hydration resistance of CaO materials[J].Journal of the European Ceramic Society,2007,27(4):1953-1959.
[21] XU T T,SU Y,SHI T,et al.Improving hydration resistance of MgO-CaO ceramics by in situ synthesized CaZrO3 coatings prepared using a non-hydrolytic sol[J].Ceramics International,2021,47(2):2165-2171.
[22] LI B R,WEI Y W,WANG J H,et al.Improved hydration resistance of CaO granules via sol-processed metal oxide protective layers[J].Journal of the American Ceramic Society,2021,104(9):4878-4890.
[23] LIU S K,WEI Y W,LI B R,et al.Microstructural and hydration resistance study of CaO with powder surface modification by Al coupling agents:alkoxy type and phosphate type[J].Ceramics International,2021,47(13):18699-18707.
[24] 蒯超,赵惠忠,陈金凤,等.浸蜡工艺对高钙镁钙质耐火材料抗水化性的影响[J].耐火材料,2013,47(3):200-203.
[25] CHEN S J,LU P G,CHEN G R,et al.Improved hydration resistance of synthesized magnesia-calcia clinker by surface modification[J].Journal of the American Ceramic Society,2004,87(12):2164-2167.
[26]GHASEMI-KAHRIZSANGI S,DEHSHEIKH H G,BOROUJERDNIA M.MgO-CaO-Cr2O3 composition as a novel refractory brick:use of Cr2O3 nanoparticles[J].Boletín de La Sociedad Espaíola de Cerámicay Vidrio,2017,56(2):83-89.
[27] 余辉,韩兵强,魏耀武,等.Zr(OH)4添加量及煅烧温度对CaO砂烧结与抗水化性能的影响[J].耐火材料,2017,51(2):100-104.
[28] CHEN M,ITO S,YAMAGUCHI A.Densification and improvement of slaking resistance of calcia clinker by addition of ZrO2[J].Journal of the Ceramic Society of Japan,2002,110(1287):975-979.
[29] 陈敏,王楠,王洋,等.合成抗水化性致密氧化钙砂的研究[J].东北大学学报(自然科学版),2007,28(2):225-228.
[30] 陆彩云.利用纳米ZrO2添加剂合成MgO-CaO-CaZrO3耐火材料的研究[D].沈阳:东北大学,2008.
[31] GHASEMI-KAHRIZSANGI S,SEDEH M B,DEHSHEIKH H G,et al.Densification and properties of ZrO2 nanoparticles added magnesia-doloma refractories[J].Ceramics International,2016,42(14):15658-15663.
[32] 黄剑.稀土氧化物对烧成镁钙材料性能影响研究[D].武汉:武汉科技大学,2012.
[33] 孙殿双,张文杰,汪厚植.添加稀土氧化物对白云石烧结和抗水化性能的影响[J].耐火材料,1994,28(4):185-188.
[34] 王周福,王玺堂,徐袁琳,等.稀土氧化物掺杂对镁钙系耐火材料性能的影响[C]//新形势下全国耐火原料发展战略研讨会论文集,太原,2014:92-97.
[35] 张达菲.稀土氧化物对MA-CA2-CA6系耐火材料性能影响的研究[D].赣州:江西理工大学,2019.
[36] 徐磊.Al2O3-MgO-CaO系耐火材料烧结行为及其性能的研究[D].沈阳:东北大学,2017.
[37] SHAHRAKI A,GHASEMI-KAHRIZSANGI S,NEMATI A.Performance improvement of MgO-CaO refractories by the addition of nano-sized Al2O3[J].Materials Chemistry and Physics,2017,198:354-359.
[38] 熊娜玲,邓俊杰.氧化铁纳米粒子对镁钙耐火材料性能的改善[J].耐火与石灰,2021,46(3):56-60.
[39] 王少阳,赵嘉亮,罗旭东.纳米颗粒改善白云石水化性能的研究[J].耐火与石灰,2020,45(2):50-53.
[40] GHASEMI-KAHRIZSANGI S,DEHSHEIKH H G,KARAMIAN E,et al.A comparative evaluation of the addition impact of nanometer-sized tetravalent oxides on the performance of doloma-magnesia ceramic refractories[J].Ceramics International,2018,44(2):2058-2064.
[41] 李金锋,王黎,漆小鹏,等.二茂铁含量对不烧镁钙系耐火材料性能的影响[J].耐火材料,2021,55(1):64-68.
[42] 任魁锋,杨景奎,王诚训,等.MgO-CaO砂的抗水化性研究[J].耐火材料,2001,35(3):174-175.
[43] LIU S K,WEI Y W,WANG J H,et al.Effect of titanium chelating compound on hydration resistance of CaO material[J].Journal of the American Ceramic Society,2020,103(9):5302-5311.
[44] GHASEMI-KAHRIZSANGI S,SHAHRAKI A,FAROOGHI M.Effect of nano-TiO2 additions on the densification and properties of magnesite-dolomite ceramic composites[J].Iranian Journal of Science and Technology,Transactions A:Science,2016,42(2):567-575.
[45] WEI J W,HAN B Q,WANG X C,et al.Improvement in hydration resistance of CaO granules based on CaO-TiO2,CaO-ZrO2 and CaO-V2O5 systems[J].Materials Chemistry and Physics,2020,254:123413.
[46] SHI H S,ZHAO Y J,LI W W.Effects of temperature on the hydration characteristics of free lime[J].Cement and Concrete Research,2002,32(5):789-793.
[47] 郭正.高钙镁钙砂的合成及其抗水化性能研究[D].西安:西安建筑科技大学,2015.
[48] 秦露露.MgO-CaO-TiO2-ZrO2材料在烧结过程中的物理化学变化[D].郑州:郑州大学,2016.
[49] 周振中.添加剂对氧化钙粉体的钝化效果影响[D].鞍山:辽宁科技大学,2012.
[50] 罗明,李楠,郑海忠,等.外加剂对白云石烧结及抗水化性的影响[J].耐火材料,2001,35(1):14-15+18.
[51] 张兴业.提高镁钙碳砖抗水化性能的措施[J].硅酸盐通报,1995 (2):38-40+49.
[52] WANG J H,WEI Y W,LI N, et al.Hydration resistance of CaO material prepared by Ca(OH)2 calcination with chelating compound[J].Materials,2019,12(14):2325.
[53] 柯昌明,李楠.水化加入物对镁白云石高温烧结性能及显微结构的影响[J].耐火材料,1994,28(5):261-264.
[54] ZHANG Q,WEI Y W,ZHANG T,et al.Preparation of CaO granules using the granulation method[J].Advances in Applied Ceramics,2018,117(6):334-339.
[55] WEI Y W,ZHANG T,ZHANG Q,et al.Improvement in hydration resistance of CaO granules by addition of Zr(OH)4 and Al(OH)3[J].Journal of the American Ceramic Society,2019,102(3):1414-1424.
[56] 闪静祎,王军凯,黄珍霞,等.外电场对水在CaO(100)表面吸附的第一性原理计算[J].耐火材料,2021,55(1):44-50. |
