Synergistic Integration of Multiple Wave Energy Converters with Adaptive Resonance and Offshore Floating Wind Turbines through Bayesian Optimization

Synergistic Integration of Multiple Wave Energy Converters with Adaptive Resonance and Offshore Floating Wind Turbines through Bayesian Optimization

We developed a synergistic ocean renewable system where an array of Wave Energy Converters (WEC) with adaptive resonance was collocated with a Floating Offshore Wind Turbine (FOWT) such that the WECs, capturing wave energy through the resonance adapting to varying irregular waves, consequently reduc...

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Bibliographic Details
Published in:Journal of marine science and engineering Vol. 12; no. 8; p. 1455
Main Authors: Meduri, Aghamarshana, Kang, HeonYong
Format: Journal Article
Language:English
Published: Basel MDPI AG 01-08-2024
Subjects:
Adaptive systems
Air-turbines
Alternative energy
Alternative energy sources
Annual
Bayesian analysis
Bayesian optimization
Bayesian theory
collocated array
Costs
coupled multibody dynamics
Electric current converters
Energy costs
Excitation spectra
Floating
Floating bodies
floating offshore wind turbines
Force and energy
Hydrodynamics
Irregular waves
Mooring
Mooring lines
Mooring systems
Nacelles
Nonlinear dynamics
Ocean waves
Offshore
Offshore energy sources
Optimization
Probability theory
Radiation
Renewable resources
Resonance
Resonant frequencies
Resonant frequency
Sea state
Sea states
Simulation methods
Spectra
Submersibles
synergies
Turbine engines
Turbines
Wave diffraction
Wave energy
wave energy converter
Wave excitation
Wave power
Wave power devices
Wind power
Wind turbines
United States
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Description
Summary:We developed a synergistic ocean renewable system where an array of Wave Energy Converters (WEC) with adaptive resonance was collocated with a Floating Offshore Wind Turbine (FOWT) such that the WECs, capturing wave energy through the resonance adapting to varying irregular waves, consequently reduced FOWFT loads and turbine motions. Combining Surface-Riding WECs (SR-WEC) individually designed to feasibly relocate their natural frequency at the peak of the wave excitation spectrum for each sea state, and to obtain the highest capture width ratio at one of the frequent sea states for annual average power in a tens of kilowatts scale with a 15 MW FOWT based on a semi-submersible, Bayesian Optimization is implemented to determine the arrangement of WECs that minimize the annual representation of FOWT’s wave excitation spectra. The time-domain simulation of the system in the optimized arrangement is performed, including two sets of interactions: one set is the wind turbine dynamics, mooring lines, and floating body dynamics for FOWT, and the other set is the nonlinear power-take-off dynamics, linear mooring, and individual WECs’ floating body dynamics. Those two sets of interactions are further coupled through the hydrodynamics of diffraction and radiation. For sea states comprising Annual Energy Production, we investigate the capture width ratio of WECs, wave excitation on FOWT, and nacelle acceleration of the turbine compared to their single unit operations. We find that the optimally arranged SR-WECs reduce the wave excitation spectral area of FOWT by up to 60% and lower the turbine’s peak nacelle acceleration by nearly 44% in highly occurring sea states, while multiple WECs often produce more than the single operation, achieving adaptive resonance with a larger wave excitation spectra for those sea states. The synergistic system improves the total Annual Energy Production (AEP) by 1440 MWh, and we address which costs of Levelized Cost Of Energy (LCOE) can be reduced by the collocation.
ISSN:2077-1312
2077-1312
DOI:10.3390/jmse12081455