Criterion for the Design of Low-Power Variable Stiffness Mechanisms

Criterion for the Design of Low-Power Variable Stiffness Mechanisms

Designing robotic systems capable of low-power operation, inherent to their compliant actuation, has been elusive in practical application. In this paper, we propose a physical measure to mathematically define mechanical designs that are suitable to realize stiffness modulation with low power cost....

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Bibliographic Details
Published in:IEEE transactions on robotics Vol. 33; no. 4; pp. 1002 - 1010
Main Authors: Chalvet, Vincent, Braun, David J.
Format: Journal Article
Language:English
Published: New York IEEE 01-08-2017
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects:
Actuation
Actuators
Analytical design conditions
Damping
Design
Energy consumption
Force
Mechanical variables measurement
Modulation
Power consumption
Power measurement
Robotics
Robots
Stiffness
variable stiffness mechanisms
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Summary:Designing robotic systems capable of low-power operation, inherent to their compliant actuation, has been elusive in practical application. In this paper, we propose a physical measure to mathematically define mechanical designs that are suitable to realize stiffness modulation with low power cost. Using this measure, we present a mathematical formulation of an ideal variable stiffness mechanism unaffected by the external load during its operation. We then analyze several existing mechanisms from the literature to relate design features with analytical conditions inherent to low power stiffness modulation in practical designs. Through this analysis, we identify an approximate practical realization of an ideal actuator capable of stiffness modulation with inherently low power cost. Similar to a number of existing efficient variable stiffness mechanisms, this mechanism is able to hold a given stiffness setting with zero input force under no external load. However, unlike many other previously designed mechanisms, it enables infinite range stiffness modulation using finite control forces. A practical variable stiffness mechanism that is capable of infinite range stiffness modulation using finite control forces leads to lower power cost and reduced energy consumption.
ISSN:1552-3098
1941-0468
DOI:10.1109/TRO.2017.2689068