锻压技术

步进梁式铝合金轮毂棒坯锻前加热炉的研制

英文标题：Development of stepping beam heating furnace for pre-forging heating of

作者：张文良罗平李爱国苏航周彤孙萌李贤君

分类号：TH181

出版年,卷(期):页码：2018,43(11):94-98

摘要：

研制了一款用于制造大型客车、货车铝合金轮毂棒坯的锻前加热步进梁式加热炉。介绍了步进梁式加热炉的组成及为解决关键性问题所采用的手段。采用流体计算动力学（CFD）软件优化了炉内导风机构，提高了炉温均匀性；将动静梁设计成相同齿面结构且动梁前进距离小于1个齿距，并且使工件在炉内前进的同时自旋转一定角度，以提高工件的加热均匀性。实践证明：该加热炉具有加热速度快、产量大、加热时径向芯表温度均匀、节能降耗、自动化程度高、运行稳定可靠等优点。经该加热炉加热的铝轮毂棒坯温度与金相组织完全满足后序锻造工艺的要求，为下一步铝轮毂成形打下了良好的温度基础。

A stepping beam heating furnace for pre-forging heating of aluminum alloy wheel hub billets used for large buses and trucks was developed, and its components and the methods solving the key problems were introduced. Then, the in-furnace air guiding mechanism was optimized by fluid calculation kinetics software CFD to enhance furnace temperature uniformity, and the dynamic and static beams were designed to have the same tooth surface structure as well as the moving beam travel distance was less than 1 pitch. Furthermore, the workpiece was heated in the furnace while rotating at a certain angle to improve the heating uniformity of workpiece. The production practice proves that the heating furnace has the advantages of high heating speed, large output, uniform radial core temperature during heating, energy saving, high automation, stable and reliable operation. Thus, the temperature and metallographic structure of aluminum alloy wheel hub billet treated by the furnace can meet the following forging process requirements and provide a good temperature foundation for the next forming process of aluminum alloy wheel hub.

基金项目：

“高档数控机床与基础制造装备”科技重大专项（2018ZX04010010）

张文良（1979-），男，学士，研究员级高级工程师,E-mail：zhangwlwork@163.com;通讯作者：李贤君（1977-），男，博士，研究员级高级工程师,E-mail：imlxj@163.com

参考文献：

[1]王丹晨, 张承基, 边翊, 等. 锻造方法对铝合金车轮轮辐组织的影响 [J]. 锻压技术, 2018, 43(5): 1-5.

Wang D C, Zhang C J, Bian Y, et al. Influence of forging method on microstructure of spoke for aluminum alloy wheel[J]. Forging & Stamping Technology, 2018, 43(5): 1-5.

[2]郑晖, 赵曦雅. 汽车轻量化及铝合金在现代汽车生产中的应用[J]. 锻压技术, 2016, 41(2): 1-5.

Zheng H, Zhao X Y. Lightweight automobile and application of aluminum alloys in modern automobile production[J]. Forging & Stamping Technology, 2016, 41(2): 1-5.

[3]应善强, 张捷, 王景晟, 等. 汽车轻量化技术途径研究[J]. 汽车工艺与材料, 2010, (2): 1-4.

Ying S Q, Zhang J, Wang J S, et al. Study on automotive lightweight technology roadmap [J]. Automobile Technology & Material, 2010, (2): 1-4.

[4]李晓敏. 我国汽车铝合金轮毂发展现状及建议[J]. 轻金属, 2011, (6): 3-4,7.

Li X M. The status of automabile alumunium alloy wheel hub in China and its suggestions[J]. Light Metals, 2011, (6): 3-4,7.

[5]王秉铨. 工业炉设计手册[M]. 3版. 北京: 机械工业出版社, 2010.

Wang B S. Design Handbook of Indestrial Furnace[M]. The Third Edition. Beijing: China Machine Press, 2010.

[6]唐龙伟. 热轧不锈钢步进梁式加热炉的设计要点研究[J]. 工业加热, 2015, 44(1): 66-68.

Tang L W. Research on the design main points of the walking-beam reheating furnace for heating steel slab[J]. Industrial Heating, 2015, 44(1): 66-68.

[7]谢善清. 现代步进式加热炉的构造及设备[J]. 冶金设备, 1992, (6): 53-58.

Xie S Q. Structure and equipment of contemporary walking beam heating furnace[J]. Metallurgical Equipment, 1992, (6): 53-58.

[8]GB/T 9452—2012，热处理炉有效加热区测定方法[S].

GB/T 9452—2012, Testing method for working zone of heat treatment furnace[S].

[9]GB/T 30825—2014，热处理温度测量[S].

GB/T 30825—2014, Pyrometry for heat treatment[S].

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