RU168260U1 - PNEUMATIC RADIATOR - Google Patents

Abstract

The utility model relates to pneumatic pulse generators and can be used by supplying a discrete portion of compressed air at a given point in time to excite elastic vibrations in an aqueous medium. The pneumatic radiator comprises a high-pressure chamber communicated through a shut-off valve with a source of compressed air, the pneumatic radiator provided with an inflatable elastic shell and a high-pressure chamber communicated with an inflatable elastic shell through an outlet pipe on which a quick-acting valve is installed, and the inflatable elastic shell is hermetically fixed on the outlet pipe passed through it, the outlet end of the outlet pipe protruding from the inflatable elastic shell, sn it is filled with an adjustable relief valve, and holes are made in the wall of the exhaust pipe located inside the inflatable elastic shell. As a result, it is possible to achieve high repeatability of the generated hydroacoustic pulse with a maximum radiation in the low frequency range, which reduces the negative impact of the formed hydroacoustic effect on living marine organisms.

Description

The utility model relates to pneumatic pulse generators and can be used by supplying a discrete portion of compressed air at a given time to excite elastic vibrations in an aqueous medium with the formation of low-frequency hydroacoustic pulses in water for conducting, in particular, seismic marine reconnaissance.

Known hydropneumatic emitter containing a pneumatic high-pressure chamber communicated through a shut-off valve with a source of compressed air, and a hydraulic chamber (see US patent No. 4753316, 06/28/1988).

However, the supply of a portion of the liquid under pressure does not allow a sufficiently powerful pressure pulse to generate sonar pulses, which narrows the scope of use of this emitter.

Closest to the utility model in terms of technical nature and the achieved result is a pneumatic emitter containing a high-pressure chamber communicated through a shut-off valve with a compressed air source (see US patent No. 3653460, 04.04.1972)

However, the direct injection of a portion of air into the water with each actuation of the shutoff valve has from time to time low repeatability of the temporal shape of the hydroacoustic pulse.

The technical problem solved by the utility model is to increase the stability of the pneumatic emitter.

The technical result is that it is possible to achieve high repeatability of the generated sonar pulse with a maximum radiation in the low frequency range, which reduces the negative impact of the formed sonar effect on living marine organisms.

The specified technical problem is solved, and the technical result is achieved due to the fact that the pneumatic radiator comprises a high-pressure chamber communicated through a shut-off valve with a source of compressed air, while the pneumatic radiator is provided with an inflatable elastic shell, and the high-pressure chamber communicates with the inflated elastic shell through the outlet a nozzle on which a quick-acting valve is installed, and the inflatable elastic shell is hermetically fixed to the outlet passed through it atrubke outlet end the outlet pipe extending from an inflatable flexible envelope provided with an adjustable bleed valve, and in the wall outlet, situated inside the inflatable flexible membrane openings.

The design features described above make it possible to achieve a high repeatability of the movement of the inflated elastic shell in comparison with the direct injection of a portion of compressed air into the aqueous medium surrounding the pneumatic radiator. It is important that the inflated elastic shell after expansion does not compress by inertia, in contrast to a gas bubble formed directly in water, but compresses relatively slowly and controlledly, which greatly simplifies the registration of pulses reflected from the bottom structures. The emission spectrum is determined not only by the pressure of compressed air and the volume of the high-pressure chamber, but also by the material and design of the inflated elastic shell. The tests showed that it is possible to obtain a radiation spectrum with a maximum in a given low frequency range from 20 to 60 Hz and a low level at high frequencies, which allows to increase the efficiency of the pneumatic emitter and reduce the destructive effect of the high-frequency component of the hydroacoustic pulse on marine animals. In addition, during the operation of a pneumatic radiator, a high-speed valve only works with compressed air without contact with water, which reduces the requirements for the material from which the high-speed valve is made and increases its service life.

The drawing schematically shows the design of a pneumatic emitter, where the inflatable elastic shell is shown in an inflated state.

Pneumatic emitter contains a high pressure chamber 1, communicated through a shut-off valve 2 with a source of compressed air.

In addition, the pneumatic radiator is equipped with an inflatable elastic shell 3, and the high-pressure chamber 1 is in communication with the inflatable elastic shell 3 through an outlet pipe 4 on which a quick-acting valve 5 is installed.

The inflatable elastic shell 3 is hermetically fixed on the outlet pipe 4 passed through it. The outlet end of the outlet pipe 4 protruding from the inflatable elastic shell 3 is provided with an adjustable relief valve 6, and holes are made in the wall of the outlet pipe 4 located inside the inflatable elastic shell 3.

Works pneumatic emitter as follows.

In the initial position, the shutoff valve 2 is open, and the high-speed valve 5 is closed, while the pressure of compressed air in the high-pressure chamber 1 reaches a maximum value.

After that, the shut-off valve 2 is closed smoothly and then quickly (within a time of not more than 10 ms), the high-speed valve 5 is opened.

Under the action of high air pressure from the high-pressure chamber 1, the inflated elastic shell 3 expands to its maximum volume.

During the tests, when the volume of the inflatable elastic shell 3 was about 10 l, the expansion time of the inflatable elastic shell 3 was no more than 20 ms, and the shell with a volume of about 40 l was not more than 40 ms.

Then, the adjustable relief valve 6 is smoothly opened and the air from the inflatable elastic shell 3 is discharged into the space surrounding the inflatable elastic shell 3.

After that, close the adjustable relief valve 6 and quick-acting valve 5 and open the shut-off valve 2 to raise the pressure of the compressed air in the high-pressure chamber 1 to a maximum value.

Next, the cycle of operation of the pneumatic emitter is repeated, as described above.

Claims (1)

A pneumatic emitter comprising a high-pressure chamber communicated through a shut-off valve with a source of compressed air, characterized in that it is provided with an inflatable elastic shell, and a high-pressure chamber communicated with an inflatable elastic shell through an outlet pipe on which a quick-acting valve is installed, wherein the inflatable elastic shell hermetically fixed on the outlet pipe passed through it, the outlet end of the outlet pipe protruding from the inflatable elastic shell is provided with osnym adjustable valve, and in the wall outlet, situated inside the inflatable flexible membrane openings.

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