Magnetic levitation-based electromagnetic energy harvesting: a semi-analytical non-linear model for energy transduction

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Abstract

Magnetic levitation has been used to implement low-cost and maintenance-free electromagnetic energy harvesting. The ability of levitation-based harvesting systems to operate autonomously for long periods of time makes them well-suited for self-powering a broad range of technologies. In this paper, a combined theoretical and experimental study is presented of a harvester configuration that utilizes the motion of a levitated hard-magnetic element to generate electrical power. A semi-analytical, non-linear model is introduced that enables accurate and efficient analysis of energy transduction. The model predicts the transient and steady-state response of the harvester a function of its motion (amplitude and frequency) and load impedance. Very good agreement is obtained between simulation and experiment with energy errors lower than 14.15% (mean absolute percentage error of 6.02%) and cross-correlations higher than 86%. The model provides unique insight into fundamental mechanisms of energy transduction and enables the geometric optimization of harvesters prior to fabrication and the rational design of intelligent energy harvesters.

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Wearable medical systems for p-Health.

Yuan Zhang, Paolo Bonato, Fei Teng … (2007)

Driven by the growing aging population, prevalence of chronic diseases, and continuously rising healthcare costs, the healthcare system is undergoing a fundamental transformation, from the conventional hospital-centered system to an individual-centered system. Current and emerging developments in wearable medical systems will have a radical impact on this paradigm shift. Advances in wearable medical systems will enable the accessibility and affordability of healthcare, so that physiological conditions can be monitored not only at sporadic snapshots but also continuously for extended periods of time, making early disease detection and timely response to health threats possible. This paper reviews recent developments in the area of wearable medical systems for p-Health. Enabling technologies for continuous and noninvasive measurements of vital signs and biochemical variables, advances in intelligent biomedical clothing and body area networks, approaches for motion artifact reduction, strategies for wearable energy harvesting, and the establishment of standard protocols for the evaluation of wearable medical devices are presented in this paper with examples of clinical applications of these technologies.

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Instrumented hip implants: electric supply systems.

Marco Soares dos Santos, Jorge A. F. Ferreira, A. Ramos … (2013)

Instrumented hip implants were proposed as a method to monitor and predict the biomechanical and thermal environment surrounding such implants. Nowadays, they are being developed as active implants with the ability to prevent failures by loosening. The generation of electric energy to power active mechanisms of instrumented hip implants remains a question. Instrumented implants cannot be implemented without effective electric power systems. This paper surveys the power supply systems of seventeen implant architectures already implanted in-vivo, namely from instrumented hip joint replacements and instrumented fracture stabilizers. Only inductive power links and batteries were used in-vivo to power the implants. The energy harvesting systems, which were already designed to power instrumented hip implants, were also analyzed focusing their potential to overcome the disadvantages of both inductive-based and battery-based power supply systems. From comparative and critical analyses of the methods to power instrumented implants, one can conclude that: inductive powering and batteries constrain the full operation of instrumented implants; motion-driven electromagnetic energy harvesting is a promising method to power instrumented passive and active hip implants.

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Instrumented hip joint replacements, femoral replacements and femoral fracture stabilizers.

Marco Soares dos Santos, Jorge A. F. Ferreira, António Ramos … (2014)

This paper reviews instrumented hip joint replacements, instrumented femoral replacements and instrumented femoral fracture stabilizers. Examination of the evolution of such implants was carried out, including the detailed analysis of 16 architectures, designed by 8 research teams and implanted in 32 patients. Their power supply, measurement, communication, processing and actuation systems were reviewed, as were the tests carried out to evaluate their performance and safety. These instrumented implants were only designed to measure biomechanical and thermodynamic quantities in vivo, in order to use such data to conduct research projects and optimize rehabilitation processes. The most promising trend is to minimize aseptic loosening and/or infection following hip or femoral replacements or femoral stabilization procedures by using therapeutic actuators inside instrumented implants to apply controlled stimuli in the bone-implant interface.

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Author and article information

Journal

Journal ID (nlm-ta): Sci Rep

Journal ID (iso-abbrev): Sci Rep

Title: Scientific Reports

Publisher: Nature Publishing Group

ISSN (Electronic): 2045-2322

Publication date (Electronic): 04 January 2016

Publication date Collection: 2016

Volume: 6

Electronic Location Identifier: 18579

Affiliations

[1 ]Centre for Mechanical Technology & Automation, TEMA, University of Aveiro , 3810-193 Aveiro, Portugal

[2 ]Department of Mechanical Engineering, University of Aveiro , 3810-193 Aveiro, Portugal

[3 ]Institute of Electronics and Informatics Engineering of Aveiro, IEETA , 3810-193 Aveiro, Portugal

[4 ]Department of Chemical and Biological Engineering, University at Buffalo, SUNY , Buffalo, NY, US

[5 ]Department of Electrical Engineering, University at Buffalo, SUNY , Buffalo, NY, US

Author notes

[a ] marco.santos@ 123456ua.pt

Article

Publisher Item ID: srep18579

DOI: 10.1038/srep18579

PMC ID: 4698582

PubMed ID: 26725842

SO-VID: 84e8649e-3b33-472d-89f9-0b08040ef734

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This work is licensed under a Creative Commons Attribution 4.0 International License. The images or other third party material in this article are included in the article’s Creative Commons license, unless indicated otherwise in the credit line; if the material is not included under the Creative Commons license, users will need to obtain permission from the license holder to reproduce the material. To view a copy of this license, visit http://creativecommons.org/licenses/by/4.0/

Magnetic levitation-based electromagnetic energy harvesting: a semi-analytical non-linear model for energy transduction

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Abstract

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Renewable Energy – Distribution Grid

Most cited references 5

Wearable medical systems for p-Health.

Instrumented hip implants: electric supply systems.

Instrumented hip joint replacements, femoral replacements and femoral fracture stabilizers.

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