Reversible plasticity shape memory effect in carbon nanotube/epoxy nanocomposites: Shape recovery studies for torsional and bending deformations

Abishera, R.; Ramachandran, V.; Gopal, K.V. Nagendra

doi:10.1002/pen.24861

Cited by 16 publications

(6 citation statements)

References 36 publications

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“…Abishera et al [ 154 ] proposed a study on the reversible plastic shape memory (RPSM) properties of multiwalled carbon nanotube- (MWCNT-) reinforced epoxy nanocomposites. They then investigated the superior properties of the system under bending and torsional deformation [ 155 ]. Yun and Liang [ 156 ] prepared a series of shape memory epoxy composites reinforced with different levels of carbon black (CB).…”

Section: Smep Compositesmentioning

confidence: 99%

Shape Memory Epoxy Resin and Its Composites: From Materials to Applications

2022

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Shape memory polymers (SMPs) have historically attracted attention for their unique stimulation-responsive and variable stiffness and have made notable progress in aerospace, civil industry, and other fields. In particular, epoxy resin (EP) has great potential due to its excellent mechanical properties, fatigue resistance, and radiation resistance. Herein, we focus on the molecular design and network construction of shape memory epoxy resins (SMEPs) to provide opportunities for performance and functional regulation. Multifunctional and high-performance SMEPs are introduced in detail, including multiple SMEPs, two-way SMEPs, outstanding toughness, and temperature resistance. Finally, emerging applications of SMEPs and their composites in aerospace, four-dimensional printing, and self-healing are demonstrated. Based on this, we point out the challenges ahead and how SMEPs can integrate performance and versatility to meet the needs of technological development.

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Section: Smep Compositesmentioning

confidence: 99%

Shape Memory Epoxy Resin and Its Composites: From Materials to Applications

2022

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“…Similar hybrid polymer composites with CNT and carbonaceous fillers showed shape memory performance [20]. Finally, it is well assessed that conductive CNT/polymer composites can be used to fabricate antennas, giving the possibility of setting up connections among the different parts in an easy and flexible way [21].…”

Section: Introductionmentioning

confidence: 99%

Piezoresistive and mechanical Behavior of CNT based polyurethane foam

et al. 2020

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Carbon nanotubes (CNT) embedded into a polymeric foam demonstrate an enhancement in electrical and mechanical properties of the final nanocomposite. The enhanced material with new characteristics, e.g., piezoresistivity, can be substituted with the traditional metallic material to design sensors, switches, and knobs directly into a single multifunctional component. Research activities in this field are moving towards a mono-material fully integrated smarts components. In order to achieve this goal, a simple method is developed to produce piezoresistive polyurethane/CNT foams. The novelty consists in applying the dispersion of CNT considering industrial production constrains, in order to facilitate its introduction into a common industrial practice. Three kinds of PU-CNT foam have been prepared and tested: PU-CNT 1.5%, PU-CNT-COOH 1.0%, and PU-CNT-COOH 1.5%. Polyurethane with CNT-COOH showed an insulating-conductive transition phenomenon when the foam reaches the 80% of its compression strain with a Gauge factor (Gf) of about 30. Instead, PU-CNT showed conductivity only at 1.5% of filler concentration and a steady piezoresistive behavior with a Gf of 80. However, this samples did not show the insulating-conductive transition. Having improved the electromechanical properties of final nanocomposite polyurethane foam demonstrates that the proposed method can be applied differently for design sensors and switches.

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“…The most widespread SMPs are based on polyurethanes, − polystyrene, methacrylate, epoxies, , and composites. , Tuning a polymer’s composition changes an SMP’s mechanical properties and, thus, its actuation performance. SMPs can undergo microstructural changes through a variety of stimuli, including heat, , light, , magnetism, and pH, affecting the shape or macroconformation in a large scale like shape-memory alloys do but with the advantage of not using any metallic wire or hard metallic parts to the soft actuators . The most common shape-memory actuation mechanism is thermal, where at temperatures above the transition temperature ( T g ), an SMP demonstrates viscoelastic behavior, while at lower temperatures, only elastic behavior is observed .…”

Section: Introductionmentioning

confidence: 99%

All-Organic Electroactive Shape-Changing Knitted Textiles Using Thermoprogrammed Shape-Memory Fibers Spun by 3D Printing

Kim

Otal

Takizawa

et al. 2022

ACS Appl. Polym. Mater.

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Here, we present knittable shape-memory polymeric fibers extruded using a 3D-printer nozzle-based melt-spinning method for high throughput of composition and condition testing. These structures are used as the basis for electroactive shape-changing knitted textiles combining several types of fibers, including organic fibrous heaters. These structures represent a different approach to “on-demand” shape-memory fibers and can be incorporated into a variety of textile architectures, including inlaid knitting, diagonal interlacements, and a knit/purl design for an anisotropic knitted texture. The influence of manufacturing process parameters (e.g., drawing ratio during melt-spinning) on physical properties of the shape-memory fibers was measured using X-ray diffraction, thermomechanical cycling, scanning electron microscopy, and mechanical testing. The degree of crystallinity increased from 19.4 to 22.4% with the increased drawing ratio, with a maximum strain % of 450 and the fibers being able to lift 457 times their own weight. Further, we present a scalable strategy for bicomponent filament production, in which two distinct polymers are melt-spun in a side-by-side configuration and when actuated showed a coiled structure with different mechanical and thermal behavior than pure SMP fibers. The knitted textiles, obtained with a computer-controlled knitting machine able to produce 3D knitted structures, are deformed from two-dimensional planar structures to three-dimensional conformations by applying a voltage to the organic fibrous heaters. The deformed structure can be fixed by removing the applied voltage and can be returned to a planar configuration by heating and applying an uniaxial stress. Therefore, a hierarchical approach for fully textile-based, bendable, knittable, and electroactive soft actuators is presented. The results presented here demonstrate lab-scale production and high-throughput screening of advanced fibers with tunable properties.

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Reversible plasticity shape memory effect in carbon nanotube/epoxy nanocomposites: Shape recovery studies for torsional and bending deformations

Cited by 16 publications

References 36 publications

Shape Memory Epoxy Resin and Its Composites: From Materials to Applications

Shape Memory Epoxy Resin and Its Composites: From Materials to Applications

Piezoresistive and mechanical Behavior of CNT based polyurethane foam

All-Organic Electroactive Shape-Changing Knitted Textiles Using Thermoprogrammed Shape-Memory Fibers Spun by 3D Printing

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