Additive-incremental forming hybrid manufacturing technique to improve customised part performance

[Display omitted] •Hybrid manufacturing combines various processes to make components, efficiently.•Subtractive, forming and additive processes can be combined to make desired parts.•SLS was used to locally thicken sheets, which were, subsequently, formed by SPIF.•Different combinations of SLS and S...

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Bibliographic Details
Published in:Journal of manufacturing processes 2019-01, Vol.37, p.386-391
Main Authors: Ambrogio, Giuseppina, Gagliardi, Francesco, Muzzupappa, Maurizio, Filice, Luigino
Format: Article
Language:English
Subjects:
Additive manufacturing
Hybrid manufacturing
SPIF
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Summary:[Display omitted] •Hybrid manufacturing combines various processes to make components, efficiently.•Subtractive, forming and additive processes can be combined to make desired parts.•SLS was used to locally thicken sheets, which were, subsequently, formed by SPIF.•Different combinations of SLS and SPIF were analyzed working stainless steel sheets.•Dimensional accuracy, part quality and complexity were the monitored outputs. Hybrid manufacturing is a new production strategy based on the combination of various processes to manufacture components more efficiently in terms of quality, productivity, and/or sustainability. Combinations of subtractive, forming, and additive manufacturing processes can follow one another to produce the desired parts. Hence, both part complexity and performance can increase significantly. The highlighted strategy has been tested by considering two different processes that are typically utilised for small batches of customised parts. Specifically, selective laser sintering has been used to thicken sheets locally, which are subsequently formed by single point incremental forming. This process combination can result in the development of a rapid prototyping technique that exploits the peculiarities of both the utilised processes, and thus allows for the manufacturing of more complex and/or higher quality parts, in a more flexible manner. In the research herein reported, various solutions have been tested to analyse the impact of the proposed hybrid manufacturing strategy on the a) dimensional accuracy, in terms of deviation from the nominal shape, b) quality, in terms of thickness distribution, and c) part complexity, in terms of the obtainable three-dimensional shape, of stainless-steel-formed sheets.
ISSN:1526-6125
2212-4616
DOI:10.1016/j.jmapro.2018.12.008