The goal of the thesis is to explore the potential use of Helmholtz resonator for tackling the noise problems caused by small wind turbines. The capabilities of different types of Helmholtz resonators are investigated via both theoretical and experimental approaches. The most appropriate type of Helmholtz resonator is used to design a noise reductive device for reducing the noise generated by a wind turbine within a specific frequency range. In the experimental study, a sound absorption measurement instrument (ASTM E1050-98: dual microphones experiment) was fabricated to measure the sound absorption coefficients of different types of Helmholtz resonators and study the characteristics (magnitude of sound absorption coefficient and frequency range) of the Helmholtz resonators. In the theoretical study, the finite element (FE) code ANSYS is used to simulate the sound fields of different Helmholtz resonators. The experimental results are used to verify the suitability of the proposed FE models. It has been shown that among the resonators under consideration, the Helmholtz resonator comprises glass-fabric perforated cover plate and hollow box fabricated with porous material can produce the best sound absorption capability for wind turbine application. The results of ANSYS sound field simulations of a small wind turbine with noise reductive device have shown that the proposed noise reduction device does have the noise reduction effects on the sound field generated by the wind turbine. Finally, a simple noise reduction experiment in which the proposed noise reduction device was used to reduce the noise generated by a small fan was conducted to further demonstrate the capability of the proposed noise reduction device. The results have indicated that this noise reduction device achieves the goal of noise reduction and has the potential to find applications in wind turbines.