A coupled formulation of fluid-structure interaction and piezoelectricity for modeling a multi-body energy harvester from vortex-induced vibrations

A coupled formulation of fluid-structure interaction and piezoelectricity for modeling a multi-body energy harvester from vortex-induced vibrations

•We develop a coupled model based on CFD approach and electro-mechanical formulation.•A new OpenFOAM library was programmed for considering piezoelectricity.•We simulated through OpenFOAM multiple piezoelectric energy harvesters based on VIV.•Numerical simulations were validated by experiments.•We c...

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Veröffentlicht in:Energy conversion and management 2021-12, Vol.249, p.114852, Article 114852
1. Verfasser: Ramírez, J.M.
Format: Artikel
Sprache:eng
Schlagworte:
Computational fluid dynamics
Coupling
Energy
Energy harvesting
Finite volume method
Fluid dynamics
Fluid flow
Fluid-structure interaction
Incompressible flow
Incompressible fluids
Libraries
Mass-spring-damper systems
Mathematical models
Mechanical properties
Multiple interacting bluff bodies
OpenFOAM
Piezoelectric energy harvester
Piezoelectricity
Rigid structures
Synchronism
Synchronization
Vibrations
Vortex-induced vibrations
Vortex-induced vibrations phenomenon
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description •We develop a coupled model based on CFD approach and electro-mechanical formulation.•A new OpenFOAM library was programmed for considering piezoelectricity.•We simulated through OpenFOAM multiple piezoelectric energy harvesters based on VIV.•Numerical simulations were validated by experiments.•We considered both types of wire connection, in series and in parallel. In this work, a coupled formulation for modeling multiple piezoelectric energy harvesters based on vortex-induced vibrations phenomenon at arbitrary locations was presented and experimentally validated. The mathematical formulation was performed by coupling the Navier-Stokes equations for incompressible fluid-flow, the Gauss law for piezoelectric equations and, a mass-spring-damper system for representing the oscillating rigid body. Piezoelectricity was described by a mixed formulation coupling mechanical and electrical variables. The coupled formulation was numerically implemented into a new OpenFOAM library. The library could be configured to add various piezoelectric materials for both types of wire connection, in series and in parallel. The numerical simulations for selected test cases were validated by experiments. After validating the numerical results, several working scenarios of three piezoelectric energy harvesters in tandem were simulated in order to evaluate the applicability of the proposed numerical formulation. The obtained results showed the synchronization state of the three harvesters operating in tandem was 500% wider than that of an isolated harvester. The interaction between cylinders played an important role in demonstrating that the output voltage of the three harvesters in tandem for a bimorph configuration connected in parallel (series) was approximately 128% (262%) higher than the unimorph one.
doi_str_mv 10.1016/j.enconman.2021.114852
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In this work, a coupled formulation for modeling multiple piezoelectric energy harvesters based on vortex-induced vibrations phenomenon at arbitrary locations was presented and experimentally validated. The mathematical formulation was performed by coupling the Navier-Stokes equations for incompressible fluid-flow, the Gauss law for piezoelectric equations and, a mass-spring-damper system for representing the oscillating rigid body. Piezoelectricity was described by a mixed formulation coupling mechanical and electrical variables. The coupled formulation was numerically implemented into a new OpenFOAM library. The library could be configured to add various piezoelectric materials for both types of wire connection, in series and in parallel. The numerical simulations for selected test cases were validated by experiments. After validating the numerical results, several working scenarios of three piezoelectric energy harvesters in tandem were simulated in order to evaluate the applicability of the proposed numerical formulation. The obtained results showed the synchronization state of the three harvesters operating in tandem was 500% wider than that of an isolated harvester. 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In this work, a coupled formulation for modeling multiple piezoelectric energy harvesters based on vortex-induced vibrations phenomenon at arbitrary locations was presented and experimentally validated. The mathematical formulation was performed by coupling the Navier-Stokes equations for incompressible fluid-flow, the Gauss law for piezoelectric equations and, a mass-spring-damper system for representing the oscillating rigid body. Piezoelectricity was described by a mixed formulation coupling mechanical and electrical variables. The coupled formulation was numerically implemented into a new OpenFOAM library. The library could be configured to add various piezoelectric materials for both types of wire connection, in series and in parallel. The numerical simulations for selected test cases were validated by experiments. 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subjects Computational fluid dynamics
Coupling
Energy
Energy harvesting
Finite volume method
Fluid dynamics
Fluid flow
Fluid-structure interaction
Incompressible flow
Incompressible fluids
Libraries
Mass-spring-damper systems
Mathematical models
Mechanical properties
Multiple interacting bluff bodies
OpenFOAM
Piezoelectric energy harvester
Piezoelectricity
Rigid structures
Synchronism
Synchronization
Vibrations
Vortex-induced vibrations
Vortex-induced vibrations phenomenon
title A coupled formulation of fluid-structure interaction and piezoelectricity for modeling a multi-body energy harvester from vortex-induced vibrations
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