An Easy‐to‐Implement Toolkit to Create Versatile and High‐Performance HASEL Actuators for Untethered Soft Robots

Mitchell, Shane K.; Wang, Xingrui; Acome, Eric; Martin, Trent; Ly, Khoi; Kellaris, Nicholas; Venkata, Vidyacharan Gopaluni; Keplinger, Christoph

doi:10.1002/advs.201900178

Cited by 138 publications

(176 citation statements)

References 55 publications

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“…Soft robots, distinguished from the conventional robotics, not only show the robotic features for complete targeted tasks, but also offer intrinsic adaptability and reconfigurability to their surroundings for easier actuation and function . LM, either in the form of droplet or in the form of doping materials, can serve as the key component for the actuation of the soft‐robotic machines via energy conversion processes that transform various kinds of energy, such as magnetic energy, electric energy, thermal energy, light energy and chemical energy to the kinetic energy .…”

Section: Applications Of Liquid Metal–based Microfluidic Systemsmentioning

confidence: 99%

Liquid Metal–Based Soft Microfluidics

Zhu

Wang

Handschuh‐Wang

et al. 2019

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159

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Motivated by the increasing demand of wearable and soft electronics, liquid metal (LM)‐based microfluidics has been subjected to tremendous development in the past decade, especially in electronics, robotics, and related fields, due to the unique advantages of LMs that combines the conductivity and deformability all‐in‐one. LMs can be integrated as the core component into microfluidic systems in the form of either droplets/marbles or composites embedded by polymer materials with isotropic and anisotropic distribution. The LM microfluidic systems are found to have broad applications in deformable antennas, soft diodes, biomedical sensing chips, transient circuits, mechanically adaptive materials, etc. Herein, the recent progress in the development of LM‐based microfluidics and their potential applications are summarized. The current challenges toward industrial applications and future research orientation of this field are also summarized and discussed.

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Section: Applications Of Liquid Metal–based Microfluidic Systemsmentioning

confidence: 99%

Liquid Metal–Based Soft Microfluidics

Zhu

Wang

Handschuh‐Wang

et al. 2019

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159

122

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“…The load–strain curves of four‐unit actuators based on rectangular and notched electrodes show that notched electrodes are advantageous compared to rectangular electrodes in the low‐load region (Figure d). The screen‐printed carbon electrodes are easier to fabricate and help the actuators achieve larger strains because they reduce the bending stiffness of the shell–electrode bilayer compared to hydrogel electrodes with inextensible BOPP backing. Thus, the screen‐printed electrodes facilitate buckling in the transition zones between the zipping and contracting regions.…”

Section: Resultsmentioning

confidence: 99%

“…Recently developed hydraulically amplified self‐healing electrostatic (HASEL) actuators combine the speed and self‐sensing ability of DEAs and the versatility of PAMs while avoiding important drawbacks by utilizing an electrohydraulic principle to locally displace a hydraulic fluid and by being able to self‐heal from electric damage . Additionally, their combination of speed, efficiency, and versatility makes them promising candidates for use in untethered systems …”

Section: Introductionmentioning

confidence: 99%

High‐Strain Peano‐HASEL Actuators

Wang

Mitchell

Rumley

et al. 2019

Adv Funct Materials

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Soft robots are intrinsically safe for use near humans and adaptable when operated in unstructured environments, thereby offering capabilities beyond traditional robots based on rigid components. Soft actuators are key components of soft robots; recently developed hydraulically amplified self‐healing electrostatic (HASEL) actuators provide a versatile framework to create high‐speed actuators with excellent all‐around performance. Peano‐HASEL actuators linearly contract upon application of voltage, closely mimicking the behavior of muscle. Peano‐HASEL actuators, however, produce a maximum strain of ≈15%, while skeletal muscles achieve ≈20% on average. Here, a new type of HASEL is introduced, termed high‐strain Peano‐HASEL (HS‐Peano‐HASEL) actuator, that achieves linear contraction up to ≈24%. A wide range of performance metrics are investigated, and the maximum strain of multiunit HS‐Peano‐HASEL actuators is optimized by varying materials and geometry. Furthermore, an artificial circular muscle (ACM) based on the HS‐Peano‐HASEL acts as a tubular pump, resembling the primordial heart of an ascidian. Additionally, a strain‐amplifying pulley system is introduced to increase the maximum strain of an HS‐Peano‐HASEL to 42%. The muscle‐like maximum actuation strain and excellent demonstrated all‐around performance of HS‐Peano‐HASEL actuators make them promising candidates for use in artificial organs, life‐like robotic faces, and a variety of other robotic systems.

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“…We believe that many types of electrohydraulic soft actuators exhibit an inertial and a viscous dynamic regime. Several types of electrohydraulic actuators exist whose shells consist of thin, inextensible films (12,35,36). For these actuators, the presented scaling analysis may readily be modified to identify the governing timescales to account for differences in geometry (12,35) and modes of electrohydraulic zipping (35,36).…”

Section: Discussionmentioning

confidence: 99%

Dynamics of electrohydraulic soft actuators

Rothemund

Kirkman

Keplinger

2020

Proc. Natl. Acad. Sci. U.S.A.

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Nature has inspired the design of robots in which soft actuators enable tasks such as handling of fragile objects and adapting to unstructured environments. Those tasks are difficult for traditional robots, which predominantly consist of hard components. Electrohydraulic soft actuators are liquid-filled shells that deform upon the application of electric fields; they excel among soft actuators with muscle-like force outputs and actuation strains, and with actuation frequencies above 100 Hz. However, the fundamental physics that governs the dynamics of electrohydraulic soft actuators is unexplored. Here, we study the dynamics of electrohydraulic soft actuators using the Peano-HASEL (hydraulically amplified self-healing electrostatic) actuator as a model system. Using experiments and a scaling analysis, we discover two dynamic regimes: a regime in which viscous dissipation reduces the actuation speed and a regime governed by inertial effects in which high-speed actuation is possible. For each regime, we derive a timescale that describes the influence of geometry, materials system, and applied external loads on the actuation speed. We also derive a model to study the dynamic behavior of Peano-HASEL actuators in both regimes. Although this analysis focuses on the Peano-HASEL actuator, the presented results may readily be generalized to other electrohydraulic actuators. When designed to operate in the inertial regime, electrohydraulic actuators will enable bio-inspired robots with unprecedented speeds of motion.

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An Easy‐to‐Implement Toolkit to Create Versatile and High‐Performance HASEL Actuators for Untethered Soft Robots

Cited by 138 publications

References 55 publications

Liquid Metal–Based Soft Microfluidics

Liquid Metal–Based Soft Microfluidics

High‐Strain Peano‐HASEL Actuators

Dynamics of electrohydraulic soft actuators

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