Journal
COMPOSITES PART A-APPLIED SCIENCE AND MANUFACTURING
Volume 147, Issue -, Pages -Publisher
ELSEVIER SCI LTD
DOI: 10.1016/j.compositesa.2021.106455
Keywords
A; Polymer-matrix composites (PMCs); B; Delamination; C; Finite element analysis (FEA); Shape memory alloy
Funding
- QinetiQ Australia
- RMIT University under the Department of Defence (Defence Science & Technology) Stage 1 SBIRD program
- DSTL
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The use of tufted shape memory alloy (SMA) filaments in fibre reinforced polymer composites enhances delamination resistance and crack closure properties, creating a new class of damage tolerant composite material. By forming a large-scale bridging process zone along delamination cracks, the SMA tufts can partially close cracks after crack growth, leading to improved fracture toughness.
A new type of fibre reinforced polymer composite is presented that uniquely combines high delamination resistance with crack closure properties via the use of tufted shape memory alloy (SMA) filaments. A carbonepoxy laminate was tufted in the through-thickness direction using thin SMA filaments of Ni-Ti alloy (nitinol). The SMA tufts increase the mode I interlaminar fracture toughness of the laminate by forming a large-scale bridging process zone along the delamination crack. Following crack growth, electrical heating of the SMA tufts activates a shape memory effect that partially closes the delamination. Finite element (FE) analysis reveals that complete crack closure occurs when the SMA tufts are not deformed above the shape memory strain limit. The use of SMA tufts offers the important opportunity to produce a new class of damage tolerant composite material that both resist the opening and aid the closing of delamination cracks formed by overloading, impact or other damaging events.
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