RU2358362C1 - Radiotransparent cupola - Google Patents

Abstract

FIELD: physics; radio.

SUBSTANCE: use of the protective cupola made from radiotransparent elastic air-tight material and pumping hot air into the cavity, formed by the outer surface of a cover made from radiotransparent material and the inner surface of the protective cupola, allows for reducing adhesion between the outer surface of the protective cupola and snow and ice and break them into pieces, which, under the effect of their own weight, slide on the outer surface of the protective cupola, after which they fall down. The inner surface of the protective cupola contains N retaining sections, joined to the outer surface of the cover made from radiotransparent material. These sections are uniformly arranged on the outer surface of the protective cupola, where N is a positive integer.

EFFECT: protection of microwave antennae from adverse meteorological and other factors.

3 cl, 1 dwg

Description

The invention relates to techniques for a microwave range of radio waves and can be used to protect antennas from adverse weather conditions (rain, snow, ice, and so on).

Known folding shovel, equipped with a pointed tip in the form of scrap [1]. It can be used both for snow removal and for cleaving the ice crust. The disadvantages of the known device are low productivity, the risk of damage to the surface being cleaned when the ice crust is chipped. In addition, working at altitude requires highly qualified staff, and the performance of the work at altitude may not be possible under weather conditions.

Known conical petal-shaped icicle breaker [2], which, using a telescoping telescopic pipe mounted on the car chassis, is brought to the edge of the roof with overhanging icicles and after turning on the electric drive destroys them. The disadvantages of the known device lies in the narrow scope and the possibility of mechanical damage to the surface being cleaned.

Known flooring to prevent snow-ice formations [3], including equipped with a heating cable rectangular in plan planes mounted on the protected surface in longitudinal and / or transverse rows. A groove is made on the upper surface of each plate along its central longitudinal axis, in which a heating cable is laid and a plug on top of it. A disadvantage of the known device is the need for large expenditures of electrical energy required for the melting of snow and ice.

Known gas-jet machine [4], in which to clean the pavement using the exhaust jet of a turbojet engine. A disadvantage of the known technical solution is the high consumption of aviation fuel. In addition, the gas-jet machine can only be used for cleaning surfaces with high heat resistance.

The closest in technical essence to the claimed technical solution is the antenna cover made of radio-transparent material used in a stabilized antenna post of a ship's navigation radar station, designed to protect the antenna from adverse weather conditions. A disadvantage of the known technical solution is that it does not provide any constructive measures for cleaning its surface from snow and ice, that is, if necessary, you have to use manual labor, most often in difficult weather conditions. If timely cleaning of the radiotransparent casing is impossible for some reason, for example, due to weather conditions (storm, rolling, wind, snow, icing), then the radiotransparent casing is subject to mechanical overload due to snow adhering to its surface and ice formed on its surface. resulting in reduced reliability and durability. In addition, the use of such radiolucent domes on ships or ships in appropriate weather requires constant cleaning of snow and (or) ice, otherwise the lateral stability of the ship or ship is reduced, resulting in reduced safety of navigation due to an increase in the likelihood of a sudden uncontrolled roll and even rollover boats.

The objective of the invention is to increase the reliability and durability of the device by ensuring the cleaning of its surface from snow and (or) ice.

The solution of the problem in accordance with claim 1 is ensured by the fact that the following improvements are made to the known device comprising a casing of radiolucent material: it further comprises a pump, a heater, three fittings, a first hose, a second hose made of radiolucent material, the third hose is made of radiolucent elastic stretchable airtight material, a protective dome, the pump is reversible, a casing of radiolucent material is placed inside the protective dome, the lower part of the protective dome is hermetically connected to the outer surface of the casing of radiolucent material, the casing of radiolucent material is provided with two through holes, the first hole is located below the lower part of the protective dome, the second hole is located in the upper part of the casing of radiolucent material, the protective dome is equipped with through hole, the first fitting is hermetically placed in the first opening of the casing of radiolucent material, the second fitting is hermetically placed in the second hole a casing made of radiolucent material, the third fitting is sealed in the opening of the protective dome and is equipped with a valve, the outlet of the pump is connected to the inlet of the first hose, the outlet of the first hose is connected to the inlet of the heater, the outlet of the heater is connected to the inlet of the second hose, the outlet of the second hose is connected to the inlet of the first fitting , the output of the first fitting is connected to the input of the third hose, the output of the third hose is connected to the input of the second fitting, the output of the second fitting is connected to the cavity formed by the outer surface of the casing from the radio transparent material and the inner surface of the protective dome, the inner surface of the protective dome contains N fixing sections connected to the outer surface of the casing of radiolucent material, and these sections are uniformly located on the inner surface of the protective dome, where N is a natural number.

Such construction of a radiotransparent dome provides, when heated air is supplied into the space between the casing of radiotransparent material and the protective dome, an increase in the area of the outer surface of the protective dome, as a result of which the ice and / or snow cover breaks into pieces, while the adhesion between the formed pieces of ice and (or ) of snow and the outer surface of the protective dome is reduced, which leads to sliding down pieces of ice and (or) snow under the action of gravity and a subsequent fall down. Heating the protective dome with heated air facilitates and accelerates the process of releasing the radiotransparent dome from snow and (or) ice.

In the particular case, in accordance with paragraph 2 of the claims, N fixing sections are made round, and these sections do not contain common points.

In the particular case, in accordance with paragraph 3 of the claims, N fixing sections are made linear in shape, and these sections do not contain common points.

The presence of fixing sections ensures uniformity of inflation of the protective dome. The absence of common points in the fixing sections ensures the free movement of heated air in the space between the casing of radiolucent material and the protective dome. The linear locking sections can form triangles, quadrangles, hexagons or other shapes on the inner surface of the protective dome.

The invention is illustrated by a description of an embodiment of the claimed device and a drawing, which shows a section of a radiolucent dome.

In accordance with claim 1, the radiolucent dome comprises a casing 1 of radiolucent material, within which an antenna 2 of the radar station is located. The radiotransparent dome also contains a pump 3, a heater 4, three fittings 5, 6 and 7, a first hose 8, a second hose 9 made of radiolucent material, a third hose 10 made of a radiotransparent elastic stretchable airtight material, a protective dome 11, pump 3 is made reversible, a casing 1 of radiolucent material is placed inside the protective dome 11, the lower part of the protective dome 11 is hermetically connected to the outer surface of the casing 1 of radiolucent material, the casing 1 of radiolucent material of sleep wives with two through holes, the first hole is located below the lower part of the protective dome 11, the second hole is located in the upper part of the casing 1 of radio-transparent material, the protective dome 11 is provided with a through hole 12, the first fitting 5 is hermetically placed in the first hole of the casing 1 of radio-transparent material, the second the nozzle 6 is hermetically placed in the second opening of the casing 1 of radiolucent material, the third nozzle 7 is hermetically placed in the hole of the protective dome 11 and is equipped with a valve 13, the outlet of the pump 3 is connected to the inlet the first hose 8, the output of the first hose 8 is connected to the input of the heater 4, the output of the heater 4 is connected to the input of the second hose 9, the output of the second hose 9 is connected to the input of the first nozzle 5, the output of the first nozzle 5 is connected to the input of the third hose 10, the output of the third hose 10 connected to the input of the second nozzle 6, the output of the second nozzle 6 is connected to the cavity formed by the outer surface of the casing 1 of radio-transparent material and the inner surface of the protective dome 11, the inner surface of the protective dome 11 contains N locking sections 14, connected to the outer surface of the casing 1 of radiolucent material, and these areas are uniformly located on the inner surface of the protective dome 11, where N is a natural number. 15 indicates the base of the radiolucent dome.

Radiolucent dome works as follows. A radiolucent dome protects the antenna 2 of the radar station inside it from adverse weather and other factors. When snow and (or) ice appear on the surface of the protective dome 11, the pump 3 and the heater 4 are turned on. Heated air enters the space between the casing 1 of radiolucent material and the protective dome 11. If the valve 13 is fully open, then the pump 3 works in direct-flow mode, in this case, heated air enters the space between the casing 1 of radiolucent material and the protective dome 11, then exits through the third fitting 7. The layer of snow and (or) ice adjacent to the protective dome 11 melts, the adhesion of snow and (or) ice from the protective m dome 11 is significantly reduced, snow cover and (or) ice breaks into pieces, resulting in pieces of ice and (or) snow under the influence of gravity slide down the outer surface of the protective dome 11, and then fall down. If the valve 13 is not fully open, then the pump 3 operates in a direct-flow mode, while the heated air enters the space between the casing 1 of radiolucent material and the protective dome 11, then goes out through the third fitting 7. In this case, the protective dome 11 is inflated, its area the outer surface increases, the layer of snow and (or) ice adjacent to the protective dome 11 melts, the adhesion of snow and (or) ice to the protective dome 11 is significantly reduced, while due to the stretching of the protective dome 11 the snow cover and (or) the ice breaks I’m in pieces, the adhesion between these pieces and the outer surface of the protective dome 11 is further reduced, as a result of which the pieces of ice and (or) snow, by gravity, slide down the outer surface of the protective dome 11, and then fall down. If the valve 13 is closed, then the pump 3 operates in a reverse mode, that is, first heats up the heated air into the space between the casing 1 of radiolucent material and the protective dome 11, then heats up the heated air from this space, after which the process is repeated for the necessary time. The choice of one of the described modes or their alternation is determined by the prevailing meteorological situation and the ratio between the amount of snow and the amount of ice. In the upper part of the protective dome, the surface slope is small, at the very top it is absent, therefore, the heated air is first supplied by the third hose 10 through the second nozzle 6 to the upper part of the space between the casing 1 made of radio-transparent material and the protective coupon 11, which ensures maximum ice heating and (or) snow in comparison with other parts of the protective dome 11. If the valve 13 is open (fully or partially), then the heated air coming out of the third fitting 7 can be used to heat the internal the volume of the casing 1 of radiolucent material and (or) office premises of the radar station. If the valve 13 is closed, then the heated air coming out of the pump 3 can be used.

Information sources

1. Zhirekhin V.I., Kurzenkov A.Ya., Lipsman D.L. etc. Shovel folding. Application No.2000124790 for a patent of the Russian Federation for an invention, prior. 09/29/2000, publ. 08.27.2002, IPC 7 А01В 1/02, А01В 1/20.

2. Adamovich B.A., Derbichev A.G., Dudov V.I. and others. Icicle breaker. RF patent for invention No. 2187595, prior. 03/14/2001, publ. 08/20/2002, IPC 7 Е01Н 5/00.

3. Zhuravsky S.A. Flooring to prevent snow and ice formations. RF patent No. 2296832 for invention, priority 07/22/2005, publ. 04/10/2007, Е01С 11/26 (2006.01).

4. Brygin B.A., Romashenko V.A. Gas-jet machine for clearing snow and ice formations on the basis of a forest tractor. RF patent No. 2288316 for invention, prior. 05/31/2005, publ. November 27, 2006, IPC E01H 5/10 (2006.01).

5. Vinogradov L.G. The stabilized antenna post of a ship navigation radar station. Application No. 97118137 for a patent of the Russian Federation for an invention, prior. 10/31/1997, publ. 04/20/1999, IPC 6 H01Q 1/34.

Claims (3)

1. Radiolucent dome containing a casing of radiolucent material, characterized in that it further comprises a pump, heater, three fittings, a first hose, a second hose made of radiolucent material, a third hose made of a radiolucent elastic stretchable airtight material protective dome, the pump is made reversible, a casing of radiolucent material is placed inside the protective dome, the lower part of the protective dome is hermetically connected to the outer surface of the casing from the radio of transparent material, the casing of radio-transparent material is provided with two through holes, the first hole is located below the lower part of the protective dome, the second hole is located in the upper part of the casing of radio-transparent material, the protective dome is provided with a through hole, the first fitting is sealed in the first opening of the casing of radio-transparent material, the second fitting is hermetically placed in the second opening of the casing of radiolucent material, the third fitting is hermetically placed in the opening of the protective dome and equipped with a valve, the pump output is connected to the inlet of the first hose, the output of the first hose is connected to the input of the heater, the output of the heater is connected to the input of the second hose, the output of the second hose is connected to the input of the first fitting, the output of the first fitting is connected to the input of the third hose, the output of the third hose is connected to the input of the second fitting, the output of the second fitting is connected to the cavity formed by the outer surface of the casing of radiolucent material and the inner surface of the protective dome, the inner surface of the protective dome with contains N fixing sections connected to the outer surface of the casing of radiolucent material, and these sections are uniformly located on the inner surface of the protective dome, where N is a natural number. 2. The radiolucent dome according to claim 1, characterized in that the N fixing sections are circular in shape, and these sections do not contain common points. 3. The radiolucent dome according to claim 1, characterized in that the N fixing sections are linear in shape, and these sections do not contain common points.