CFD-based design optimization of a 5 kW ducted hydrokinetic turbine with practical constraints
Ducted hydrokinetic turbines enhance energy-harvesting efficiency by better conditioning the flow to the blades, which may yield higher power output than conventional freestream turbines for the same reference area. In this work, we present a ducted hydrokinetic turbine design obtained by simultaneo...
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| creator | Park, Jeongbin Mangano, Marco Seraj, Sabet Pacini, Bernardo Liao, Yingqian Knight, Bradford G Naik, Kartik Maki, Kevin J Martins, Joaquim R. R. A Sun, Jing Pan, Yulin |
| description | Ducted hydrokinetic turbines enhance energy-harvesting efficiency by better
conditioning the flow to the blades, which may yield higher power output than
conventional freestream turbines for the same reference area. In this work, we
present a ducted hydrokinetic turbine design obtained by simultaneously
optimizing the duct, blade, and hub geometries. Our optimization framework
combines a CFD solver, an adjoint solver, and a gradient-based optimizer to
efficiently explore a large design space, together with a feature-based
parameterization method to handle the complex geometry. Practical geometrical
constraints ensure the manufacturability of the duct in terms of a minimum
thickness and the housing of a 5 kW generator within the hub. The optimization
converges to a short, thin duct with a rounded leading edge and an elongated
hub protruding the duct inlet. The optimized ducted turbine achieves up to 50%
efficiency when evaluated by RANS/URANS solvers despite a bulky hub,
outperforming the 45% efficiency of the freestream Bahaj turbine featuring the
same hub. This work showcases the effectiveness of CFD-based optimization in
advancing ducted turbine designs and demonstrates the hydrodynamic benefits of
a ducted configuration, paving the way for future research and real-world
applications. |
| doi_str_mv | 10.48550/arxiv.2411.13492 |
| format | Article |
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conditioning the flow to the blades, which may yield higher power output than
conventional freestream turbines for the same reference area. In this work, we
present a ducted hydrokinetic turbine design obtained by simultaneously
optimizing the duct, blade, and hub geometries. Our optimization framework
combines a CFD solver, an adjoint solver, and a gradient-based optimizer to
efficiently explore a large design space, together with a feature-based
parameterization method to handle the complex geometry. Practical geometrical
constraints ensure the manufacturability of the duct in terms of a minimum
thickness and the housing of a 5 kW generator within the hub. The optimization
converges to a short, thin duct with a rounded leading edge and an elongated
hub protruding the duct inlet. The optimized ducted turbine achieves up to 50%
efficiency when evaluated by RANS/URANS solvers despite a bulky hub,
outperforming the 45% efficiency of the freestream Bahaj turbine featuring the
same hub. This work showcases the effectiveness of CFD-based optimization in
advancing ducted turbine designs and demonstrates the hydrodynamic benefits of
a ducted configuration, paving the way for future research and real-world
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conditioning the flow to the blades, which may yield higher power output than
conventional freestream turbines for the same reference area. In this work, we
present a ducted hydrokinetic turbine design obtained by simultaneously
optimizing the duct, blade, and hub geometries. Our optimization framework
combines a CFD solver, an adjoint solver, and a gradient-based optimizer to
efficiently explore a large design space, together with a feature-based
parameterization method to handle the complex geometry. Practical geometrical
constraints ensure the manufacturability of the duct in terms of a minimum
thickness and the housing of a 5 kW generator within the hub. The optimization
converges to a short, thin duct with a rounded leading edge and an elongated
hub protruding the duct inlet. The optimized ducted turbine achieves up to 50%
efficiency when evaluated by RANS/URANS solvers despite a bulky hub,
outperforming the 45% efficiency of the freestream Bahaj turbine featuring the
same hub. This work showcases the effectiveness of CFD-based optimization in
advancing ducted turbine designs and demonstrates the hydrodynamic benefits of
a ducted configuration, paving the way for future research and real-world
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conditioning the flow to the blades, which may yield higher power output than
conventional freestream turbines for the same reference area. In this work, we
present a ducted hydrokinetic turbine design obtained by simultaneously
optimizing the duct, blade, and hub geometries. Our optimization framework
combines a CFD solver, an adjoint solver, and a gradient-based optimizer to
efficiently explore a large design space, together with a feature-based
parameterization method to handle the complex geometry. Practical geometrical
constraints ensure the manufacturability of the duct in terms of a minimum
thickness and the housing of a 5 kW generator within the hub. The optimization
converges to a short, thin duct with a rounded leading edge and an elongated
hub protruding the duct inlet. The optimized ducted turbine achieves up to 50%
efficiency when evaluated by RANS/URANS solvers despite a bulky hub,
outperforming the 45% efficiency of the freestream Bahaj turbine featuring the
same hub. This work showcases the effectiveness of CFD-based optimization in
advancing ducted turbine designs and demonstrates the hydrodynamic benefits of
a ducted configuration, paving the way for future research and real-world
applications.</abstract><doi>10.48550/arxiv.2411.13492</doi><oa>free_for_read</oa></addata></record> |
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| title | CFD-based design optimization of a 5 kW ducted hydrokinetic turbine with practical constraints |
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