Design of a Stirling Thermocompressor for a Pneumatically Actuated Ankle-Foot Orthosis

Authors :: Nithin S. Kumar
Eric J. Barth
Mark E. Hofacker
Source :: Volume 1: Aerial Vehicles; Aerospace Control; Alternative Energy; Automotive Control Systems; Battery Systems; Beams and Flexible Structures; Biologically-Inspired Control and its Applications; Bio-Medical and Bio-Mechanical Systems; Biomedical Robots and Rehab; Bipeds and Locomotion; Control Design Methods for Adv. Powertrain Systems and Components; Control of Adv. Combustion Engines, Building Energy Systems, Mechanical Systems; Control, Monitoring, and Energy Harvesting of Vibratory Systems.
Publication Year :: 2013
Publisher :: American Society of Mechanical Engineers, 2013.
Abstract: This paper presents the design, modeling, and simulated performance of a prototype Stirling thermocompressor. The thermocompressor is intended to be mounted on the back of a user’s lower leg and convert a hydrocarbon fuel source into 50 W of pneumatic power at 650 kPa to power an ankle foot orthosis. Consisting only of a displacer piston, the Stirling thermocompressor’s displacer piston motion is directly controlled by a brushless DC motor so that the frequency of operation can be tuned to output the maximum power. Simulation indicates that this operating frequency is influenced by the intended reservoir pressure and heat transfer properties of the thermocompressor.Copyright © 2013 by ASME

Subjects :: Engineering
medicine.medical_specialty
Stirling engine
Maximum power principle
business.industry
Electrical engineering
Mechanical engineering
Orthotics
DC motor
Power (physics)
law.invention
Piston
law
Ankle/foot orthosis
Reservoir pressure
medicine
business

Database :: OpenAIRE
Journal :: Volume 1: Aerial Vehicles; Aerospace Control; Alternative Energy; Automotive Control Systems; Battery Systems; Beams and Flexible Structures; Biologically-Inspired Control and its Applications; Bio-Medical and Bio-Mechanical Systems; Biomedical Robots and Rehab; Bipeds and Locomotion; Control Design Methods for Adv. Powertrain Systems and Components; Control of Adv. Combustion Engines, Building Energy Systems, Mechanical Systems; Control, Monitoring, and Energy Harvesting of Vibratory Systems
Accession number :: edsair.doi...........731a2b2d2c0eb86b3deac6d824c3c7a7
Full Text :: https://doi.org/10.1115/dscc2013-3995

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