Solid particle erosion and scratch behavior of novel scrap carbon fiber/glass fabric/polyamide 6.6 hybrid composites

This study investigated the tribological performance of hybrid composites composed of scrap carbon fiber (CF), glass fabric (GF), and polyamide 6.6 (PA6.6) through an innovative approach for reusing scrap CFs in high‐value composite structures. The experimental setup included CF/GF/PA6.6 hybrid comp...

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Veröffentlicht in:Polymer composites 2023-10, Vol.44 (10), p.7197-7211
Hauptverfasser: Kocoglu, Hurol, Korkusuz, Orkan Baran, Ozzaim, Pelin, Kodal, Mehmet, Altan, M. Cengiz, Sinmazcelik, Tamer, Ozcelik, Babur, Ozkoc, Guralp
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container_end_page 7211
container_issue 10
container_start_page 7197
container_title Polymer composites
container_volume 44
creator Kocoglu, Hurol
Korkusuz, Orkan Baran
Ozzaim, Pelin
Kodal, Mehmet
Altan, M. Cengiz
Sinmazcelik, Tamer
Ozcelik, Babur
Ozkoc, Guralp
description This study investigated the tribological performance of hybrid composites composed of scrap carbon fiber (CF), glass fabric (GF), and polyamide 6.6 (PA6.6) through an innovative approach for reusing scrap CFs in high‐value composite structures. The experimental setup included CF/GF/PA6.6 hybrid composite laminates with varying CF contents and surface‐modified GFs, as well as PA6.6 sheets and GF/PA6.6 composite laminates. Solid particle erosion and scratch tests were conducted to assess the influence of scrap CF hybridization and GF surface modification on the tribological properties of the composites. The results demonstrated that neat PA6.6 sheets exhibited the lowest erosion rate, while the incorporation of CF and GF reinforcements had a detrimental effect on erosion resistance. The highest erosion rate was observed within the impact angle range of 15°–30° for pure PA6.6 sheets, whereas for composite laminates, it occurred within the range of 30°–45°. In contrast, CFs positively affected scratch hardness despite their negative impact on erosion resistance. Additionally, the silane treatment of GFs, which enhanced interfacial strength, improved the erosion resistance and scratch hardness of GF/PA6.6 composite laminates without CF. Profilometer‐based topographic analysis revealed a correlation between the average surface roughness of the eroded surfaces and the weight loss resulting from solid particle erosion.
doi_str_mv 10.1002/pc.27627
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subjects Carbon fiber reinforced plastics
Carbon fibers
Composite structures
Erosion rates
Erosion resistance
Glass fiber reinforced plastics
Hybrid composites
Interfacial strength
Laminates
Mechanical properties
Polyamide resins
Scrap
Scratch hardness
Scratch resistance
Scratch tests
Surface roughness
Tribology
Weight loss
title Solid particle erosion and scratch behavior of novel scrap carbon fiber/glass fabric/polyamide 6.6 hybrid composites
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