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Magnesium recycling: State-of-the-Art developments, part II

Publikation: Beiträge in ZeitschriftenKonferenzaufsätze in FachzeitschriftenForschungbegutachtet

Standard

Magnesium recycling: State-of-the-Art developments, part II. / Fechner, D.; Hort, N.; Blawert, C. et al.

in: Light Metal Age, Jahrgang 67, Nr. 5, 09.2009, S. 34-36.

Publikation: Beiträge in ZeitschriftenKonferenzaufsätze in FachzeitschriftenForschungbegutachtet

Harvard

Fechner, D, Hort, N, Blawert, C, Dietzel, W & Kainer, KU 2009, 'Magnesium recycling: State-of-the-Art developments, part II', Light Metal Age, Jg. 67, Nr. 5, S. 34-36.

APA

Fechner, D., Hort, N., Blawert, C., Dietzel, W., & Kainer, K. U. (2009). Magnesium recycling: State-of-the-Art developments, part II. Light Metal Age, 67(5), 34-36.

Vancouver

Fechner D, Hort N, Blawert C, Dietzel W, Kainer KU. Magnesium recycling: State-of-the-Art developments, part II. Light Metal Age. 2009 Sep;67(5):34-36.

Bibtex

@article{d0b5efd07d7d4da799a628c6dede8a53,
title = "Magnesium recycling: State-of-the-Art developments, part II",
abstract = "Two methods of industrial recycling of magnesium scrap using flux and without flux are described. Refining fluxes work by picking up oxides from the melt in the recycling process. The quantity of salt is determined by the content of oxides in the material because MgO has a thickening effect on the flux. Recycling of class 1 scrap requires little to no salt, whereas material with a higher oxide content needs more salt. Molten refining fluxes adhere to oxide layers but not to the magnesium melt. Flux-free recycling process is used for scrap with low contents of oxides, like class 1 scrap. It will never replace the flux-based process. Fluxless recycling of magnesium and magnesium alloys is widely applied as an in-house process by many die casters. The formation of dross takes place mainly in the melting furnace. Oxides and intermetallic particles are removed periodically from the melt surface and from the bottom of the melting crucible.",
keywords = "Engineering",
author = "D. Fechner and N. Hort and C. Blawert and W. Dietzel and K.U. Kainer",
note = "cited By 1",
year = "2009",
month = sep,
language = "English",
volume = "67",
pages = "34--36",
journal = "Light Metal Age",
issn = "0024-3345",
publisher = "Fellom Publishing Co.",
number = "5",

}

RIS

TY - JOUR

T1 - Magnesium recycling: State-of-the-Art developments, part II

AU - Fechner, D.

AU - Hort, N.

AU - Blawert, C.

AU - Dietzel, W.

AU - Kainer, K.U.

N1 - cited By 1

PY - 2009/9

Y1 - 2009/9

N2 - Two methods of industrial recycling of magnesium scrap using flux and without flux are described. Refining fluxes work by picking up oxides from the melt in the recycling process. The quantity of salt is determined by the content of oxides in the material because MgO has a thickening effect on the flux. Recycling of class 1 scrap requires little to no salt, whereas material with a higher oxide content needs more salt. Molten refining fluxes adhere to oxide layers but not to the magnesium melt. Flux-free recycling process is used for scrap with low contents of oxides, like class 1 scrap. It will never replace the flux-based process. Fluxless recycling of magnesium and magnesium alloys is widely applied as an in-house process by many die casters. The formation of dross takes place mainly in the melting furnace. Oxides and intermetallic particles are removed periodically from the melt surface and from the bottom of the melting crucible.

AB - Two methods of industrial recycling of magnesium scrap using flux and without flux are described. Refining fluxes work by picking up oxides from the melt in the recycling process. The quantity of salt is determined by the content of oxides in the material because MgO has a thickening effect on the flux. Recycling of class 1 scrap requires little to no salt, whereas material with a higher oxide content needs more salt. Molten refining fluxes adhere to oxide layers but not to the magnesium melt. Flux-free recycling process is used for scrap with low contents of oxides, like class 1 scrap. It will never replace the flux-based process. Fluxless recycling of magnesium and magnesium alloys is widely applied as an in-house process by many die casters. The formation of dross takes place mainly in the melting furnace. Oxides and intermetallic particles are removed periodically from the melt surface and from the bottom of the melting crucible.

KW - Engineering

UR - https://www.scopus.com/record/display.uri?eid=2-s2.0-71849087041&origin=inward&txGid=c24c847318a1953e2f8d6713f539d4ee

M3 - Conference article in journal

VL - 67

SP - 34

EP - 36

JO - Light Metal Age

JF - Light Metal Age

SN - 0024-3345

IS - 5

ER -

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