Adaptive Concepts for Herschel–Quincke Waveguides

Abstract: The enhancement of Herschel–Quincke (HQ) waveguides to incorporate adaptive capabilities is investigated. Passive HQ waveguides are known to provide noise attenuation in pipes and ducts at selective narrow frequency bands associated with their resonances. The approach to achieve adaptation is to produce a frequency shift in these resonances to allow targeting incoming tonal noise of variable frequency. The frequency shift is obtained by placing a variable cross-section constriction along the interior of the wa… Show more

“…They mainly considered two devices: the first variable cross-section was a fixed-diameter ball that could move axially in the waveguide to obtain frequency shift by the ball position function; the second type of variable cross-section was composed of a fixed-position diaphragm, which obtained a variable cross-section through the deformation of the diaphragm, in which case, the frequency shift depended on the diaphragm deflection function. The internal acoustics and dynamics of these two devices were analyzed and experimentally studied, and the calculated and experimental results were compared and analyzed to verify the reliability of the model [16].…”

Research on the Impact of a Fluid Field on an Acoustic Field in Herschel–Quincke Tube

“…They mainly considered two devices: the first variable cross-section was a fixed-diameter ball that could move axially in the waveguide to obtain frequency shift by the ball position function; the second type of variable cross-section was composed of a fixed-position diaphragm, which obtained a variable cross-section through the deformation of the diaphragm, in which case, the frequency shift depended on the diaphragm deflection function. The internal acoustics and dynamics of these two devices were analyzed and experimentally studied, and the calculated and experimental results were compared and analyzed to verify the reliability of the model [16].…”

Research on the Impact of a Fluid Field on an Acoustic Field in Herschel–Quincke Tube

Side-branch resonators modelling with Green׳s function methods

Passive control of vibrations of a beam by means of Herschel–Quincke vibration filters