3D-printed programmable tensegrity for soft robotics

Lee, Hajun; Jang, Yeonwoo; Choe, Jun Kyu; Lee, Suwoo; Song, Hyeonseo; Lee, Jin Pyo; Lone, Nasreena; Kim, Jiyun

doi:10.1126/scirobotics.aay9024

Cited by 137 publications

(100 citation statements)

References 73 publications

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“…Moreover, direct 3D printing of PAMs (similarly to other soft actuators) is becoming a feasible option, when carefully tuning the printing parameters for soft materials [14]. Indeed, such 3D printing technology enables programmable multidimensional actuations that feature complex architectures and tunable stiffness by using multi-materials [15][16][17]. Nevertheless, main challenges are still to be met, such as large pulling force, deformation, and fast response [18,19].…”

Section: Introductionmentioning

confidence: 99%

Development of the Ultralight Hybrid Pneumatic Artificial Muscle: Modelling and optimization

et al. 2021

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Pneumatic artificial muscles (PAMs) are one of the key technologies in soft robotics, and they enable actuation in mobile robots, in wearable devices and exoskeletons for assistive and rehabilitative purposes. While they recently showed relevant improvements, they still present quite low payload, limited bandwidth, and lack of repeatability, controllability and robustness. Vacuum-based actuation has been recently demonstrated as a very promising solution, and many challenges are still open, like generating at the same time a large contraction ratio, and a high blocking force with enhanced axial stiffness. In this paper, a novel Ultralight Hybrid PAM (UH-PAM), based on bellow-type elastomeric skin and vacuum actuation, is presented. In particular, open-cell foam is exploited as a structural backbone, together with plastic rings, all embedded in a thin skin. The design and optimization combine numerical, analytical, and experimental data. Both static and dynamic analysis are performed. The weight of the optimized actuator is only 20 g. Nevertheless, a contraction ratio up to 50% and a maximum payload of 3 kg can be achieved. From a dynamic point of view, a rise time of 0.5 s for the contraction phase is observed. Although hysteresis is significant when using the whole contraction span, it can be reduced (down to 11.5%) by tuning both the vacuum range and the operating frequency for cyclic movements. Finally, to demonstrate the potentiality of this soft actuation approach, a 3 DoFs Stewart platform is built. The feasibility of performing smooth movements by exploiting open-loop control is shown through simple and more complex handwriting figures projected on the XY plane.

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Section: Introductionmentioning

confidence: 99%

Development of the Ultralight Hybrid Pneumatic Artificial Muscle: Modelling and optimization

et al. 2021

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“…The various stages of snap‐through are shown in Figure 3J and in Video S5, Supporting Information. Such snap‐through properties have been identified to be important for soft‐robotics applications, [ 27 ] and this study shows for the first time that MEW‐fabricated products can demonstrate this property and is due to the increased layers. Compressing such MEW tubes end‐on‐end results in a collapsible material with either recovering or lockable positions, depending on the extent of compression (Video S5, Supporting Information).…”

Section: Resultsmentioning

confidence: 64%

Convergence of Machine Vision and Melt Electrowriting

et al. 2021

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Melt electrowriting (MEW) is a high‐resolution additive manufacturing technology that balances multiple parametric variables to arrive at a stable fabrication process. The better understanding of this balance is underscored here using high‐resolution camera vision of jet stability profiles in different electrical fields. Complementing this visual information are fiber‐diameter measurements obtained at precise points, allowing the correlation to electrified jet properties. Two process signatures—the jet angle and for the first time, the Taylor cone area—are monitored and analyzed with a machine vision system, while SEM imaging for diameter measurement correlates real‐time information. This information, in turn, allows the detection and correction of fiber pulsing for accurate jet placement on the collector, and the in‐process assessment of the fiber diameter. Improved process control is used to successfully fabricate collapsible MEW tubes; structures that require exceptional accuracy and printing stability. Using a precise winding angle of 60° and 300 layers, the resulting 12 mm‐thick tubular structures have elastic snap‐through instabilities associated with mechanical metamaterials. This study provides a detailed analysis of the fiber pulsing occurrence in MEW and highlights the importance of real‐time monitoring of the Taylor cone volume to better understand, control, and predict printing instabilities.

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“…Trade‐offs between the actuation/shape adaptivity, stiffness tuning, and sensing capability are unavoidable. Recently, thanks to the progress of 3D printing technology in the processing of soft polymer materials, [ 193–195 ] researchers have explored design and manufacturing methods for achieving synchronized motility and multisensory perception in a compact soft robot. [ 196 ] In the future, soft robotic manipulators should make up a monolithically integrated complex at the system level. 3)Sensing and proprioception: Embedding or integrating distributed sensing in soft robotic manipulators will improve the ability of soft robotic manipulators to perceive their environment and closed‐loop control.…”

Section: Summary and Future Prospectsmentioning

confidence: 99%

Soft Robotic Manipulators: Designs, Actuation, Stiffness Tuning, and Sensing

Dou

Zhong

Cao

et al. 2021

Adv Materials Technologies

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Soft robotic manipulators are continuum robots made of soft materials and flexible components. The goal of soft robotic manipulators research is to enable these manipulators to adapt their shapes to cluttered environments and to have safer interactions with human. However, there is still a problem with effectively using soft robotic manipulators in practical applications. The challenges of soft robotic manipulators in terms of materials and structure design, stiffness control, perception, and function control remain to be overcome. Here, an overview of recent advances in this field is presented, covering device architectures, actuation, variable stiffness, and sensing. Actuator technologies are discussed and roughly divided into three categories: a) tendon‐driven actuation, b) fluidic actuation, and c) stimuli‐responsive actuation, which is based on smart materials. Considering the working principle of stiffness variation technologies, stiffness variation technologies can be divided into two categories: a) using the interactions between structural elements, b) direct material rigidity tuning strategies. A briefly review of soft sensing technologies is presented. From the functional perspective, sensor technologies are divide into two categories: proprioception and exteroception. A conception for designing soft robotic manipulators is proposed from the perspective of soft robotic manipulator applications. Finally, the challenges this field faces are discussed.

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3D-printed programmable tensegrity for soft robotics

Cited by 137 publications

References 73 publications

Development of the Ultralight Hybrid Pneumatic Artificial Muscle: Modelling and optimization

Development of the Ultralight Hybrid Pneumatic Artificial Muscle: Modelling and optimization

Convergence of Machine Vision and Melt Electrowriting

Soft Robotic Manipulators: Designs, Actuation, Stiffness Tuning, and Sensing

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