Standardization of shape memory alloy test methods toward certification of aerospace applications

The response of shape memory alloy (SMA) components employed as actuators has enabled a number of adaptable aero-structural solutions. However, there are currently no industry or government-accepted standardized test methods for SMA materials when used as actuators and their transition to commercialization and production has been hindered. This brief fast track communication introduces to the community a recently initiated collaborative and pre-competitive SMA specification and standardization effort that is expected to deliver the first ever regulatory agency-accepted material specification and test standards for SMA as employed as actuators for commercial and military aviation applications. In the first phase of this effort, described herein, the team is working to review past efforts and deliver a set of agreed-upon properties to be included in future material certification specifications as well as the associated experiments needed to obtain them in a consistent manner. Essential for the success of this project is the participation and input from a number of organizations and individuals, including engineers and designers working in materials and processing development, application design, SMA component fabrication, and testing at the material, component, and system level. Going forward, strong consensus among this diverse body of participants and the SMA research community at large is needed to advance standardization concepts for universal adoption by the greater aerospace community and especially regulatory bodies. It is expected that the development and release of public standards will be done in collaboration with an established standards development organization.

[1]  Dimitris C. Lagoudas,et al.  Thermomechanical Characterization of Shape Memory Alloy Materials , 2008 .

[2]  James H. Mabe,et al.  Boeing's Variable Geometry Chevron, Morphing Aerostructure for Jet Noise Reduction , 2006 .

[3]  Othmane Benafan,et al.  Shape memory alloy actuator design: CASMART collaborative best practices and case studies , 2013, International Journal of Mechanics and Materials in Design.

[4]  John A. Shaw,et al.  Tips and tricks for characterizing shape memory alloy wire: Part 1—differential scanning calorimetry and basic phenomena , 2008 .

[5]  Darren J. Hartl,et al.  Comparison of three-dimensional shape memory alloy constitutive models: Finite element analysis of actuation and superelastic responses of a shape memory alloy tube , 2013 .

[6]  K. Denoyer,et al.  Development and transition of low-shock spacecraft release devices , 2000, 2000 IEEE Aerospace Conference. Proceedings (Cat. No.00TH8484).

[7]  Dimitris C. Lagoudas,et al.  Roundrobin SMA modeling , 2009 .

[8]  Dimitris C. Lagoudas,et al.  Design of space systems using shape memory alloys , 2003, SPIE Smart Structures and Materials + Nondestructive Evaluation and Health Monitoring.

[9]  John A. Shaw,et al.  Tips and tricks for characterizing shape memory alloy wire: Part 2—fundamental isothermal responses , 2009 .

[10]  Dimitris C. Lagoudas,et al.  Aerospace applications of shape memory alloys , 2007 .

[11]  Ion Stiharu,et al.  More Intelligent Gas Turbine Engines (Des turbomoteurs plus intelligents) , 2009 .

[12]  L G Machado,et al.  Medical applications of shape memory alloys. , 2003, Brazilian journal of medical and biological research = Revista brasileira de pesquisas medicas e biologicas.

[13]  Diego Mantovani,et al.  Shape memory alloys: Properties and biomedical applications , 2000 .

[14]  K. Melton,et al.  Ni-Ti Based Shape Memory Alloys , 1990 .

[15]  M. Friswell,et al.  A review on shape memory alloys with applications to morphing aircraft , 2014 .