Investigation of the hydrodynamic performance of a novel small moored tidal-current turbine with Banki rotor

Journal Article

Title: Investigation of the hydrodynamic performance of a novel small moored tidal-current turbine with Banki rotor

Author:

Hu, Y.; Mao, Z.; Li, B.; Cheng, B.; Tian, W.

Publication Date:

January 1, 2026

Journal:

Renewable Energy

Volume:

256

Pages:

124598

Publisher:

Elsevier

Affiliation:

Northwestern Polytechnical University

Technology:

Current, Axial Flow Turbine

Collection Method:

Modeling

Engineering:

Hydrodynamics, Performance

Language:

English

Document Access

Website:

External Link

Citation

APA
BibTex
RIS

Hu, Y.; Mao, Z.; Li, B.; Cheng, B.; Tian, W. (2026). Investigation of the hydrodynamic performance of a novel small moored tidal-current turbine with Banki rotor. Renewable Energy, 256, 124598. https://doi.org/10.1016/j.renene.2025.124598

@article{Hu-2026-,
author = {Hu, Y and Mao, Z and Li, B and Cheng, B and Tian, W},
title = {Investigation of the hydrodynamic performance of a novel small moored tidal-current turbine with Banki rotor},
journal = {Renewable Energy},
year = {2026},
month = {jan},
publisher = {Elsevier},
volume = {256},
pages = {124598},
doi = {10.1016/j.renene.2025.124598},
url = {https://www.sciencedirect.com/science/article/pii/S0960148125022621},
keywords = {Current, Axial Flow Turbine, Modeling, Hydrodynamics, Performance},
}

Export Citation to BibTex

TY - JOUR
TI - Investigation of the hydrodynamic performance of a novel small moored tidal-current turbine with Banki rotor
AU - Hu, Y
AU - Mao, Z
AU - Li, B
AU - Cheng, B
AU - Tian, W
T2 - Renewable Energy
AB - The global energy supply, which heavily depends on fossil fuels, confronts the challenges of resource depletion and environmental pollution, requiring a shift to renewable energy. Tidal-current energy has significant potential but is characterized by intermittency, which restricts its efficiency. To tackle this problem, this study proposes and designs a novel small moored tidal-current energy turbine (SMTET). The SMTET integrates a floating body, Banki rotor, and counterweight to synergistically harness tidal-current and wave energy. Through coupled CFD and mooring dynamics simulations, the system demonstrates: (1) The mooring system induces only deflection (approximately 3°), enabling the turbine to maintain stable underwater operation while preserving hydrodynamic performance; (2) The power coefficient (Cp) peaks at TSR = 0.4, where wave action enhances Cp by 17.5 % (from 0.1680 to 0.1974). This performance improvement confirms the wave-energy enhancement mechanism, primarily achieved through synchronized vortex shedding. These findings provide critical design insights for hybrid tidal-wave energy systems.
DA - 2026/01//
PY - 2026
PB - Elsevier
VL - 256
SP - 124598
UR - https://www.sciencedirect.com/science/article/pii/S0960148125022621
DO - 10.1016/j.renene.2025.124598
LA - English
KW - Current
KW - Axial Flow Turbine
KW - Modeling
KW - Hydrodynamics
KW - Performance
ER -

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Abstract

The global energy supply, which heavily depends on fossil fuels, confronts the challenges of resource depletion and environmental pollution, requiring a shift to renewable energy. Tidal-current energy has significant potential but is characterized by intermittency, which restricts its efficiency. To tackle this problem, this study proposes and designs a novel small moored tidal-current energy turbine (SMTET). The SMTET integrates a floating body, Banki rotor, and counterweight to synergistically harness tidal-current and wave energy. Through coupled CFD and mooring dynamics simulations, the system demonstrates: (1) The mooring system induces only deflection (approximately 3°), enabling the turbine to maintain stable underwater operation while preserving hydrodynamic performance; (2) The power coefficient (Cp) peaks at TSR = 0.4, where wave action enhances Cp by 17.5 % (from 0.1680 to 0.1974). This performance improvement confirms the wave-energy enhancement mechanism, primarily achieved through synchronized vortex shedding. These findings provide critical design insights for hybrid tidal-wave energy systems.