Synthesis of Mullite from High-alumina Fly Ash:a Case from the Jungar Power Plant in Inner Mongolia, Northern China 被引量：2

Synthesis of Mullite from High-alumina Fly Ash:a Case from the Jungar Power Plant in Inner Mongolia, Northern China

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摘要 In this paper, an experimental study was conducted in order to test the feasibility of sintering mullite directly from the high-alumina fly ash, without adding any extra material. The results show that the mullite contents in most sintered samples are over 70%. The samples sintered from the beneficiated fly ash have a higher content of mullite than those from the as-received fly ash under the same synthetic conditions. To obtain an equal amount of mullite, a higher sintering temperature is needed for the beneficiated fly ash than for the as-received fly ash. Considering the physical properties of sintered mullite, the favorable sintering temperature is 1400℃ for the as-received fly ash and 1500℃ for the beneficiated fly ash. A higher sintering temperature and a shorter holding time are profitable to sintering mullite. The orthogonal test confirmed that the dominant factor affecting mullite synthesis is sintering temperature, and that the most profitable matching conditions are 200 MPa-1500℃-3 h for the as-received fly ash and 200 MPa-1500 ℃-4 h for the beneficiated fly ash. In this paper, an experimental study was conducted in order to test the feasibility of sintering mullite directly from the high-alumina fly ash, without adding any extra material. The results show that the mullite contents in most sintered samples are over 70%. The samples sintered from the beneficiated fly ash have a higher content of mullite than those from the as-received fly ash under the same synthetic conditions. To obtain an equal amount of mullite, a higher sintering temperature is needed for the beneficiated fly ash than for the as-received fly ash. Considering the physical properties of sintered mullite, the favorable sintering temperature is 1400℃ for the as-received fly ash and 1500℃ for the beneficiated fly ash. A higher sintering temperature and a shorter holding time are profitable to sintering mullite. The orthogonal test confirmed that the dominant factor affecting mullite synthesis is sintering temperature, and that the most profitable matching conditions are 200 MPa-1500℃-3 h for the as-received fly ash and 200 MPa-1500 ℃-4 h for the beneficiated fly ash.

作者 CHEN Jiangfeng SHAO Longyi LU Jing

机构地区 Department of Resources and Environmental Engineering The State Key Laboratory of Coal Resources and Safe Mining

出处《Acta Geologica Sinica(English Edition)》 SCIE CAS CSCD 2008年第1期99-104,共6页 地质学报（英文版）

基金 This work was financed by the National Natural Science Foundation of China （Grant No. 40672103 , 40575065） the Program for New Century Excellent Talents in University of the Chinese Ministry of Education. The authors sincerely thank Professor Li Kaiqi for his constructive suggestions and useful discussions.

关键词 high-alumina fly ash sintering temperature MULLITE orthogonal test high-alumina fly ash, sintering temperature, mullite, orthogonal test

分类号 P57 [天文地球—矿物学]

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参考文献14

1周忠华.用粉煤灰生产陶瓷用莫来石材料[J].粉煤灰综合利用,2003,17(6):28-29. 被引量：2
2孙俊民,程照斌,李玉琼,邵淑英,司全景.利用粉煤灰与工业氧化铝合成莫来石的研究[J].中国矿业大学学报,1999,28(3):247-250. 被引量：13
3陈震宙,陈天明,郑启祥.粉煤灰形成莫来石条件的研究[J].福州大学学报（自然科学版）,1994,22(5):93-96. 被引量：5
4J. S. Jung,H. C. Park,R. Stevens.Mullite ceramics derived from coal fly ash[J].Journal of Materials Science Letters.2001(12) 被引量：1
5Hong,S.H,and Messing,G.L.Anisotropic grain growth in diphasic-gel-derived titania-doped mullite[].JAmCeramic Soc.1998 被引量：1
6Huang,T,Rahaman,M.N,Mah,T,and Parthasarathay,T.A.Anisotropic grain growth and microstructural evolution of dense mullite above 1550℃[].JAmCeramic Soc.2000 被引量：1
7Huang,X,Hwang,J.Y,and Mutsuddy,B.C.Properties of mullite synthesized from fly ash and alumina mixture[].Interceram.1995 被引量：1
8Hwang,J.Y,Huang,X,and Hein,A.M.Mullite synthesis from beneficiated fly ash waste minimization by using alternative materials[].Journal of Occupational Medicine.1994 被引量：1
9Johnson.S.M,and Pask.J.A.mixture[].AmCeramic SocBull.1982 被引量：1
10Kong,L.B,Zhang,T.S,Chen,Y.Z,Ma,J,Boey,F,and Huang, H.Microstrnctural composite mullite derived from oxides via a high-energy ball milling process[].Ceramics Intl.2004 被引量：1

二级参考文献5

1Andrew J S.莫来石及其作为结合相的应用[J].国外耐火材料,1992,(2):11-18. 被引量：1
2徐平坤郭景荣等.合成莫来石工艺研究[J].耐火材料,1982,(4):15-22. 被引量：1
3Andrew J S，国外耐火材料，1992年，2期，11页被引量：1
4陆佩文，硅酸盐物理化学，1991年，291页被引量：1
5徐平坤，耐火材料，1982年，4期，15页被引量：1

共引文献16

1邵龙义,陈江峰,吕劲,Oldroyd A,肖正辉.燃煤电厂粉煤灰的矿物学研究[J].煤炭学报,2004,29(4):448-452. 被引量：32
2陆银平,李凯琦,刘钦甫.脱硅高岭土制备莫来石材料的研究[J].硅酸盐学报,2004,32(8):1033-1035. 被引量：14
3邢净,李金洪,魏尊莉.Y_2O_3对高铝粉煤灰合成莫来石的影响[J].硅酸盐通报,2007,26(2):291-295. 被引量：7
4戴武斌,曾令可,刘艳春,税安泽.煅烧温度对铝型材厂污泥晶相结构影响的研究[J].中国陶瓷,2009,45(10):30-33.
5李军旗,蒲锐,陈朝轶,宫敏.碱法对粉煤灰的预脱硅处理[J].轻金属,2010(11):11-13. 被引量：17
6蒲锐,宫敏,范全升.碱法提高铝硅矿物的铝硅比[J].粉煤灰,2011,23(2):19-20. 被引量：2
7宋绍雷,甄强,王方方,王亚丽.低品位煤矸石制备多孔莫来石研究[J].耐火材料,2014,48(1):18-21. 被引量：26
8赵瑞.粉煤灰合成高温陶瓷材料的研究进展[J].现代技术陶瓷,2014,35(4):32-38. 被引量：3
9林滨,李少鹏,侯新娟,李会泉.工艺条件对高铝粉煤灰制备莫来石性能的影响[J].硅酸盐通报,2015,34(6):1459-1464. 被引量：3
10杨静,马丽萍,李建铎,刘红盼,赵思琪,崔晓婧.粉煤灰制备耐火材料最佳烧结温度的探究[J].硅酸盐通报,2017,36(4):1303-1308. 被引量：2

同被引文献11

1白志民,杨静,丁浩.硅酸盐固体废弃物应用的研究进展Ⅰ——粉煤灰应用研究新成果[J].硅酸盐学报,2007,35(S1):172-179. 被引量：27
2LIUGuijian,GAOLianfen,ZHENGLiugen,ZHANGHaoyuan,PENGZicheng.Leaching Behavior of Fly Ashes from Power Plants[J].Acta Geologica Sinica(English Edition),2004,78(3):720-723. 被引量：3
3魏存弟,马鸿文,杨殿范,张军,李益.煅烧煤系高岭石高温相变特征及火山灰活性研究[J].硅酸盐通报,2005,24(2):13-16. 被引量：20
4魏存弟,杨殿范,李益,三国彰.煅烧温度对高岭石相转变过程及Si、Al活性的影响[J].矿物学报,2005,25(3):197-202. 被引量：29
5WANG Tong,WANG Ying,WANG Jun.Research on Potential Fertilization of Coal Gangue in the Weibei Coalfield,China[J].Acta Geologica Sinica(English Edition),2008,82(3):717-721. 被引量：7
6孙旺,郑诗礼,张亦飞,徐红彬,张懿.NaOH亚熔盐法处理拜尔法赤泥的铝硅行为[J].过程工程学报,2008,8(6):1148-1152. 被引量：32
7杜淄川,李会泉,包炜军,李少鹏,蔡卫权.高铝粉煤灰碱溶脱硅过程反应机理[J].过程工程学报,2011,11(3):442-447. 被引量：30
8苏双青,马鸿文,邹丹,李歌.高铝粉煤灰碱溶法制备氢氧化铝的研究[J].岩石矿物学杂志,2011,30(6):981-986. 被引量：24
9杨权成,马淑花,谢华,张然,郑诗礼.高铝粉煤灰提取氧化铝的研究进展[J].矿产综合利用,2012(3):3-7. 被引量：46
10薄春丽,郑诗礼,马淑花,谢华.高铝粉煤灰铝硅化合物在稀碱溶液中的浸出行为[J].过程工程学报,2012,12(4):613-617. 被引量：19

引证文献2

1WANG Lihua,ZHAO Pengda,LI Geng.Character of the Si and Al Phases in Coal Gangue and Its Ash[J].Acta Geologica Sinica(English Edition),2009,83(6):1116-1121. 被引量：6
2孙振华,包炜军,李会泉,回俊博,王晨晔,唐清.高铝粉煤灰预脱硅碱溶提铝过程中的物相转变规律[J].过程工程学报,2013,13(3):403-408. 被引量：12

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1郑烨,张锴,李建波,关彦军,杨凤玲,程芳琴.准东煤和煤矸石共燃对灰熔融特性和钠元素释放行为影响[J].环境化学,2020,39(8):2112-2119. 被引量：2
2陈永春,李守勤,周春财.淮南矿区煤矸石的物质组成特征及资源化评价[J].中国煤炭地质,2011,23(11):20-23. 被引量：23
3马兆菲,白杰,李春萍,张永锋,江宇.以内蒙古地区的高铝煤矸石为原料合成4A分子筛[J].化工进展,2013,32(3):657-660. 被引量：8
4SUN Yuzhuang,ZHAO Cunliang,LI Yanheng,WANG Jinxi,ZHANG Jianya,JIN Zhe,LIN Mingyue,Wolfgang KALKREUTH.Further Information of the Associated Li Deposits in the No.6 Coal Seam at Jungar Coalfield, Inner Mongolia, Northern China[J].Acta Geologica Sinica(English Edition),2013,87(4):1097-1108. 被引量：36
5郭曦尧,马淑花,吕松青,郑诗礼,邹兴.以脱铝赤泥-脱铝粉煤灰为原料制备硬硅钙石[J].中国有色金属学报,2015,25(2):534-544. 被引量：5
6林滨,李少鹏,侯新娟,李会泉.工艺条件对高铝粉煤灰制备莫来石性能的影响[J].硅酸盐通报,2015,34(6):1459-1464. 被引量：3
7秦倩,王金满,胡斯佳.利用煤矸石粉煤灰制成农田排水混凝土材料的研制实验[J].中国矿业,2015,24(7):39-43. 被引量：4
8赵永彬.粉煤灰的矿物学性质研究[J].洁净煤技术,2015,21(4):112-116. 被引量：16
9李会泉,许德华,王晨晔,回俊博,包炜军,孙振华.高铝粉煤灰两步碱水热法浸出氧化铝工艺研究[J].轻金属,2016(12):5-10. 被引量：15
10Ganyu Zhu,Huiquan Li,Shaopeng Li,Xinjuan Hou,Xingrui Wang.Crystallization of calcium silicate at elevated temperatures in highly alkaline system of Na_2O–CaO–SiO_2–H_2O[J].Chinese Journal of Chemical Engineering,2017,25(10):1539-1544. 被引量：1

1NONMETALS DEPOSITS[J].Abstracts of Chinese Geological Literature,2009,25(2):86-88.
2ZHANG Xuebin,WU Zuosheng,MENG Guangyao,LIU Xingqin.Formation and kinetics of porous cordierite from fly ash[J].Chinese Journal Of Geochemistry,2008,27(4):395-400.
3Hua wang, Qiang Zhang, Cunyi Song, Fengmei Liu Civil and Environmental Engineering School, University of Science and Technology Beijing, Beijing 100083, China.Synthesis of Zeolites by Alkaline Activation of Fly Ash[J].Journal of University of Science and Technology Beijing,2001,8(3):161-163. 被引量：2
4MINERALOGY[J].Abstracts of Chinese Geological Literature,2006,22(3):41-47.
5拨开雾霾见青天[J].汽车之友,2013(6):2-2.
6丁伯阳,刘卫平,陶海冰.泥浆护壁孔中剪切波速直接测试[J].工程勘察,2003,31(3):67-69. 被引量：2
7胡连荣.揭开苍蝇难打之谜[J].知识就是力量,2008(10):4-4.
8Huang Wenhui Yang Qi Department of Energy Resources and Geology , China University of Geosciences , Beijing 100083 Peng Suping Department of Geology and Engineering, China University of Mining and Technology, Beijing 100083 Zhao Zhigen Department of R.Geochemistry of Permian Coal and Its Combustion Residues in Huainan Coalfield, China[J].Journal of China University of Geosciences,2001,12(4):283-290. 被引量：2
9Jean-Charles Benezet,Pierre Adamiec,Ali Benhassaine.Relation between silico-aluminous fly ash and its coal of origin[J].Particuology,2008,6(2):85-92. 被引量：2
10月球大冒险（下）[J].动漫界．兴趣数学（小学中高年级）,2009(11):30-33.

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