Lower-limb biomechatronic devices (i.e., prostheses and exoskeletons) depend upon onboard batteries to power wearable sensors, actuators, and microprocessors, therein inherently limiting their operating durations. Regenerative braking, also termed electrical energy regeneration, represents a promising solution to the aforementioned shortcomings. Regenerative braking converts the otherwise dissipated mechanical energy during locomotion into electrical energy for recharging the onboard batteries, while simultaneously providing negative mechanical work for controlled system deceleration. This paper reviewed the electromechanical design and optimization of lower-limb biomechatronic devices with electrical energy regeneration. The technical review starts by examining human walking biomechanics (i.e., mechanical work, power, and torque about the hip, knee, and ankle joints) and proposes general design principles for regenerative braking prostheses and exoskeletons. Analogous to electric and hybrid electric vehicle powertrains, there are numerous mechatronic design components that could be optimized to maximize electrical energy regeneration, including the mechanical power transmission, electromagnetic machine, electrical drive, device mass and moment of inertia, and energy storage devices. Design optimization of these system components is individually discussed while referencing the latest advancements in robotics and automotive engineering. The technical review demonstrated that existing systems (1) are limited to level-ground walking applications and (2) have maximum energy regeneration efficiencies between 30% and 37%. Accordingly, potential future directions for research and innovation include (1) regenerative braking during dynamic movements like sitting down and slope and staircase descent and (2) utilizing high-torque-density electromagnetic machines and low-impedance mechanical power transmissions to maximize energy regeneration efficiencies.
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August 2019
Review Articles
Lower-Limb Prostheses and Exoskeletons With Energy Regeneration: Mechatronic Design and Optimization Review
Brock Laschowski,
Brock Laschowski
1
Institute of Biomaterials and Biomedical Engineering,
Toronto, ON,
e-mail: brock.laschowski@mail.utoronto.ca
University of Toronto
,Toronto, ON,
Canada
M5S 3G9e-mail: brock.laschowski@mail.utoronto.ca
1Corresponding author.
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John McPhee,
John McPhee
Fellow ASME
Department of Systems Design Engineering,
Waterloo, ON,
e-mail: mcphee@uwaterloo.ca
Department of Systems Design Engineering,
University of Waterloo
,Waterloo, ON,
Canada
N2L 3G1e-mail: mcphee@uwaterloo.ca
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Jan Andrysek
Jan Andrysek
Mem. ASME
Bloorview Research Institute,
Toronto, ON,
e-mail: jandrysek@hollandbloorview.ca
Bloorview Research Institute,
Holland Bloorview Kids Rehabilitation Hospital
,Toronto, ON,
Canada
M4G1R8e-mail: jandrysek@hollandbloorview.ca
Search for other works by this author on:
Brock Laschowski
Institute of Biomaterials and Biomedical Engineering,
Toronto, ON,
e-mail: brock.laschowski@mail.utoronto.ca
University of Toronto
,Toronto, ON,
Canada
M5S 3G9e-mail: brock.laschowski@mail.utoronto.ca
John McPhee
Fellow ASME
Department of Systems Design Engineering,
Waterloo, ON,
e-mail: mcphee@uwaterloo.ca
Department of Systems Design Engineering,
University of Waterloo
,Waterloo, ON,
Canada
N2L 3G1e-mail: mcphee@uwaterloo.ca
Jan Andrysek
Mem. ASME
Bloorview Research Institute,
Toronto, ON,
e-mail: jandrysek@hollandbloorview.ca
Bloorview Research Institute,
Holland Bloorview Kids Rehabilitation Hospital
,Toronto, ON,
Canada
M4G1R8e-mail: jandrysek@hollandbloorview.ca
1Corresponding author.
Contributed by the Mechanisms and Robotics Committee of ASME for publication in the Journal of Mechanisms and Robotics. Manuscript received June 1, 2018; final manuscript received March 29, 2019; published online May 17, 2019. Assoc. Editor: Clement Gosselin.
J. Mechanisms Robotics. Aug 2019, 11(4): 040801 (8 pages)
Published Online: May 17, 2019
Article history
Received:
June 1, 2018
Revision Received:
March 29, 2019
Accepted:
April 3, 2019
Citation
Laschowski, B., McPhee, J., and Andrysek, J. (May 17, 2019). "Lower-Limb Prostheses and Exoskeletons With Energy Regeneration: Mechatronic Design and Optimization Review." ASME. J. Mechanisms Robotics. August 2019; 11(4): 040801. https://doi.org/10.1115/1.4043460
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