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层流冷却过程低碳钢相变模型的适用性分析 被引量:1

Applicability Assessment of Phase Transfromation Models of Low Carbon Steel in Laminar Flow Cooling Process
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摘要 选取了现有典型的C-Mn钢相变过程的物理冶金模型,包括5组孕育期模型、7组相变动力学方程模型、5组相变后铁素体晶粒尺寸模型。利用自行开发的组织性能预报系统软件模拟计算了在3组实际冷却工艺条件下各模型的奥氏体转变过程,并对各模型进行了评价。结果表明,对于所设定的成分和工艺条件,适用性较好的孕育期模型是Kwon所提出的模型;适用性较好的动力学方程模型是Liu、Donnay和Sun所提出的模型;适用性较好的铁素体晶粒尺寸模型是Hodgson所提出的模型。 Available austenite phase transformation models of C-Mn steels were collected and compared to investigate their applicability. Five groups of incubation period models (according to Scheil's additivity rule) were used to calculate ferrite transformation start temperature, seven groups of avrami equations were used to describe phase transformation kinetic process, and five groups of grain size models were used to predict ferrite grain size after transformation completion. By use of a developed integrated process modeling system in which thermal, mechanical and metallurgical processes from reheating furnace to coiling of a steel strip had been numerically and successfully coupled together. Phase transformation process was investigated under three different runout table cooling conditions (cooling rate is 10 ℃/s, 20℃/s and 40 ℃/s respectively) during hot strip rolling at 2050 HSM of Baosteel Co. Ltd. Applicability of phase transformation models were discussed by comparing the calculated data with experimental data. The results show that models proposed by Kwon are suitable for the incubation period, models of Avrami equations proposed by Liu, Donnay and Sun are suitable for the kinetics of phase transformation, and for the ferrite grain size, models proposed by Hodgson is suitable.
作者 程杰锋 唐广波 刘正东
机构地区 钢铁研究总院结构材料研究所
出处 《钢铁研究学报》 CAS CSCD 北大核心 2011年第1期42-46,共5页 Journal of Iron and Steel Research
关键词 孕育期 相变 适用性分析 incubation period phase transformation applicability assessment
分类号 TG142.11 [金属学及工艺—金属材料]
  • 相关文献

参考文献11

  • 1PAN Y T. Measurement and Modeling of Diffusional TransiCormarion of Austenite in C-Mn Steels[D]. Kaohsiung: NSYSU, 2001.
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二级参考文献2

共引文献13

同被引文献12

  • 1刘亦鹏.基于导热反问题的层流冷却过程换热系数计算[D].上海:上海交通大学,2009.
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  • 3Blackwell B. A Technique for Uncertainty Analysis for Inverse Heat Conduction Problems [J]. International Journal of Heat and Mass Transfer, 2010,53(4) : 753.
  • 4Wen P H. Inverse Heat Conduction Problems by Using Parti- cular Solutions [J]. Heat Transfer-Asian Research, 2011,40 (2):171.
  • 5Vakili S. A Modified Sequential Particle Swarm Optimization Algorithm With Future Time Data for Solving Transient In- verse Heat Conduction Problems [J]. International Journal of Corn putation and Methodology, 2011,59 ( 12 ) : 911.
  • 6Ling X W. Efficient a Non-Iterative Finite Element Method for Inverse Heat Conduction Problems [J]. International Journal for Numerical Methods in Engineering, 2003,56 (9) : 1315.
  • 7Nicholson D W. Finite Element Analysis Thermomechanies of Solids IMP. Boca Raton~ The Chemical Rubber Company Press, 2008.
  • 8张有为,李辉,姜培学,KIMINOBU Hojo,MAYUMI Ochi,KOICHI Tanimoto.采用共轭梯度法的管内壁温度导热反问题求解[J].工程热物理学报,2009,30(7):1188-1190. 被引量:14
  • 9方萍,金峰,邢振华,彭昌海,吴智深.基于遗传算法的多孔体一维瞬态导热反问题[J].重庆理工大学学报(自然科学),2010,24(11):34-37. 被引量:2
  • 10朱丽娜,王广军,陈红.采用共轭梯度法求解多变量稳态传热反问题[J].中国电机工程学报,2011,31(8):58-61. 被引量:22

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钢铁研究学报
2011年 第1期

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