Litcius/Paper detail

Smart and repeatable easy-repairing and self-sensing composites with enhanced mechanical performance for extended components life

Thomas D.S. Thorn, Yi Liu, Xudan Yao, Dimitrios G. Papageorgiou, P. Robinson, Emiliano Bilotti, Ton Peijs, Han Zhang

2022Composites Part A Applied Science and Manufacturing20 citationsDOIOpen Access PDF

Abstract

Structural composites with smart functionalities of self-healing and self-sensing are of particular interest in the fields of aerospace, automotive, and renewable energy. However, most of the current self-healing methodologies either require a relatively complex design of the healing network, or sacrifice the initial mechanical or thermal performance of the carbon fibre composite system after introducing the healing agents. Herein, an extremely simple methodology based on commonly used thermoplastic interleaves has been demonstrated to achieve repeatable easy-repairing and self-sensing functionalities, alongside enhanced mechanical performance in comparison with unmodified carbon fibre/epoxy system. Moreover, due to the high glass transition temperature of the thermoplastic, the repairable composites are shown to have an unchanged storage modulus up to 80 °C, solving the previous limitation of repairable epoxy matrix systems with thermoplastics. High retention of peak load (99%) and a decent recovery of interlaminar fracture toughness (34%) was achieved. Most importantly, the mechanical properties remained greater than the unmodified system after four consecutive cycles of damage and healing. Repeatable in-situ damage sensing was achieved based on the piezoresistive method. This “new” discovery based on an “old” approach, which is fully compatible with current composite manufacturing, may overcome existing conflicts between mechanical performance and healing functions, providing a new solution to extend components’ service life towards a more sustainable development of the composite sector.

Topics & Concepts

Materials scienceComposite materialSelf-healingSmart materialMedicineAlternative medicinePathologyPolymer composites and self-healingAdditive Manufacturing and 3D Printing TechnologiesSilicone and Siloxane Chemistry