高强度硼钢空冷热交换系数实验与模拟研究被引量：1

Experiment and Simulation Study on Heat Transfer Coefficient of High-strength Boron Steel Cooling in Air

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摘要通过测量硼钢B1500HS空冷过程中板料中心点的温度变化,结合有限元分析及反传热模型获得了板料空冷换热系数与温度的关系。结果表明：板料温度从930～700℃下降相对较快,平均热交换系数高于200W/（m^＋2℃）;温度在700～400℃,其温度下降趋于平缓,平均热交换系数为114 W/（m^＋2℃）;温度在400～200℃时,其温度下降缓慢,平均热交换系数为83W/（m^＋2℃）,而温度低于200℃,热交换系数小于70W/（m^＋2℃）。 Heat transfer coefficient of boron steel cooling in air is the key factor to obtain the initial temperature of boron steel hot stamping parts. By measuring the temperature changes of blank in the process of cooling in air and combining with finite element analysis and the inverse heat transfer model, the relationship between heat transfer coefficient and temperature was obtained. The results show that the temperature of blank between 930 ℃ to 700 ℃ decreases rapidly and heat transfer coefficient ishigherthan200W/（m^＋2℃）.Blanktemperaturedropgentlybetween700and400℃ andheattransfercoefficientis l14W/ （m^＋2℃）. When the temperature of blank is 400 ℃ to 200 ℃, heat transfer coefficient is 83 W/（m^＋2℃）.When the temperature of the blank drops to below 200 ℃, the heat transfer coefficient is less than 70 W/（m^＋2℃）.

作者张志强李宪爽赵勇李湘吉

机构地区吉林大学材料科学与工程学院吉林大学辊锻工艺研究所

出处《热加工工艺》 CSCD 北大核心 2015年第2期44-46,共3页 Hot Working Technology

基金国家自然科学基金资助项目(51205162) 国家自然科学基金资助项目(51275203)

关键词硼钢热冲压换热系数反传热模型 boron steel hot stamping heat transfer coefficient inverse heat transfer model

分类号 TG156.3 [金属学及工艺—热处理]

作者简介张志强（1977-），男，吉林长春人，副教授，博士，主要研究方向为高强度钢成形工艺：电话：13604424829；E-mail：zhangzq@jlu．edu．cn

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1胡平,贺斌,盈亮.基于有限元的热冲压界面换热系数反算[J].材料热处理学报,2016,37(3):188-195. 被引量：4

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