RU88237U1 - COMBINED HYDROACOUSTIC RECEIVER - Google Patents

Abstract

1. The combined hydroacoustic receiver containing a spherical hollow body, a hydrophone channel connected to the output of the first amplifier, a vector channel made in the form of two series-connected bimorph piezoelectric elements located inside the spherical body and connected to the second amplifier, characterized in that it contains two additional similar vector channels made in the form of two series-connected bimorph piezoelectric elements located inside a spherical of the housing and connected respectively to the additionally introduced third and fourth amplifiers, while the bimorphic piezoelectric elements of each vector channel are pairwise mounted on the housing opposite each other, and the sensitivity axes of the vector channels form a Cartesian coordinate system, and the hydrophone channel is made in the form of two hollow piezoelectric elements fixed outside the spherical body opposite each other and electrically connected in parallel. ! 2. The combined hydroacoustic receiver according to claim 1, characterized in that it further comprises pins mounted opposite each other outside the spherical body symmetrically with respect to its center. ! 3. The combined hydroacoustic receiver according to claim 1, characterized in that the spherical body is made of non-absorbent plastic. ! 4. The combined hydroacoustic receiver according to claim 3, characterized in that the spherical body is made of two pressed hemispheres connected by bolts, while the internal cavity of the body is sealed with a rubber gasket. ! 5. Combi

Description

The utility model relates to the field of sonar and can be used to measure the parameters of sonar noise in the seas and oceans.

Known combined hydroacoustic receiver (QGP), adopted for the prototype, containing a spherical hollow body, a hydrophone channel connected to the output of the first amplifier, a vector channel made in the form of two series-connected bimorph piezoelectric elements located inside the spherical body and connected to the second amplifier / A .FROM. USSR No. 243981, Cl. G10L 1/00, 1969 /.

The disadvantages of the prototype is the inability to measure the direction of propagation of sound vibrations.

The technical result obtained from the implementation of the utility model is the ability to measure the three components of the intensity of the acoustic field.

This technical result is achieved due to the fact that the well-known QGP containing a spherical hollow body, a hydrophone channel connected to the output of the first amplifier, a vector channel made in the form of two series-connected bimorph piezoelectric elements located inside the spherical body and connected to the second amplifier, contains two additional similar vector channels made in the form of two series-connected bimorph piezoelectric elements located inside spherical the housing and connected respectively to the additionally introduced third and fourth amplifiers, while the bimorphic piezoelectric elements of each vector channel are pairwise mounted on the housing opposite each other, and the sensitivity axes of the vector channels form a Cartesian coordinate system, and the hydrophone channel is made in the form of two hollow piezoelectric elements fixed outside the spherical body opposite each other and electrically connected in parallel.

KGP may additionally contain studs mounted opposite each other outside the spherical body symmetrically relative to its center.

The spherical body of the CGP can be made of non-hygroscopic plastic, and two pressed hemispheres can be bolted, while the inner cavity of the body is sealed with a rubber gasket.

Bimorphic piezoelectric QGP elements can be made in the form of disks fixed in centers on supports.

Inside a spherical hollow body, a board for four amplifiers and a similar empty board can be installed symmetrically with respect to one of its axes.

QGP may additionally contain a switch and four electric capacitors, equal in capacitance to the capacities of the corresponding hydrophone and vector channels and installed on the board for four amplifiers, while the outputs of the capacitors, hydrophone and vector channels are made with the possibility of controlled connection to the inputs of the respective amplifiers using a switch.

On the inner surface of the spherical body a multilayer metal spraying is applied, electrically connected to the metal coverings of the hydrophone and to the common bus of the amplifier board.

A metal coating is applied to the outer surface of the hydrophone.

The utility model is illustrated in the drawing, which shows a structural diagram of the QGP.

The receiver contains a spherical hollow body 1 and a hollow piezoelectric hydrophone 2 made of two elements 2 ₁ and 2 ₂ , mounted outside the spherical body 1.

There are also three vector channels located inside the housing 1, each of which is made in the form of two bimorphic piezoelectric elements 3 ₁ and 3 ₂ , set in pairs opposite each other. The sensitivity axes X, Y, Z of each of the vector channels form a Cartesian coordinate system, the origin of which coincides with the center of the spherical hollow body 1.

Inside the hollow body 1, symmetrically with respect to one of its axes, there is a board 4 of four amplifiers and a similar empty board 5.

Studs 6 are attached to the housing 1, mounted opposite each other symmetrically with respect to the center of the housing, made of non-hygroscopic plastic.

The housing 1 is made of two pressed hemispheres connected by bolts (not shown in the drawing).

Bimorph piezoelectric elements 3 are made in the form of discs fixed in the centers on supports (not digitized).

A waterproofed metal coating is applied to the outer surfaces of the hydrophone 2.

On the inner surface of the spherical body 1 is applied a multilayer metal spraying electrically connected to the metal coverings of the hydrophone and to the common bus of the amplifier board (not shown).

The hydrophone elements are mounted on the housing 1 on the plastic bushings 7.

Capacitors are installed on the amplifier board 4, the electric capacitance of each of which is equal to the electric capacitance of the corresponding vector channel, while the outputs of the capacitors and the corresponding channels are configured to connect them to the corresponding amplifier, for example, using a relay or switch (not shown in the drawing).

KGP works as follows.

When a sound wave acts on a QGP from a hydrophone 2 and from vector channels 3, electrical signals are obtained proportional to the acoustic pressure and vibrational velocity of the particles of the medium in the sound wave, respectively, in three coordinates X, Y, Z.

The received signals are amplified by pre-amplifiers and sent through the communication lines (not shown in the drawing) for processing and recorded.

Before starting and ending work, an end-to-end electrical calibration of the channels is carried out, including the communication line and monitoring the operability of all systems.

Claims (9)

1. The combined hydroacoustic receiver containing a spherical hollow body, a hydrophone channel connected to the output of the first amplifier, a vector channel made in the form of two series-connected bimorph piezoelectric elements located inside the spherical body and connected to the second amplifier, characterized in that it contains two additional similar vector channels made in the form of two series-connected bimorph piezoelectric elements located inside a spherical of the housing and connected respectively to the additionally introduced third and fourth amplifiers, while the bimorphic piezoelectric elements of each vector channel are pairwise mounted on the housing opposite each other, and the sensitivity axes of the vector channels form a Cartesian coordinate system, and the hydrophone channel is made in the form of two hollow piezoelectric elements fixed outside the spherical body opposite each other and electrically connected in parallel. 2. The combined hydroacoustic receiver according to claim 1, characterized in that it further comprises pins mounted opposite each other outside the spherical body symmetrically with respect to its center. 3. The combined hydroacoustic receiver according to claim 1, characterized in that the spherical body is made of non-absorbent plastic. 4. The combined hydroacoustic receiver according to claim 3, characterized in that the spherical body is made of two pressed hemispheres connected by bolts, while the internal cavity of the body is sealed with a rubber gasket. 5. The combined hydroacoustic receiver according to claim 1, characterized in that the bimorph piezoelectric elements are made in the form of disks mounted in the centers on supports. 6. The combined hydroacoustic receiver according to claim 1, characterized in that a board for four amplifiers and a similar empty board are installed symmetrically relative to one of its axes inside a spherical hollow body. 7. The combined hydroacoustic receiver according to claim 6, characterized in that it further comprises a switch and four electric capacitors, equal in capacitance to the capacities of the corresponding hydrophone and vector channels and installed on the board for four amplifiers, while the outputs of the capacitors, hydrophone and vector channels are made with the possibility of controlled connection to the inputs of the respective amplifiers using a switch. 8. The combined hydroacoustic receiver according to claim 6 or 7, characterized in that a multilayer metal spraying is applied to the inner surface of the spherical body electrically connected to the metal coverings of the hydrophone and to the common bus of the amplifier board. 9. The combined hydroacoustic receiver according to claim 1, characterized in that a metal coating is applied to the outer surface of the hydrophone.