Modeling of Strip Temperature in Rapid Cooling Section of Vertical Continuous Annealing Furnace 被引量：3

Modeling of Strip Temperature in Rapid Cooling Section of Vertical Continuous Annealing Furnace

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摘要 The strip temperature is affected by many factors in rapid cooling section （RCS） of the vertical continuous annealing furnace （VCAF）. They can he divided into four types： the physical properties of cooling gas, the geometry characteristics of configuration of cooling equipment, the heat transfer between the strip and the cooling gas, and the conductivity of the strip. It aims to model the strip temperature in the cooling section based on the fundamental heat transfer theory and the four aspects factors. The model for transient Nusselt number is obtained by considering Reynolds number, Prandtl number and geometry characteristics of RCS. Then cooling model of the strip transient temperature is built by Nusselt number, heat transfer coefficient and heat conductivity of the strip. The results are compared with the data from production line. The comparisons indicate that the model can well predict cooling temperature of the strip. It is hoped that the proposed model can be used for design and control of the vertical continuous annealing furnace. The strip temperature is affected by many factors in rapid cooling section （RCS） of the vertical continuous annealing furnace （VCAF）. They can he divided into four types： the physical properties of cooling gas, the geometry characteristics of configuration of cooling equipment, the heat transfer between the strip and the cooling gas, and the conductivity of the strip. It aims to model the strip temperature in the cooling section based on the fundamental heat transfer theory and the four aspects factors. The model for transient Nusselt number is obtained by considering Reynolds number, Prandtl number and geometry characteristics of RCS. Then cooling model of the strip transient temperature is built by Nusselt number, heat transfer coefficient and heat conductivity of the strip. The results are compared with the data from production line. The comparisons indicate that the model can well predict cooling temperature of the strip. It is hoped that the proposed model can be used for design and control of the vertical continuous annealing furnace.

作者 WAN Fei WANG Yong-qin QIN Shu-ren

机构地区 State Key Laboratory of Mechanical Transmission Baosteel Engineering and Technologies Group Co Ltd

出处《Journal of Iron and Steel Research International》 SCIE CAS CSCD 2012年第11期27-32,共6页

基金 Item Sponsored by National Science and Technology Support Program in 12th Five-Year Plan of China(2011BAE13B02)

关键词 rapid cooling jet impinging convection heat transfer coefficient rapid cooling jet impinging convection heat transfer coefficient

分类号 TK423.42 [动力工程及工程热物理—动力机械及工程] TG155.1 [金属学及工艺—热处理]

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参考文献10

1XIANG Shumhua, LIU Hua-fei, WEN Hong-quan, et al. Cooling Speed of Strip Temperature by Gas Jet Impinging With H2[C]//LI Wen-xiu. 2005 CSM Annual Meeting Pro eeedings. Beijing: The Chinese Society for Metals, 2005:421 (in Chinese).
2王永萍,鲍戟,高立.连续退火炉冷却技术的发展和现状[J].工业炉,2002,24(1):21-24. 被引量：26
3Incropera F P, Dewitt D P, Bergman T L, et al. Fundamentals of Heat and Mass Transfer [M]. Beijing: Chemistry Industry Press, 2009 (in Chinese).
4ZHU Guang-jun, SUN Y~qin. Transport Principal [M]. Bei- jing: Metallurgical Industry Press, 2009 (in Chinese).
5Abdlmonem H B, Michel A S. Effects of Surface Roughness on the Average Heat Transfer of an Impinging Air Jet [J]. In ternational Communication in Heat Mass Transfer, 2000, 27 (1) : 1.
6Lee J, Lee S J. The Effect of Nozzle Aspect Ratio on Stagna tion Region Heat Transfer Characteristics of Elliptic Impinging Jet [C] // International Journal of Heat and Mass Transfer. [s. 1. ]: Elsevier Science Ltd, 2000: 555.
7WANG Hou-hua, ZHOU Gen-ming, JI Xin-yu, et al. Funda- mentals of Heat Transfer [M]. Chongqing: Chongqing Uni- versity Press, 2006 (in Chinese).
8J1A Li di, Li Feng. Process Analysis for Heat Transfer in Rapid Cooling Section of Vertical Continuous Annealing Fur- nace on Hot Dip Galvanizing [J]. Energy for Metallurgical In- dustry, 2007, 26(3): 34.
9XU Jing-lei, XU Zhong, XIAO Min, et al. Numriary for Ana- lyzing Jet Impinging [J]. Mechanics in Engineering, 2007, 21 (6) : 8.
10Fuchs L, Hallqvist T. Numerical Study of Impinging Jets With Heat Transfer Inlet Conditions Effects [C]//Ameticfin Institute of Aeronatics and Astronautics 47th AIAA Aero- space Sciences Meeting Including the New Horizons Forum and Aerospace Exposition. Orlando: [s. n. ], 2009 : 1578.

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2辜蕾钢,徐文章.冷轧带钢连续退火冷却技术及建设的连续退火机组[J].钢铁技术,2007(5):13-17. 被引量：7
3王文乐,李建平,花福安,刘相华.CAS-300光亮连续退火模拟实验机的研究与开发[J].自动化与仪表,2008,23(8):40-42.
4王运起,包祥明.新型带钢连续退火机组概述[J].梅山科技,2008(3):8-10. 被引量：2
5花福安,王文乐,李建平,刘相华.自学习在模拟连续退火过程控制中的应用[J].东北大学学报（自然科学版）,2008,29(12):1718-1720. 被引量：2
6李建平,花福安,王文乐,王国栋.冷轧带钢连续退火模拟实验机的数学模型[J].东北大学学报（自然科学版）,2009,30(3):373-376.
7徐烨明,张爱华.新型冷却技术在梅钢1420mm连续退火机组上的应用[J].梅山科技,2009(4):63-64. 被引量：2
8翟正耀,柳翠翠,刘华飞.多排圆孔和狭缝喷气冷却风箱的阻力特性研究及应用[J].冶金能源,2010,29(4):18-20. 被引量：3
9柳智博,于顺兵,周利.连退机组炉内带钢振动特性分析及自动监控技术[J].机械工程与自动化,2010(6):166-167. 被引量：2
10邢改兰,刘华飞,周绍萍.多排狭缝气体冲击射流换热的实验研究[J].矿冶,2011,20(1):38-42. 被引量：8

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1张玲,蒋大强,高仲龙.带钢连续热镀锌立式炉热过程数学模型[J].工业炉,2006,28(5):27-29. 被引量：1
2王建刚,叶国城,刘华飞,向顺华,胡广魁.连续退火线辐射管炉内传热过程模型[J].宝钢技术,2008,1(4):34-38. 被引量：5
3马太,陈海耿,朱伟素,胡文超,肖楠.带钢镀锌退火炉热过程模拟[J].中国冶金,2008,18(6):7-10. 被引量：2
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5陈银莉,余伟,苏岚,白冰.热轧带钢层流冷却过程中残余应力分析[J].材料热处理学报,2010,31(6):155-160. 被引量：17
6田野,刘训良,温治,余跃.蓄热式辐射管的国内外专利情况及其发展趋势[J].金属热处理,2011,36(3):86-90. 被引量：3
7万飞,王勇勤,金敏.立式连续退火炉快冷段带钢冷却温度分析计算[J].钢铁研究学报,2011,23(4):14-18. 被引量：3
8万飞,王勇勤,金敏.立式连续退火炉预热段带钢加热温度分析计算[J].中国冶金,2011,21(5):40-43. 被引量：4
9徐惊雷,徐忠,肖敏,黄淑娟.冲击射流的研究概述[J].力学与实践,1999,21(6):8-17. 被引量：39
10曹艺,王昭东,吴迪,王国栋.变形及合金元素对NM400连续冷却转变的影响[J].热加工工艺,2011,40(22):1-4. 被引量：3

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2俞峰.C412连续退火炉机组节能研究[J].上海节能,2014(2):35-40.
3谢天华.连续退火炉余热回收技术应用分析[J].工业加热,2011,40(1):72-73. 被引量：1
4谢天华.连续退火炉余热回收技术应用分析[J].冶金环境保护,2011(4):58-59.
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7真空热处理小常识[J].热加工工艺,2009,38(12):39-39.
8孙占波,王宥宏,郭娟.Liquid phase separation of Cu-Cr alloys during rapid cooling[J].中国有色金属学会会刊：英文版,2006,16(5):998-1002. 被引量：5
9潘良明,毛鸣汐.连续退火炉中保护气氛及结构特性对带钢冷却特性的影响[J].钢铁,2009,44(10):46-50. 被引量：3
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2012年第11期

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