Abstract
Transformer noise is dominated by low frequency components, which are hard to be controlled with traditional noise control approaches. The shunt loudspeaker consisting of a closed-box loudspeaker and a shunt circuit has been proposed as an effective sound absorber by storing and dissipating the electrical energy converted from the incident sound. In this paper, an array of shunt loudspeakers is proposed to control the 100 Hz and 200 Hz components of transformer noise. The prototype under tests has a thickness of 11.8 cm, which is only 1/28 of the wavelength of 100 Hz. The sound absorption performance of the array under random incidence is analyzed with the parallel impedance method, and the arrangement of array elements is optimized. The test results in a reverberation room show that the proposed array has sound absorption coefficients of 1.04 and 0.93 at 100 Hz and 200 Hz, respectively, which provides potential of applying this type of thin absorbers for low-frequency sound control.
Highlights
Transformer noise is dominated by low frequency components, which are hard to be controlled with traditional noise control approaches
These results demonstrate that a single shunt loudspeaker (SL) can be an effective and adjustable sound absorber
Several SLs have been used for the room mode e qualizations[32,33], the sound absorption performance of SL arrays under the random incidence is unknown, which is reported in this paper
Summary
Transformer noise is dominated by low frequency components, which are hard to be controlled with traditional noise control approaches. Five layout patterns with different intervals of 33 cm, 25 cm, 16.5 cm, 8.3 cm and 0 cm were investigated and the random incident absorption coefficient was measured in the reverberation room.
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