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VACUUM ›› 2024, Vol. 61 ›› Issue (6): 61-66.doi: 10.13385/j.cnki.vacuum.2024.06.11

• Vacuum Metallurgy and Thermal Engineering • Previous Articles     Next Articles

Analysis of the Development Trend of Vacuum Cold Crucible Induction Skull Furnace

SONG Jing-si1, ZHANG Qiang2, SUN Mian3, HOU Jing-yue1, ZHANG Zhe-kui1   

  1. 1. Shenyang Vacuum Technology Institute Co., Ltd., Shenyang 110042, China;
    2. AECC Beijing Institute of Aeronautical Materials, Beijing 100095, China;
    3. AECC Shenyang Liming Aero-Engine Co., Ltd., Shenyang 110043, China
  • Received:2024-06-12 Online:2024-11-25 Published:2024-11-29

Abstract: In recent years, the new generation of TiAl alloy turbine blades have been widely used in domestic and foreign aviation engines. With the increasing demand for TiAl blades, the development of the cold crucible induction skull furnace which is the key equipment for TiAl blade production, has also entered a new stage. In this context, the mainstream forms, technical characteristics and current usage status of vacuum cold crucible induction skull melting furnaces are introduced at first. Then, the differences between the vacuum cold crucible induction skull melting and levitation melting are explained, and the application scope of vacuum cold crucible induction skull melting furnace is described. Finally, the development trend and prospects of vacuum cold crucible induction skull melting furnace are analyzed.

Key words: cold crucible, ISM, TiAl, precision casting

CLC Number:  TF341.7

[1] 苑世剑. 轻量化成形技术[M]. 北京:国防工业出版社, 2010.
[2] 马开道,鲁毅,马琨. 稀有金属真空熔铸技术及其设备设计[M]. 北京:冶金工业出版社, 2011.
[3] CONSARC. Two chamber horizontal induction skull melting furnace[EB/OL].[2024-06-09]. https://consarc.com/products/two-chamber-horizontal/.
[4] ALD. LEICOMELT with cold wall induction crucible[EB/OL].[2024-06-09]. https://www.ald-vt.com/cn/portfolio/engineering/vacuum-metallurgy/leicomelt-leybold-induction-cold-melting/.
[5] BOJAREVICS V, PERICLEOUS K, HARDING R A, et al.The development and experimental validation of a numerical model of an induction skull melting furnace[J]. Metallurgical and Materials Transactions B, 2004,35(4): 785-803.
[6] 郭景杰,苏彦庆. 钛合金ISM熔炼过程热力学与动力学分析[M]. 哈尔滨:哈尔滨工业大学出版社, 1998.
[7] 苏彦庆, 郭景杰, 刘贵仲. 有色合金真空熔炼过程熔体质量控制[M]. 哈尔滨:哈尔滨工业大学出版社, 2005.
[8] SCHIPPEREIT G H, LEATHERMAN A F, EVERS D.Cold-crucible induction melting of reactive metals[J]. JOM, 1961,13(2): 140-143.
[9] OKRESS E C, WROUGHTON D M, COMENETZ G, et al.Electromagnetic levitation of solid and molten metals[J]. Journal of Applied Physics, 1952,23(5): 545-552.
[10] SNEYD A D, MOFFATT H K.Fluid dynamical aspects of the levitation-melting process[J]. Journal of Fluid Mechanics, 2006,117: 45-70.
[11] HOLMES L M.Stability of magnetic levitation[J]. Journal of Applied Physics, 1978,49(6): 3102-3109.
[12] 只野英顕, 貝沼研吾. 浮揚溶解装置(CCLM)の進展 (誘導加熱特集)[J]. Fuji Electric Journal, 1998,71(5): 259-263.
[13] 篠倉恒樹, 武達男. 浮揚溶解装置(CCLM)の特長と溶解実績 (誘導加熱特集)[J]. Fuji Electric Journal, 1998,71: 264-267.
[14] 刘如水. 制备难熔的玻璃、陶瓷和晶体材料的新方法——冷坩埚技术简介[J]. 硅酸盐通报, 1982(3): 31-36.
[15] 刘丽君, 张生栋. 放射性废物冷坩埚玻璃固化技术发展分析[J]. 原子能科学技术, 2015,49(4): 589-596.
[16] 杨丽莉, 李晓海, 徐卫. 冷坩埚玻璃固化技术及应用[J]. 辐射防护通讯, 2013,33(3): 37-41.
[17] DEMINE A V, KRYLOVA N V, POLYEKTOV P P, et al.High level liquid waste solidification using a “cold” crucible induction melter[J]. MRS Online Proceedings Library (OPL), 2000,663:27.
[18] HARDING R, WICKINS M, LI Y, et al.Progress towards the production of high quality and TiAl castings[C]//Structural Intermetallics 2001, Warrendale, Pennsylvania, 2001: 181-189.
[19] PERICLEOUS K, BOJAREVICS V, DJAMBAIOV G, et al.Experimental and numerical study of the cold crucible melting process[J]. Applied Mathematical Modelling, 2006,30(11): 1262-1280.
[20] 宋青竹,鄂东梅,王玲玲,等. 真空电弧炉及凝壳炉的控制技术进展[J]. 真空,2022,59(6):1-9.
[21] 杨锐. 钛铝金属间化合物的进展与挑战[J]. 金属学报,2015,51(2):129-147.
[22] 姚文静. 美国RTI为leap发动机供应钛铝合金[J]. 中国钛业, 2014(4): 32.
[23] 中国有色网. 国产钛铝叶片应用于C919大飞机[J]. 特种铸造及有色合金, 2021,41(2): 197.
[24] 贾均. 钛铝合金及其熔炼技术[J]. 特种铸造及有色合金, 1998(4): 8-13.
[25] CHOUDHURY A, BLUM M.Economical production of titanium-aluminide automotive valves using cold wall induction melting and centrifugal casting in a permanent mold[J]. Vacuum, 1996,47(6): 829-831.
[26] 宋静思, 赵帅, 陈久强, 等. 搅动式真空细晶铸造炉及其使用方法: CN109719278A[P].2019-05-17.
[27] 宋静思, 张强, 左野, 等. 新式连续型真空冷坩埚感应凝壳炉[J]. 真空, 2023,60(2): 73-77.
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