Untethered soft robotic jellyfish

Cheng, Tingyu; Li, Guori; Liang, Ye; Zhang, Mingqi; Liu, Bangyuan; Wong, Tuck Whye; Forman, Jack; Chen, Mianhong 'Cherie'; Wang, Guanyun; Tao, Ye; Li, Tiefeng

doi:10.1088/1361-665x/aaed4f

Cited by 73 publications

(44 citation statements)

References 41 publications

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“…The ability to utilize the fluidic flow to achieve multiple functions and tasks is independent of the magnetic field since the incurred flow structures only rely on the interplay between the robot body and the fluid. Therefore, the above design and swimming modes may potentially be realized by current or future jellyfish-like soft robots built with other on-board or off-board actuation methods 48 such as biological muscle cells 30 , shape memory alloys 5 , hydraulic actuators 1 , dielectric elastomers 2,49 , hydrogels 50 , and liquid crystal elastomers 51 .…”

Section: Discussionmentioning

confidence: 99%

“…Inspired by ephyra, we propose an untethered jellyfish-like soft millirobot, which could realize multiple functionalities by producing diverse controlled fluidic flows around its body using its lappets, which are actuated by magnetic composite elastomer and bent by remote magnetic fields. Using this experimental setup, we study five distinct swimming modes to particularly investigate the interaction between the robot’s soft body and incurred fluidic flows due to the robot’s body motion and utilize such physical interaction for predation-inspired object manipulation capability of the robot, in addition to the robot’s swimming propulsion, which has been the only focus of previous jellyfish-like robot studies 1,2,5,30 . The proposed soft robot’s different lappet motion kinematics are used to conduct four different robotic tasks: selectively trap and transport objects of two different sizes, burrow into granular media consisting of fine beads to either camouflage or search a target object, enhance the local mixing of two different chemicals, and generate a desired concentrated chemical path.…”

Section: Introductionmentioning

confidence: 99%

“…The magnetic composite elastomer is chosen here because it can be actuated and controlled wirelessly and fast by remote magnetic fields, which have minimal effects on the fluidic flow under investigation. Existing robots, including other jellyfish-like robots 1,2,5,30 , could also complete the same tasks if they generate the same proposed lappet kinematics and local flow structures at the same length and time scale. Moreover, the proposed soft robotic platform, which has similar size and fluidic flow generating behaviors as an ephyra, could be used to study the impacts of changing their morphology and kinematics, which can happen due to pollutants, ionic changes, and temperature variation, to their survivability and habitat 24,31–34 .…”

Section: Introductionmentioning

confidence: 99%

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Multi-functional soft-bodied jellyfish-like swimming

et al. 2019

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The functionalities of the untethered miniature swimming robots significantly decrease as the robot size becomes smaller, due to limitations of feasible miniaturized on-board components. Here we propose an untethered jellyfish-inspired soft millirobot that could realize multiple functionalities in moderate Reynolds number by producing diverse controlled fluidic flows around its body using its magnetic composite elastomer lappets, which are actuated by an external oscillating magnetic field. We particularly investigate the interaction between the robot’s soft body and incurred fluidic flows due to the robot’s body motion, and utilize such physical interaction to achieve different predation-inspired object manipulation tasks. The proposed lappet kinematics can inspire other existing jellyfish-like robots to achieve similar functionalities at the same length and time scale. Moreover, the robotic platform could be used to study the impacts of the morphology and kinematics changing in ephyra jellyfish.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Multi-functional soft-bodied jellyfish-like swimming

et al. 2019

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“…Their work demonstrated the ability to effectively swim and transport cargo, but required an external field for propulsion. Recently, Cheng et al demonstrated an untethered soft robotic jellyfish that was powered by dielectric elastomer actuators (DEAs) that swam with a maximum speed of 1 cm s −1 (Cheng et al, 2019 ). While the work of Cheng et al was the first demonstration of an untethered jellyfish-inspired robot powered by DEAs, their work relies upon a prestretched membrane and hydrogel electrodes.…”

Section: Introductionmentioning

confidence: 99%

Jellyfish-Inspired Soft Robot Driven by Fluid Electrode Dielectric Organic Robotic Actuators

Christianson

Bayag

et al. 2019

Front. Robot. AI

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Robots for underwater exploration are typically comprised of rigid materials and driven by propellers or jet thrusters, which consume a significant amount of power. Large power consumption necessitates a sizeable battery, which limits the ability to design a small robot. Propellers and jet thrusters generate considerable noise and vibration, which is counterproductive when studying acoustic signals or studying timid species. Bioinspired soft robots provide an approach for underwater exploration in which the robots are comprised of compliant materials that can better adapt to uncertain environments and take advantage of design elements that have been optimized in nature. In previous work, we demonstrated that frameless DEAs could use fluid electrodes to apply a voltage to the film and that effective locomotion in an eel-inspired robot could be achieved without the need for a rigid frame. However, the robot required an off-board power supply and a non-trivial control signal to achieve propulsion. To develop an untethered soft swimming robot powered by DEAs, we drew inspiration from the jellyfish and attached a ring of frameless DEAs to an inextensible layer to generate a unimorph structure that curves toward the passive side to generate power stroke, and efficiently recovers the original configuration as the robot coasts. This swimming strategy simplified the control system and allowed us to develop a soft robot capable of untethered swimming at an average speed of 3.2 mm/s and a cost of transport of 35. This work demonstrates the feasibility of using DEAs with fluid electrodes for low power, silent operation in underwater environments.

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“…19 Example of a bimorph bending DEA with oriented carbon fibers to constrain the defor-mation along predefined directions and therefore generate different actions (courtesy from Prof. David Clarke, Harvard University, USA) However, in this case, one of the two compliant electrodes required for actuation was replaced by the surrounding (conductive) water and the control electronics was embedded on board, obtaining an untethered (i.e., fully autonomous) robot. Plastic extensions were added to increase the thrust force (Cheng et al 2019).…”

Section: Robotic Jellyfishesmentioning

confidence: 99%

Bioinspired Electromechanically Active Polymer-Based Robotics

Carpi¹,

Coppola²,

Franco³

et al. 2020

Encyclopedia of Robotics

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Electromechanically active polymers are smart materials that can be used for actuation with biomimetic properties. Overview Electromechanically Active Polymers (EAPs) are "smart materials" that exhibit a mechanical response (deformation/force) to an electrical stimulus (Bar-Cohen 2004; Carpi 2016; Carpi and Smela 2009). They are referred to as "artificial muscle materials," as they can emulate the main functional properties of natural muscles, in that they can combine biomimetic motion with selfsensing ability and variable stiffness operation. They also show additional attractive properties, such as light weight, mechanical compliance, compact size, simple structure, low power consumption, acoustically silent operation, and low cost. Among the various types of EAPs available (Carpi 2016; Carpi and Smela 2009), this chapter focuses on the special kind known as "dielectric elastomers" (DEs)

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Untethered soft robotic jellyfish

Cited by 73 publications

References 41 publications

Multi-functional soft-bodied jellyfish-like swimming

Multi-functional soft-bodied jellyfish-like swimming

Jellyfish-Inspired Soft Robot Driven by Fluid Electrode Dielectric Organic Robotic Actuators

Bioinspired Electromechanically Active Polymer-Based Robotics

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