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Design and Analysis of Hydromine for Harvesting Energy from Ocean Currents with No External Moving Parts

Conference Paper

Title: Design and Analysis of Hydromine for Harvesting Energy from Ocean Currents with No External Moving Parts
Author:
Houchens, B.; deVelder, N.; Krath, E.; Lewis, J.
Publication Date:
Event Name:
OCEANS 2023 Limerick
Event Location:
Limerick, Ireland
Publisher:
IEEE
Affiliation:
Sandia National Laboratories
Technology:
Current, Ocean Current
Collection Method:
Modeling
Engineering:
Hydrodynamics, Performance
Economics:
Cost Assessment
Signature Project:
RM4: Ocean Current Turbine
Language:
English

Document Access

Website:
External Link

Citation

Houchens, B.; deVelder, N.; Krath, E.; Lewis, J. (2023). Design and Analysis of Hydromine for Harvesting Energy from Ocean Currents with No External Moving Parts. Paper presented at OCEANS 2023 Limerick, Limerick, Ireland.https://doi.org/10.1109/OCEANSLimerick52467.2023.10244683
@conference{Houchens-2023-21448,
author = {Houchens, B and deVelder, N and Krath, E and Lewis, J},
title = {Design and Analysis of Hydromine for Harvesting Energy from Ocean Currents with No External Moving Parts},
year = {2023},
month = {jun},
series = {OCEANS 2023 Limerick},
address = {Limerick, Ireland},
publisher = {IEEE},
doi = {10.1109/OCEANSLimerick52467.2023.10244683},
url = {https://ieeexplore.ieee.org/abstract/document/10244683},
keywords = {Current, Ocean Current, Modeling, Hydrodynamics, Performance, Cost Assessment},
}
Export Citation to BibTex
TY - CONF
TI - Design and Analysis of Hydromine for Harvesting Energy from Ocean Currents with No External Moving Parts
AU - Houchens, B
AU - deVelder, N
AU - Krath, E
AU - Lewis, J
T2 - OCEANS 2023 Limerick
C1 - Limerick, Ireland
AB - The novel Hydromine harvests energy from flowing water with no external moving parts, resulting in a robust system with minimal environmental impact. Here two deployment scenarios are considered: an offshore floating platform configuration to capture energy from relatively steady ocean currents at megawatt-scale, and a river-based system at kilowatt-scale mounted on a pylon. Hydrodynamic and techno-economic models are developed. The hydrodynamic models are used to maximize the efficiency of the power conversion. The techno-economic models optimize the system size and layout and ultimately seek to minimize the levelized-cost-of-electricity produced. Parametric and sensitivity analyses are performed on the models to optimize performance and reduce costs.
DA - 2023/06//
PY - 2023
PB - IEEE
UR - https://ieeexplore.ieee.org/abstract/document/10244683
DO - 10.1109/OCEANSLimerick52467.2023.10244683
LA - English
KW - Current
KW - Ocean Current
KW - Modeling
KW - Hydrodynamics
KW - Performance
KW - Cost Assessment
ER -
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Abstract

The novel Hydromine harvests energy from flowing water with no external moving parts, resulting in a robust system with minimal environmental impact. Here two deployment scenarios are considered: an offshore floating platform configuration to capture energy from relatively steady ocean currents at megawatt-scale, and a river-based system at kilowatt-scale mounted on a pylon. Hydrodynamic and techno-economic models are developed. The hydrodynamic models are used to maximize the efficiency of the power conversion. The techno-economic models optimize the system size and layout and ultimately seek to minimize the levelized-cost-of-electricity produced. Parametric and sensitivity analyses are performed on the models to optimize performance and reduce costs.