A blind test on wind turbine wake modelling: Benchmark results and Phase II announcement

I. Chondromatidis; V. Pappa; B. S. Dsouza; A. Sciacchitano; S. Tamaro; F. V. Mühle; F. Campagnolo; M. Manolesos

doi:10.1088/1742-6596/3016/1/012035

A blind test on wind turbine wake modelling: Benchmark results and Phase II announcement

I. Chondromatidis, V. Pappa, B. S. Dsouza, A. Sciacchitano, S. Tamaro, F. V. Mühle, F. Campagnolo, M. Manolesos

Aerodynamics

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Abstract

Accurate modelling of wind turbine wakes is critical for optimizing wind farm performance, but the complexity of wake interactions poses significant challenges. This study presents a two-phase blind test campaign, part of the Horizon Europe TWEET-IE project, designed to benchmark numerical models and investigate wake control strategies using wind tunnel experiments. Conducted with tandem wind turbine models at the Technical University of Munich and the National Technical University of Athens, the tests include inflow, load, power, and wake velocity measurements under controlled conditions. Phase I serves as an open-data benchmarking exercise for a baseline scenario without wake control, while Phase II introduces active individual blade pitch control to the upstream turbine, challenging participants to simulate advanced wake dynamics. This paper reviews Phase I results and details the experimental framework for Phase II, providing a foundation for advancing wake modelling and control in wind energy research.

Original language	English
Article number	012035
Number of pages	10
Journal	Journal of Physics: Conference Series
Volume	3016
Issue number	1
DOIs	https://doi.org/10.1088/1742-6596/3016/1/012035
Publication status	Published - 2025
Event	10th Wake Conference 2025 - Visby, Sweden Duration: 10 Jun 2025 → 12 Jun 2025

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Chondromatidis_2025_J._Phys.__Conf._Ser._3016_012035Final published version, 1.79 MBLicence: CC BY

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title = "A blind test on wind turbine wake modelling: Benchmark results and Phase II announcement",

abstract = "Accurate modelling of wind turbine wakes is critical for optimizing wind farm performance, but the complexity of wake interactions poses significant challenges. This study presents a two-phase blind test campaign, part of the Horizon Europe TWEET-IE project, designed to benchmark numerical models and investigate wake control strategies using wind tunnel experiments. Conducted with tandem wind turbine models at the Technical University of Munich and the National Technical University of Athens, the tests include inflow, load, power, and wake velocity measurements under controlled conditions. Phase I serves as an open-data benchmarking exercise for a baseline scenario without wake control, while Phase II introduces active individual blade pitch control to the upstream turbine, challenging participants to simulate advanced wake dynamics. This paper reviews Phase I results and details the experimental framework for Phase II, providing a foundation for advancing wake modelling and control in wind energy research.",

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AU - Chondromatidis, I.

AU - Pappa, V.

AU - Dsouza, B. S.

AU - Sciacchitano, A.

AU - Tamaro, S.

AU - Mühle, F. V.

AU - Campagnolo, F.

AU - Manolesos, M.

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AB - Accurate modelling of wind turbine wakes is critical for optimizing wind farm performance, but the complexity of wake interactions poses significant challenges. This study presents a two-phase blind test campaign, part of the Horizon Europe TWEET-IE project, designed to benchmark numerical models and investigate wake control strategies using wind tunnel experiments. Conducted with tandem wind turbine models at the Technical University of Munich and the National Technical University of Athens, the tests include inflow, load, power, and wake velocity measurements under controlled conditions. Phase I serves as an open-data benchmarking exercise for a baseline scenario without wake control, while Phase II introduces active individual blade pitch control to the upstream turbine, challenging participants to simulate advanced wake dynamics. This paper reviews Phase I results and details the experimental framework for Phase II, providing a foundation for advancing wake modelling and control in wind energy research.

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A blind test on wind turbine wake modelling: Benchmark results and Phase II announcement

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