Wind farm interference and terrain interaction simulation by means of an adaptive actuator disc

Wind turbine wake interference is a relevant phenomenon that involves speed losses and turbulence increments which greatly affect downstream turbines, and power efficiency of wind farms. To precisely simulate wake interaction, the most common simplified wind turbine model, the Actuator Disc (AD) mod...

Descripción completa

Guardado en:
Detalles Bibliográficos
Publicado: 2019
Materias:
Actuator disc model
Computational fluid dynamics
Wake interference
Wind farm power efficiency
Wind turbine
Actuator disks
Efficiency
Electric power system interconnection
Electric utilities
Landforms
Open source software
Open systems
Velocity
Wakes
Wind tunnels
Wind turbines
Actuator disc
Characteristic value
Interaction simulations
Non-uniform velocities
Power efficiency
Wake interferences
Wind tunnel experiment
Wind turbine modeling
Onshore wind farms
Acceso en línea:https://bibliotecadigital.exactas.uba.ar/collection/paper/document/paper_01676105_v186_n_p58_NavarroDiaz
http://hdl.handle.net/20.500.12110/paper_01676105_v186_n_p58_NavarroDiaz
Aporte de:
Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA) de Universidad de Buenos Aires
id paper:paper_01676105_v186_n_p58_NavarroDiaz
record_format dspace
spelling paper:paper_01676105_v186_n_p58_NavarroDiaz2023-06-08T15:16:36Z Wind farm interference and terrain interaction simulation by means of an adaptive actuator disc Actuator disc model Computational fluid dynamics Wake interference Wind farm power efficiency Wind turbine Actuator disks Computational fluid dynamics Efficiency Electric power system interconnection Electric utilities Landforms Open source software Open systems Velocity Wakes Wind tunnels Wind turbines Actuator disc Characteristic value Interaction simulations Non-uniform velocities Power efficiency Wake interferences Wind tunnel experiment Wind turbine modeling Onshore wind farms Wind turbine wake interference is a relevant phenomenon that involves speed losses and turbulence increments which greatly affect downstream turbines, and power efficiency of wind farms. To precisely simulate wake interaction, the most common simplified wind turbine model, the Actuator Disc (AD) model, is improved adding the capability to adapt the thrust force distribution to a non-uniform velocity field over the disc, and the orientation to different local wind directions. These situations are typically found in wind farm situation where turbines interact with wakes of upstream turbines and the terrain. This development is based on the OpenFOAM open source finite volume parallel software. The improved AD model is first validated against wind tunnel experiments. Then, an onshore wind farm case is presented, in which the complex interaction of the turbines and terrain is studied. Comparing with power efficiency of field measurements, the simulations succeed to capture the characteristic values for low and high wake impact situations, with differences of 2.5% and 1.3%, respectively. Results show that this improved AD model produces a better solution for wake interaction cases. Its usefulness to predict the wind farm power output at feasible computational cost is also evidenced. © 2018 2019 https://bibliotecadigital.exactas.uba.ar/collection/paper/document/paper_01676105_v186_n_p58_NavarroDiaz http://hdl.handle.net/20.500.12110/paper_01676105_v186_n_p58_NavarroDiaz
institution Universidad de Buenos Aires
institution_str I-28
repository_str R-134
collection Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA)
topic Actuator disc model
Computational fluid dynamics
Wake interference
Wind farm power efficiency
Wind turbine
Actuator disks
Computational fluid dynamics
Efficiency
Electric power system interconnection
Electric utilities
Landforms
Open source software
Open systems
Velocity
Wakes
Wind tunnels
Wind turbines
Actuator disc
Characteristic value
Interaction simulations
Non-uniform velocities
Power efficiency
Wake interferences
Wind tunnel experiment
Wind turbine modeling
Onshore wind farms
spellingShingle Actuator disc model
Computational fluid dynamics
Wake interference
Wind farm power efficiency
Wind turbine
Actuator disks
Computational fluid dynamics
Efficiency
Electric power system interconnection
Electric utilities
Landforms
Open source software
Open systems
Velocity
Wakes
Wind tunnels
Wind turbines
Actuator disc
Characteristic value
Interaction simulations
Non-uniform velocities
Power efficiency
Wake interferences
Wind tunnel experiment
Wind turbine modeling
Onshore wind farms
Wind farm interference and terrain interaction simulation by means of an adaptive actuator disc
topic_facet Actuator disc model
Computational fluid dynamics
Wake interference
Wind farm power efficiency
Wind turbine
Actuator disks
Computational fluid dynamics
Efficiency
Electric power system interconnection
Electric utilities
Landforms
Open source software
Open systems
Velocity
Wakes
Wind tunnels
Wind turbines
Actuator disc
Characteristic value
Interaction simulations
Non-uniform velocities
Power efficiency
Wake interferences
Wind tunnel experiment
Wind turbine modeling
Onshore wind farms
description Wind turbine wake interference is a relevant phenomenon that involves speed losses and turbulence increments which greatly affect downstream turbines, and power efficiency of wind farms. To precisely simulate wake interaction, the most common simplified wind turbine model, the Actuator Disc (AD) model, is improved adding the capability to adapt the thrust force distribution to a non-uniform velocity field over the disc, and the orientation to different local wind directions. These situations are typically found in wind farm situation where turbines interact with wakes of upstream turbines and the terrain. This development is based on the OpenFOAM open source finite volume parallel software. The improved AD model is first validated against wind tunnel experiments. Then, an onshore wind farm case is presented, in which the complex interaction of the turbines and terrain is studied. Comparing with power efficiency of field measurements, the simulations succeed to capture the characteristic values for low and high wake impact situations, with differences of 2.5% and 1.3%, respectively. Results show that this improved AD model produces a better solution for wake interaction cases. Its usefulness to predict the wind farm power output at feasible computational cost is also evidenced. © 2018
title Wind farm interference and terrain interaction simulation by means of an adaptive actuator disc
title_short Wind farm interference and terrain interaction simulation by means of an adaptive actuator disc
title_full Wind farm interference and terrain interaction simulation by means of an adaptive actuator disc
title_fullStr Wind farm interference and terrain interaction simulation by means of an adaptive actuator disc
title_full_unstemmed Wind farm interference and terrain interaction simulation by means of an adaptive actuator disc
title_sort wind farm interference and terrain interaction simulation by means of an adaptive actuator disc
publishDate 2019
url https://bibliotecadigital.exactas.uba.ar/collection/paper/document/paper_01676105_v186_n_p58_NavarroDiaz
http://hdl.handle.net/20.500.12110/paper_01676105_v186_n_p58_NavarroDiaz
_version_ 1768545184115589120

Ejemplares similares