Switchable stiffness morphing aerostructures based on granular jamming

Brigido-González, J David; Burrow, Steve G; Woods, Benjamin K.S.

doi:10.1177/1045389x19862372

Cited by 14 publications

(12 citation statements)

References 23 publications

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“…As load is increased further still, there will be a progressive movement of this splitting point inwards through the thickness, and an increasing portion of the span of the beam will become ineffective. This leads to a progressive reduction in the effective second moment of area of the beam, which induces a softening response, as shown experimentally in previous work by these authors [15].…”

Section: Flexural Properties In Granular Jamming Beamssupporting

confidence: 70%

“…This basic principle can create a significant change in the resulting stiffness of a morphing structure such as the FishBAC. Initial prototypes of this concept showed that the granular jamming media allows for real-time control of the bending stiffness of the FishBAC [15]. It is also capable of switching the stiffness to withstand the aerodynamic loads without requiring power from the actuator.…”

Section: Fig 1 Aircraft Wings Versus Avian Wingsmentioning

confidence: 99%

“…For example, it is possible to provide a zero-energy consumption, if the actuator is switch off during holding position because the shape is maintained due to granular jamming. The combination of these two concepts (FishBAC and granular jamming) shows the development of a new morphing concept known as Switchable stiffness FishBAC (SwitchBAC) [15], and is shown schematically in Fig. 3.…”

Section: Fig 1 Aircraft Wings Versus Avian Wingsmentioning

confidence: 99%

“…The stress-strain curves are used on a non-linear FEA model based on Von-Mises plasticity to obtain the flexural stiffness. The previous approach is a useful approach to predict the variation of stiffness of granular jamming beams in a simplified way, and within the constraints of Euler-Bernoulli beam bending assumptions [15]. However; a more generally applicable modelling of the complex, non-linear micro-mechanical response of granular jamming bending structures is needed, which motivates the combined experimental and analytical approach pursued here.…”

Section: B Granular Jammingmentioning

confidence: 99%

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An analytical model for granular jamming beams with applications in morphing aerostructures

Brigido

Burrow

Woods

2020

AIAA Scitech 2020 Forum

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Modern aircraft wings use discrete, flapped control surfaces that are simple and effective, but which create a significant drag and noise penalty when used. This research is working towards the replacement of these flaps with a continuous morphing device that can increase the aerodynamic performance and reduce noise emissions. However, the need to create smoothly morphing aerostructures presents a fundamental challenge in that the structures need to be stiff enough to resist aerodynamic and inertial loads while being flexible enough to change shape with minimal energy required. One way to address this competing set of constraints would be to use a material that is able to actively vary its stiffness. Such a device could be softened while morphing and then stiffened to hold its morphed shape. In this work, granular jamming is proposed as a mechanism for creating a material which can change stiffness from a liquid-like state to a solid-like state through the application of an applied pressure field which jams together the grains to stiffen an otherwise soft material. The basic concept of switchable stiffness for morphing aircraft has been shown in previous work. This paper introduces an analytical model to describe the bending dominated behaviour of granular jamming based morphing structures. Four-point bending experiments are performed to validate the model, and detailed strain fields from digital image correlation measurements are used to further elucidate the micro-mechanics. The experimental data was compared against predictions from the proposed model, where it was seen that while the model is able to capture the presence of different regimes of response, the overall stiffness and strength are overpredicted. Possible sources of discrepancy are highlighted and motivate future work.

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Section: Flexural Properties In Granular Jamming Beamssupporting

confidence: 70%

Section: Fig 1 Aircraft Wings Versus Avian Wingsmentioning

confidence: 99%

Section: Fig 1 Aircraft Wings Versus Avian Wingsmentioning

confidence: 99%

Section: B Granular Jammingmentioning

confidence: 99%

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An analytical model for granular jamming beams with applications in morphing aerostructures

Brigido

Burrow

Woods

2020

AIAA Scitech 2020 Forum

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“…Much work has focused on the drivers, implications, and characteristics of the jamming transition in grains. Manipulation of the transition, back and forth between fluid-like and solid-like properties via external confinement has presented a basis of actuation in soft robotics 16,74,75 and deformable aerostructures 76 . Architects and artists have recently demonstrated the elegance and practical versatility that comes with embracing disorder and self-assembly instead of prescriptive control to build reconfigurable structures of emergent stability.…”

Section: Discussionmentioning

confidence: 99%

Mechanics of randomly packed filaments—The “bird nest” as meta-material

Weiner

Bhosale

Gazzola

et al. 2020

Journal of Applied Physics

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Systems of randomly packed, macroscopic elements, from jammed spherical grains to tangled long filaments, represent a broad class of disordered meta-materials with a wide range of applications and manifestations in nature. A 'bird nest' presents itself at an interface between hard round grains described by granular physics to long soft filaments, the center of textile material science. All of these randomly packed systems exhibit forms of self assembly, evident through their robust packing statistics, and a common, unusual elastoplastic response to oedometric compression. In reviewing packing statistics, mechanical response characterization and consideration of boundary effects, we present a perspective that attempts to establish a link between the bulk and local behaviour of a pile of sand and a wad of cotton, demonstrating the nest's relationship with each. Finally, potential directions for impactful applications are outlined.

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Soft Actuators Made of Discrete Grains

et al. 2022

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microscale actuation. However, these material-based actuators are often slow or only expand or contract axially, preventing use in applications that require volumetric expansions. To address such limitations of existing actuating materials, actuators based on the liquid-to-gas phase change of solvent inclusions encapsulated in a hyperelastic matrix have been realized. Phasechange actuators are capable of inducing rapid volumetric expansion similar to fluidic actuators, without being tethered to an external fluid source. [29][30][31][32] Accepting the advantages of phasechange actuators, we now turn our attention to granular media. Granular assemblies, consisting of discrete grains, can be tuned to accomplish a variety of different responses. For example, favorable self-assembly of granular media can be achieved via modulating interparticle interactions and external stimuli, [33][34][35][36] and granular assemblies with different packing configurations have been shown to yield different bulk properties. [36][37][38][39] Furthermore, granular media can exhibit optimized changes in stiffness during jamming transitions, enabling tunable moduli. [16,[40][41][42][43][44] When unjammed, the bulk material is compliant, and when jammed, the bulk material can achieve the stiffness of the grains. Finally, when mixed into carrier fluids, granular media can impart thixotropic behavior on the carrier fluid due to dynamic jamming, [45][46][47][48] enabling 3D printing of previously unprintable materials. With all the advantageous properties granular media has to offer, the technology has seen application in soft robotics, [49][50][51][52] medical devices, [53][54][55] flexible airfoils, [56] and programmable aggregate architecture. [57] Here, we bring together the unique advantages of phasechange soft actuators and granular media to introduce soft granular actuators made of discrete, volumetrically expanding grains. A single active grain consists of multiple solvent cores encapsulated in a hyperelastic silicone shell (Ecoflex 00-30). At elevated temperatures, the encapsulated solvent vaporizes and increases the internal pressure of the hyperelastic shell, inducing volumetric expansion of the grain. The grains are independently capable of rapid, high-force microscopic actuation, and are also easily arranged into granular assemblies to form larger-scale bulk actuators. Furthermore, agglomerates of active grains can self-assemble from disordered arrangements to conform around objects and exhibit variable moduli. Finally, the use of grains suspended in a carrier solvent or resin enables compatibility with granular self-assembly and 3D printing techniques, offering the potential to print volumetrically expanding actuators into freeform patterns across scales.Recent work has demonstrated the potential of actuators consisting of bulk elastomers with phase-changing inclusions for generating high forces and large volumetric expansions. Simultaneously, granular assemblies have been shown to enable tunable properties via different packing...

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Switchable stiffness morphing aerostructures based on granular jamming

Cited by 14 publications

References 23 publications

An analytical model for granular jamming beams with applications in morphing aerostructures

An analytical model for granular jamming beams with applications in morphing aerostructures

Mechanics of randomly packed filaments—The “bird nest” as meta-material

Soft Actuators Made of Discrete Grains

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