Capillary puddle vibrations linked to casting-defect formation in planar-flow melt spinning

Capillary puddle vibrations linked to casting-defect formation in planar-flow melt spinning

Planar-flow melt spinning (PFMS) is a single-stage rapid manufacturing/solidification technique for producing thin metal sheets or ribbons. Molten metal is forced through a nozzle onto the substrate where it freezes and is spun as ribbon product. A puddle of molten metal held by surface tension (cap...

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Bibliographic Details
Published in:Metallurgical and materials transactions. B, Process metallurgy and materials processing science Vol. 37; no. 3; pp. 445 - 456
Main Authors: BYRNE, Cormac J, THEISEN, Eric A, REED, Barry L, STEEN, Paul H
Format: Journal Article
Language:English
Published: Heidelberg Springer 01-06-2006
Springer Nature B.V
Subjects:
Aluminum alloys
Applied sciences
Casting
Defects
Exact sciences and technology
Melt spinning
Metals. Metallurgy
Production of metals
Vibration analysis
Melt spinning
Vibration
Foundry
Casting defect
Planar defect
Defect formation
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Summary:Planar-flow melt spinning (PFMS) is a single-stage rapid manufacturing/solidification technique for producing thin metal sheets or ribbons. Molten metal is forced through a nozzle onto the substrate where it freezes and is spun as ribbon product. A puddle of molten metal held by surface tension (capillarity) forms between the nozzle and substrate. An important measure of product quality is the uniformity of thickness along and across the ribbon. At small length scales, local thickness changes or surface defects are present that are undesirable. This work examines the cross wave, a well-defined periodic surface defect, seen when casting aluminum-silicon alloys. The presence of the defect is related to processing conditions and puddle dynamics. Motions of the puddle menisci are captured using high-speed video and analyzed for frequency content. A high frequency vibration of both menisci corresponds to the observed frequency of the surface defect. A scaling analysis reveals these motions to be capillary in nature and comparisons are made with two model problems of vibrating capillary liquids.
Bibliography:ObjectType-Article-2
SourceType-Scholarly Journals-1
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content type line 23
ISSN:1073-5615
1543-1916
DOI:10.1007/s11663-006-0029-4