Numerical and Experimental Investigation of a Ducky Wave Energy Converter and Its Impact on Floating Ocean Wind Turbines

Journal Article

Title: Numerical and Experimental Investigation of a Ducky Wave Energy Converter and Its Impact on Floating Ocean Wind Turbines

Author:

Tao, T.; Dong, Y.; Guo, X.; Liu, S.; Jiang, Y.; Yuan, Z.

Publication Date:

August 8, 2025

Journal:

Marine Science and Engineering

Volume:

Issue:

Pages:

Publisher:

MDPI

Affiliation:

China Southern Power Grid Technology Co., Ltd., Dalian University of Technology, University of Strathclyde

Technology:

Wave, Point Absorber

Collection Method:

Lab Data, Modeling

Engineering:

Array Effects, Hydrodynamics, Mooring, Power Take Off, Substructure

Language:

English

Document Access

Website:

External Link

Attachment:

Access File

Notice: This material may be protected by Copyright Law.

Citation

APA
BibTex
RIS

Tao, T.; Dong, Y.; Guo, X.; Liu, S.; Jiang, Y.; Yuan, Z. (2025). Numerical and Experimental Investigation of a Ducky Wave Energy Converter and Its Impact on Floating Ocean Wind Turbines. Marine Science and Engineering, 13(8), 36. https://doi.org/10.3390/jmse13081527

@article{Tao-2025-,
author = {Tao, T and Dong, Y and Guo, X and Liu, S and Jiang, Y and Yuan, Z},
title = {Numerical and Experimental Investigation of a Ducky Wave Energy Converter and Its Impact on Floating Ocean Wind Turbines},
journal = {Marine Science and Engineering},
year = {2025},
month = {aug},
publisher = {MDPI},
volume = {13},
number = {8},
pages = {36},
doi = {10.3390/jmse13081527},
url = {https://www.mdpi.com/2077-1312/13/8/1527},
keywords = {Wave, Point Absorber, Lab Data, Modeling, Array Effects, Hydrodynamics, Mooring, Power Take Off, Substructure},
}

Export Citation to BibTex

TY - JOUR
TI - Numerical and Experimental Investigation of a Ducky Wave Energy Converter and Its Impact on Floating Ocean Wind Turbines
AU - Tao, T
AU - Dong, Y
AU - Guo, X
AU - Liu, S
AU - Jiang, Y
AU - Yuan, Z
T2 - Marine Science and Engineering
AB - The ocean represents a vast reservoir of energy. To address the issue of wave-induced motion in floating wind farms—particularly pitch motion—while harnessing the otherwise dissipated wave energy for power generation, this study proposes an integrated solution. Specifically, a duck-shaped wave energy converter incorporating mooring and power take-off systems is introduced. By combining computational fluid dynamics with experimental fluid dynamics methodologies, the performance of the device was systematically evaluated and its key parameters—including floating attitude, power take-off damping, and mooring configuration—were optimized. Furthermore, results indicate that deploying the duck-shaped converter around the periphery of a wind farm can reduce the wave-induced motion amplitude of the floating wind turbine platform by more than 70%, especially in terms of pitch motion, thereby significantly improving the operational efficiency and structural stability of the wind turbines.
DA - 2025/08//
PY - 2025
PB - MDPI
VL - 13
IS - 8
SP - 36
UR - https://www.mdpi.com/2077-1312/13/8/1527
DO - 10.3390/jmse13081527
LA - English
KW - Wave
KW - Point Absorber
KW - Lab Data
KW - Modeling
KW - Array Effects
KW - Hydrodynamics
KW - Mooring
KW - Power Take Off
KW - Substructure
ER -

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Abstract

The ocean represents a vast reservoir of energy. To address the issue of wave-induced motion in floating wind farms—particularly pitch motion—while harnessing the otherwise dissipated wave energy for power generation, this study proposes an integrated solution. Specifically, a duck-shaped wave energy converter incorporating mooring and power take-off systems is introduced. By combining computational fluid dynamics with experimental fluid dynamics methodologies, the performance of the device was systematically evaluated and its key parameters—including floating attitude, power take-off damping, and mooring configuration—were optimized. Furthermore, results indicate that deploying the duck-shaped converter around the periphery of a wind farm can reduce the wave-induced motion amplitude of the floating wind turbine platform by more than 70%, especially in terms of pitch motion, thereby significantly improving the operational efficiency and structural stability of the wind turbines.