Analytical Modeling and Simulation of an Electromagnetic Energy Harvester for Pulsating Fluid Flow in Pipeline

This paper presents the analytical modeling and simulation of an electromagnetic energy harvester (having linear behaviour) that generates power from pulsating fluid flow for pipeline condition monitoring systems. The modeled energy harvester is comprised of a cylindrical permanent magnet and a wound coil attached to a flexible membrane which oscillates due to the pulsating fluid flow in the pipe over which the prototype is considered to be mounted. In the harvester electrical energy is produced due to the relative motion between the coil and magnet. Based on the harvester’s architecture a lumped parameter model (single degree of freedom system) is developed and is simulated at different physical operational conditions. The simulation is performed at pressure amplitude of 625 Pa. When subjected to the operational frequency sweep, at the harvester’s resonant frequency (500 Hz) and damping ratio of 0.01, the devised model predicted the maximum open circuit voltage of 2.55 V and load voltage of 1.27 V. While operating under resonance, the maximum load voltage of 2.45 V is estimated at load resistance of 100 Ω. However, at an optimum load of 4.3 Ω, the simulation shows a production of 188151.2 μW power at a frequency of 500 Hz.

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Mathematical modeling parametric vibrations of the pipeline with pulsating fluid flow

IOP Conference Series Earth and Environmental Science ◽

10.1088/1755-1315/614/1/012103 ◽

2020 ◽

Vol 614 ◽

pp. 012103

Author(s):

B A Khudayarov ◽

F Zh Turaev

Keyword(s):

Mathematical Modeling ◽

Fluid Flow ◽

Parametric Vibrations ◽

Pulsating Fluid Flow ◽

Pulsating Fluid

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Osteocytes subjected to pulsating fluid flow regulate osteoblast proliferation and differentiation

Biochemical and Biophysical Research Communications ◽

10.1016/j.bbrc.2006.07.146 ◽

2006 ◽

Vol 348 (3) ◽

pp. 1082-1088 ◽

Cited By ~ 95

Author(s):

Peter S. Vezeridis ◽

Cornelis M. Semeins ◽

Qian Chen ◽

Jenneke Klein-Nulend

Keyword(s):

Fluid Flow ◽

Osteoblast Proliferation ◽

Pulsating Fluid Flow ◽

Proliferation And Differentiation ◽

Pulsating Fluid

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Analytical Modeling for Switched Damping Electromagnetic Energy Harvester

Theory and Applications of Applied Electromagnetics - Lecture Notes in Electrical Engineering ◽

10.1007/978-3-319-30117-4_1 ◽

2016 ◽

pp. 1-12 ◽

Cited By ~ 1

Author(s):

Beng Lee Ooi ◽

James M. Gilbert ◽

A. Rashid A. Aziz ◽

Chung Ket Thein

Keyword(s):

Analytical Modeling ◽

Energy Harvester ◽

Electromagnetic Energy

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Parametric vibrations of flexible hoses excited by a pulsating fluid flow, Part I: Modelling, solution method and simulation

Journal of Fluids and Structures ◽

10.1016/j.jfluidstructs.2015.02.011 ◽

2015 ◽

Vol 55 ◽

pp. 155-173 ◽

Cited By ~ 13

Author(s):

Jan Łuczko ◽

Andrzej Czerwiński

Keyword(s):

Fluid Flow ◽

Solution Method ◽

Parametric Vibrations ◽

Pulsating Fluid Flow ◽

Flow Part ◽

Pulsating Fluid

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1,25-Dihydroxyvitamin D3 affects pulsating fluid flow-induced nitric oxide production by osteoblasts dependent on the vdr pathway activated

Bone ◽

10.1016/j.bone.2009.03.557 ◽

2009 ◽

Vol 44 ◽

pp. S303

Author(s):

H.M.E. Willems ◽

A.D. Bakker ◽

E.G.H. Van den Heuvel ◽

J. Klein-Nulend

Keyword(s):

Nitric Oxide ◽

Fluid Flow ◽

Nitric Oxide Production ◽

Dihydroxyvitamin D3 ◽

1,25 Dihydroxyvitamin D3 ◽

Oxide Production ◽

Pulsating Fluid Flow ◽

Pulsating Fluid

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Numerical Assessment of a One-Mass Spring-Based Electromagnetic Energy Harvester on a Vibrating Object

Archives of Acoustics ◽

10.1515/aoa-2016-0012 ◽

2016 ◽

Vol 41 (1) ◽

pp. 119-131 ◽

Cited By ~ 3

Author(s):

Min-Chie Chiu ◽

Ying-Chun Chang ◽

Long-Jyi Yeh ◽

Chiu-Hung Chung

Keyword(s):

Optimal Design ◽

Energy Harvester ◽

Damping Ratio ◽

Electrical Power ◽

Electromagnetic Energy ◽

Design Parameters ◽

Helical Springs ◽

Spring Wire ◽

Excitation Period ◽

Mass Spring

Abstract The paper is an exploration of the optimal design parameters of a space-constrained electromagnetic vibration-based generator. An electromagnetic energy harvester is composed of a coiled polyoxymethylen circular shell, a cylindrical NdFeB magnet, and a pair of helical springs. The magnet is vertically confined between the helical springs that serve as a vibrator. The electrical power connected to the coil is actuated when the energy harvester is vibrated by an external force causing the vibrator to periodically move through the coil. The primary factors of the electrical power generated from the energy harvester include a magnet, a spring, a coil, an excited frequency, an excited amplitude, and a design space. In order to obtain maximal electrical power during the excitation period, it is necessary to set the system’s natural frequency equal to the external forcing frequency. There are ten design factors of the energy harvester including the magnet diameter (Dm), the magnet height (Hm), the system damping ratio (ζsys), the spring diameter (Ds), the diameter of the spring wire (ds), the spring length (ℓs), the pitch of the spring (ps), the spring’s number of revolutions (Ns), the coil diameter (Dc), the diameter of the coil wire (dc), and the coil’s number of revolutions (Nc). Because of the mutual effects of the above factors, searching for the appropriate design parameters within a constrained space is complicated. Concerning their geometric allocation, the above ten design parameters are reduced to four (Dm, Hm, ζsys, and Nc). In order to search for optimal electrical power, the objective function of the electrical power is maximized by adjusting the four design parameters (Dm, Hm, ζsys, and Nc) via the simulated annealing method. Consequently, the optimal design parameters of Dm, Hm, ζsys, and Nc that produce maximum electrical power for an electromagnetic energy harvester are found.

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