Lessons learned from the design and operation of a small-scale cross-flow tidal turbine

Journal Article

Title: Lessons learned from the design and operation of a small-scale cross-flow tidal turbine

Author:

Bassett, C.; Gibbs, P.; Wood, H.; Cavagnaro, R.; Cunningham, B.; Dosher, J.; Polagye, B.

Publication Date:

July 1, 2025

Journal:

Journal of Ocean Engineering and Marine Energy

Publisher:

Springer Nature

Affiliation:

Applied Physics Laboratory (APL-UW), Pacific Northwest National Laboratory (PNNL)

Technology:

Current, Cross Flow Turbine, Tidal

Collection Method:

Full Scale

Resource:

Site Characterization

Engineering:

Power Take Off, Substructure

Language:

English

Document Access

Website:

External Link

Attachment:

Access File

Notice: This material may be protected by Copyright Law.

Citation

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BibTex
RIS

Bassett, C., Gibbs, P., Wood, H. et al. Lessons learned from the design and operation of a small-scale cross-flow tidal turbine. J. Ocean Eng. Mar. Energy (2025). https://doi.org/10.1007/s40722-025-00411-y

@article{Bassett-2025-24062,
author = {Bassett, C and Gibbs, P and Wood, H and Cavagnaro, R and Cunningham, B and Dosher, J and Polagye, B},
title = {Lessons learned from the design and operation of a small-scale cross-flow tidal turbine},
journal = {Journal of Ocean Engineering and Marine Energy},
year = {2025},
month = {jul},
publisher = {Springer Nature},
doi = {10.1007/s40722-025-00411-y},
url = {https://link.springer.com/article/10.1007/s40722-025-00411-y},
keywords = {Current, Cross Flow Turbine, Tidal, Full Scale, Site Characterization, Power Take Off, Substructure},
}

Export Citation to BibTex

TY - JOUR
TI - Lessons learned from the design and operation of a small-scale cross-flow tidal turbine
AU - Bassett, C
AU - Gibbs, P
AU - Wood, H
AU - Cavagnaro, R
AU - Cunningham, B
AU - Dosher, J
AU - Polagye, B
T2 - Journal of Ocean Engineering and Marine Energy
AB - In 2023, a first-generation prototype of a small-scale marine current turbine was operated in Sequim Bay, Washington (USA) for 141 days. The system, referred to as the Turbine Lander, was the product of a laboratory-to-field effort to develop a system that enables enhanced ocean sensing or vehicle recharge in remote, energetic settings. The turbine consists of a vertical-axis, cantilevered rotor (1.19 m x 0.85 m) with four foils installed on a gravity foundation. A broader range of constraints including the deployment strategy, site characteristics, and estimated loads, drove the system’s design. This work presents the design, characterization, operation, and post-recovery engineering assessment of the Turbine Lander. Pre-deployment characterization efforts yielded a peak power coefficient of approximately 0.3 for the rotor, although system losses resulted in much lower water-to-wire efficiencies under most operating conditions. The results demonstrate the importance of co-design among key components of the powertrain and control systems to achieve acceptable system efficiency across operating conditions.
DA - 2025/07//
PY - 2025
PB - Springer Nature
UR - https://link.springer.com/article/10.1007/s40722-025-00411-y
DO - 10.1007/s40722-025-00411-y
LA - English
KW - Current
KW - Cross Flow Turbine
KW - Tidal
KW - Full Scale
KW - Site Characterization
KW - Power Take Off
KW - Substructure
ER -

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Abstract

In 2023, a first-generation prototype of a small-scale marine current turbine was operated in Sequim Bay, Washington (USA) for 141 days. The system, referred to as the Turbine Lander, was the product of a laboratory-to-field effort to develop a system that enables enhanced ocean sensing or vehicle recharge in remote, energetic settings. The turbine consists of a vertical-axis, cantilevered rotor (1.19 m x 0.85 m) with four foils installed on a gravity foundation. A broader range of constraints including the deployment strategy, site characteristics, and estimated loads, drove the system’s design. This work presents the design, characterization, operation, and post-recovery engineering assessment of the Turbine Lander. Pre-deployment characterization efforts yielded a peak power coefficient of approximately 0.3 for the rotor, although system losses resulted in much lower water-to-wire efficiencies under most operating conditions. The results demonstrate the importance of co-design among key components of the powertrain and control systems to achieve acceptable system efficiency across operating conditions.

Lessons learned from the design and operation of a small-scale cross-flow tidal turbine is located in Washington, United States of America.