On the Hydrodynamic Analysis of a Vertical Axis MHK Turbine - Investigating Fish Trajectories via large-eddy simulation

Conference Paper

Title: On the Hydrodynamic Analysis of a Vertical Axis MHK Turbine - Investigating Fish Trajectories via large-eddy simulation

Author:

Seyedzadeh, H.; Anjiraki, M.; Sorisio, Guglielmo; Wilson, C.; Khosreonejad, A.

Publication Date:

August 7, 2024

Event Name:

UMERC + METS 2024

Event Location:

Duluth, MN, USA

Pages:

Publisher:

UMERC

Affiliation

Stony Brook University, Cardiff University

Technology:

Marine Energy, Tidal

Stressor:

Collision

Receptor:

Fish

Language:

English

Document Access

Website:

External Link

Attachment:

Access File

Citation

APA
BibTex
RIS

Seyedzadeh, H.; Anjiraki, M.; Sorisio, Guglielmo; Wilson, C.; Khosreonejad, A. (2024). On the Hydrodynamic Analysis of a Vertical Axis MHK Turbine - Investigating Fish Trajectories via large-eddy simulation. Paper presented at UMERC + METS 2024, Duluth, MN, USA. https://doi.org/10.5281/zenodo.15168544

@conference{Seyedzadeh-2024-2084281,
author = {Seyedzadeh, H and Anjiraki, M and Sorisio, Guglielmo and Wilson, C and Khosreonejad, A},
title = {On the Hydrodynamic Analysis of a Vertical Axis MHK Turbine - Investigating Fish Trajectories via large-eddy simulation},
year = {2024},
month = {aug},
series = {UMERC + METS 2024},
pages = {6},
address = {Duluth, MN, USA},
publisher = {UMERC},
doi = {10.5281/zenodo.15168544},
url = {https://zenodo.org/records/15168544},
keywords = {Marine Energy, Tidal, Collision, Fish},
}

Export Citation to BibTex

TY - CONF
TI - On the Hydrodynamic Analysis of a Vertical Axis MHK Turbine - Investigating Fish Trajectories via large-eddy simulation
AU - Seyedzadeh, H
AU - Anjiraki, M
AU - Sorisio, Guglielmo
AU - Wilson, C
AU - Khosreonejad, A
T2 - UMERC + METS 2024
C1 - Duluth, MN, USA
AB - Marine hydrokinetic (MHK) turbines offer a robust renewable energy solution to address the challenges of energy scarcity and environmental degradation. However, owing to the potential impact of MHK turbines on the aquatic ecosystem, evaluating the implications of deploying such devices on fish life is essential. Herein, we conducted large eddy simulation (LES) of a vertical axis turbine (VAT) using the turbine geometry-resolving model to gain insights into the relationship between turbulent flow dynamics and fish trajectory. The LES results were validated using experimental data obtained at the Hydro-environmental Research Centre's hydraulic laboratory of Cardiff University, UK. The LES results of the turbulent wake flow field demonstrate meaningful alignment with fish behavioral experimental data, thus serving as a reliable turbulence map for elucidating the trajectories of fish movement within the flow.
DA - 2024/08//
PY - 2024
SP - 6
PB - UMERC
UR - https://zenodo.org/records/15168544
DO - 10.5281/zenodo.15168544
LA - English
KW - Marine Energy
KW - Tidal
KW - Collision
KW - Fish
ER -

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Abstract

Marine hydrokinetic (MHK) turbines offer a robust renewable energy solution to address the challenges of energy scarcity and environmental degradation. However, owing to the potential impact of MHK turbines on the aquatic ecosystem, evaluating the implications of deploying such devices on fish life is essential. Herein, we conducted large eddy simulation (LES) of a vertical axis turbine (VAT) using the turbine geometry-resolving model to gain insights into the relationship between turbulent flow dynamics and fish trajectory. The LES results were validated using experimental data obtained at the Hydro-environmental Research Centre's hydraulic laboratory of Cardiff University, UK. The LES results of the turbulent wake flow field demonstrate meaningful alignment with fish behavioral experimental data, thus serving as a reliable turbulence map for elucidating the trajectories of fish movement within the flow.