4.7 Article

Design of high-performance resin by tuning cross-linked network topology to improve CF/bismaleimide composite compressive properties

Journal

COMPOSITES SCIENCE AND TECHNOLOGY
Volume 242, Issue -, Pages -

Publisher

ELSEVIER SCI LTD
DOI: 10.1016/j.compscitech.2023.110170

Keywords

Polymer-matrix composites (PMCs); Mechanical properties; Interfacial strength; Cross-linked network topology

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This research introduces a bottom-up reinforcement strategy for carbon fiber reinforced polymer (CFRP) composites by modifying the bismaleimide resin matrix through molecular structure design. The modified resin matrix achieved a significant increase in mechanical properties, with the tensile modulus reaching 5.59 GPa. The compressive strength and interlaminar shear strength of CFRP composites also showed noticeable improvements, indicating that increasing the modulus of the resin matrix is an effective strategy for enhancing the compressive and interfacial properties of the composite material.
One effective method for addressing the imbalance between the compression-to-tensile strength ratio in carbon fiber reinforced polymer (CFRP) composites is to create a high-performance resin matrix. We have introduced a bottom-up reinforcement strategy for CFRP composites that involves modifying the bismaleimide resin matrix through the design of its molecular structure. This research utilized the Wittig olefination reaction to convert the polar carbonyl on the bismaleimide monomer to allyl, which resulted in a change in the cross-linked network topology of the bismaleimide resin matrix, and achieved a significant increase in mechanical properties. The tensile modulus of the modified bismaleimide resin matrix reached 5.59 GPa and the mechanism behind this enhancement is discussed in detail. This work is particularly significant due to the preparation and performance evaluation of CF/bismaleimide composites. The compressive strength and interlaminar shear strength of CF/ bismaleimide composites showed noticeable improvements of 30.08% and 22.23% respectively, indicating that increasing the modulus of the resin matrix is an effective strategy for enhancing the compressive and interfacial properties of the composite material. Our work aims to offer research insights and design ideas for future exploration of bismaleimide resins in advanced composite resin matrices.

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