Pneumatic Networks for Soft Robotics that Actuate Rapidly

Mosadegh, Bobak; Polygerinos, Panagiotis; Keplinger, Christoph; Wennstedt, Sophia W; Shepherd, Robert F.; Gupta, Unmukt; Shim, Jongmin; Bertoldi, Katia; Walsh, Conor J.; Whitesides, George M.

doi:10.1002/adfm.201303288

Cited by 1,196 publications

(778 citation statements)

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“…[1][2][3][4][5][6][7][8] They also offer an attractive approach to simplifying control, [5][6][7][8] since they make it possible-in some circumstances-to substitute the properties of soft materials and structures for some of the control loops, sensors, and actuators of hard machines (machines fabricated in metals, ceramics, and structural polymers). [9,10] The simplification of control is important in the field of robotics as a potential strategy for designing robots that work in unstructured environments.…”

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confidence: 99%

Buckling Pneumatic Linear Actuators Inspired by Muscle

Yang

Verma

et al. 2016

Adv Materials Technologies

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The mechanical features of biological muscles are difficult to reproduce completely in synthetic systems. A new class of soft pneumatic structures (vacuum‐actuated muscle‐inspired pneumatic structures) is described that combines actuation by negative pressure (vacuum), with cooperative buckling of beams fabricated in a slab of elastomer, to achieve motion and demonstrate many features that are similar to that of mammalian muscle.

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confidence: 99%

Buckling Pneumatic Linear Actuators Inspired by Muscle

Yang

Verma

et al. 2016

Adv Materials Technologies

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“…one channel actuation at increasing pressure. 16 Inspired by the formability of dragonskin scales, the concept also been used in architecture given the high formability of dragon skin designs (Figure 6(a)), a three-pneumatic channel module was designed made from Ecoflex 0050, with a corrugated sheet of the harder Dragonskin 0030, and the corrugated sheet gaps were filled the soft Ecoflex 0030, as is presented in the CAD model of Figure 6(b). FEA of one-channel actuation to 90 o bending in Figure 6(b) shows minimum ballooning for the innovative design.…”

Section: Designs and Resultsmentioning

confidence: 99%

“…[15] Ingenious designs of pneumatic networks can bring intelligent actuation patterns and create coordinated system motion or deformation. [16] On the other hand individual pneumatic chambers can create bending modes in different directions via mechanisms of chamber elongation or ballooning effect. Figure 1 displays a soft cylindrical module with three pneumatic chambers which upon individual pneumatic actuation offer bending in three directions.…”

Section: Introductionmentioning

confidence: 99%

Skins and Sleeves for Soft Robotics: Inspiration from Nature and Architecture

et al. 2015

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This paper is on the design, fabrication and testing of skins and sleeves for soft robotics with the focus on the mechanical features of the microstructure of these skins, drawing inspiration from nature and architecture. Biological inspirations drawn from animals are used for designing skin membranes or skin structures for soft robotic actuators, in particular pneumatic actuators, that protect, guide and contribute to the development of the actuated shape. The results presented in this paper will be a new step towards advancing the state-of-the-art of biologically inspired soft robots for minimally invasive surgery. Inspirations from architecture are of particular interest in the areas of formability of design and continuous flow. The report presents a trade-off study using various skin and sleeve technologies of innovative fiber structures and combinations of different materials in different innovative designs, surrounding a pneumatically actuated, soft robot of variable stiffness.3

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“…[4,5] The first generation of these systems-originally sketched by Suzumori, [6][7][8] and then realized and elaborated by us, [5,[9][10][11][12][13] and by others [4] -use pneumatic actuators, comprising networks of micro-channels; in our systems, differential expansion of these pneumatic networks (PneuNets) by pressurization using air produces motions (especially bending, curling, and variants on them) that are already established as useful in grippers, and interesting for their potential in walkers, tentacles, and a number of other soft, actuated systems. [14] 4 Although the design of the first of these systems has been relatively simple, the motion they produce on actuation can be surprisingly sophisticated: for example, a representative structure-the "finger" or "tentacle" of a gripper-curls non-uniformly, starting from its tip and proceeding to its stem, although the pressure applied in the PneuNet is approximately uniform throughout the system of inflatable channels.…”

Section: Motionmentioning

confidence: 99%

Buckling of Elastomeric Beams Enables Actuation of Soft Machines

et al. 2015

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Motion 3Historically, many machines (especially robots) were designed to mimic the motions of humans and other animals, but to add power, speed, "endurance," and reproducibility to those motions. [1] The robots on industrial assembly lines, for example, extend the capabilities of the workers that originally carried out assembly by hand using simple tools, by adding power, complex tools, indifference to environmental conditions, and mechanical "endurance". Similarly, four-wheeled robots are loosely derived from fourlimbed animals, and aerial drones can be traced in design backwards in time through manned aircraft, to birds. Conventional machines-especially those fabricated from metal, ceramics, and structural polymers (so-called "hard" machines)-can carry out almost arbitrarily complex motions using pulleys, cables, gears, and electric or hydraulic actuators. To achieve controlled motion, however, they also normally require complex systems for active controls (networks of sensors, actuators, and feedback controllers). [2,3] Some of these "hard" systems are exquisitely and highly developed, but can be heavy, energy inefficient, dangerous to humans, and expensive.We are exploring soft actuators and robots-machines modeled after simpler animals (e.g., starfish, worms, and squid) having no hard internal or external structures, and fabricated entirely or predominantly in soft, compliant polymers. [4,5] The first generation of these systems-originally sketched by Suzumori, [6][7][8] and then realized and elaborated by us, [5,[9][10][11][12][13] and by others [4] -use pneumatic actuators, comprising networks of micro-channels; in our systems, differential expansion of these pneumatic networks (PneuNets) by pressurization using air produces motions (especially bending, curling, and variants on them) that are already established as useful in grippers, and interesting for their potential in walkers, tentacles, and a number of other soft, actuated systems. [14] 4 Although the design of the first of these systems has been relatively simple, the motion they produce on actuation can be surprisingly sophisticated: for example, a representative structure-the "finger" or "tentacle" of a gripper-curls non-uniformly, starting from its tip and proceeding to its stem, although the pressure applied in the PneuNet is approximately uniform throughout the system of inflatable channels. [10,11] This motion reflects a non-linear property of soft materials and structures, referred to as a "snapthrough instability". [15][16][17][18][19] Although nonlinear properties of materials are often considered a disadvantage, this type of non-linearity, illustrated by snap-through, and other complex mechanical characteristics of soft systems, are proving to be useful, and to offer new capabilities to effectors, machines, and robots, because they enable a range of motions of sufficient complexity that-although they might be possible to replicate in a hard robotic system [20] -it would be complicated and expensive to do so. This paper demonstrates the ut...

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Pneumatic Networks for Soft Robotics that Actuate Rapidly

Cited by 1,196 publications

References 24 publications

Buckling Pneumatic Linear Actuators Inspired by Muscle

Buckling Pneumatic Linear Actuators Inspired by Muscle

Skins and Sleeves for Soft Robotics: Inspiration from Nature and Architecture

Buckling of Elastomeric Beams Enables Actuation of Soft Machines

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