Simulating current-energy converters: SNL-EFDC model development, verification, and parameter estimation
Increasing interest in power production from ocean, tidal, and river currents has led to significant efforts to maximize energy conversion through optimal design and siting and to minimize effects on the environment. Turbine-based, current-energy-converter (CEC) technologies remove energy from curre...
- Autores:
- Tipo de recurso:
- Fecha de publicación:
- 2020
- Institución:
- Universidad de Medellín
- Repositorio:
- Repositorio UDEM
- Idioma:
- eng
- OAI Identifier:
- oai:repository.udem.edu.co:11407/5744
- Acceso en línea:
- http://hdl.handle.net/11407/5744
- Palabra clave:
- Current-energy conversion
Marine renewable energy
Numerical modeling
SNL-EFDC
Energy conversion
Numerical models
Ocean currents
Tidal power
Turbulence models
Wakes
Water quality
Current energy
Environmental fluid dynamics code
Marine renewable energy
Sandia National Laboratories
SNL-EFDC
Three-dimensional model
Turbulence measurements
Turbulence parameters
Parameter estimation
- Rights
- License
- http://purl.org/coar/access_right/c_16ec
| Summary: | Increasing interest in power production from ocean, tidal, and river currents has led to significant efforts to maximize energy conversion through optimal design and siting and to minimize effects on the environment. Turbine-based, current-energy-converter (CEC) technologies remove energy from current-driven systems and in the process generate distinct wakes, which can interact with other CEC devices and can alter flow regimes, sediment dynamics, and water quality. This work introduces Sandia National Laboratories-Environmental Fluid Dynamics Code CEC module and verifies it against a two-dimensional analytical solution for power generation and hydrodynamic response of flow through a CEC tidal fence. With a two-dimensional model that accurately reflects an analytical solution, the effort was extended to three-dimensional models of three different laboratory-flume experiments that measured the impacts of CEC devices on flow. Both flow and turbulence model parameters were then calibrated against wake characteristics and turbulence measurements. This is the first time that turbulence parameter values have been specified for CEC devices. Measurements and simulations compare favorably and demonstrate the utility and accuracy of this numerical approach for simulating the impacts of CEC devices on the flow field. The model can be extended to future siting and analyses of CEC arrays in complex domains. © 2017 Elsevier Ltd |
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