Synergistic effects of hyperbranched flow modifiers and toughening agents on the processability and interfacial properties of pultruded glass fiber/PA6 composites
Chenchao Fu, Xianfeng Liang, Deshen Liu, Run Zhang, Mingyin JiaAbstract
This study addresses the critical challenges of high melt viscosity and matrix brittleness in pultruded continuous glass fiber reinforced polyamide 6 (GF/PA6) composites. A synergistic modification strategy combining a hyperbranched polymer (HBP) flow modifier and a reactive elastomer (POE-g-MAH) was developed to optimize the “process-structure-property” relationship. Results indicate that at a high fiber loading (36 bundles), the addition of 3 phr HBP significantly reduced porosity to 0.49 % and enhanced flexural strength to 928.4 MPa through a “ball-bearing” effect and heterogeneous nucleation. Furthermore, the incorporation of 4 phr POE-g-MAH achieved an optimal stiffness-toughness balance. In-situ interfacial reactions formed stable imide linkages, increasing notched impact strength by 18.6 % while maintaining a high flexural strength of 836.6 MPa. This multi-scale co-design strategy effectively overcomes the trade-off between impregnation quality and mechanical toughening, providing a theoretical framework for manufacturing high-performance thermoplastic pultruded profiles.