Abstract
Abstract. The low-frequency emissions from a generic 5 MW wind turbine are investigated numerically. In order to regard airborne noise and structure-borne noise simultaneously, a process chain is developed. It considers fluid–structure coupling (FSC) of a computational fluid dynamics (CFD) solver and a multi-body simulations (MBSs) solver as well as a Ffowcs-Williams–Hawkings (FW-H) acoustic solver. The approach is applied to a generic 5 MW turbine to get more insight into the sources and mechanisms of low-frequency emissions from wind turbines. For this purpose simulations with increasing complexity in terms of considered components in the CFD model, degrees of freedom in the structural model and inflow in the CFD model are conducted. Consistent with the literature, it is found that aeroacoustic low-frequency emission is dominated by the blade-passing frequency harmonics. In the spectra of the tower base loads, which excite seismic emission, the structural eigenfrequencies become more prominent with increasing complexity of the model. The main source of low-frequency aeroacoustic emissions is the blade–tower interaction, and the contribution of the tower as an acoustic emitter is stronger than the contribution of the rotor. Aerodynamic tower loads also significantly contribute to the external excitation acting on the structure of the wind turbine.
Highlights
Renewable sources of energy and especially wind power have seen a strong expansion in the last years
As wind turbines are counted among the tallest machines on the planet that work in an uncontrolled outside environment, noise and vibration emissions occur in a broad frequency range
The aim of the present paper is to identify the sources of low-frequency emissions and to investigate the impact of the complexity of the numerical model on the calculated low-frequency emissions from a generic 5 MW wind turbine
Summary
Renewable sources of energy and especially wind power have seen a strong expansion in the last years. Zieger and Ritter (2018) observed an increase in amplitudes in a frequency range from 0.5 to 10 Hz dependent on the rotational speed of the turbine and wind speed at a distance of 5.5 km away from a wind turbine. This confirms the measurements by Stammler and Ceranna (2016) and Styles et al (2005), who found that nearby wind. The measured deformations between deformed and undeformed markers are composed of flexible deformations of the body itself plus rigid-body motion due to the deformation or motion of the adjacent body
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