Maneuver based design of a passive-assist device for augmenting linear motion drives

Brown, Willis E.; Ulsoy, A. Galip

doi:10.1109/acc.2013.6580537

Cited by 5 publications

(1 citation statement)

References 17 publications

(15 reference statements)

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“…To increase the EOES of the robots, a variable stiffness elastic actuator (EA), realized by the variable length of linkage, has been designed by Visser and his team, 1,2 and the design theory of their mechanism has been verified with simulation and experiment. Brown has presented a passiveassist device, [3][4][5] which consisted of actuator and elastic element, and introduced the optimization method of the spring and the results of the experiments to verify that EOES of the parallel elastic actuator (PEA) is higher than other mechanisms. Mazumdar has designed a robotic joint with PEA, 6 which increased the EOES, according to the motion data of the walking robotic joint.…”

Section: Introductionmentioning

confidence: 99%

Mechanical design and energy storage efficiency research of a variable stiffness elastic actuator

Liu

Zhao

et al. 2020

International Journal of Advanced Robotic Systems

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The energy storage efficiency is an important performance of a robot or a man–machine interaction device. This article will introduce the process of design and energy storage research of a variable stiffness elastic actuator with a two-elements and one actuator mod. Firstly, the principle model will be present to analyze the operation theory. Then, the simulation and experiment model will be described to calculate the characteristics of the device. The stiffness ratio of the two springs constituting the elastic element of the device will be studied in detail, and the results can present the rule of the energy storage value. Finally, the performance of the device, the error of the experiment, and a special mechanism which presented at the extreme shape condition of the ratio will be discussed. The conclusion is that the maximum energy that the device can store is 1.415 J at the stiffness ratio equaling 0.46, and the energy storage efficiency is 1.3608 at the ratio equaling 0.45, when the weight of the device is 3.54 kg and the apparent stiffness is about 3450 N/m.

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Section: Introductionmentioning

confidence: 99%

Mechanical design and energy storage efficiency research of a variable stiffness elastic actuator

Liu

Zhao

et al. 2020

International Journal of Advanced Robotic Systems

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Robust design of Passive Assist Devices for multi-DOF robotic manipulator arms

Brown¹,

Ulsoy²

2017

Robotica

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SUMMARYA comparison of series, parallel, and dual Passive Assist Devices(PADs) designed using energy minimization based on a known maneuver is presented. Implementation of a PAD can result in an improvement in system performance with respect to efficiency, reliability, and/or utility. We introduce a new initial design using a weighted force displacement curve fit. A robust design approach for a family of maneuvers is developed and presented. Applications to a 3-link manipulator arm show that PADs could reduce energy consumption between 60% and 80%.

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A Maneuver Based Design of a Passive-Assist Device for Augmenting Active Joints

Brown¹,

Ulsoy

2013

Journal of Mechanisms and Robotics

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This paper describes a novel, general methodology for designing a parallel, passive-assist device to augment an active system using optimization based on a known maneuver of the active system. Implementation of the passive-assist device can result in an improvement in system performance with respect to efficiency, reliability, and/or utility. The methodology is demonstrated with a torsional spring designed to minimize energy consumption of a prototypical unmanned ground vehicle robot arm. Initial results indicate that this procedure can reduce maximum required torque by ~50% and energy consumed by as much as 25%. The proposed method is experimentally verified and compared to other state-of-the-art design approaches.

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Maneuver based design of a passive-assist device for augmenting linear motion drives

Cited by 5 publications

References 17 publications

Mechanical design and energy storage efficiency research of a variable stiffness elastic actuator

Mechanical design and energy storage efficiency research of a variable stiffness elastic actuator

Robust design of Passive Assist Devices for multi-DOF robotic manipulator arms

A Maneuver Based Design of a Passive-Assist Device for Augmenting Active Joints

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