Constitutive modeling and experimental validation of the thermo-mechanical response of a shape memory composite containing shape memory alloy fibers and shape memory polymer matrix
Restricted accessResearch articleFirst published online March, 2016
Constitutive modeling and experimental validation of the thermo-mechanical response of a shape memory composite containing shape memory alloy fibers and shape memory polymer matrix
Multifunctional shape memory composites composed of shape memory polymers and shape memory alloys exhibit superior shape memory properties; therefore, it is of great interest to researchers to model their thermo-mechanical behavior numerically. Although a number of constitutive models of shape memory alloys and shape memory polymers have been developed, very few models have been developed for shape memory composites and validated with experimental data. In this study, we first review separately constitutive models of shape memory alloys and shape memory polymers developed in previous studies. Both models were validated with thermo-mechanical tests conducted on a shape memory alloy fiber and shape memory polymer, respectively. A constitutive model for the shape memory composite was then developed utilizing the homogenization scheme. Shape memory composites containing 0.5% or 1% of the shape memory alloy fiber volume content embedded in the shape memory polymer matrix were fabricated. Thermo-mechanical tests were carried out on these shape memory composites to validate the proposed constitutive model. The experimental results showed that the proposed shape memory composite model was able to predict the general trend of the thermo-mechanical behavior of the shape memory composites.
ASTM Standard F2516:2007e1 (2007) Standard test method for tension testing of nickel-titanium superelastic materials.
2.
BernardiniDPenceTJ (2002) Shape memory alloys: modeling. In: SchwartzM (chief ed.) Encyclopedia of Smart Materials, vol. 2. New York: John Wiley & Sons, pp. 964–980.
3.
BrinsonLC (1993) One-dimensional constitutive behavior of shape memory alloys: thermo-mechanical derivation with non-constant material functions and redefined martensite internal variable. Journal of Intelligent Material Systems and Structures4(2): 229–242.
4.
BrinsonLCHuangMS (1996) Simplifications and comparisons of shape memory alloy constitutive models. Journal of Intelligent Material Systems and Structures7(1): 108–114.
5.
Dynalloy, Inc. (2014) Technical Characteristics of Flexinol¯ Actuator Wires. Irvine, CA: Dynalloy, Inc.
6.
FengXZhaoLMiX. (2013) Improved shape memory composites combined with TiNi wire and shape memory epoxy. Materials & Design50: 724–727.
7.
HerzogHJacquetE (2006) From a shape memory alloys model implementation to a composite behavior. Computational Materials Science39: 365–375.
8.
HuJ (2007) Shape Memory Polymers and Textiles. Cambridge: Woodhead Publishing.
JaraliCSRajaSUpadhyaAR (2008) Micro-mechanical behaviors of SMA composites materials under hygro-thermo-elastic strain fields. International Journal of Solids and Structures45(9): 2399–2419.
11.
JaraliCSRajaSUpadhyaAR (2010) Constitutive modeling of SMA SMP multifunctional high performance smart adaptive shape memory composite. Smart Materials and Structures19(10): 105029.
12.
JiménezFLPellegrinoS (2012) Constitutive modeling of fiber composites with a soft hyperelastic matrix. International Journal of Solids and Structures49(3–4): 635–647.
13.
LaiSMLanYC (2013) Shape memory properties of melt-blended polylactic acid (PLA)/thermoplastic polyurethane (TPU) bio-based blends. Journal of Polymer Research20(140): 1–8.
14.
LendleinA (2010) Advances in polymer sciences. In: LendleinA (Ed.) Shape-Memory Polymers. 1st ed.Berlin: Springer, pp. 1–40.
15.
LendleinABehlMHieblB. (2010) Shape-memory polymers as a technology platform for biomedical applications. Expert Review of Medical Devices7(3): 357–379.
LiangCRogersCA (1990) One-dimensional thermo-mechanical constitutive relations for shape memory materials. Journal of Intelligent Material Systems and Structures1(2): 207–234.
18.
LiuCQinHMatherPT (2007) Review of progress in shape-memory polymers. Journal of Materials Chemistry17: 1543–1558.
19.
LiuYDuHLiuL. (2014) Shape memory polymers and their composites in aerospace applications: a review. Smart Materials and Structures23(2): 1–22.
20.
LiuYGallKDunnML. (2006) Thermomechanics of shape memory polymers: uniaxial experiments and constitutive modeling. International Journal of Plasticity22(2): 279–313.
MengQHuJ (2009) A review of shape memory polymer composites and blends. Composites Part A: Applied Science and Manufacturing40(11): 1661–1672.
23.
NguyenTD (2013) Modeling shape-memory behavior of polymers. Polymer Reviews53(1): 130–152.
24.
OtsukaKWaymanCM (1998a) Chapter 1. Introduction. In: OtsukaKWaymanCM (eds) Shape Memory Materials. Cambridge: Cambridge University Press, pp. 1–26.
25.
OtsukaKWaymanCM (1998b) Chapter 2. Mechanism of shape memory effect and superelasticity. In: OtsukaKWaymanCM (eds) Shape Memory Materials. Cambridge: Cambridge University Press, pp. 27–48.
26.
PinderaMJ (2013) The self-consistent scheme. MIE 1399 special topics in solid mechanics lecture notes, Department of Mechanical and Industrial Engineering, University of Toronto, Toronto, ON, Canada.
27.
SaburiT (1998) Chapter 3. Ti-Ni shape memory alloys. In: OtsukaKWaymanCM (eds) Shape Memory Materials. Cambridge: Cambridge University Press, pp. 49–96.
28.
SittnerPStalmansRTokudaM (2000) An algorithm for prediction of the hysteretic responses of shape memory alloys. Smart Materials and Structures9(4): 452–465.
29.
SongJSrivastavaIKowalskiJ. (2014) Fabrication and characterization of a foamed polylactic acid (PLA)/ thermoplastic polyurethane (TPU) shape memory polymer (SMP) blend for biomedical and clinical applications. In: SPIE smart structures/NDE 2014, San Diego, CA, 9–13 March, paper no. 9058–11.
30.
TanQLiuLLiuY. (2014) Thermal mechanical constitutive model of fiber reinforced shape memory polymer composite: based on bridging model. Composites Part A: Applied Science and Manufacturing64: 132–138.
31.
TanakaKIwasakiR (1985) A phenomenological theory of trans-formation superplasticity. Engineering Fracture Mechanics21(4): 709–720.
32.
TanakaKNagakiS (1982) A thermo-mechanical description of materials with internal variables in the process of phase transitions. Ingenieur Archiv51(5): 287–299.
33.
TobushiHHayashiSHoshioK. (2006) Bending actuation characteristics of shape memory composite with SMA and SMP. Journal of Intelligent Material Systems and Structures17(12): 1075–1081.
34.
TobushiHHayashiSSugimotoY. (2010) Fabrication and two-way deformation of shape memory composite with SMA and SMP. Materials Science Forum638–642: 2189–2194.
35.
WeiZGSandströmRMiyazakiS (1998) Shape-memory materials and hybrid composites for smart systems: part I shape-memory materials. Journal of Materials Science33(15): 3743–3762.
36.
XieT (2011) Recent advances in polymer shape memory. Polymer52(22): 4985–5000.
37.
ZakAJCartmellMPOstachowiczWM. (2003) One-dimensional shape memory alloy models for use with reinforced composite structures. Smart Materials and Structures12(3): 338–346.
