Wind tunnel experiments on wind turbine wakes in yaw: effects of inflow turbulence and shear J Bartl, F Mühle, J Schottler, L Sætran, J Peinke, M Adaramola, M Hölling Wind Energy Science 3 (1), 329-343, 2018 | 105 | 2018 |
Experimental study on influence of pitch motion on the wake of a floating wind turbine model S Rockel, E Camp, J Schmidt, J Peinke, RB Cal, M Hölling Energies 7 (4), 1954-1985, 2014 | 87 | 2014 |
The turbulent nature of the atmospheric boundary layer and its impact on the wind energy conversion process M Wächter, H Heißelmann, M Hölling, A Morales, P Milan, T Mücke, ... Journal of Turbulence, N26, 2012 | 76 | 2012 |
Wind tunnel experiments on wind turbine wakes in yaw: redefining the wake width J Schottler, J Bartl, F Mühle, L Sætran, J Peinke, M Hölling Wind energy science 3 (1), 257-273, 2018 | 61 | 2018 |
Wake to wake interaction of floating wind turbine models in free pitch motion: An eddy viscosity and mixing length approach S Rockel, J Peinke, M Hölling, RB Cal Renewable Energy 85, 666-676, 2016 | 55 | 2016 |
Multi-scale generation of turbulence with fractal grids and an active grid S Weitemeyer, N Reinke, J Peinke, M Hölling Fluid Dynamics Research 45 (6), 061407, 2013 | 53 | 2013 |
Insights into the periodic gust response of airfoils NJ Wei, J Kissing, TTB Wester, S Wegt, K Schiffmann, S Jakirlic, M Hölling, ... Journal of Fluid Mechanics 876, 237-263, 2019 | 52 | 2019 |
Note on the limitations of the Theodorsen and Sears functions U Cordes, G Kampers, T Meißner, C Tropea, J Peinke, M Hölling Journal of Fluid Mechanics 811, R1, 2017 | 46 | 2017 |
Blind test comparison on the wake behind a yawed wind turbine F Mühle, J Schottler, J Bartl, R Futrzynski, S Evans, L Bernini, P Schito, ... Wind Energy Science 3 (2), 883-903, 2018 | 41 | 2018 |
Dynamic wake development of a floating wind turbine in free pitch motion subjected to turbulent inflow generated with an active grid S Rockel, J Peinke, M Hölling, RB Cal Renewable Energy 112, 1-16, 2017 | 41 | 2017 |
Generation of user defined turbulent inflow conditions by an active grid for validation experiments L Kröger, J Frederik, JW van Wingerden, J Peinke, M Hölling Journal of Physics: Conference Series 1037, 052002, 2018 | 38 | 2018 |
Design and implementation of a controllable model wind turbine for experimental studies J Schottler, A Hölling, J Peinke, M Hölling Journal of Physics: Conference Series 753 (7), 072030, 2016 | 36 | 2016 |
Distinct turbulent regions in the wake of a wind turbine and their inflow-dependent locations: the creation of a wake map I Neunaber, M Hölling, RJAM Stevens, G Schepers, J Peinke Energies 13 (20), 5392, 2020 | 34 | 2020 |
Round-robin tests of porous disc models S Aubrun, M Bastankhah, RB Cal, B Conan, RJ Hearst, D Hoek, M Hölling, ... Journal of Physics: Conference Series 1256 (1), 012004, 2019 | 32 | 2019 |
Comparative study on the wake deflection behind yawed wind turbine models J Schottler, F Mühle, J Bartl, J Peinke, MS Adaramola, L Sætran, ... Journal of Physics: Conference Series 854 (1), 012032, 2017 | 32 | 2017 |
On the impact of non-Gaussian wind statistics on wind turbines–an experimental approach J Schottler, N Reinke, A Hölling, J Whale, J Peinke, M Hölling Wind Energy Science 2 (1), 1-13, 2017 | 32 | 2017 |
Comparison of the turbulence in the wakes of an actuator disc and a model wind turbine by higher order statistics: A wind tunnel study I Neunaber, M Hölling, J Whale, J Peinke Renewable Energy 179, 1650-1662, 2021 | 29 | 2021 |
Wind tunnel tests on controllable model wind turbines in yaw J Schottler, A Hölling, J Peinke, M Hölling 34th wind energy symposium, 1523, 2016 | 29 | 2016 |
Wind turbine wake intermittency dependence on turbulence intensity and pitch motion H Kadum, S Rockel, M Hölling, J Peinke, RB Cal Journal of Renewable and Sustainable Energy 11 (5), 2019 | 24 | 2019 |
Exploring the capabilities of active grids L Neuhaus, F Berger, J Peinke, M Hölling Experiments in Fluids 62 (6), 130, 2021 | 21 | 2021 |