In this research, the benzoxazine-epoxy shape memory polymers with outstanding recovery stress improvement were prepared by filling with highly adamantine silicon carbide whisker at 0–20 wt%. The results revealed that the storage modulus at room temperature increased with increasing silicon carbide whisker, that is, from 5.1 GPa (without silicon carbide whisker) to 8.8 GPa (at 20 wt%). Glass transition temperatures were increased with increasing silicon carbide whisker in the range of 154°C–170°C. Furthermore, all samples exhibited approximately 99% of shape fixity with recovery time ranging from 8 to 27 min. Interestingly, the incorporation of silicon carbide whisker could significantly increase recovery stress from 3.4 MPa (without silicon carbide whisker) to 11.2 MPa (at 20 wt%). Moreover, the addition of silicon carbide whisker provides microwave actuating ability to the sample. Recovery time under microwave heating was significantly shortened to be in a range of 3–5 min. These results suggest potential use of the composites as microwave-responsive sensors and other shape memory devices.
AbrahamsonERLakeMSMunshiNAet al. (2003) Shape memory mechanics of an elastic memory composite resin. Journal of Intelligent Material Systems and Structures14(10): 623–632.
2.
AnisAFaizSLuqmanMet al. (2013) Developments in shape memory polymeric materials. Polymer: Plastics Technology and Engineering52(15): 1574–1589.
3.
DuHSongZWangJet al. (2015) Microwave-induced shape-memory effect of silicon carbide/poly(vinyl alcohol) composite. Sensors and Actuators A: Physical228: 1–8.
4.
FejosMKarger-KocsisJ (2013) Shape memory performance of asymmetrically reinforced epoxy/carbon fibre fabric composites in flexure. Express Polymer Letters7(6): 528–534.
5.
FejosMRomhányGKarger-KocsisJ (2012) Shape memory characteristics of woven glass fibre fabric reinforced epoxy composite in flexure. Journal of Reinforced Plastics & Composites31(22): 1532–1537.
6.
HarriesGL (1995) Properties of Silicon Carbide. London: INSPEC, Institution of Electrical Engineers.
7.
HuJ (2007) Characterization of shape memory properties in polymers. In: HuJ (ed.) Shape Memory Polymers and Textiles. London: Woodhead Publishing, pp. 197–217.
8.
IshidaH (1996) Process for preparation of benzoxazine compounds in solventless systems. Patent 5543516A, USA.
9.
JinFLParkSJ (2012) Thermal properties of epoxy resin/filler hybrid composites. Polymer Degradation and Stability97: 2148–2153.
10.
KardosJL (1983) The role interface in polymer composites—some myths, mechanisms, and modifications. In: IshidaHKumarK (eds) Molecular Characterization of Composite Interfaces. Washington, DC: Springer, pp. 1–11.
11.
LanXLiuYLvHet al. (2009) Fiber reinforced shape-memory polymer composite and its application in a deployable hinge. Smart Materials and Structures18(2): 024002.
12.
LiuCQinHMatherPT (2007) Review of progress in shape-memory polymers. Journal of Materials Chemistry17: 1543–1558.
13.
LiuYDuHLiuL (2014) Shape memory polymers and their composites in aerospace applications: a review. Smart Materials and Structures23(2): 023001.
14.
LiuYGallKDunnMLet al. (2004) Thermomechanics of shape memory polymer nanocomposites. Mechanics of Materials36(10): 929–940.
15.
LiuYHanCTanHet al. (2010) Thermal, mechanical and shape memory properties of shape memory epoxy resin. Materials Science & Engineering A527(10–11): 2510–2514.
16.
LuHBYuKSunSHet al. (2010) Mechanical and shape-memory behavior of shape-memory polymer composites with hybrid fillers. Polymer International59(6): 766–771.
17.
MengHHuJ (2010) A brief review of stimulus-active polymers responsive to thermal, light, magnetic, electric, and water/solvent stimuli. Journal of Intelligent Material Systems and Structures21(9): 859–885.
18.
MengHLiG (2013) A review of stimuli-responsive shape memory polymer composites. Polymer54(9): 2199–2221.
19.
NiQ-QZhangCFuet al. (2007) Shape memory effect and mechanical properties of carbon nanotube/shape memory polymer nanocomposites. Composite Structures81: 176–184.
20.
PlengudomkitRManuyaORimdusitS (2016) Highly filled graphene-benzoxazine composites as bipolar plates in fuel cell applications. Polymer Composites37(6): 1715–1727.
21.
RimdusitSIshidaH (2000) Development of new class of electronic packaging materials based on ternary systems of benzoxazine, epoxy, and phenolic resins. Polymer41: 7941–7949.
22.
RimdusitSJiraprawatthagoolVJubsilpCet al. (2007) Effect of SiC whisker on benzoxazine-epoxy-phenolic ternary systems: microwave curing and thermomechanical characteristics. Journal of Applied Polymer Science105(4): 1968–1977.
23.
RimdusitSJiraprawatthagoolVTiptipakornSet al. (2006) Characterization of SiC whisker-filled polybenzoxazine cured by microwave radiation and heat. International Journal of Polymer Analysis and Characterization11(6): 441–453.
24.
RimdusitSLohwerathamaMHemvichianKet al. (2013) Shape memory polymers from benzoxazine-modified epoxy. Smart Materials and Structures22(7): 075033.
25.
RousseauIA (2008) Challenges of shape memory polymers: a review of the progress toward overcoming SMP’s limitations. Polymer Engineering & Science48(11): 2075–2089.
SunJLiuYLengJ (2015) Mechanical properties of shape memory polymer composites enhanced by elastic fibers and their application in variable stiffness morphing skins. Journal of Intelligent Material Systems and Structures26(15): 2020–2027.
28.
TanpitaksitTJubsilpCRimdusitS (2015) Effects of benzoxazine resin on property enhancement of shape memory epoxy: a dual function of benzoxazine resin as a curing agent and a stable network segment. Express Polymer Letters9(9): 824–837.
29.
TobushiHHayashiSHoshioKet al. (2006) Bending actuation characteristics of shape memory composite with SMA and SMP. Journal of Intelligent Material Systems and Structures17(12): 1075–1081.
30.
WangLSChenHCZhangLFet al. (2011) Biodegradable thermoplastic elastomer comprising PLLCA and CaCO3 whiskers: mechanical properties, thermal stability and shape memory properties. Journal of Polymer Research18(3): 329–336.
31.
XieFHuangLLengJet al. (2016) Thermoset shape memory polymers and their composites. Journal of Intelligent Material Systems and Structures27: 2433–2455.
32.
XieT (2011) Recent advances in polymer shape memory. Polymer52(22): 4985–5000.
33.
XieTRousseauIA (2009) Facile tailoring of thermal transition temperatures of epoxy shape memory polymers. Polymer50(8): 1852–1856.
34.
YuKLiuYLiuYet al. (2014) Mechanical and Shape recovery properties of shape memory polymer composite embedded with cup-stacked carbon nanotube. Journal of Intelligent Material Systems and Structures25(10): 1264–1275.
35.
YuanZKYuJHRaoBLet al. (2014) Enhanced thermal properties of epoxy composites by using hyperbranched aromatic polyamide grafted silicon carbide whiskers. Macromolecular Research22(4): 405–411.
