Coupled LES and bed morphodynamics of a utility-scale vertical-axis MHK turbine under rigid- and mobile-bed conditions

Conference Paper

Title: Coupled LES and bed morphodynamics of a utility-scale vertical-axis MHK turbine under rigid- and mobile-bed conditions

Author:

Anjiraki, M.; Seyedzadeh, H.; Aksen, M.; Khosronejad, A.

Publication Date:

August 7, 2024

Event Name:

UMERC + METS 2024

Event Session:

Session 6: Environmental, Social, and Economic

Event Location:

Duluth, MN, USA

Pages:

Publisher:

University Marine Energy Research Community

Affiliation:

Stony Brook University

Technology:

Current, Axial Flow Turbine

Collection Method:

Modeling

Engineering:

Hydrodynamics, Performance

Language:

English

Document Access

Website:

External Link

Attachment:

Access File

Notice: This material may be protected by Copyright Law.

Citation

APA
BibTex
RIS

Anjiraki, M.; Seyedzadeh, H.; Aksen, M.; Khosronejad, A. (2024). Coupled LES and bed morphodynamics of a utility-scale vertical-axis MHK turbine under rigid- and mobile-bed conditions. Paper presented at UMERC + METS 2024, Duluth, MN, USA. https://doi.org/10.5281/zenodo.15185393

@conference{Anjiraki-2024-24119,
author = {Anjiraki, M and Seyedzadeh, H and Aksen, M and Khosronejad, A},
title = {Coupled LES and bed morphodynamics of a utility-scale vertical-axis MHK turbine under rigid- and mobile-bed conditions},
year = {2024},
month = {aug},
series = {UMERC + METS 2024},
pages = {4},
address = {Duluth, MN, USA},
publisher = {University Marine Energy Research Community},
doi = {10.5281/zenodo.15185393},
url = {https://zenodo.org/records/15185394},
keywords = {Current, Axial Flow Turbine, Modeling, Hydrodynamics, Performance},
}

Export Citation to BibTex

TY - CONF
TI - Coupled LES and bed morphodynamics of a utility-scale vertical-axis MHK turbine under rigid- and mobile-bed conditions
AU - Anjiraki, M
AU - Seyedzadeh, H
AU - Aksen, M
AU - Khosronejad, A
T2 - UMERC + METS 2024
C1 - Duluth, MN, USA
AB - We present a coupled large-eddy simulation (LES) and bed morphodynamics study to examine the sediment dynamics around a utility-scale vertical-axis marine hydrokinetic (MHK) turbine under two flume bed conditions: rigid and mobile. Carefully comparing the coupled LES and morphodynamics numerical results under the rigid- and mobile-bed conditions, we attempt to quantify the effect of scour development on the wake recovery and power production of the turbine and to gain insight into the formation, development, and migration of dunes over the mobile bed. The sediment dynamics are obtained using the Exner-Polya equation, which is solved until an equilibrium bed morphology is reached. A mass-balance-based sand-slide module is used to ensure that bed deformation angles are physically accurate. The model's flow and sediment transport results are validated using experimental data of adequate Reynolds numbers representing large-scale tidal farms.The presentation for this paper at UMERC+METS 2024 can be found here.
DA - 2024/08//
PY - 2024
SP - 4
PB - University Marine Energy Research Community
UR - https://zenodo.org/records/15185394
DO - 10.5281/zenodo.15185393
LA - English
KW - Current
KW - Axial Flow Turbine
KW - Modeling
KW - Hydrodynamics
KW - Performance
ER -

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Abstract

We present a coupled large-eddy simulation (LES) and bed morphodynamics study to examine the sediment dynamics around a utility-scale vertical-axis marine hydrokinetic (MHK) turbine under two flume bed conditions: rigid and mobile. Carefully comparing the coupled LES and morphodynamics numerical results under the rigid- and mobile-bed conditions, we attempt to quantify the effect of scour development on the wake recovery and power production of the turbine and to gain insight into the formation, development, and migration of dunes over the mobile bed. The sediment dynamics are obtained using the Exner-Polya equation, which is solved until an equilibrium bed morphology is reached. A mass-balance-based sand-slide module is used to ensure that bed deformation angles are physically accurate. The model's flow and sediment transport results are validated using experimental data of adequate Reynolds numbers representing large-scale tidal farms.

The presentation for this paper at UMERC+METS 2024 can be found here.