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| Hydrogen diffusion in slab for stacking slowcooling |
| WANG Weihua1,2,LI Zhanjun1,2,CHU Rensheng1,2,CHEN Xia1,2 |
(1. Research Institute of Technology, Shougang Group Co., Ltd., Beijing 100043,China;
2. Beijing Key Laboratory of Green Recyclable Process for Iron and Steel Production Technology, Beijing 100043, China)
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Abstract In order to investigate the removal effect of hydrogen element in the slab slow cooling process of a medium plate plant, and finally to prevent the occurrence of white spots and improve the qualified rate of flaw detection, eight slabs with 250 mm×1 600 mm cross section were selected as the research objects according to the Fick′s second law unsteady mass transfer equation, and a twodimensional hydrogen diffusion model for the stacking slowcooling process of medium and heavy slabs was established using the software ABAQUS. The calculation results show that the stacking slowcooling of continuous casting slab is a powerful dehydrogenation measure by utilizing the dehydrogenation peak effect during phase transformation. After 24 to 48 h of the stacking cooling, the dehydrogenation rate of offline continuous casting slab can reach over 84.6% when the stacking slowcooling conditions are reasonable. If the average w (H)= 0.000 1% is taken as the criterion to prevent the occurrence of "white spots", the hydrogen content in the slab can be considered to be in the safe range after 24 h of stacking cooling. If the maximum w (H)= 0.000 1% is taken as the criterion to prevent the occurrence of "white spots", the w (H) in the slab is considered to be in the safe range after 36 h of stacking.
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Received: 11 January 2019
Published: 15 November 2019
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| [6] |
蒋文春,巩建鸣,唐建群,等.焊接残余应力下氢扩散的数值模拟[J].焊接学报, 2006, 27(11):57-60
|
| [7] |
吴晓金,王家序,金山宽,等.裂纹尖端弹塑性与氢扩散耦合分析[J].农业机械学报, 2010, 41(6):193-198
|
| [1] |
杨东,许少普等.钢板中氢扩散的数值模拟[J].钢铁研究, 2016, 44(1):19-23
|
| [2] |
王俊凯.钢中氢含量影响因素分析[J].第15届全国炼钢学术会议文集, 2008, :573-580
|
| [8] |
蒋锡军.连铸大方坯气瓶钢白点缺陷的防止[J].宝钢技术, 2013, (6):12-15
|
| [9] |
刘宗昌,杨慧,李文学,等.去氢退火工艺的设计及应用[J].金属热处理, 2003, 28(3):51-53
|
| [10] |
陶平,王艳飞,巩建鸣.氢在双相不锈钢中的扩散模拟[J].上海交通大学学报, 2018, 52(9):1086-1091
|
| [3] |
H.Lachmund,VSchwinn and H. A. Jungblut.Heavy plate production: demand on hydrogen control[J].Ironmaking and Steelmaking, 2000, 27(5):381-386
|
| [4] |
蒋文春,巩建鸣,唐建群,等.湿环境下钢氢鼓泡的有限元模拟[J].吉林大学学报工学版, 2008, 38(1):61-65
|
| [5] |
温吉利,严祯荣.裂纹尖端氢扩散的有限元分析[J].化工装备技术, 2009, 30(2):65-68
|
| [6] |
蒋文春,巩建鸣,唐建群,等.焊接残余应力下氢扩散的数值模拟[J].焊接学报, 2006, 27(11):57-60
|
| [7] |
吴晓金,王家序,金山宽,等.裂纹尖端弹塑性与氢扩散耦合分析[J].农业机械学报, 2010, 41(6):193-198
|
| [8] |
蒋锡军.连铸大方坯气瓶钢白点缺陷的防止[J].宝钢技术, 2013, (6):12-15
|
| [9] |
刘宗昌,杨慧,李文学,等.去氢退火工艺的设计及应用[J].金属热处理, 2003, 28(3):51-53
|
| [10] |
陶平,王艳飞,巩建鸣.氢在双相不锈钢中的扩散模拟[J].上海交通大学学报, 2018, 52(9):1086-1091
|
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2019, Vol. 54 
