Boosting the Electrostatic MEMS Converter Output Power by Applying Three Effective Performance-Enhancing Techniques-Reference-Cited by-同舟云学术

Boosting the Electrostatic MEMS Converter Output Power by Applying Three Effective Performance-Enhancing Techniques

Published:2023-02-19 Issue:2 Volume:14 Page:485
ISSN:2072-666X
Container-title:Micromachines
language:en
Short-container-title:Micromachines

Author:

Salem Mona S.¹,Zekry Abdelhalim¹^ORCID,Abouelatta Mohamed¹^ORCID,Shaker Ahmed²^ORCID,Salem Marwa S.³,Gontrand Christian⁴⁵,Saeed Ahmed⁶^ORCID

Affiliation:

1. Electronics and Communications Engineering Department, Faculty of Engineering, Ain Shams University (ASU), Cairo 11566, Egypt

2. Physics and Mathematics Engineering Department, Faculty of Engineering, Ain Shams University (ASU), Cairo 11566, Egypt

3. Department of Computer Engineering, Computer Science and Engineering College, University of Ha’il, Ha’il 55211, Saudi Arabia

4. National Institute of Applied Sciences of Lyon (INSA Lyon), 69621 Lyon, France

5. IEP, INSA—Fès, Université Euro-Méditerranéenne de Fès, Fès 30120, Morocco

6. Electrical Engineering Department, Faculty of Engineering and Technology, Future University in Egypt, New Cairo 11835, Egypt

Abstract

This current study aims to enhance the electrostatic MEMS converter performance mainly by boosting its output power. Three different techniques are applied to accomplish such performance enhancement. Firstly, the power is boosted by scaling up the technology of the converter CMOS accompanied circuit, the power conditioning, and power controlling circuits, from 0.35 µm to 0.6 µm CMOS technology. As the converter area is in the range of mm2, there are no restrictions concerning the scaling up of the accompanied converter CMOS circuits. As a result, the maximum voltage of the system for harvesting energy, Vmax, which is the most effective system constraint that greatly affects the converter’s output power, increases from 8 V to 30 V. The output power of the designed and simulated converter based on the 0.6 µm technology increases from 2.1 mW to 4.5 mW. Secondly, the converter power increases by optimizing its technological parameters, the converter thickness and the converter finger width and length. Such optimization causes the converter output power to increase from 4.5 mW to 11.2 mW. Finally, the converter structure is optimized to maximize its finger length by using its wasted shuttle mass area which does not contribute to its capacitances and output power. The proposed structure increases the converter output power from 11.2 mW to 14.29 mW. Thus, the three applied performance enhancement techniques boosted the converter output power by 12.19 mW, which is a considerable enhancement in the converter performance. All simulations are carried out using COMSOL Multiphysics 5.4.

Publisher

MDPI AG

Subject

Electrical and Electronic Engineering,Mechanical Engineering,Control and Systems Engineering

Link

https://www.mdpi.com/2072-666X/14/2/485/pdf

Reference51 articles.

1. Sullivan, J.L., and Gaines, L. (2010). A Review of Battery Life-Cycle Analysis: State of Knowledge and Critical Needs, Argonne National Lab (ANL). Technical Report.

2. Paulo, J., and Gaspar, P.D. (July, January 30). Review and future trend of energy harvesting methods for portable medical devices. Proceedings of the World Congress on Engineering, London, UK.

3. Energy harvesting in wireless sensor networks: A comprehensive review;Shaikh;Renew. Sustain. Energy Rev.,2016

4. Recent advances in energy harvesting technologies for structural health monitoring applications;Davidson;Recent Adv. Energy Harvest. Technol. Struct. Health Monit. Appl.,2014

5. Photovoltaic performances of mono-and mixed-halide structures for perovskite solar cell: A review;Ng;Renew. Sustain. Energy Rev.,2018