Production of net-shape Mn-Al permanent magnets by electron beam melting

I. A. Radulov; V. V. Popov; A. Koptyug; F. Maccari; A. Kovalevsky; S. Essel; J. Gassmann; K. P. Skokov; M. Bamberger

doi:10.1016/j.addma.2019.100787

Production of net-shape Mn-Al permanent magnets by electron beam melting

I. A. Radulov
, V. V. Popov
, A. Koptyug
, F. Maccari
, A. Kovalevsky
, S. Essel
, J. Gassmann
, K. P. Skokov
, M. Bamberger

Research output: Contribution to journal › Article › peer-review

35 Scopus citations

Abstract

The main goal of this work is the adoption of additive manufacturing for the production of inexpensive rare-earth free MnAl-based permanent magnets. The use of more advanced binder-free additive manufacturing technique such as Electron Beam Melting (EBM) allows obtaining fully-dense magnetic materials with advanced topology and complex shapes. We focus on the feasibility of controlling the phase formation in additively manufactured Mn-Al alloys by employing post-manufacturing heat treatment. The as-manufactured EBM samples contain 8% of the desired ferromagnetic τ-MnAl phase. After the optimized annealing treatment, the content of the τ-phase was increased to 90%. This sample has a coercivity value of 0.15 T, which is also the maximum achieved in conventionally produced binary MnAl magnets. Moreover, the EBM samples are fully dense and have the same density as the samples produced by conventional melting density.

Original language	English
Article number	100787
Journal	Additive Manufacturing
Volume	30
DOIs	https://doi.org/10.1016/j.addma.2019.100787
State	Published - Dec 2019
Externally published	Yes

Keywords

Additive manufacturing
Electron beam melting
Mn-Al alloys
Permanent magnets
Printed magnets

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10.1016/j.addma.2019.100787

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title = "Production of net-shape Mn-Al permanent magnets by electron beam melting",

abstract = "The main goal of this work is the adoption of additive manufacturing for the production of inexpensive rare-earth free MnAl-based permanent magnets. The use of more advanced binder-free additive manufacturing technique such as Electron Beam Melting (EBM) allows obtaining fully-dense magnetic materials with advanced topology and complex shapes. We focus on the feasibility of controlling the phase formation in additively manufactured Mn-Al alloys by employing post-manufacturing heat treatment. The as-manufactured EBM samples contain 8\% of the desired ferromagnetic τ-MnAl phase. After the optimized annealing treatment, the content of the τ-phase was increased to 90\%. This sample has a coercivity value of 0.15 T, which is also the maximum achieved in conventionally produced binary MnAl magnets. Moreover, the EBM samples are fully dense and have the same density as the samples produced by conventional melting density.",

keywords = "Additive manufacturing, Electron beam melting, Mn-Al alloys, Permanent magnets, Printed magnets",

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year = "2019",

month = dec,

doi = "10.1016/j.addma.2019.100787",

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volume = "30",

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AU - Radulov, I. A.

AU - Popov, V. V.

AU - Koptyug, A.

AU - Maccari, F.

AU - Kovalevsky, A.

AU - Essel, S.

AU - Gassmann, J.

AU - Skokov, K. P.

AU - Bamberger, M.

PY - 2019/12

Y1 - 2019/12

N2 - The main goal of this work is the adoption of additive manufacturing for the production of inexpensive rare-earth free MnAl-based permanent magnets. The use of more advanced binder-free additive manufacturing technique such as Electron Beam Melting (EBM) allows obtaining fully-dense magnetic materials with advanced topology and complex shapes. We focus on the feasibility of controlling the phase formation in additively manufactured Mn-Al alloys by employing post-manufacturing heat treatment. The as-manufactured EBM samples contain 8% of the desired ferromagnetic τ-MnAl phase. After the optimized annealing treatment, the content of the τ-phase was increased to 90%. This sample has a coercivity value of 0.15 T, which is also the maximum achieved in conventionally produced binary MnAl magnets. Moreover, the EBM samples are fully dense and have the same density as the samples produced by conventional melting density.

AB - The main goal of this work is the adoption of additive manufacturing for the production of inexpensive rare-earth free MnAl-based permanent magnets. The use of more advanced binder-free additive manufacturing technique such as Electron Beam Melting (EBM) allows obtaining fully-dense magnetic materials with advanced topology and complex shapes. We focus on the feasibility of controlling the phase formation in additively manufactured Mn-Al alloys by employing post-manufacturing heat treatment. The as-manufactured EBM samples contain 8% of the desired ferromagnetic τ-MnAl phase. After the optimized annealing treatment, the content of the τ-phase was increased to 90%. This sample has a coercivity value of 0.15 T, which is also the maximum achieved in conventionally produced binary MnAl magnets. Moreover, the EBM samples are fully dense and have the same density as the samples produced by conventional melting density.

KW - Additive manufacturing

KW - Electron beam melting

KW - Mn-Al alloys

KW - Permanent magnets

KW - Printed magnets

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VL - 30

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JF - Additive Manufacturing

M1 - 100787

ER -

Production of net-shape Mn-Al permanent magnets by electron beam melting

Abstract

Keywords

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