Abstract
This article reviews some of the intrinsic self-healing epoxy materials that have been investigated throughout the course of the last twenty years. Emphasis is placed on those formulations suitable for the design of high-performance composites to be employed in the aerospace field. A brief introduction is given on the advantages of intrinsic self-healing polymers over extrinsic counterparts and of epoxies over other thermosetting systems. After a general description of the testing procedures adopted for the evaluation of the healing efficiency and the required features for a smooth implementation of such materials in the industry, different self-healing mechanisms, arising from either physical or chemical interactions, are detailed. The presented formulations are critically reviewed, comparing major strengths and weaknesses of their healing mechanisms, underlining the inherent structural polymer properties that may affect the healing phenomena. As many self-healing chemistries already provide the fundamental aspects for recyclability and reprocessability of thermosets, which have been historically thought as a critical issue, perspective trends of a circular economy for self-healing polymers are discussed along with their possible advances and challenges. This may open up the opportunity for a totally reconfigured landscape in composite manufacturing, with the net benefits of overall cost reduction and less waste. Some general drawbacks are also laid out along with some potential countermeasures to overcome or limit their impact. Finally, present and future applications in the aviation and space fields are portrayed.
Highlights
Polymer matrix composites (PMCs) have been broadly studied and employed for several decades and find an application in different engineering fields, including aerospace
This review focuses exclusively on the description of the main intrinsic self-healing epoxy systems found in the literature, both as a standalone material and as matrices in PMCs, with an emphasis on those systems that are suitable for aerospace applications
The net benefit gained from the synergic effect of these two areas translates to (a) less inspection and maintenance times, i.e., an increase in the in-service/out-of-work ratio, as structures inherently possess what is necessary for healing damages; (b) a longer life cycle of any composite component; and (c) overall reduction of costs, as well as an increment of safety
Summary
Polymer matrix composites (PMCs) have been broadly studied and employed for several decades and find an application in different engineering fields, including aerospace. In this view, the of implementation the self-healing principle to aerospace the the self-healingofprinciple to aerospace composite can be composite beneficial canincrease be beneficial to increase reliability andconsiderably safety and itreduce will considerably to both reliability andboth safety and it will maintenancereduce costs. The of implementation the self-healing principle to aerospace the the self-healingofprinciple to aerospace composite can be composite beneficial canincrease be beneficial to increase reliability andconsiderably safety and itreduce will considerably to both reliability andboth safety and it will maintenancereduce costs From such considerations, theconsiderations, research has shifted towards design of self-healing of self-healing materials, possess the ability to recover a in functionality in order to materials, which possess which the ability to recover a functionality order to extend their service [5], aslifetime shown in. For a general overview on selfand their classification, we classification, refer the reader some published comprehensive healing polymers and their wetorefer therecently reader to some recently published reviews and inspiring research in the field [6,7,8,9].in the field [6,7,8,9]
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