21 April 2016 Fracture toughness of shape memory alloy actuators: effect of transformation-induced plasticity
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Abstract
Numerical analysis of static cracks in a plane strain center-cracked infinite medium shape memory alloy (SMA) panel subjected to cyclic thermal variations and a constant mechanical load is conducted using the finite element method. In solid-state SMA actuators, permanent changes in the material's microstructure in the form of dislocations are caused during cyclic thermomechanical loading, leading to macroscopic irreversible strains, known as transformation induced plastic (TRIP) strains. The influence of these accumulated TRIP strains on mechanical fields close to the crack tip is investigated in the present paper. Virtual crack growth technique (VCCT) in ABAQUS FEA suite is employed to calculate the crack tip energy release rate and crack is assumed to be stationary (or static) so that the crack tip energy release rate never reaches the material specific critical value. Increase in the crack tip energy release rate is observed during cooling and its relationship with accumulation of TRIP due to cyclic transformation is studied.
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Sameer Jape, Alexandros Solomou, Theocharis Baxevanis, Dimitris C. Lagoudas, "Fracture toughness of shape memory alloy actuators: effect of transformation-induced plasticity", Proc. SPIE 9800, Behavior and Mechanics of Multifunctional Materials and Composites 2016, 98000C (21 April 2016); doi: 10.1117/12.2219495; https://doi.org/10.1117/12.2219495
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