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Parametric Studies of Shape Memory Alloy Hybrid Composite Laminates Under Low-Velocity Impact

Published online by Cambridge University Press:  20 April 2016

Y.-C. Lin*
Affiliation:
School of Defense Science Chung Cheng Institute of Technology National Defense University Taoyuan, Taiwan
Y.-L. Chen
Affiliation:
Department of Power Vehicle and Systems Engineering Chung Cheng Institute of Technology National Defense University Taoyuan, Taiwan
H.-W. Chen
Affiliation:
Chung San Institute of Sciences and Technology Taoyuan, Taiwan
*
*Corresponding author ([email protected])
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Abstract

In the paper, the influence of shape memory alloy (SMA) by varying the parameters such as volume fraction, orientation, and temperature on the hybrid-SMA composite laminate subjected to low-velocity impact is studied. A theoretical model for the composite laminated plate bonded with SMA reinforced layers is presented. The constitutive relation of the SMA layer is obtained by using the method of micromechanics. The governing relations obtained can be used for theoretical predications of thermomechanical properties of SMA plies in this paper. The analytical expressions for the hybrid SMA composite plate are derived based on Tanaka's constitutive equation and linear phase transformation kinetics presented by Liang and Rogers.

The laminated plate theory, first-order shear deformation theory and minimal potential energy principle is utilized to solve the governing equations of the hybrid composite plate and calculate the absorbed energies including tensile, shear and bending.

An orthogonal array and analysis of variance is employed to investigate the influence of the mentioned parameters on the energy absorption of the hybrid laminated plate. The results showed that the effects of the phase transformation temperature are more significant than the effects of the volume fraction and orientation of SMA on structural energy absorption.

Type
Research Article
Copyright
Copyright © The Society of Theoretical and Applied Mechanics 2016 

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References

1. Shokuhfar, A., et al., “Analysis and Optimization of Smart Hybrid Composite Plates Subjected to Low-Velocity Impact Using the Response Surface Methodology (RSM),” Thin-Walled Structures, 46, pp. 12041212 (2008).CrossRefGoogle Scholar
2. John, S. and Hariri, M., “Effect of Shape Memory Alloy Actuation on the Dynamic Response of Polymeric Composite Plates,” Composites Part A: Applied Science and Manufacturing, 39, pp. 769776 (2008).CrossRefGoogle Scholar
3. Meo, M., Antonucci, E., Duclaux, P. and Giordano, M., “Finite Element Simulation of Low Velocity Impact on Shape Memory Alloy Composite Plates,” Composite Structures, 71, pp. 337342 (2005).CrossRefGoogle Scholar
4. Chen, Y. L., Chen, H. W. and Lin, Y. C., “Analysis of Shape Memory Alloy Hybrid Composite Plates under Low Velocity Impact,” Applied Mechanics and Materials, pp. 473476 (2014).Google Scholar
5. Lee, H. J., Lee, J. J. and Huh, J. S., “A Simulation Study on the Thermal Buckling Behavior of Laminated Composite Shells with Embedded Shape Memory Alloy (Sma) Wires,” Composite Structures, 47, pp. 463469 (1999).CrossRefGoogle Scholar
6. Chen, Y. L., Chen, H. W. and Lin, Y. C., “A Study of Composite Laminated Plate with Embedded Shape Memory Alloy Wires under Impact Load,” IUMRS-ICEM 2014 International Conference, Taiwan (2014).Google Scholar
7. Liang, C., and Rogers, C., “One-Dimensional Thermomechanical Constitutive Relations for Shape Memory Materials,” Journal of Intelligent Material Systems and Structures, 1, pp. 207234 (1990).CrossRefGoogle Scholar
8. Roh, J.-H. and Kim, J.-H., “Adaptability of Hybrid Smart Composite Plate under Low Velocity Impact,” Composites Part B: Engineering, 34, pp. 117125 (2003).CrossRefGoogle Scholar
9. Brinson, L., “One-Dimensional Constitutive Behavior of Shape Memory Alloys: Thermomechanical Derivation with Non-Constant Material Functions and Redefined Martensite Internal Variable,” Journal of Intelligent Material Systems and Structures, 4, pp. 229242 (1993).CrossRefGoogle Scholar
10. Brinson, L. and Lammering, R., “Finite Element Analysis of the Behavior of Shape Memory Alloys and Their Applications,” International Journal of Solids and Structures, 30, pp. 32613280 (1993).CrossRefGoogle Scholar
11. Brinson, L., Bekker, A. and Hwang, S., “Deformation of Shape Memory Alloys Due to Thermo-Induced Transformation,” Journal of Intelligent Material Systems and Structures, 7, pp. 97107 (1996).CrossRefGoogle Scholar
12. Lee, J. J. and Choi, S., “Thermal Buckling and Postbuckling Analysis of a Laminated Composite Beam with Embedded Sma Actuators,” Composite Structures, 47, pp. 695703 (1999).CrossRefGoogle Scholar
13. Auricchio, F. and Sacco, E., “A One-Dimensional Model for Superelastic Shape-Memory Alloys with Different Elastic Properties between Austenite and Martensite,” International Journal of Non-Linear Mechanics, 32, pp. 11011114 (1997).CrossRefGoogle Scholar
14. Wu, Y., Zhong, W., Wu, G. and Zou, J., “Low Velocity Impact Response Analysis of Shape Memory Alloy Reinforced Composite Beam,” Journal of Wuhan University of Technology, Materials Science Edition, 20, pp. 7073 (2005).Google Scholar
15. Shariyat, M. and Moradi, M., “Enhanced Algorithm for Nonlinear Impact of Rectangular Compo-site Plates with Sma Wires, Accurately Tracing the Instantaneous and Local Phase Changes,” Composite Structures, 108, pp. 834847 (2014).CrossRefGoogle Scholar
16. Shariyat, M., Moradi, M. and Samaee, S., “Enhanced Model for Nonlinear Dynamic Analysis of Rectangular Composite Plates with Embedded Sma Wires, Considering the Instantaneous Local Phase Changes,” Composite Structures, 109, pp. 106118 (2014).CrossRefGoogle Scholar
17. Shariyat, M. and Jafari, R., “Nonlinear Low-Velocity Impact Response Analysis of a Radially Preloaded Two-Directional-Functionally Graded Circular Plate: A Refined Contact Stiffness Approach,” Composites Part B: Engineering, 45, pp. 981994 (2013).CrossRefGoogle Scholar
18. Birman, V., Chandrashekhara, K. and Sain, S., “An Approach to Optimization of Shape Memory Alloy Hybrid Composite Plates Subjected to Low-Velocity Impact,” Composites Part B: Engineering, 27, pp. 439446 (1996).CrossRefGoogle Scholar
19. Wu, Y., Wu, Y., Wang, Y. and Zhong, W., “Study on the Response to Low-Velocity Impact of a Composite Plate Improved by Shape Memory Alloy,” Acta Mechanica Solida Sinica, 20, pp. 357362 (2007).CrossRefGoogle Scholar
20. Kim, E.-H., et al., “Effects of Shape Memory Alloys on Low Velocity Impact Characteristics of Composite Plate,” Composite Structures, 93, pp. 29032909 (2011).CrossRefGoogle Scholar
21. Mohd Jani, J., Leary, M., Subic, A. and Gibson, M. A., “A Review of Shape Memory Alloy Research, Applications and Opportunities,” Materials and Design, 56, pp. 10781113 (2014).CrossRefGoogle Scholar
22. Ro, J. and Baz, A., “Nitinol-Reinforced Plates: Part Ii. Static and Buckling Characteristics,” Composites Engineering, 5, pp. 7790 (1995).CrossRefGoogle Scholar
23. Lu, P., Cui, F. S. and Tan, M. J., “A Theoretical Model for the Bending of a Laminated Beam with Sma Fiber Embedded Layer,” Composite Structures, 90, pp. 458464 (2009).CrossRefGoogle Scholar
24. Shiau, L.-C., Kuo, S.-Y. and Chang, S.-Y., “Free Vibration of Buckled Sma Reinforced Composite Laminates,” Composite Structures, 93, pp. 26782684 (2011).CrossRefGoogle Scholar
25. Figucia, F., “Energy Absorption of Kevlar (Trade Name) Fabrics under Ballistic Impact,” DTIC Document, U.S., pp. 2941 (1980).Google Scholar
26. Hoo Fatt, M. S., Lin, C., Revilock, D. M. Jr and Hopkins, D. A., “Ballistic Impact of Glare™ Fiber - Metal Laminates,” Composite Structures, 61, pp. 7388 (2003).CrossRefGoogle Scholar
27. Hoo Fatt, M. S. and Lin, C., “Perforation of Clamped, Woven E-Glass/Polyester Panels,” Composites Part B: Engineering, 35, pp. 359378 (2004).CrossRefGoogle Scholar
28. Mahapatra, S. S. and Patnaik, A., “Study on Mechanical and Erosion Wear Behavior of Hybrid Composites Using Taguchi Experimental Design,” Materials and Design, 30, pp. 27912801 (2009).CrossRefGoogle Scholar
29. Khondker, O. A., Herszberg, I. and Hamada, H., , “Measurements and Prediction of the Compression-after-Impact Strength of Glass Knitted Textile Composites,” Composites Part A: Applied Science and Manufacturing, 35, pp. 145157 (2004).CrossRefGoogle Scholar
30. Satapathy, B. K., et al., “Targeted Material Design of Flyash Filled Composites for Friction Braking Application by Non-Linear Regression Optimization Technique,” Computational Materials Science, 50, pp. 31453152 (2011).CrossRefGoogle Scholar
31. Chang, Y. C., Yeh, L. J. and Chiu, M. C., “Optimization of Constrained Composite Absorbers Using Simulated Annealing,” Applied Acoustics, 66, pp. 341352 (2005).CrossRefGoogle Scholar
32. Erdal, O. and Sonmez, F. O., “Optimum Design of Composite Laminates for Maximum Buckling Load Capacity Using Simulated Annealing,” Composite Structures, 71, pp. 4552 (2005).CrossRefGoogle Scholar
33. Vasant, P. and Barsoum, N., “Hybrid Pattern Search and Simulated Annealing for Fuzzy Production Planning Problems,” Computers and Mathematics with Applications, 60, pp. 10581067 (2010).CrossRefGoogle Scholar
34. Akbulut, M., and Sonmez, F. O., “Design Optimization of Laminated Composites Using a New Variant of Simulated Annealing,” Computers and Structures, 89, pp. 17121724 (2011).CrossRefGoogle Scholar
35. Li, P., Yang, Y. and Lu, H., “A New Thermal Property Measurement Technique by Modified Pattern Search Method,” Measurement, 45, pp. 21212127 (2012).CrossRefGoogle Scholar