特厚钢板射流淬火过程厚向冷速实验研究

doi:10.12068/j.issn.1005-3026.2017.11.007

东北大学学报:自然科学版 ›› 2017, Vol. 38 ›› Issue (11): 1548-1553.DOI: 10.12068/j.issn.1005-3026.2017.11.007

特厚钢板射流淬火过程厚向冷速实验研究

付天亮，韩钧，邓想涛，王昭东

(东北大学轧制技术及连轧自动化国家重点实验室，辽宁沈阳110819)

收稿日期:2016-04-25 修回日期:2016-04-25 出版日期:2017-11-15 发布日期:2017-11-13
通讯作者: 付天亮
作者简介:付天亮(1981-)，男，黑龙江阿城人，东北大学副教授；王昭东(1968-)，男，安徽淮南人，东北大学教授，博士生导师.
基金资助:
国家重点研发计划项目(2016YFB0300601)；东北大学基本科研业务费重大科技创新项目(N160708001).

Experimental Study on Thickness Cooling Rate of Jet Impingement Quenching for Ultra Heavy Plate

FU Tian-liang， HAN Jun， DENG Xiang-tao， WANG Zhao-dong

State Key Laboratory of Rolling and Automation， Northeastern University， Shenyang 110819， China.

Received:2016-04-25 Revised:2016-04-25 Online:2017-11-15 Published:2017-11-13
Contact: FU Tian-liang
About author:-
Supported by:
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摘要/Abstract

摘要： 利用特厚钢板射流淬火试验装置，研究了15~35℃水温、1.0~3.0m/min辊速对特厚钢板厚向冷速的影响，分析钢板在不同温降区间内的厚向温降、温度梯度和冷速影响因素.利用导热微分方程，采用反传热法计算钢板淬火温度场和冷速.结果表明:采用射流冲击淬火方式时，160mm钢板心部冷速大于1.2℃/s;水温和辊速除影响钢板表面平均传热系数和换热形式外，还通过改变厚向温度梯度分布影响厚向冷速;水温或辊速升高，钢板厚向冷速降低，降低幅度与冷却强度、淬火时间以及钢板内部导热特性有关.

关键词: 特厚钢板, 辊式淬火, 厚向冷速, 温度梯度, 射流换热

Abstract: The effects of water temperature(15~35℃) and roll speed(1.0~3.0m/min) on the thickness cooling rate of jet impingement quenching for ultra heavy steel plate are experimentally investigated. The temperature decrease，temperature gradient and the factors of cooling rate along thickness direction in difference sections of the plate are analyzed. Using the inverse heat conduction method to solve the differential equation of heat conduction， the quenching temperature field and cooling rate of the plate can be calculated. The results indicate that the cooling rate of the 160mm steel core is greater than 1.2℃/s under the jet impingement quenching， and water temperature and roll speed affect not only the average heat transfer coefficient and the type of heat transfer near the plate surface， but also the thickness cooling rate by changing temperature gradient distribution. The thickness cooling rate decreases when water temperature and roll speed increase， and the decreasing range of cooling rate depends on cooling intensity， quenching time and thermal conductivity of the plate.

Key words: ultra heavy plate, roller quenching, thickness cooling rate, temperature gradient, jet heat transfer

中图分类号:

TG156.3

付天亮，韩钧，邓想涛，王昭东. 特厚钢板射流淬火过程厚向冷速实验研究[J]. 东北大学学报:自然科学版, 2017, 38(11): 1548-1553.

FU Tian-liang， HAN Jun， DENG Xiang-tao， WANG Zhao-dong. Experimental Study on Thickness Cooling Rate of Jet Impingement Quenching for Ultra Heavy Plate[J]. Journal of Northeastern University Natural Science, 2017, 38(11): 1548-1553.

参考文献

[1]Cao Z Q，Bao Y P，Xia Z H，et al.Toughening mechanisms of a high-strength acicular ferrite steel heavy plate［J］.International Journal of Minerals，Metallurgy and Materials，2010，17(5):567-572.
[2]Han B，Liu X H，Wang G D，et al.Development of cooling process control technique in hot strip mill［J］.Journal of Iron and Steel Research，International，2005，12(1):12-16.
[3]Sun Y K，Wu D.Effect of ultra-fast cooling on micro-structure of large section bars of bearing steel［J］.Iron and Steel Research，International，2009，16(5):61-65.
[4]Zhou J W，Mahulikar S P.Cooling characteristics during bath quenching of test probe using inverse heat transfer［J］.Experimental Heat Transfer，2006，19(4):297-308.
[5]Sagheby S H，Kowsary F.Experimental design and methodology for estimation of local heat transfer coefficient in jet impingement using transient inverse heat conduction problem［J］.Experimental Heat Transfer，2009，22(4):300-315.
[6]Zeitoun O.Heat transfer between a vertical water jet and a horizontal square surface［J］.Experimental Heat Transfer，2012，25(3):206-221.
[7]Visaria M，Mudawar I.A systematic approach to predicting critical heat flux for inclined sprays［J］.Journal of Electronic Packaging:ASME，2007，129(4):452-459.
[8]Islam M，Mallik S H，Kanoria M.Dynamic response in two-dimensional transversely isotropic thick plate with spatially varying heat sources and body force［J］.Applied Mathematics and Mechanics，2011，32(10):1315-1332.
[9]Wang H，Yu W，Cai Q W.Experimental study of heat transfer coefficient on hot steel plate during water jet impingement cooling［J］.Journal of Materials Processing Technology，2012，212(9):1825-1831.
[10]Bhattacharya P，Samanta A N，Chakraborty S.Spray evaporative cooling to achieve ultra fast cooling in runout table［J］.International Journal of Thermal Science，2009，48(9):1741-1747.
[11]Choi Y H，Lee Y W，Choi K，et al.Temperature distribution and thermal stresses in various conditions of moving heating source during line heating process［J］.Journal of Thermal Science，2012，21(1):82-87.

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特厚钢板射流淬火过程厚向冷速实验研究

Experimental Study on Thickness Cooling Rate of Jet Impingement Quenching for Ultra Heavy Plate

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