RU2071622C1 - Sonar antenna dome - Google Patents

Abstract

FIELD: hydroacoustics; sonar antenna anti-interference devices on board moving carrier ships. SUBSTANCE: antennas are placed in domes in the form of flexible rubber envelope of varying thickness filled with water in working state. EFFECT: improved efficiency of flexible dome due to air space built up in its stern part for shielding antennas from noise produced by carrier ship propeller. 1 dwg

Description

 The invention relates to sonar, and in particular to devices for protecting sonar antennas from interference caused by the movement of the carrier vessel.

 The technical result of the invention is to increase the efficiency of a flexible fairing by creating an air cavity in its aft part to shield the antenna from the noise of the propeller of the carrier vessel.

This is achieved by the fact that the fairing for hydroacoustic antennas containing a flexible rubber shell 1 and a water supply system 2 for creating and maintaining pressure inside the flexible rubber shell is additionally equipped with a sealed cavity 3 formed by the inner surface of the stern of the flexible rubber shell 1, the length of which is in the projection on the horizontal plane allows the antenna viewing angle range of at least ± 120 ^o, and a flexible membrane 4 made of synthetic elastomeric material such as polyurethane, is fixed for this second boundary surface and the air supply system and adjusting the pressure thereof within a sealed cavity 5 connected to the uppermost and lowermost aft bow portions sealed cavity (see. the drawing).

 The air supply system and the regulation of its pressure 5 inside the airtight cavity consists of the air supply system 6 itself, connected to the airtight cavity in its uppermost part and a pressure meter 7 with electrical parameters connected to the airtight cavity in its lowermost nose, which carries out control of the air supply system 6. The air supply system 6 can be implemented, for example, in the form of a series-connected compressor, a tank equipped with a pressure meter with lektrokontaktnymi pairs, and the pressure line with remote controlled valves coupled to the sealed cavity in the uppermost part of the feed.

 Fairing for sonar antennas works as follows.

 After bringing the flexible rubber shell 1 into position using the overboard water supply system 2 under pressure, the air supply system 6 in the sealed cavity 3 is turned on. As the volume of air supplied to the sealed cavity 3 increases, the elastic membrane 4 moves away from the inner surface of the flexible rubber shell 1, and air fills the entire airtight cavity 3.

 At the same time, the pressure meter connected to the lowest nose of the pressurized cavity 7 with electrocontact pairs 7, upon reaching the value of the air pressure for the fairing in the pressurized cavity, gives a command to stop the air supply to the system 6. When the pressure drops in the cavity, the pressure meter with electrocontact pairs 7 issues a command for air supply by system 6, thereby automatically adjusting the pressure in the sealed cavity 3. To bring the fairing to its original state in Air from the sealed cavity and water from the flexible rubber shell are removed.

Claims (2)

 1. A fairing for a hydroacoustic antenna, comprising a flexible rubber shell of variable thickness with aft and fore parts and a water supply system for creating pressure inside the said shell, characterized in that the fairing is equipped with air supply systems, regulating its pressure and an elastic membrane fixed to it internal feed surface with the formation of a sealed cavity, while the aforementioned air supply system is connected to this cavity in its upper aft part, and the control system The magnitude of its pressure is connected to this cavity in its lower nasal part.  2. The fairing according to claim 1, characterized in that the elastic membrane is made of synthetic elastomeric material, mainly polyurethane, and the thickness of the elastic membrane does not exceed one tenth of the sound wavelength in water at the operating frequency.