Fluidization behavior and reducibility of iron ore fines during hydrogen-induced fluidized bed reduction 被引量：3

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摘要 A laboratory fluidized bed reactor was used to investigate the fluidization behavior and reducibility of various iron ore fines.Hydrogen was chosen as a reducing agent across a temperature range of 873-1073 K.The magnetite ore used exhibited strong sticking behavior after the initiation of metallic iron formation.All other tested ores fluidized sufficiently well when subjected to the same high reduction temperatures.Parallel kinetic analysis was conducted using a previously developed model to include three rate-limiting step types.The trend of apparent activation energy was correlated with the degree of reduction.Additionally,the influence of varying the specific gas rate was investigated.The results show the variation in reducibility as a result of different interactions,which influence the rate-limiting mechanisms of nucleation and the undertaken chemical reactions,which vary as a function of temperature and degree of conversion.The apparent activation energies,determined from the reduction of wtistite to metallic iron,were in the range of 15-60 kJ/mol,depending on the iron ore used and the degree of conversion.The change in apparent activation energy deriving from the increased specific gas rate can be explained by an increasing nucleation effect,especially at lower reduction temperatures.

作者 Daniel Spreitzer Johannes Schenk

机构地区 Chair of Ferrous Metallurgy

出处《Particuology》 SCIE EI CAS CSCD 2020年第5期36-46,共11页 颗粒学报（英文版）

基金 the financial support from the project E3-SteP(Enhanced Energy Efficient Steel Production),which is funded by the Austrian Research Promotion Agency(FFG).

关键词 Fluidized bed Iron ore reduction HYDROGEN Fluidization behavior Kinetic analysis

分类号 TF55 [冶金工程—钢铁冶金] TQ051.13 [化学工程]

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参考文献2

1Chunbao (Charles) XU,CANG Da-qiang.A Brief Overview of Low CO_2 Emission Technologies forIron and Steel Making[J].Journal of Iron and Steel Research International,2010,17(3):1-7. 被引量：23
2Johannes Leopold Schenk.Recent status of fluidized bed technologies for producing iron input materials for steelmaking[J].Particuology,2011,9(1):14-23. 被引量：18

二级参考文献45

1International Energy Agency. Biofuels for Transport-An International Perspective [M]. Paris: Office of Energy Efficiency, Technology and Research and Development, OECD/IEA, 2004. 被引量：1
2The International Energy Outlook 2008 [M]. Washington: Energy Information Administration, 2008. 被引量：1
3Jiang Q, Liu R. Analysis of Greenhouse Gas Emission and Reduction in Chinese Steel Industry [EB/OL]. [2007-01-12]. http://cdm. ccchina. gov. cn/WebSite/CDM/UpFile/File1150. pdf. 被引量：1
4IPCC. Climate Change 2007: The Physical Science Basis [M]. Geneva: Contribution of Working Group I to the Fourth Assessment Report of the Intergovernmental Panel on Climate Change, 2007. 被引量：1
5Jitsuhara I. Sectoral Approach for Climate Change in the World Steel Industry-A New Challenge for Establishing a Concerted World Steel Industry Specific Approach for CO2 Emissions Mitigation [C/OL]//First Meeting of the CEPS Task Force on Sectoral Industry Approaches. Brussels: [s. n.], 2007-09-18 [2008-10-01]. http://www. ceps. eu/files/Jitsuhara _ CEPS _ workshop_on_SA.pdf. 被引量：1
6Orth A, Anastasijevic N, Eichberger H. Low CO2 Emission Technologies for iron and steelmaking as well as titania slag production [J]. Minerals Engineering, 2007, 20(9): 854. 被引量：1
7Michard J A, Schneider M, de Lassat de Pressigny Y, et al. Blast Furnace vs. Smelting Reduction: Competition or Synergy? [C] // de la Revue de Metallurgie. The 4th European Conference of Iron and Steel (ECIC). Paris: ATS-RM, 2000: 710. 被引量：1
8Fay J A, Golomb D. Energy and the Environment [M]. London: Oxford University Press, 2002. 被引量：1
9Meng K C, Williams R H, Celia M A. Opportunities for Low- Cost CO2 Storage Demonstration Projects in China [J]. Energy Policy, 2007, 35(4): 2368. 被引量：1
10Cavenati S, Grande C A, Rodriges A E. Removal of Carbon Dioxide From Natural Gas by Vacuum Pressure Swing Adsorption [J]. Energy Fuels, 2006, 20(6): 2648. 被引量：1

共引文献39

1高攀,李强,张作良,张伟,邹宗树,干勇.喷吹循环煤气氧气高炉的静态模型[J].材料与冶金学报,2013,12(1):7-12. 被引量：4
2郭培民,高建军,赵沛.氧气高炉多区域约束性数学模型[J].北京科技大学学报,2011,33(3):334-338. 被引量：13
3汤忖江,王华,卿山,施哲,丁跃华,李亮清,张竹明,杨雪峰.富氧顶吹熔融还原技术冶炼高磷铁矿的研究[J].材料导报,2011,25(8):95-99. 被引量：5
4HU Chang-qing,HAN Tao,ZHANG Yu-zhu,ZHANG Zhi-xia.Theoretical Foundation of Carbonation Pellet Process for Ferrous Sludge Recycling[J].Journal of Iron and Steel Research International,2011,18(12):27-31. 被引量：1
5罗立群,黄红,余永富.Characterization and technology of fast reducing roasting for fine iron materials[J].Journal of Central South University,2012,19(8):2272-2278. 被引量：15
6卢鑫,白皓,赵立华,刘雪婷,苍大强.钢铁企业能源消耗与CO_2减排关系[J].北京科技大学学报,2012,34(12):1445-1452. 被引量：18
7徐文青,李寅蛟,朱廷钰,曹万杰.中国钢铁工业CO_2排放现状与减排展望[J].过程工程学报,2013,13(1):175-180. 被引量：18
8Lothar Reh.Process engineering in circular economy[J].Particuology,2013,11(2):119-133. 被引量：3
9Hai-bin Zuo,Zheng-wen Hu,Jian-liang Zhang,Jing Li,Zheng-jian Liu.Direct reduction of iron ore by biomass char[J].International Journal of Minerals,Metallurgy and Materials,2013,20(6):514-521. 被引量：6
10Qingshan Zhu,Rongfang Wua,Hongzhong Li.Direct reduction of hematite powders in a fluidized bed reactor[J].Particuology,2013,11(3):294-300. 被引量：9

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1邵剑华,张虎成,方觉,安志伟.流化床和竖炉对熔融还原流程煤耗的影响[J].钢铁研究学报,2008,20(3):5-8. 被引量：8
2Johannes Leopold Schenk.Recent status of fluidized bed technologies for producing iron input materials for steelmaking[J].Particuology,2011,9(1):14-23. 被引量：18
3王其洪,邵剑华,林银河,郭占成,唐惠庆.微型流化床内CO还原铁矿粉动力学试验[J].钢铁研究学报,2012,24(4):6-9. 被引量：9
4Qingshan Zhu,Rongfang Wua,Hongzhong Li.Direct reduction of hematite powders in a fluidized bed reactor[J].Particuology,2013,11(3):294-300. 被引量：9
5林银河,郭占成,唐惠庆.微型流化床中气氛对还原度的影响[J].钢铁研究学报,2014,26(4):18-23. 被引量：3
6Feng PAN,Qing-shan ZHU,Zhan DU,Hao-yan SUN.Oxidation Kinetics,Structural Changes and Element Migration during Oxidation Process of Vanadium-titanium Magnetite Ore[J].Journal of Iron and Steel Research International,2016,23(11):1160-1167. 被引量：2
7李丽.多因素多水平复杂正交试验的方差分析[J].延安大学学报（自然科学版）,2018,37(3):27-31. 被引量：6
8Jue Tang,Man-sheng Chu,Feng Li,Cong Feng,Zheng-gen Liu,Yu-sheng Zhou.Development and progress on hydrogen metallurgy[J].International Journal of Minerals,Metallurgy and Materials,2020,27(6):713-723. 被引量：68
9练强,张杰.锰渣硫酸浸出正交实验探究[J].矿冶工程,2020,40(2):108-110. 被引量：4
10徐其言,李志平,谷张涵,殷志宏.巴西铁矿粉流态化还原条件优化研究[J].钢铁钒钛,2020(3):99-104. 被引量：3

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2C.J.M.Hessels,A.H.J.Smeets,G.Finotello,N.G.Deen,Y.Tang.Sintering behavior of combusted iron powder in a packed bed reactor with nitrogen and hydrogen[J].Particuology,2023(12):8-17.
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3Ruofeng Wang,Shuai Yuan,Yanjun Li,Peng Gao,Ru Li.Hydrogen-based mineral phase transformation mechanism investigation of pyrolusite ore[J].International Journal of Minerals,Metallurgy and Materials,2024,31(11):2445-2457.
4Haoyan Sun,Ajala Adewole Adetoro,Zhiqiang Wang,Qingshan Zhu.Behavior and mechanism of pre-oxidation improvement on fluidization in the fluidized reduction of titanomagnetite[J].International Journal of Minerals,Metallurgy and Materials,2024,31(11):2458-2465.

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