Insect-scale fast moving and ultrarobust soft robot

Wu, Yulin; Yim, Justin K.; Liang, J. Nellie; Shao, Zhichun; Qi, Mingjing; Zhong, Junwen; Luo, Zihao; Yan, Xiangqiao; Zhang, Min; Wang, Xiaohao; Fearing, Ronald S.; Full, Robert J.; Liu, Lin

doi:10.1126/scirobotics.aax1594

Cited by 318 publications

(249 citation statements)

References 86 publications

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Section: Piezoelectric Ceramics Polymers and Compositesmentioning

confidence: 99%

Section: Piezoelectric Ceramics Polymers and Compositesmentioning

confidence: 99%

“…In 2018, Yen and Guo reported a PVDF sensor that is applied to an oscillating robotic fish to monitor pressure fluctuations as it locomotes 145. Soft robotics with complex motion profiles utilizing PVDF/Silicone multilayers have also recently been demonstrated by Wu et al146 In these robots, Pd/Au electrodes sandwich the piezoelectric PVDF film that is then mounted to a silicone/PET bilayer in order to mimic cockroach locomotion (Figure 7f). The actuators use large vibration amplitude and a bouncing gait mechanism to achieve wavelike locomotion near their resonant frequency, but only consist of soft and compliant materials to do so (Figure 7g).…”

Section: Piezoelectric Ceramics Polymers and Compositesmentioning

confidence: 99%

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Materials as Machines

2020

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of responsive materials as machines is in robotics. The vision, leadership, and research of Bar-Cohen is seminal in both invigorating and focusing current-day research activities to develop responsive materials [2] and implement [3] them as lightweight, dexterous, and gentle (e.g., soft) robotic elements. In this spirit, this review exhaustively details the materials, the nature of their stimuli-response, and discusses considerations for their implementation in robotic systems and subsystems.Robotics is a well-established but growing field of research. Sustained progress in both performance and functionality continue to be realized in commercial robotic systems largely based on conventional materials and their integration with mechanisms. A recent example is the Atlas robot from Boston Dynamics [4] (Figure 1a). The incorporation of stimuli-responsive materials in robotics has largely focused on component-level demonstrations to extend the performance of a subsystem (such as a hand or gripper).Stimuli-responsive materials, spanning nearly all classes of materials and size scales, are currently subject to widespread examination in corporate, government, and academic research laboratories (Figure 1b-d). [5][6][7] In some cases, these materials have already found widespread commercial implementation in end use and are comparatively mature. The materials and fundamentals of their responses are summarized in Figure 2. Shape memory alloys (SMAs) and ceramic piezoelectric materials are distinctive in that they are hard, stimuli-responsive materials. Deformation of these materials can produce large energy densities due to their inherent stiffness. Electroactive polymers (EAPs) remain a topic of considerable interest, particularly dielectric elastomer actuators (DEAs). Engineered systems are rapidly emerging and enabling performance gains in robotics, largely based on pneumatic or fluidic (such as HASEL [8] actuators) transport processes that localize deformation to generate force or produce motion. Soft materials, such as shape memory polymers (SMPs), hydrogels, and liquid crystalline polymer networks (LCNs) and elastomers (LCEs) may offer distinctive functional performance to robotic systems in allowing local control of deformation without the need for complex interfacing with mechanisms. As will be evident, each of these materials has inherent advantages and performance tradeoffs that must be considered in functional implementations. However, responsive material systems have a common obstacle to widespread use: the performance and Machines are systems that harness input power to extend or advance function. Fundamentally, machines are based on the integration of materials with mechanisms to accomplish tasks-such as generating motion or lifting an object. An emerging research paradigm is the design, synthesis, and integration of responsive materials within or as machines. Herein, a particular focus is the integration of responsive materials to enable robotic (machine) functions such as gripping, lifting, or motility (walk...

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Section: Piezoelectric Ceramics Polymers and Compositesmentioning

confidence: 99%

Section: Piezoelectric Ceramics Polymers and Compositesmentioning

confidence: 99%

Section: Piezoelectric Ceramics Polymers and Compositesmentioning

confidence: 99%

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Materials as Machines

2020

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“…Electromagnetic field is an excellent external source to power untethered robots and produce fast locomotion; nonetheless, it requires a preprogrammed electromagnetic stage on which the robot moves. Although the insect‐scale robot with piezoelectric actuation is major advancement with the robots being small, lightweight, fast, and robust, it remains challenging to make improvements so as to maneuver over rough surfaces, overcome hurdles, or move backward. Electrostatic actuation is an ideal candidate for lightweight and small mechanisms.…”

Section: Introductionmentioning

confidence: 99%

Tunable, Flexible, and Resilient Robots Driven by an Electrostatic Actuator

Jin

Zhang

Xü

et al. 2020

Advanced Intelligent Systems

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Robustness, deformability, maneuverability, and ease of fabrication are among the most desirable features of soft robots that can adapt to various working environments and complex terrains. Herein, polymeric thin‐film‐based flexible robots are designed, prototyped, and examined that use mechanical instability and electrostatic force actuation for locomotion. An electrostatic actuator is first developed using a buckled beam that can deform by up to 68% of its height under an applied voltage. A centimeter‐scale robotic bug is then designed that shows superb flexibility, adaptability, and maneuverability by incorporating origami structural elements. For instance, the robotic bug can be completely smashed and still recover its mobility, walk on various terrains, slopes (up to 30°) and narrow spaces, overcome hurdles, make turns, and even move backward with a crawling (linear) and turning (rotation) speed up to 40 mm s−1 and ≈45° s−1, respectively. Such remarkable characteristics are controlled by a set of parameters such as the amplitude and frequency of the input voltage and/or the origami geometries. The facile and tunable design and the actuation principle can potentially enable ample opportunities for the development of the next‐generation soft robotics.

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“…[1][2][3] Soft actuators can be driven by mechanical, [4,5] optical, [6][7][8][9] chemical, [10] magnetic, [11][12][13] and electrical [14,15] stimuli but need to be actuated with an easily accessible power source for practical applications. [1][2][3] Soft actuators can be driven by mechanical, [4,5] optical, [6][7][8][9] chemical, [10] magnetic, [11][12][13] and electrical [14,15] stimuli but need to be actuated with an easily accessible power source for practical applications.…”

mentioning

confidence: 99%

Heterogeneous Conductance‐Based Locally Shape‐Morphable Soft Electrothermal Actuator

Ahn

Jeong

Zhao

et al. 2019

Adv Materials Technologies

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appropriate for human-machine interactions and use in wearable devices, as they can handle soft materials and arbitrary shapes. [1][2][3] Soft actuators can be driven by mechanical, [4,5] optical, [6][7][8][9] chemical, [10] magnetic, [11][12][13] and electrical [14,15] stimuli but need to be actuated with an easily accessible power source for practical applications. Among them, electrical stimuli provided by electroactive and field-activated polymers such as electro-driven hydrogels [16] and ionic polymer-metal composites (IPMCs) [17] are considered to be the most suited for this purpose. However, electro-driven hydrogels can be used only in electrolyte-containing environments, and IPMCs feature a short-range working stroke. Thus, recent research has focused on electrically stimulated actuators driven by Joule heating rather than by direct electrical stimulation, as exemplified by shape memory polymers (SMPs) [18] and electrothermal actuators (ETAs). [19,20] SMPs exhibit the disadvantages of limited material and actuation shape diversity, as they are driven by two-stage discontinuous deformation of a specific polymer over its transition temperature. Therefore, ETAs, which are driven by bending due to the coefficient of thermal expansion (CTE)

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Insect-scale fast moving and ultrarobust soft robot

Cited by 318 publications

References 86 publications

Materials as Machines

Materials as Machines

Tunable, Flexible, and Resilient Robots Driven by an Electrostatic Actuator

Heterogeneous Conductance‐Based Locally Shape‐Morphable Soft Electrothermal Actuator

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