Induction melting in a cold crucible furnace applied to innovative high-melting temperature metals

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

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  • K.N. Toosi University of Technology
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OriginalspracheEnglisch
Seiten (von - bis)523-532
Seitenumfang10
FachzeitschriftMagnetohydrodynamics
Jahrgang58
Ausgabenummer4
PublikationsstatusVeröffentlicht - 2022

Abstract

The necessity to process chemically reactive metals makes the cold wall crucible an attractive alternative to conventional furnaces, even for materials with a melting point of 2500 C and higher. A significant research work in this field is though missing. In this paper, steps conducing to melting high-melting temperature metals (niobium, in this case) by electromagnetic induction are described. Multiphysical numerical simulations were successfully validated for aluminium and titanium-aluminium alloy. In the case of niobium, authors evidence some differences between numerical and experimental results, and limits of the induction melting setup are examined for future improvements.

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Induction melting in a cold crucible furnace applied to innovative high-melting temperature metals. / Guglielmi, M.; Baake, E.; Köppen, A. et al.
in: Magnetohydrodynamics, Jahrgang 58, Nr. 4, 2022, S. 523-532.

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Guglielmi M, Baake E, Köppen A, Holzmann E, Herbst S, Moradi Maryamnegari S. Induction melting in a cold crucible furnace applied to innovative high-melting temperature metals. Magnetohydrodynamics. 2022;58(4):523-532. doi: 10.22364/mhd.58.4.17
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AU - Guglielmi, M.

AU - Baake, E.

AU - Köppen, A.

AU - Holzmann, E.

AU - Herbst, S.

AU - Moradi Maryamnegari, S.

PY - 2022

Y1 - 2022

N2 - The necessity to process chemically reactive metals makes the cold wall crucible an attractive alternative to conventional furnaces, even for materials with a melting point of 2500◦ C and higher. A significant research work in this field is though missing. In this paper, steps conducing to melting high-melting temperature metals (niobium, in this case) by electromagnetic induction are described. Multiphysical numerical simulations were successfully validated for aluminium and titanium-aluminium alloy. In the case of niobium, authors evidence some differences between numerical and experimental results, and limits of the induction melting setup are examined for future improvements.

AB - The necessity to process chemically reactive metals makes the cold wall crucible an attractive alternative to conventional furnaces, even for materials with a melting point of 2500◦ C and higher. A significant research work in this field is though missing. In this paper, steps conducing to melting high-melting temperature metals (niobium, in this case) by electromagnetic induction are described. Multiphysical numerical simulations were successfully validated for aluminium and titanium-aluminium alloy. In the case of niobium, authors evidence some differences between numerical and experimental results, and limits of the induction melting setup are examined for future improvements.

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VL - 58

SP - 523

EP - 532

JO - Magnetohydrodynamics

JF - Magnetohydrodynamics

SN - 0024-998X

IS - 4

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