Controllable Stiffness Origami “Skeletons” for Lightweight and Multifunctional Artificial Muscles

Lin, Yangqiao; Yang, Geng; Liang, Yingwei; Zhang, Chao; Wang, Wei; Qian, Dahong; Yang, Huayong; Zou, Jun

doi:10.1002/adfm.202000349

Cited by 47 publications

(50 citation statements)

References 34 publications

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“…In previous work, reconfigurable robots capable of locomotion have been built by assembling pneumatically actuated voxels able only of contraction and expansion Zou et al (2018) , Sui et al (2019) . Lin et al designed more complex and versatile soft robots, using bending and contractile pneumatic voxels Lin et al (2020) , but requiring an important amount of pressure lines and complex pressure signals. The heat-actuated fixed kinematic voxels presented in this work compromise among the design simplicity, ease of actuation, and the loss of reconfigurability of the voxels.…”

Section: Discussionmentioning

confidence: 99%

Optimization of Phase-Change Material–Elastomer Composite and Integration in Kirigami-Inspired Voxel-Based Actuators

et al. 2021

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Phase-change material–elastomer composite (PCMEC) actuators are composed of a soft elastomer matrix embedding a phase-change fluid, typically ethanol, in microbubbles. When increasing the temperature, the phase change in each bubble induces a macroscopic expansion of the matrix. This class of actuators is promising for soft robotic applications because of their high energy density and actuation strain, and their low cost and easy manufacturing. However, several limitations must be addressed, such as the high actuation temperature and slow actuation speed. Moreover, the lack of a consistent design approach limits the possibility to build PCMEC-based soft robots able to achieve complex tasks. In this work, a new approach to manufacture PCMEC actuators with different fluid–elastomer combinations without altering the quality of the samples is proposed. The influence of the phase-change fluid and the elastomer on free elongation and bending is investigated. We demonstrate that choosing an appropriate fluid increases the actuation strain and speed, and decreases the actuation temperature compared with ethanol, allowing PCMECs to be used in close contact with the human body. Similarly, by using different elastomer materials, the actuator stiffness can be modified, and the experimental results showed that the curvature is roughly proportional to the inverse of Young’s modulus of the pure matrix. To demonstrate the potential of the optimized PCMECs, a kirigami-inspired voxel-based design approach is proposed. PCMEC cubes are molded and reinforced externally by paper. Cuts in the paper induce anisotropy into the structure. Elementary voxels deforming according to the basic kinematics (bending, torsion, elongation, compression and shear) are presented. The combination of these voxels into modular and reconfigurable structures could open new possibilities towards the design of flexible robots able to perform complex tasks.

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Section: Discussionmentioning

confidence: 99%

Optimization of Phase-Change Material–Elastomer Composite and Integration in Kirigami-Inspired Voxel-Based Actuators

et al. 2021

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“…Elastomers (Ecoflex [6][7][8][9][10][11][12][13][14][15][16], Dragon Skin [17], Sylgard 184 [18,19], other [20][21][22][23][24][25]), fabric [15,26,27], Filaflex [28], hydrogels [29], Diels-Alder polymer [30], polypropylene [31], FC72 fluid [24], ethanol [16], paper [32], urethane [27], gelatin-based biogel [33] Phase Change Material Elastomer Composite (PCMEC) Elastomers [34][35][36], phase change material (wax [35], ethanol [34])…”

Section: Fluidic Chambermentioning

confidence: 99%

“…Ze et al [74] used a custom SMP with stiffness varying between 2.4 MPa and 2.9 GPa in a similar temperature range. Finally, granular or layer jamming is another common tunable stiffness solution [12,32]. When a vacuum is applied on a granular medium or on a stack of layers (e.g., paper [32]), the friction forces between the grains/layers increase, leading to a higher stiffness.…”

Section: Stiffness Variation Transducersmentioning

confidence: 99%

“…Finally, granular or layer jamming is another common tunable stiffness solution [12,32]. When a vacuum is applied on a granular medium or on a stack of layers (e.g., paper [32]), the friction forces between the grains/layers increase, leading to a higher stiffness. This solution presents the advantage of being fast, but the stiffness change is generally more limited compared to material-based solutions [155].…”

Section: Stiffness Variation Transducersmentioning

confidence: 99%

“…As illustrated in Figure 7m, a variable stiffness layer can be added to control the actuation behaviour of a transducer and to lock it in the actuated configuration [25] (orange layer in the bottom of the schematic). A similar principle can be applied for the other basic kinematics [32]. Variable stiffness can be used to control the actuator kinematics by reducing the stiffness of a given point or segment of an actuator, which will consequently deform under the transducer action [75,159].…”

Section: Stiffness Variationmentioning

confidence: 99%

See 2 more Smart Citations

Programmable Stimuli-Responsive Actuators for Complex Motions in Soft Robotics: Concept, Design and Challenges

et al. 2020

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During the last years, great progress was made in material science in terms of concept, design and fabrication of new composite materials with conferred properties and desired functionalities. The scientific community paid particular interest to active soft materials, such as soft actuators, for their potential as transducers responding to various stimuli aiming to produce mechanical work. Inspired by this, materials engineers today are developing multidisciplinary approaches to produce new active matters, focusing on the kinematics allowed by the material itself more than on the possibilities offered by its design. Traditionally, more complex motions beyond pure elongation and bending are addressed by the robotics community. The present review targets encompassing and rationalizing a framework which will help a wider scientific audience to understand, sort and design future soft actuators and methods enabling complex motions. Special attention is devoted to recent progress in developing innovative stimulus-responsive materials and approaches for complex motion programming for soft robotics. In this context, a challenging overview of the new materials as well as their classification and comparison (performances and characteristics) are proposed. In addition, the great potential of soft transducers are outlined in terms of kinematic capabilities, illustrated by the related application. Guidelines are provided to design actuators and to integrate asymmetry enabling motions along any of the six basic degrees of freedom (translations and rotations), and strategies towards the programming of more complex motions are discussed. As a final note, a series of manufacturing methods are described and compared, from molding to 3D and 4D printing. The review ends with a Perspectives section, from material science and microrobotic points of view, on the soft materials’ future and close future challenges to be overcome.

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Current Development on Origami/Kirigami‐Inspired Structure of Creased Patterns toward Robotics

Chen

et al. 2021

Adv Eng Mater

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Origami/kirigami, the ancient art of paper folding and cutting techniques, has provided considerable inspiration for structural design routes in the engineering and medical fields over the last few decades. The practicability of the methods and concepts of origami/kirigami has been demonstrated in several emerging classes of technologies, e.g., stretchable electronics, deformable devices, self‐assembly fabrication, etc. More and more related products are produced pursuing a folding form for better storage, deformation capacity, and multifunction realization. Herein, the innovative creased patterns of origami/kirigami designs are distinguished and discussed, and the four most widely used creased pattern types are introduced, which may potentially provide origami/kirigami related inspiration and additional solutions toward many research fields.

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Controllable Stiffness Origami “Skeletons” for Lightweight and Multifunctional Artificial Muscles

Cited by 47 publications

References 34 publications

Optimization of Phase-Change Material–Elastomer Composite and Integration in Kirigami-Inspired Voxel-Based Actuators

Optimization of Phase-Change Material–Elastomer Composite and Integration in Kirigami-Inspired Voxel-Based Actuators

Programmable Stimuli-Responsive Actuators for Complex Motions in Soft Robotics: Concept, Design and Challenges

Current Development on Origami/Kirigami‐Inspired Structure of Creased Patterns toward Robotics

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