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Mikro- und Nanosystemintegration in Leichtbaustrukturen

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Technologiefusion für multifunktionale Leichtbaustrukturen

Zusammenfassung

Die Funktionalisierung von Hybridstrukturen in Leichtbauanwendungen erlaubt nicht nur, die Masse noch weiter zu reduzieren, sondern auch neue Wege in der konstruktiven und technologischen Ausführung von intelligenten Leichtbauanwendungen zu beschreiten. Durch die Integration von Sensoren, Aktoren und Mikroelektronik lässt sich so die Funktionsdichte hybrider Leichtbaustrukturen deutlich erhöhen, was auch eine substanzielle Leistungssteigerung zur Folge hat. Diese Funktionsvielfalt erfordert die Entwicklung robuster Verfahren zur textilen und kunststofftechnischen Einbettung aktiver sowie passiver Elektronikkomponenten. Dabei wird das Ziel verfolgt, die wesentlichen aktorischen und sensorischen Effekte bei der Bauteilherstellung zu realisieren und gleichzeitig in einem massenproduktionstauglichen Prozess darzustellen. Dafür wird eine Kombination aus Insitu- und In-line-Verfahren genutzt, die beispielsweise das Spritzgießverfahren mit funktionalisierten Kunststoffschichten für elektrische Kontaktierung und das Massendruckverfahrenvereinigt.

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  1. Technische Universität Chemnitz Bundesexzellenzcluster MERGE, Chemnitz, Deutschland

    Lothar Kroll

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    Lothar Kroll

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Kroll, L. (2019). Mikro- und Nanosystemintegration in Leichtbaustrukturen. In: Kroll, L. (eds) Technologiefusion für multifunktionale Leichtbaustrukturen. Springer Vieweg, Berlin, Heidelberg. https://doi.org/10.1007/978-3-662-54734-2_6

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