SU625234A1 - Discrete frequency acoustic signal radiator - Google Patents

Description

This invention relates to the field of acoustics and can be used to create directional high-intensity sound waves.

Constructions of discrete-frequency acoustic emitters are known, consisting of a resonant chamber with output nozzles, a wedge and a slotted nozzle located in the plane of symmetry of the wedge passing through its ij edge.

The closest in technical essence to the proposed device is a discrete-frequency acoustic signal emitter, comprising a resonant chamber with an output nozzle, a wedge and a slot nozzle 2J.

The disadvantages of the known devices are the receiving of non-directional radiation and the low acoustic efficiency of the device.

The aim of the invention is to obtain directional radiation and increase the acoustic efficiency of the device.

This is achieved in that the resonant chamber is made in the form of two identical

in height and radius of intersecting cylindrical cavities with common end surfaces, the outlet nozzles being identical and located symmetrically relative to the intersection plane of the cylindrical cavities, the wedge is formed by intersecting lateral surfaces of the cavities, and the slot nozzle is located opposite the wedge in the intersection plane of the cavities, while an external soundproofed screen located in the same plane; in addition, the soundproofed screen is round and the diameter is the screen and the distance between the outlet sections of the nozzles are related by

4-f -) - i

Lee

where d is the diameter of the screen;

 - the distance between the outlet sections of the nozzles;

Claims (2)

L is the wavelength of the emitted acoustic signal of a discrete frequency. Outlets are made in the form of nozzles Vekturn. The drawing schematically shows the emitter. It consists of two resonating cavities 1 and 2 with common end surfaces 3 and 4, two output pipes 5 and 6, a wedge 7, a slotted nozzle 8 and a screen 9. The device works as follows. A gas jet is supplied to the nozzle 8. A leakage to the wedge 7, it is deflected into one of the resonating cavities, for example 1, bounded above and below by surfaces 3 and 4, where a sound pressure pulse is generated, which is radiated through the outlet nozzle 5. At the same time sound pressure from the resonant cavity 1 throws a jet of gas in. resonating cavity 2 and further this process is periodically repeated. Moreover, the output nozzles 5 and 6 emit a sound in antiphase. The radiation pattern is formed by a circular screen 9 separating the outlet nozzle 5 from the output nozzle 6. A signal emitted from, for example, nozzle 5, arrives at the nozzle 6 in phase with the signal emitted from this nozzle 6. Due to this, the radiation resistance increases and consequently, the radiated acoustic power, which leads to an increase in the efficiency of the device. The highest efficiency of the device - 25% is achieved with an overpressure of 0.1 at the cut of the slotted nozzle 8. The radiation pattern of the soundproof screen is circular, and 90% of the radiated power in the direction perpendicular to the screen is emitted with an angle of ratios. Claim 1. An acoustic signal emitter of a discrete frequency, containing a resonant chamber with output nozzles, a wedge and a slot nozzle located in the plane of symmetry of the wedge, passes through its edge, characterized in that, in order to obtain directional radiation and increase the acoustic Efficiency, the resonant chamber is made in the form of two intersecting cylindrical cavities of the same height and radius with common end surfaces, the outlet nozzles being identical and symmetrical Regarding the plane of intersection of the cylindrical strips, the wedge is formed by intersecting side surfaces of the cavities, and the slotted nozzle is located opposite the wedge in the plane of intersection of the cavities, while the radiator is provided with an external soundproof screen located in the same plane. 2. An emitter according to claim 1, characterized in that the soundproof screen is made round, and its diameter and the distance between the outlet sections of the pipes are related by the relation (-f) where d is the screen diameter; E is the distance between the outlet sections of the pipes; iJ is the wavelength of the emitted acoustic signal of a discrete frequency. 3. The emitter according to claim 1, which means that the output pipes are made in the form of Venturi nozzles. . Sources of information taken into account during the examination: 1. US patent number 678625, cl. 116-137,1956. 2. Collection Acoustic coagulation of aerosols. M., Goskhimizdat, 1961, p. 4154.