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DIGITAL LIBRARY: SAMPE 2023 | SEATTLE, WA | APRIL 17-20

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CHALLENGES IN AM THERMOSET CONTINUOUSLY-REINFORCED COMPOSITES

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Title: CHALLENGES IN AM THERMOSET CONTINUOUSLY-REINFORCED COMPOSITES

Authors: Jevan Furmanski, Andrew Abbott, G. P. Tandon, Mark Flores, Philip Barnett, Marco Salviato, Jeffery Baur, Dennis Butcher

DOI: 10.33599/nasampe/s.23.0141

Abstract: Continuously-reinforced composite additive manufacturing (CC-AM) is set to revolutionize the manufacturing and design of complex high-strength, low-weight structures. Longitudinal tensile strengths of CC-AM have been reported exceeding 1500 MPa with minimal porosity, making this system available for structural applications. However, there remain a number of morphological non-idealities that are unique to the CC-AM process that challenge the performance of a complex AM build. These can be categorized into material non-idealities (fiber clustering, resin-rich zones, matrix quality) and topological constraint non-idealities (joint design constraints, minimum path radius, tow cuts). Furthermore, for UV snap-cured carbon fiber CC-AM, limited penetration of the incident UV through the carbon fiber tow presents a challenge to optimal in-situ curing. The present work lays out these challenges, with specific case examples for material built with the CF3D system (Continuous Composites Inc.) using T-1100 12K carbon fiber tows and a UV snap curing acrylate resin. Most of the issues highlighted are inherent to CC-AM, so the recommendations for future development to mitigate the various non-idealities are expected to translate to other CC-AM technologies, such as those using a thermoplastic polymer.

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Conference: SAMPE 2023

Publication Date: 2023/04/17

SKU: TP23-0000000141

Pages: 12

Price: $24.00

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