RU46610U1 - ANTENNA DEVICE FOR RESCUE BOAT - Google Patents

Abstract

The utility model relates to the field of emergency communications technology, in particular to means of exhaust antenna devices used in emergency situations on submarines.

The device comprises a radio transmitter antenna with a retractable device mounted on an emergency buoy, while a durable glass is installed on the cover of the emergency buoy, in which three cylindrical volumes are coaxially located, one above the other, an inflatable shell is laid in the lower volume, inside of which there is an antenna emitter. A “large” gas generator is located on the cover of the DCS, and a “small” gas generator is located inside the DCS block. When the ASB ascends to the sea surface, an electric impulse is supplied to the electric igniter of the “combustible” gas generator by the signal of the ASB software device. Gas through a non-return valve enters the cavity under the plug, creating a lot of pressure in the cavity. Under the influence of internal pressure, the plug flies out of the glass. After that, a signal is applied to the electric igniter of the “small” gas generator at the signal of the software device, gas from which is supplied through the non-return valve to the antenna shell, inflating it. When straightening, the shell lifts the lid and pushes it out of the glass, the conductors of antenna radiation are brought into working position.

The use of the device should provide high operational reliability and survivability of the antenna device ASB.

Description

The proposed utility model relates to the field of emergency communications technology, in particular, to means of exhaust antenna devices used in emergency situations on submarines.

Today, all submarines are equipped with alarm buoys and autonomous emergency beacons. Emergency signal buoys are placed in the baffles on the aft and bow superstructures of the light submarine hull - they are equipped with a signal lamp, a telephone and a radio station. Communication with the emergency submarine is carried out via a cable cable. The buoy is surrendered from the submarine compartment [A. A. Katanovich Alarm systems VKS Navy. - St. Petersburg: Shipbuilding, No. 6, 2000, p.40.].

Currently, COSPAS-SARSAT radio transmitters are installed in submarines. The antenna of this radio transmitter must withstand repeated exposure to external hydrostatic pressure up to 60 kgf / cm ² when the submarine is submerged to a depth. In the working position, to ensure optimal radiation conditions, the antenna should rise 18-20 cm above the top cover of the buoy. In the "stowed" position, the antenna should not protrude outside the outer cover of the emergency buoy (ASB), otherwise it will create turbulence of the incident water flow, which will increase the noise of the submarine. In addition, the protruding antenna may be damaged during the daily operation of submarines (mooring, loading operations, etc.).

Known rescue buoy with a radar transponder [Patent EPO. No. 114754, cl. B 63 B 21/52, 1985.].

The buoy is equipped with a radar transponder that transmits radio signals in response to signals sent by the radar

search vessel. The buoy contains a hollow waterproof housing made of rigid plastic, in which there is a receiving antenna, a receiver, a transmitting antenna, a transmitter, a battery, and other devices.

The deep-sea buoy is also known [USSR AS No. 994333, class. B 63 B 21/52, 1987.].

The buoy contains an instrument container, a buried cargo with a device for its separation, ballast containers with ballast of different specific gravities, having valves, and a buoyancy buoyancy control mechanism. The buoyancy buoyancy control mechanism is made of autonomous units.

The closest in purpose, technical nature and positive effect to the claimed device is an emergency buoy [USSR AS No. 718323, cl. B 63 B 21/52, 1972].

The emergency buoy contains a body connected to the main float and a telescopic antenna passing through the center of the float with a retractable device, while the buoy is equipped with an additional float made in the form of an inflatable ring and connected by flexible connections with the body and the main float.

The disadvantages of both analogues and the prototype are the low survivability and reliability during operation, as well as the inability to install these buoys on submarines.

The purpose of the utility model is to increase the operational reliability of the emergency buoy antenna device.

This goal is achieved by the fact that the antenna device of the emergency buoy, containing an inflatable shell with an emitter placed inside it in the form of segments of a conductor, is placed in a strong glass. The glass is installed on the top cover of the block of a radio signal device (DCS), mounted on an emergency rescue buoy (ASB). In the glass there are three cylindrical volumes located coaxially one above the other, with the upper cylindrical volume having the largest diameter and the lower volume having the smallest diameter. The end face of the upper cylindrical volume is flush with the upper ASB cover. An inflatable shell made of rubberized fabric with an antenna emitter located inside the shell is laid in the lower volume. There are two holes in the bottom of the glass. In one

the hole passes the antenna’s hermetic inlet, the second serves to supply gas from the “small” gas generator located inside the DCS unit. The top of the glass is closed by a plug. Sealing is carried out by four rubber sealing rings, which are installed in two annular grooves located on the side surface of the plug, and in two grooves on the lower surface of the upper cylindrical volume. In the side surface of the middle cylindrical volume of the glass there is an opening for supplying gas from the second “large” gas generator to the cavity under the gas plug. The durable case of the second gas generator is located on the cover of the DCS block. Through the hole in the lower part of the body of the second gas generator from the DCS block, the cable gland of the electric igniter of the “pellets” of the gas generator passes the cable gland. The lower cylindrical volume is closed from above by a strong cover of the “T-shaped" profile, which freely fits onto the lower surface of the second cylindrical volume, the latter acts as an end stop. Under the cover, in the groove on the annular stop, a rubber o-ring is installed. The cover serves to protect the antenna shell with the emitter from compression when gas is supplied to the cavity under the plug.

The antenna device of the rescue buoy is depicted in figure 1 and figure 2.

In figure 1, the device contains:

1 - a cap used to protect against external water;

2 - sealing rings, which serve to ensure the tightness of the inner cavity of the glass;

3 - a durable glass, used to place the inflatable antenna shell in it when folded, caps and lids;

4 - gas supply pipe from a large gas generator;

5 - non-return valve;

6 - a large gas generator, which serves to supply gas into the cavity of the glass. The principle of operation of the gas generator is based on the release of gaseous products during the thermal decomposition of the gas-generating composition. The gas-generating composition is made in the form of a set of tablets (change in quantity

tablets allows you to quickly develop gas generating devices with the required volume and working pressure of the generated gas);

7 - T-shaped cover, used to close the lower cylindrical volume;

8 - antenna shell (folded);

9 - pressure lead of an electric igniter of a large gas generator;

10 - hermetic input of the antenna emitter;

11 - a small gas generator for supplying gas to the antenna shell;

12 - gas supply pipe from a small gas generator with a non-return valve;

13 - the top cover of the DCS block, which serves as the basis for installing a durable glass on it;

14 - the top cover of the ASB, which serves to create optimal conditions for flowing around the ASB with an oncoming flow of water during the movement of the submarine. In Fig.2 the device contains:

15 - a "large" gas generating device;

16 - "small" gas generating device;

17 - software device ASB;

18 is a radio transmitting device.

The device operates as follows.

After the emergence of the alarm buoy to the sea surface, according to the signal of the ASB software device located in the DCS block, an electric pulse is supplied to the electric igniter of the "large" gas generator (Fig. 2). Gas through a non-return valve enters the cavity under the plug, creating an increased pressure in it (about 20 kgf / cm ² ). Under the influence of internal pressure, the plug flies out of the glass. The cover covering the lower cylindrical volume serves to protect the antenna from being squeezed when gas is supplied to the cavity under the plug. After that, a signal is applied to the electric igniter of the “small” gas generator at the signal of the software device, gas from which is supplied through the non-return valve to the antenna shell, inflating it. When melted, the shell lifts the lid, and pushes it out of the glass. With further pressurization, the casing is brought into working position, i.e. it straightens and sets into working position

conductors of an antenna emitter. After that, at the command of the software device, the operation of the radio transmitter begins. To protect against rupture, the shell is equipped with a safety valve.

The use of this utility model provides high operational reliability and survivability of the antenna device of the emergency rescue buoy.

Claims (1)

An emergency buoy antenna device comprising a telescopic radio transmitter antenna with a retractable device mounted on an emergency buoy, characterized in that in order to increase the operational reliability of the emergency buoy antenna device, on the top cover of the radio signal device (DCS) block mounted on the emergency signal buoy (ASB), a solid figured cup is installed, in which three cylindrical volumes are coaxially located, one below the other, with the upper cylinder having the largest diameter The rim volume, the smallest - the lower volume, the end face of the upper cylindrical volume is flush with the top cover of the alarm buoy, an inflatable shell of rubberized fabric is laid in the lower volume, conductors representing the antenna radiator are located inside the shell, there are two holes in the bottom of the cup the antenna’s hermetic inlet passes through the first hole, and the second hole serves to supply gas from the “small” gas generator located inside the DCS block, the top is closed by a plug, and in there is a hole on the side surface of the glass for supplying gas from the second “large” gas generator to the cavity above the gas plug, a strong second gas generator housing is located on the top cover of the DCS unit, a pressure inlet of the gas generator “tablet” electric igniter cable passes through the hole in the second gas generator housing, and the electric igniter cable passes through the pressure seal passes from the DCS block, the lower cylindrical volume of the glass is closed from above by a strong cover of the “T-shaped" profile, which fits freely on zhnyuyu surface of the second cylindrical volume, the latter acts as a ring stop, under the lid in abutment on the annular groove, a rubber O-ring.