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Modellierung, integrative Simulation und Optimierung

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Technologiefusion für multifunktionale Leichtbaustrukturen

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Zusammenfassung

Gemäß der Leitidee einer Bivalenten Ressourceneffizienz (BRE) verfolgt der MERGECluster die Erschließung besonders hoher Einspar- und Innovationspotenziale. Bei effizienter Nutzung der zur Verfügung stehenden Ressourcen während des Fertigungsprozesses werden demnach Hybridprozesse und -bauteile erforscht, die sich bei mobilen Anwendungen auch während der Nutzungsphase durch hohe Energieeffizienz auszeichnen. Vor diesem Hintergrund widmet sich dieses Kapitel der konkreten Umsetzung dieser Zielstellung, indem es eine bivalente Optimierung des Herstellungsprozesses beim Spritzgießen und der resultierenden mechanischen Eigenschaften der gefertigten Bauteile anstrebt. Dabei interessieren die Wahl der Prozessparameter wie beispielsweise Einspritzpunkt, Einspritzdruck und Einspritzdauer, sodass in möglichst kurzer Zeit unter wenig Energieaufwand Bauteile mit hoher Festigkeit und geringem Gewicht gefertigt werden können. Als Demonstratoren dieser Optimierungskette dienen der sog. Chemnitzer Haken, eine Platte mit Einleger sowie ein Kettenglied.

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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). Modellierung, integrative Simulation und Optimierung. In: Kroll, L. (eds) Technologiefusion für multifunktionale Leichtbaustrukturen. Springer Vieweg, Berlin, Heidelberg. https://doi.org/10.1007/978-3-662-54734-2_8

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