Ultragentle manipulation of delicate structures using a soft robotic gripper

Sinatra, Nina R.; Teeple, Clark B.; Vogt, Daniel M.; Parker, Kevin Kit; Gruber, David F.; Wood, Robert J.

doi:10.1126/scirobotics.aax5425

Cited by 205 publications

(109 citation statements)

References 59 publications

Supporting

Mentioning

108

Contrasting

Order By: Relevance

“…Moreover, the gripper system is shown to be stimulated using low hydraulic pressures compared with ambient (6.9-41.4 kPa) and resulting in a pull force of 0.77 N and a retraction speed of 0.050 m s À1 . [260] Galloway et al demonstrated a hydraulically stimulated soft robot for gripper application as well, as shown in Figure 17b. The grippers are monolithic structures and are coupled to a palm.…”

Section: Hydraulic Actuatorsmentioning

confidence: 98%

Soft Actuators for Soft Robotic Applications: A Review

El‐Atab

Mishra

Al‐Modaf

et al. 2020

Advanced Intelligent Systems

283

190

View full text Add to dashboard Cite

The compliant, continuum, and configurable robotics field in general has gained growing interest in the past years especially with the exciting advances in artificial intelligence technology, [1] which could enable various valuable applications ranging from manufacturing to safety and healthcare. [2,3] Soft robots are of notable interest because, unlike their rigid counterpart, they can easily deform while being mechanically resilient, [4,5] adapt to the outer environment without harm to humans, [6] and finally, enable low-cost manufacturing. [7] For robots to interact with the outer environment and complete tasks, a set of sensors and actuators need to be integrated into the system. Soft robots, in specific, present additional challenges because their sensing and actuation devices are generally highly integrated within the body of the robot and its whole functionality. These challenges become even more critical when the soft robot is scaled down to sub-centimeter size as the sensing, power, and data analysis units are moved off-board. As a result, miniaturized soft actuators that respond to various stimuli and show large deformations in addition to mechanical resilience are crucial. These would be particularly promising for application in artificial muscles, microrobots, and micro-manipulators. [8-10] Active and soft materials are promising for this task as they can be actuated through various external stimuli, such as photons, thermal, magnetic and/or electric field. Such materials range from particles, to polymers (either electroactive or shape memory), papers, fluids, shape memory alloys (SMAs), liquid metals, hydrogels, 2D materials, or a combination of these. [6-25] Nevertheless, some materials can be more suitable for a specific set of applications than others; for instance, materials stimulated by the near-infrared (NIR) spectrum are promising for biomedical applications, whereas sunlight-stimulated materials are suitable for nature-inspired soft robots used in outside environments. Various useful metrics are generally used to assess the performance of the actuators; these include the generated stress and strain, Young's modulus or measured stiffness, in addition to their power, work, energy, and force density. In this Review article, however, we focus on the application of the soft actuators in soft robotics where the reported metrics include mode and speed of actuation (or locomotion), power, voltage, current (of the driving signal), lifting force, and weight among others. In this Review article, different active materials that have been developed and used in soft actuators for soft robotics are discussed and grouped by the stimulus that generates the actuation response as shown in Figure 1. The physics of operation, resulting deformations, mechanical resilience, and their pros and cons are presented with a focus on the applications of the different soft

show abstract

Section: Hydraulic Actuatorsmentioning

confidence: 98%

Soft Actuators for Soft Robotic Applications: A Review

El‐Atab

Mishra

Al‐Modaf

et al. 2020

Advanced Intelligent Systems

283

190

View full text Add to dashboard Cite

show abstract

“…2014; Galloway et al, 2016;Laschi, 2017;Stuart et al, 2017;Mura et al, 2018;Takeuchi et al, 2018;Sinatra et al, 2019). While the non-adaptive end-effectors are most consistently utilized, they are not as suitable for nondestructive, gentle biological and archaeological tasks.…”

Section: Oceanmentioning

confidence: 99%

“…A number of hands are deployed in the ocean, from single-DOF rigid claws, such as the Schilling Titan gripper 1 , to adaptive grippers with compliant elements or underactuation (e.g., Cianchetti et al, 2011 ; Lemburg et al, 2011 ; Bemfica et al, 2014 ; Galloway et al, 2016 ; Laschi, 2017 ; Stuart et al, 2017 ; Mura et al, 2018 ; Takeuchi et al, 2018 ; Sinatra et al, 2019 ). While the non-adaptive end-effectors are most consistently utilized, they are not as suitable for nondestructive, gentle biological and archaeological tasks.…”

Section: Hands In the Fieldmentioning

confidence: 99%

Hands in the Real World

2020

View full text Add to dashboard Cite

Robots face a rapidly expanding range of potential applications beyond controlled environments, from remote exploration and search-and-rescue to household assistance and agriculture. The focus of physical interaction is typically delegated to end-effectors-fixtures, grippers or hands-as these machines perform manual tasks. Yet, effective deployment of versatile robot hands in the real world is still limited to few examples, despite decades of dedicated research. In this paper we review hands that found application in the field, aiming to discuss open challenges with more articulated designs, discussing novel trends and perspectives. We hope to encourage swift development of capable robotic hands for long-term use in varied real world settings. The first part of the paper centers around progress in artificial hand design, identifying key functions for a variety of environments. The final part focuses on the overall trends in hand mechanics, sensors and control, and how performance and resiliency are qualified for real world deployment.

show abstract

“…designed an underwater gripper driven by pressure air featuring “ultragentle” manipulation, which is shown in Figure 4(c). 27 To decrease the contact pressure, the nanofiber was used to reinforce the soft actuator, and as a result of it, the jellyfish can be grasped by the grippers. All the above grippers using silicone elastomer for its compliance and easy manufacturability.…”

Section: State-of-the-art Of the Design Of Soft Underwater Manipulatorsmentioning

confidence: 99%

“…Fluid-driven soft underwater grippers: (a) the pneumatic gripper with PA structure 25 ; (b) the hydraulic soft grippers with PA (up) and FRA (down) structure 2 ; (c) the gripper with “ultragentle” manipulation 27 ; (d) the universal soft grippers using jamming effect 29 ; and (e) a soft hydraulic gripper using hydrogel as the body material. 28 …”

Section: State-of-the-art Of the Design Of Soft Underwater Manipulatorsmentioning

confidence: 99%

For safe and compliant interaction: an outlook of soft underwater manipulators

Wang

Cui

2020

Proceedings of the Institution of Mechanical Engineers, Part M:

View full text Add to dashboard Cite

As underwater missions become more and more complex, novel underwater manipulators with better performance are demanding. Soft underwater manipulators are judged to be the development direction and expected to have better performance in safe and compliant interaction with the target in underwater operations such as biological sampling. This paper provides an overview on the state-of-the-art of both hard and soft underwater manipulators to give a prospect for soft underwater manipulators. Key technologies in the design of soft underwater manipulators are identified, including the configuration design, actuator design and stiffening design of them.

show abstract

Ultragentle manipulation of delicate structures using a soft robotic gripper

Cited by 205 publications

References 59 publications

Soft Actuators for Soft Robotic Applications: A Review

Soft Actuators for Soft Robotic Applications: A Review

Hands in the Real World

For safe and compliant interaction: an outlook of soft underwater manipulators

Contact Info

Product

Resources

About