Continuous wave peristaltic motion in a robot

Boxerbaum, Alexander S.; Shaw, Kendrick M.; Chiel, Hillel J.; Quinn, Roger D.

doi:10.1177/0278364911432486

Cited by 153 publications

(86 citation statements)

References 32 publications

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“…Compliant motor-driven transmissions generally fall into the categories of cable-driven tendons or series elastic actuators (SEAs). Although complex systems such as [16] and [17] have successfully used cable tendon methods, the design and fabrication of cable-driven systems remains highly complex. Since cables require tension, these tendon systems require significant infrastructure, such as rigid pulleys, sheathing, and spindles [18].…”

Section: Introductionmentioning

confidence: 99%

Compliant electric actuators based on handed shearing auxetics

Chin

Lipton

MacCurdy

et al. 2018

2018 IEEE International Conference on Soft Robotics (RoboSoft)

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Abstract-In this paper, we explore a new class of electric motor-driven compliant actuators based on handed shearing auxetic cylinders. This technique combines the benefits of compliant bodies from soft robotic actuators with the simplicity of direct coupling to electric motors. We demonstrate the effectiveness of this technique by creating linear actuators, a four degree-of-freedom robotic platform, and a soft robotic gripper. We compare the soft robotic gripper against a state of the art pneumatic soft gripper, finding similar grasping performance in a significantly smaller and more energy-efficient package.

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Section: Introductionmentioning

confidence: 99%

Compliant electric actuators based on handed shearing auxetics

Chin

Lipton

MacCurdy

et al. 2018

2018 IEEE International Conference on Soft Robotics (RoboSoft)

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“…dustrial pipeline networks often contain large amounts of oil and grease traces; it is these plications where wall-pressing systems such as these excel due to their low contact area end ectors. Case Western Reserve University have developed a new method of in-pipe robotic omotion using continuous-wave peristalsis, the same mechanism employed by earthworms [35]. e robot, named CMMWorm, is composed of many interlinked joints forming a mesh like structure at can deform in the presence of an environmental change.…”

Section: Discussionmentioning

confidence: 99%

Advances in the Inspection of Unpiggable Pipelines

2017

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Abstract:The field of in-pipe robotics covers a vast and varied number of approaches to the inspection of pipelines with robots specialising in pipes ranging anywhere from 10 mm to 1200 mm in diameter. Many of these developed systems focus on overcoming in-pipe obstacles such as T-sections and elbows, as a result important aspects of exploration are treated as sub-systems, namely shape adaptability. One of the most prevalent methods of hybridised locomotion today is wall-pressing; generating traction using the encompassing pipe walls. A review of wall-pressing systems has been performed, covering the different approaches taken since their introduction. The advantages and disadvantages of these systems is discussed as well as their effectiveness in the inspection of networks with highly varying pipe diameters. When compared to unconventional in-pipe robotic techniques, traditional full-bore wall-pressing robots were found to be at a disadvantage.

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“…In this manner, a contraction of the cells will cause motion in a single forward direction.. To achieve this, a small metallic bristle was added to the end caps of the cells, all aligned in one direction when the cells are assembled end-to-end. This bristle provides an anisotropic frictional contact with the ground [27], allowing the group to inch forward in a peristalsis-like locomotion [28] thus the entire motion occurs in the direction allowed by the bristle. Overall, this setup causes the group of four cells to contract and relax, all in one direction because of their aligned bristles in contact with the ground (made of a rough foam to increase friction).…”

Section: Experimental Implementation Of Groups Of Cellsmentioning

confidence: 99%

Simple, scalable active cells for articulated robot structures

Swensen

Nawroj

Pounds

et al. 2014

2014 IEEE International Conference on Robotics and Automation (ICRA)

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The proposed research effort explores the development of active cells -simple contractile electromechanical units that can be used as the material basis for larger articulable structures. Each cell, which might be considered a "muscle unit", consists of a contractile Nitinol SMA core with conductive terminals. Large numbers of these cells might be combined and externally powered to change phase, contracting to either articulate with a large strain or increase the stiffness of the ensemble, depending on the cell design. Unlike traditional work in modular robotics, the approach presented here focuses on cells that have a simplistic design and function, are inexpensive to fabricate, and are eventually scalable to sub-millimeter sizes, working towards our vision of robot structures that can be custom-fabricated from large numbers of general cell units, similar to biological structures.

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Continuous wave peristaltic motion in a robot

Cited by 153 publications

References 32 publications

Compliant electric actuators based on handed shearing auxetics

Compliant electric actuators based on handed shearing auxetics

Advances in the Inspection of Unpiggable Pipelines

Simple, scalable active cells for articulated robot structures

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