Effect of axial preloads on torsional behavior of superelastic shape memory alloy tubes - experimental investigation and simulation/predictions of intricate inner loops

• Published in: International journal of computational methods in engineering science and mechanics Vol. 25; no. 5; pp. 286 - 320
• Main Authors: Rao, Ashwin, Chohan, Shoaib, Srinivasa, Arun R.
• Format: Journal Article
• Language: English
• Published: Taylor & Francis 02.09.2024
• Subjects: combined loading; intricate internal loops; return point memory(RPM); Shape memory alloy (SMA); sink point memory (SPM); superelastic/pseudoelastic effect; torsion; tube
• ISSN: 1550-2287; 1550-2295
• DOI: 10.1080/15502287.2024.2342875

Shape memory alloy (SMA) devices (utilizing wires/rods, springs or tubes) engage unique superelastic/pseudoelastic (SE) phenomenon for large stroke recovery, energy dissipation and damping applications. In particular, SMA components in torsion are also generally subjected to some pre-tension loads and hence understanding their combined effects on the torsional response is vital. In this work, some intricate internal loop and outer loop responses (large twists > 1500°) of SMA tubes under different twisting-untwisting scenarios are investigated to understand the effects of static pre-load on torsional responses. Key SMA hysteretic features like sink point memory (SPM) and return point memory (RPM) have not been well understood under torsion (with and without axial loads) have been investigated here. Further, a modified two variant thermodynamic Preisach modeling approach is proposed to simulate responses of twisted tubes with varying extents of twist and different axial loads. The central principle here is the use of a Gibbs Potential framework to separate the dissipative and thermoelastic parts of the SE responses using well established thermodynamic principles and then utilizing a non-ideal switching type disjunctive Preisach model to fit the nonlinear hysteretic dissipative section of the SE response. By using the outer loop response for model calibration, other complex loading unloading scenarios leading to intricate internal loops and effects of axial loads on these can be predicted. It is also shown that addition of a single interior loop detail for model calibration significantly enhances prediction of other more intricate internal loops. This approach dramatically simplifies the experimental data needed for the simulation of SMA components even under complex loading.