Data from Numerical Modeling of Halona Oscillating Water Column Wave Energy Converter for Autonomous Underwater Vehicle Docking

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In this project, we applied the Forchheimer flow model in Computational Fluid Dynamics (CFD) simulation to characterize the flow through an orifice used as a quadratic Power Takeoff (PTO) for the Halona oscillating water column (OWC) wave energy convertor (WEC) in the experiments. This proposed method has been successfully utilized for a fixed omnidirectional spar buoy WEC in regular waves. The objective of this project was to extend the application of this method to a floating WEC.

This resource contains the final project report and the modeling data associated with each figure contained in the final project report. The file names are consistent with the figure numbering in the final report. There is a README included in each ZIP folder if the file name is not self-explained. Additional description and explanation for each figure can be found in the report.

Download All Resources 408.01 MB — 20 files

Figure_10_Wave_elevation_wave_only_case.zip

The simulated versus target free surface elevation from the wave-only simulation

Download 276.23 kB

Figure_11_Mesh_Article1_coarse_medium_fine.zip

Coarse, medium, and fine overset grids for the grid-size convergence test for Article 1 (without PTO).

Download 163.86 MB

Figure_12_Motion_Article1_coarse_medium_fine_grids.zip

The simulated motions using the coarse, medium, and fine grids for Article 1

Download 2.4 MB

Figure_13_Motion_Article2_coarse_medium_fine_grids.zip

The simulated motions using the coarse, medium, and fine grids for Article 2.

Download 2.14 MB

Figure_14_Free_decay_No_PTO.zip

Time histories of the simulated heave motion and heave rate for WECs without PTO

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Figure_15_Free_decay_PTO.zip

Comparison of the simulated heave motion with and without PTO from selected tests for Articles 1 and 2

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Figure_16_pressure.zip

The simulated pressure distribution in the symmetry plane of the WEC based on different setups of the parameters d and f for the Forchheimer model (f_0 =1.32e5). For ea... more

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Figure_18_Free_surface_Article1_H0.08m_T2.5s.zip

The simulated free surface elevation for Article 1 without PTO (H = 0.08 m, T = 2.5 s). The numerical wave probe location is marked by the arrow tip

Download 5.05 MB

Figure_19_Artcile1_PTO_H0.08m_T2.5s.zip

The simulated and measured motion and pressure difference results for Article 1 with PTO in a regular wave (H = 0.08 m and T = 2.5 s).

Download 1.37 MB

Figure_20_Artcile2_PTO_H0.24m_T2.5s.zip

The simulated and measured motion and pressure difference for Article 2 with PTO in a regular wave (H = 0.24 m and T = 2.5 s).

Download 945.75 kB

Figure_21_Cf_and_extract_efficiency.zip

(a) Correlation between the simulated and estimated Cf values, (b) extract efficiencies from the optimization test cases.

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Figure_22_Absolute_and_relative_velocities.zip

The simulated absolute and relative air velocities through the chamber in the Forchheimer flow zone for selected cases

Download 2.76 MB

Figure_7_CFD_mesh.zip

CFD mesh for a regular wave case tested for Article 1 with PTO (H = 0.08 m, T = 2.5 s)

Download 147.7 MB

Figure_A1.zip

The simulated and measured motion and pressure results for Article 1 in regular waves (H = 0.08 m and T = 1.5 s)

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Figure_A2.zip

The simulated and measured motion and pressure results for Article 1 in regular waves (H = 0.08 m and T = 2.0 s).

Download 1.07 MB

Figure_A3.zip

The simulated and measured motion and pressure results for Article 1 in regular waves (H = 0.14 m and T = 2.0 s).

Download 1.38 MB

Figure_A4.zip

The simulated and measured relative free surface elevation, motion, and pressure for Article 2 in regular waves (H = 0.24 m and T = 3.0 s).

Download 1.38 MB

Figure_A5.zip

The simulated and measured relative free surface elevation, motion, and pressure for Article 2 in regular waves (H = 0.24 m and T = 3.5 s).

Download 1.11 MB

Figure_A6.zip

The simulated and measured relative free surface elevation, motion, and pressure for Article 2 in regular waves (H = 0.24 m and T = 3.0 s).

Download 1.09 MB

TEAMER-Test-Plan-ABS Hawaii_2024_Final_Report - CLEAN.pdf

The final TEAMER report for this project.

Download 4.52 MB

Citation Formats

TY  - DATA
AB  - In this project, we applied the Forchheimer flow model in Computational Fluid Dynamics (CFD) simulation to characterize the flow through an orifice used as a quadratic Power Takeoff (PTO) for the Halona oscillating water column (OWC) wave energy convertor (WEC) in the experiments. This proposed method has been successfully utilized for a fixed omnidirectional spar buoy WEC in regular waves. The objective of this project was to extend the application of this method to a floating WEC.

This resource contains the final project report and the modeling data associated with each figure contained in the final project report. The file names are consistent with the figure numbering in the final report. There is a README included in each ZIP folder if the file name is not self-explained. Additional description and explanation for each figure can be found in the report.
AU  - Hsieh, Yvonne
DB  - Marine and Hydrokinetic Data Repository
DP  - Open EI | National Renewable Energy Laboratory
DO  - 
KW  - MHK
KW  - energy
KW  - power
KW  - CFD
KW  - WEC
KW  - Computational Fluid Dynamics
KW  - Power Takeoff
KW  - wave energy convertor
KW  - oscillating water column
KW  - OWC
KW  - Forchheimer flow model
KW  - Halona
KW  - AUV
KW  - Halona WEC
KW  - Autonomous underwater vehicle
KW  - modeling data
KW  - quadratic power takeoff
KW  - PTO
KW  - floating WEC
LA  - English
DA  - 2025/04/17
PY  - 2025
PB  - American Bureau of Shipping
T1  - Data from Numerical Modeling of Halona Oscillating Water Column Wave Energy Converter for Autonomous Underwater Vehicle Docking
UR  - https://mhkdr.openei.org/submissions/617
ER  -

Export Citation to RIS

Hsieh, Yvonne. Data from Numerical Modeling of Halona Oscillating Water Column Wave Energy Converter for Autonomous Underwater Vehicle Docking. American Bureau of Shipping, 17 April, 2025, Marine and Hydrokinetic Data Repository. https://mhkdr.openei.org/submissions/617.

Hsieh, Y. (2025). Data from Numerical Modeling of Halona Oscillating Water Column Wave Energy Converter for Autonomous Underwater Vehicle Docking. [Data set]. Marine and Hydrokinetic Data Repository. American Bureau of Shipping. https://mhkdr.openei.org/submissions/617

Hsieh, Yvonne. Data from Numerical Modeling of Halona Oscillating Water Column Wave Energy Converter for Autonomous Underwater Vehicle Docking. American Bureau of Shipping, April, 17, 2025.  Distributed by Marine and Hydrokinetic Data Repository. https://mhkdr.openei.org/submissions/617

@misc{MHKDR_Dataset_617,
title = {Data from Numerical Modeling of Halona Oscillating Water Column Wave Energy Converter for Autonomous Underwater Vehicle Docking},
author = {Hsieh, Yvonne},
abstractNote = {In this project, we applied the Forchheimer flow model in Computational Fluid Dynamics (CFD) simulation to characterize the flow through an orifice used as a quadratic Power Takeoff (PTO) for the Halona oscillating water column (OWC) wave energy convertor (WEC) in the experiments. This proposed method has been successfully utilized for a fixed omnidirectional spar buoy WEC in regular waves. The objective of this project was to extend the application of this method to a floating WEC.



This resource contains the final project report and the modeling data associated with each figure contained in the final project report. The file names are consistent with the figure numbering in the final report. There is a README included in each ZIP folder if the file name is not self-explained. Additional description and explanation for each figure can be found in the report.},
url = {https://mhkdr.openei.org/submissions/617},
year = {2025},
howpublished = {Marine and Hydrokinetic Data Repository, American Bureau of Shipping, https://mhkdr.openei.org/submissions/617},
note = {Accessed: 2025-11-02}
}

Details

Data from Apr 17, 2025

Last updated Aug 18, 2025

Submitted Apr 18, 2025

Organization

American Bureau of Shipping

Contact

Yvonne Hsieh

Authors