Analysis of Low-Velocity Impact Resistance of Carbon Fiber Reinforced Polymer Composites Based on the Content of Incorporated Graphite Fluoride

• Published in: Materials Vol. 13; no. 1; p. 187
• Main Authors: Leng, Jing, Guo, Tianzi, Yang, Meng, Guo, Zeshi, Fang, Zhengqin, Liu, Zhipeng, Li, Dandan, Sun, Dazhi
• Format: Journal Article
• Language: English
• Published: Switzerland MDPI AG 02.01.2020; MDPI
• Subjects: Aviation; Carbon fiber reinforced plastics; Carbon fiber reinforcement; cfrp composites; Composite materials; Compressive strength; Crack propagation; Damage; Deflection; Delamination; Drop tests; Energy; Epoxy resins; Fiber composites; Fiber reinforced polymers; Fluorides; Fracture surfaces; Fracture toughness; Graphite; graphite fluoride; Impact analysis; Impact resistance; Impact tests; Laminates; Load; Polymer matrix composites; Polymers; Propagation; Velocity; China; impact resistance; graphite fluoride; CFRP composites
• ISSN: 1996-1944; 1996-1944
• DOI: 10.3390/ma13010187

As a graphite derivative, graphite fluoride (GrF) has a remarkable fracture toughness improvement effect on epoxy materials. The fracture toughness variation of the epoxy could exert an influence on the low velocity impact resistance of the corresponding carbon fiber reinforced polymer (CFRP) composite. Therefore, the dependence of the low velocity impact resistance of the incorporated CFRP on the GrF content is worth analyzing. Here, different contents of GrF were applied to incorporate CFRP laminates and planned to find the optimal GrF content, in turn leading to the best impact resistance. Using a drop-weight impact test, the load vs. time curves and load vs. displacement curves were obtained. The incipient damage loads and maximum loads of various GrF contents of the samples were compared carefully. The absorbed energies during the impact process were calculated. The trend of absorbed energy decreased up to the 1 wt% sample, then increased significantly with the rise of GrF content. This deflection behavior can be explained by the combination of crack pinning, crack deflection and crack propagation, due to the rise in GrF content. Through the ultrasonic C-scan evaluation, the delamination areas of different GrF content of samples were measured. The trend of delamination area variation was accordant with the trend of absorbed energy variation. This presents a demonstration of the correlation between the absorbed energy and the damage level. The SEM images of the fracture surfaces were analyzed for the deflection behavior of the fracture toughness with various GrF contents. The plot of residual compression strength versus GrF content further indicated the 1 wt% was the optimal content at which the incorporated GrF endowed the most impact-resistant property to the CFRP laminates.