SU1184110A1 - Acoustic radiator - Google Patents

Description

The invention relates to electroacoustics and can be used in the sound systems of open spaces and rooms.

Known gradient emitter, 5 containing a loudspeaker mounted in the housing, the back wall of which is made with a hole (or a group of holes), closed cloth G1]. ^ten

In a known radiator, with increasing frequency, the radiation directivity of the front side of the loudspeaker cone sharpens.

The closest to the technical essence of the invention is a gradient source of the second order, containing four radiating elements having a circular aperture located 20

one after another at equal distances, a low-pass filter and a phase-shifting circuit connected in series to the third and fourth radiating elements. At the same time, the second 25 and the third radiating elements have the inclusion polarity opposite to the first and fourth elements of the sign [2].

thirty

The disadvantage of the known emitter is that its effective frequency range is limited, while the sound pressure reaches its maximum at a frequency outside the effective range, i.e. within the effective range of the emitter has a low sensitivity.

The purpose of the invention is the increase of 40

radiator sensitivity, as well as frequency stabilization of the directivity characteristic.

This goal is achieved by the fact that an acoustic radiator ^ ^ 5 containing four radiating elements installed at equal distances one after the other, as well as a phase-shifting element and a low-pass filter, introduced a second phase-shifting element, with the first phase-shifting element connected in series to the second radiating element, and the second phase-shifting element is connected in series to the 55th fourth radiating element.

On fig.ί presents a diagram of the emitter; figure 2 - one of the options for the possible implementation; on fig.Z - radiation pattern.

The acoustic emitter contains four point radiating elements 1-4, elements 2 and 3 have a polarity of inclusion, opposite to the sign of elements 1 and 4, two 5.5 ^x phase-shifting elements, which are connected in series to radiating elements 2 and 4, as well as one phase-shifting element connected to the radiating elements 2 and 4. In series with the radiating elements 3 and 4, a low-pass filter 6 is connected.

An acoustic emitter is a dipole compound of two gradient sources of the first order with a cardioid directional characteristic. The directionality characteristic of such a source is defined as the product of a cardioid and a cosinusoid, i.e.

K-cos,

I

and the frequency response of the sound pressure is expressed by

These expressions are valid if the phase-shifting circuits 5 and 5 ¹ impart to the oscillatory velocities of elements 2 and 4 a linear phase shift equal to 27HG / L.

The effective frequency range of the emitter is limited by the frequency corresponding to L / R | = 0.5. In this range, the sound pressure reaches a maximum value of P = 4 at = 0.25, and the directional characteristic has the form shown in FIG. 3 (curve I).

The acoustic emitter is made in the form of two gradient emitters of the first order (figure 2).

They must be located one after the other at a distance of b and switched on in antiphase. The radiating elements 1 and 3 here are the front sides of the loudspeaker diffusers, and the elements 2 and 4 are holes on the back walls of the drawers.

In this case, the emitter has two identical acoustic phase-shifting HS chains 5 and 5 ', about 1184110

developed by the parameters of acoustic designs of loudspeakers, which are simultaneously acoustic low-pass filters with a cut-off frequency corresponding to L / 3 = 0.5. Using the low-pass filter 6, the rear loudspeaker is turned off with increasing frequency and the directionality of the radiator is determined by the directionality of the front side of the front loudspeaker diffuser, i.e. retains in the mid-frequency region an outstretched shape.

On fig.Z shows the radiation pattern of the radiator for the low frequency region, i.e. for b / l <0.5 (curve I) and the region of average hours5, that is, for b / 3> 0.5 (curve II).

The use of an acoustic emitter with the specified inclusion of phase-shifting elements will allow to increase the sensitivity and stabilize the directivity in a wider frequency range.

FIG. g

Fig.Z

Claims (2)

ACOUSTIC RADIATOR, containing four radiating elements having circular directivity characteristics in the low-frequency region and located respectively one after the other at equal distances, as well as a phase-shifting element having a linear phase-frequency characteristic and a low-pass filter connected in series with the third and fourth radiating elements, while the second and third radiating elements have an inclusion polarity opposite to the first and fourth elements, characterized in that, in order to increase For the purpose of frequency stabilization, the second phase-shifting element is inserted into it, the first phase-shifting element is connected in series to the second radiating element, and the second phase-shifting element is connected in series to the fourth radiating element. , _I 5i „., 1184110 > one 1184110 2