Microscale metal additive manufacturing of multicomponent medical devices

Purpose The purpose of this paper is to familiarize the reader with the capabilities of EFAB technology, a unique additive manufacturing process which yields fully assembled, functional mechanisms from metal on the micro to millimeter scale, and applications in medical devices. Designmethodologyappr...

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Veröffentlicht in:	Rapid prototyping journal 2010-04, Vol.16 (3), p.209-215
Hauptverfasser:	Cohen, Adam, Chen, Richard, Frodis, Uri, Wu, MingTing, Folk, Chris
Format:	Artikel
Sprache:	eng
Schlagworte:	Manufacturing systems Medical equipment MEMS Metals
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container_title	Rapid prototyping journal
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creator	Cohen, Adam Chen, Richard Frodis, Uri Wu, MingTing Folk, Chris
description	Purpose The purpose of this paper is to familiarize the reader with the capabilities of EFAB technology, a unique additive manufacturing process which yields fully assembled, functional mechanisms from metal on the micro to millimeter scale, and applications in medical devices. Designmethodologyapproach The process is based on multilayer electrodeposition and planarization of at least two metals one structural and one sacrificial. After a period of initial commercial development, it was scaled up from a prototypingonly to a production process, and biocompatible metals were developed for medical applications. Findings The process yields complex, functional metal microcomponents and mechanisms with tight tolerances from biocompatible metals, in lowhigh production volume. Practical implications The process described has multiple commercial applications, including minimally invasive medical instruments and implants, probes for semiconductor testing, military fuzing and inertial sensing devices, millimeter wave components, and microfluidic devices. Originalityvalue The process described in this paper is unusual among additive fabrication processes in being able to manufacture in high volume, and in its ability to produce devices with microscale features. It is one of only a few additive manufacturing processes that can produce metal parts or multicomponent mechanisms.
doi_str_mv	10.1108/13552541011034889
format	Article
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Designmethodologyapproach The process is based on multilayer electrodeposition and planarization of at least two metals one structural and one sacrificial. After a period of initial commercial development, it was scaled up from a prototypingonly to a production process, and biocompatible metals were developed for medical applications. Findings The process yields complex, functional metal microcomponents and mechanisms with tight tolerances from biocompatible metals, in lowhigh production volume. Practical implications The process described has multiple commercial applications, including minimally invasive medical instruments and implants, probes for semiconductor testing, military fuzing and inertial sensing devices, millimeter wave components, and microfluidic devices. Originalityvalue The process described in this paper is unusual among additive fabrication processes in being able to manufacture in high volume, and in its ability to produce devices with microscale features. 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subjects	Manufacturing systems Medical equipment MEMS Metals
title	Microscale metal additive manufacturing of multicomponent medical devices
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