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Energy Harvesting and Storage Applications, Volume II

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Dear Colleagues,

This Special Issue is proposed to encourage further research and development of energy harvesters as mobile and remote power sources.

Development of energy harvesting devices should be carefully planned considering their target application. Powering wireless sensor nodes is one of the most attractive applications of energy harvesting technology for various monitoring purposes for large-scale structures and machines such as bridges, railroad, wind turbines, and naval platforms, as well as biosystems, such as the human body and/or animals. An energy harvester needs to be designed to meet the power requirements of the application (e.g. sensor), and integrated with a power management circuit for maximum power conversion and seamless sensor operation.

Original contributions including the state-of-the-art, point out the benefits of emerging technologies, experimental studies, or investigate the novel schemes and applications are welcome to submit. The topics of interest include, but are not limited to the following:

Integration of wireless sensor nodes with energy harvesters
Power management circuit and power storage
Battery science for minimum leakage
Novel energy harvesting concept to meet the power requirements of a specific application(s)

Dr. Soobum Lee
Guest Editor

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Research

22 pages, 7115 KiB

Open AccessArticle

Design Scalability Study of the Γ-Shaped Piezoelectric Harvester Based on Generalized Classical Ritz Method and Optimization

by Sinwoo Jeong, Soobum Lee and Honghee Yoo

Electronics 2021, 10(16), 1887; https://doi.org/10.3390/electronics10161887 - 6 Aug 2021

Viewed by 2291

Abstract

This paper studies the design scalability of a

Γ

-shaped piezoelectric energy harvester (

Γ

This paper studies the design scalability of a

Γ

-shaped piezoelectric energy harvester (

Γ

EH) using the generalized classical Ritz method (GCRM) and differential evolution algorithm. The generalized classical Ritz method (GCRM) is the advanced version of the classical Ritz method (CRM) that can handle a multibody system by assembling its equations of motion interconnected by the constraint equations. In this study, the GCRM is extended for analysis of the piezoelectric energy harvesters with material and/or orientation discontinuity between members. The electromechanical equations of motion are derived for the PE harvester using GCRM, and the accuracy of the numerical simulation is experimentally validated by comparing frequency response functions for voltage and power output. Then the GCRM is used in the power maximization design study that considers four different total masses—15 g, 30 g, 45 g, 60 g—to understand design scalability. The optimized

Γ

EH has the maximum normalized power density of 23.1 × 10³ kg·s·m⁻³ which is the highest among the reviewed PE harvesters. We discuss how the design parameters need to be determined at different harvester scales. Full article

(This article belongs to the Special Issue Energy Harvesting and Storage Applications, Volume II)

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