Dome Combustion Hot Blast Stove for Huge Blast Furnace 被引量：14

Dome Combustion Hot Blast Stove for Huge Blast Furnace

导出

摘要 In Shougang Jingtang 5 500m 3 huge blast furnace ( BF ) design , dome combustion hot blast stove ( DCHBS ) technology is developed.DCHBS process is optimized and integrated , and reasonable hot blast stove ( HBS ) technical parameters are determined.Mathematic model is established and adopted by computational fluid dynamics ( CFD ) .The transmission theory is studied for hot blast stove combustion and gas flow , and distribution results of HBS velocity field , CO density field and temperature field are achieved.Physical test model and hot trail unit are established , and the numeral calculation result is verified through test and investigation.3-D simulation design is adopted.HBS process flow and process layout are optimized and designed.Combustion air two-stage high temperature preheating technology is designed and developed.Two sets of small size DCHBSs are adopted to preheat the combustion air to 520-600℃.With the precondition of BF gas combustion , the hot blast stove dome temperature can exceed 1 420 ℃. According to DCHBS technical features , reasonable refractory structure is designed.Effective technical measures are adopted to prevent hot blast stove shell intercrystalline stress corrosion.Hot blast stove hot pipe and lining system are optimized and designed.After blowing in , the blast temperature keeps increasing , and the monthly average blast temperature reaches 1 300℃ when burning single BF gas. In Shougang Jingtang 5 500m 3 huge blast furnace ( BF ) design , dome combustion hot blast stove ( DCHBS ) technology is developed.DCHBS process is optimized and integrated , and reasonable hot blast stove ( HBS ) technical parameters are determined.Mathematic model is established and adopted by computational fluid dynamics ( CFD ) .The transmission theory is studied for hot blast stove combustion and gas flow , and distribution results of HBS velocity field , CO density field and temperature field are achieved.Physical test model and hot trail unit are established , and the numeral calculation result is verified through test and investigation.3-D simulation design is adopted.HBS process flow and process layout are optimized and designed.Combustion air two-stage high temperature preheating technology is designed and developed.Two sets of small size DCHBSs are adopted to preheat the combustion air to 520-600℃.With the precondition of BF gas combustion , the hot blast stove dome temperature can exceed 1 420 ℃. According to DCHBS technical features , reasonable refractory structure is designed.Effective technical measures are adopted to prevent hot blast stove shell intercrystalline stress corrosion.Hot blast stove hot pipe and lining system are optimized and designed.After blowing in , the blast temperature keeps increasing , and the monthly average blast temperature reaches 1 300℃ when burning single BF gas.

作者 ZHANG Fu-ming , MAO Qing-wu , MEI Cong-hua , LI Xin , HU Zu-rui ( Beijing Shougang International Engineering Technology Co Ltd , Beijing 100043 , China )

出处《Journal of Iron and Steel Research International》 SCIE EI CAS CSCD 2012年第9期1-7,共7页

关键词 dome combustion hot blast stove high blast temperature ceramic burner high temperature combustion air preheating CFD dome combustion hot blast stove high blast temperature ceramic burner high temperature combustion air preheating CFD

分类号 TF578 [冶金工程—钢铁冶金]

引文网络
相关文献

参考文献3

1张福明,钱世崇,张建,毛庆武,苏维.首钢京唐5500m^3高炉采用的新技术[J].钢铁,2011,46(2):12-17. 被引量：26
2张福明.现代大型高炉关键技术的研究与创新[J].钢铁,2009,44(4):1-5. 被引量：6
3张福明.我国大型顶燃式热风炉技术进步[J].炼铁,2002,21(5):5-9. 被引量：21

二级参考文献16

1陈炳霖.关于我国高炉高风温的探讨[J].炼铁,1993,12(3):13-18. 被引量：8
2陆熔,李维国,陶荣尧.宝钢炼铁20年的回顾及展望[J].炼铁,2005,24(B09):2-8. 被引量：7
3吴建洲,徐少兵.宝钢4高炉设计采用的新技术及其特点[J].宝钢技术,2006(5):35-39. 被引量：3
4毛庆武,张福明,姚轼,等.迁钢2号高炉工艺优化与技术创新[A].中国金属学会.2008年全国炼铁生产会议暨炼铁年会文集[c].北京:中国金属学会,2008.90.
5任绍峰张福明周为民等.大型高炉煤气含尘量在线监测系统的设计与实现.冶金自动化,2008,32(1):1-1.
6毛庆武,张福明,张建,等.首钢高炉高风温技术进步[A].中国金属学会.2007中国钢铁年会论文集[c].北京:冶金工业出版社,2007.3.
7高成云.马钢4000m^3级高炉的主要技术特点及装备水平[J].炼铁,2007,26(4):1-3. 被引量：5
8Zhang Fu-ming, Qian Shi-chong, Zhang Jian, et al. Design of 5500m^3 Blast Furnace at Shougang Jingtang [J]. Journal of I-ron and Steel Research International, 2009, 16 (Supplement2) : 1029.
9Stephenson E D, Parratt J E, Bowler K, et al. Towards the Year 2000--the Second Campaign of Redear Blast Furnace [C]//2nd International Congress on the Science and Technolo- gy of Ironmaking and 57th Ironmaking Conference Proceed- ings. Toronto: Ironmaking Division of the Iron and Steel Soci- ety, 1998: 625.
10Evans J L. Design and Construction of Lining of No. 4 Blast Furnace Port Talbot Works [J]. Ironmaking and Steelmaking, 1994, 21(2): 101.

共引文献46

1唐兴智.浅析热风炉炉顶内衬结构型式[J].工业加热,2004,33(4):40-42.
2唐兴智,唐冬宁,汪浩,陈静之,陈习文.高温长寿型顶燃式热风炉的应用[J].鞍钢技术,2005(5):11-14.
3唐兴智,唐冬宁,汪浩,陈静之,陈习文.高温长寿型顶燃式热风炉的应用[J].工业加热,2005,34(5):44-47. 被引量：1
4杨俊,杜涛,蔡九菊,董辉.国外热风炉发展综述[J].沈阳工程学院学报（自然科学版）,2005,1(4):18-20. 被引量：8
5陈冠军,王连尉,胡雄光.首秦卡卢金热风炉技术研究进展[J].冶金能源,2007,26(1):31-33. 被引量：9
6唐兴智.热风炉炉顶内衬结构型式探究[J].工业加热,2008,37(2):41-44.
7邬纳新,李彤,黄俊东.马钢热风炉残氧分析与优化燃烧技术[J].自动化仪表,2008,29(7):43-45. 被引量：1
8王永强,吴爽.浅析热风炉炉顶内衬结构型式[J].江苏冶金,2008,36(6):67-69.
9李勇,薄钧,刘雄章.热风炉长寿与低蠕变Al2O3-SiO2系耐火材料的探究[J].耐火材料,2008,42(3):215-218. 被引量：10
10黄国华,邢桂菊.高炉热风炉高风温技术的发展与应用[J].工业加热,2008,37(6):10-14. 被引量：3

同被引文献80

1樊波,齐渊洪,严定鎏,许海川.热风炉燃烧控制技术的研究[J].钢铁,2005,40(4):17-20. 被引量：15
2刘骋.可调谐光滤波器及其WDM应用[J].光通信研究,2005(3):64-66. 被引量：2
3李营,张书练.基于可调谐FP滤波器的光纤光栅解调系统[J].激光技术,2005,29(3):237-240. 被引量：34
4张炳哲,张欣欣,于帆,焦吉成,彭宝翠.卡卢金热风炉气体燃烧与流动数值模拟[J].工业炉,2005,27(6):1-3. 被引量：9
5任刚伟,常亮,卫晓辉,黄振武,刘卓峰,高振昕.硅砖中α-方石英的晶体结构与形貌[J].硅酸盐学报,2006,34(1):123-126. 被引量：11
6施国优.热火焰清理工艺之探讨[J].宝钢技术,1990(3):41-45. 被引量：7
7胡日君,程素森.考贝式热风炉拱顶空间烟气分布的数值模拟[J].北京科技大学学报,2006,28(4):338-342. 被引量：10
8童剑辉,冯青,汪和平.辊道窑烧成带气体流场与温度场的三维数值模拟[J].中国陶瓷,2006,42(5):27-31. 被引量：27
9HU Chang-qing,CHEN Li-yun,ZHANG Chun-xia,QI Yuan-hong,YIN Rui-yu.Emission Mitigation of CO_2 in Steel Industry: Current Status and Future Scenarios[J].Journal of Iron and Steel Research International,2006,13(6):38-42. 被引量：3
10马竹梧.高炉热风炉自动换炉的研究和应用实践[J].冶金自动化,2007,31(2):29-32. 被引量：7

引证文献14

1岳林,伍成波,张江斌,吴乾江.卡鲁金热风炉流场特性研究[J].工业炉,2015,37(2):1-3. 被引量：1
2欧阳强强,方挺,谷文平,王彦,胡兴柳.基于LCFM的分布式光纤热风管温度检测[J].激光技术,2016,40(4):541-544. 被引量：1
3方挺,欧阳强强,张敬棋,刘剑琴,胡兴柳,王彦.基于环绕式光纤的热风管温度解调技术[J].激光技术,2016,40(5):746-749.
4陈智勇,王璟博,田勇.铸坯火焰清理机烧嘴火焰特性模拟[J].钢铁,2016,51(11):87-92. 被引量：8
5蒋朝辉,周刚,张海峰,桂卫华,阳春华,谢永芳.顶燃式球式热风炉烧炉过程温度场建模[J].中南大学学报（自然科学版）,2018,49(9):2216-2224. 被引量：13
6邢东明,李勇,张秀华,郑清瑶,和弦,马晨红,薄钧.热风炉高温区用硅砖中鳞石英的结构演变[J].硅酸盐学报,2019,47(12):1818-1824. 被引量：11
7王一男,刘晓志,孙超,王伟兵,李仁华,杨英华.基于深度神经网络的热风炉烟温预测模型[J].河北冶金,2021(1):34-36. 被引量：8
8艾中路,钟树周,杨君,邓晖.热风炉在线排砖装置[J].上海金属,2021,43(6):82-84.
9史建凯,岳峰,田儒良,郑力宁,翟万里,林鹏.连铸工艺参数对20CrMnTi齿轮钢150mm×150mm铸坯凝固组织影响数值模拟和生产应用[J].特殊钢,2022,43(2):16-20. 被引量：5
10陈宁,李彬艳,赫学实,罗彪,桂卫华,阳春华.基于参数估计误差的辊道窑温度场优化控制方法[J].控制理论与应用,2022,39(9):1609-1618. 被引量：2

二级引证文献47

1亢克松,张建舒,巩鹏辉.基于多网络模型融合的烟雾检测系统[J].河北冶金,2023(S01):62-66. 被引量：1
2张炯,王干,范海宁,张立鑫,周亚辉,王泉.马钢板坯自动火焰清理机生产实践[J].连铸,2018,43(6):38-41. 被引量：4
3赵成林,唐复平,朱晓雷,廖相巍,陈东.IF钢连铸坯表层夹杂分布特征的试验[J].钢铁,2017,52(12):42-47. 被引量：10
4王畅,于洋,王林,青靓,陈瑾,王明哲.热轧卷表面机清条纹的形成机理与预防措施[J].中国冶金,2018,28(7):46-49. 被引量：2
5陈智勇,王璟博,杨轶龙,王鹏,王俭.火焰清理机能源介质对清理质量的影响[J].中国冶金,2018,28(8):32-37. 被引量：5
6邢作霞,赵海川,陈雷,齐凤升,代俊雯,颜宁.基于耦合传热的电制热固体蓄热结构优化研究[J].中国电机工程学报,2019,39(20):5999-6007. 被引量：16
7杨海东,陈强,徐康康,朱成就.基于数值模拟的马蹄焰玻璃窑蓄热室热效率研究[J].化工学报,2019,70(12):4608-4616. 被引量：3
8吴良玉.热风炉的燃油推广效益研究[J].南方农机,2020,51(8):216-216.
9胡飘,宋艳艳,董殿敏,王战民,彭西高.脉冲激振法测试耐火材料杨氏模量的原理与应用[J].耐火材料,2020,54(3):253-255. 被引量：1
10张秀华,李勇,田志宏,郑清瑶,邢东明,和弦,薄钧.压蠕变实验方法对硅砖蠕变结果的适应性探究[J].硅酸盐学报,2020,48(9):1499-1504. 被引量：3

1Zhu Rong, Sun Yanhui, Qiu Yongquan, Ouyang Guang,Chen Haiping, Guo Changhua.Research and Application of Internal Combustion Coal-Oxygen Burner for Fluxing in EAF[J].Journal of Iron and Steel Research International,1999,6(1):23-26.
2Li Yiwei Shi Jian＇ en Bao Lei Wang Yi.Practice of improving the hot blast temperature for the 2500 m^3 BF[J].Baosteel Technical Research,2008,2(2):31-35.
3Spalling Resistance Brick for Stove[J].China's Refractories,1995,4(4):38-38.
4一季度Trail冶炼厂铅锌产量均下降[J].中国铅锌锡锑,2014(5):63-63.
5Trail冶炼厂二季度精铅产量下降[J].中国铅锌锡锑,2013(10):55-55.
6ShuchenZhang,HongzhiGuo,XiangjunLiu,ZhangpingCai,XianchengGao,SidongXu.Numerical calculation of flow and heat transfer process in the new-type external combustion swirl-flowing hot stove[J].Journal of University of Science and Technology Beijing,2003,10(5):31-34.
7Guang-sheng WEI,Rong ZHU,Ting CHENG,Fei ZHAO.Numerical Simulation of Jet Behavior and Impingement Characteristics of Preheating Shrouded Supersonic Jets[J].Journal of Iron and Steel Research International,2016,23(10):997-1006. 被引量：2
8Jie Fu,Heming Chang,Shixiang Zhou,Boping Chen (Metallurgy Engineering School, University of Science and Technology Beijing, Beijing 100083, China).Kinetics of Nitrogen Removal from Molten Steel under Vacuum and Gas-Blowing Conditions[J].International Journal of Minerals,Metallurgy and Materials,1998,12(1):5-8.
9周萍,王志奇,周乃君.Numerical simulation of temperature field during gas preheating and start-up of drained aluminum reduction cell[J].中国有色金属学会会刊：英文版,2006,16(4):960-964. 被引量：1
10WEI Facan.Influencing Factors of Properties of Castables for Hot Blast Stove Pipes[J].China's Refractories,2014,23(3):44-52. 被引量：1

Journal of Iron and Steel Research International

2012年第9期

浏览历史

内容加载中请稍等...