RU2777542C1 - Anti-icing system for satellite communication stations - Google Patents

Abstract

FIELD: antenna systems.

SUBSTANCE: invention relates to the heating of antenna systems. The anti-icing system for satellite communication stations includes a casing (3) fixed to the rear side of the reflector. Thermal air heaters (1) are placed inside the protective casing (3). Precipitation and temperature sensors (2) are located over the entire working surface of the reflector of the antenna system from the back. The work automation controller for satellite communication stations is connected to precipitation and temperature sensors (2) and air heaters (1). The protective casing (3) of the anti-icing system is divided into quadrants (4) inside, and at least one thermal air heater (1) is located in each quadrant (4).

EFFECT: simplified design and improved anti-icing efficiency for the main reflector of the antenna system.

5 cl, 2 dwg

Description

The present invention relates to auxiliary equipment for satellite communication stations and is intended for use as part of heating systems for antenna systems. The anti-icing system provides heating of the full reflector of the antenna system or its fragment (dedicated sector of the reflector), and prevents the formation of ice on the antenna surface when the dew point is reached.

In principle, anti-icing devices for satellite communication stations are known from the prior art.

Japanese Patent No. JP 2554297 B2, Nov. 13, 1996, discloses a snow melting device for an antenna, comprising a rear cover that covers the rear surface of a built-in main reflector. A heater and a finned fan used to circulate hot air are provided in the space between the main reflecting mirror and the back cover, the operation is adjusted in response to the operation of the outside temperature sensing thermostat, and the main reflecting mirror is evenly heated and the deposited snow is melted. The disadvantage of the technical solution of this device is that there is no splitting in the space between the back cover and the main reflecting mirror, because of this, the antenna mirror is completely heated, which is inefficient and entails a large power consumption for the operation of the heater and fan.

China Patent No. 2071242698 U dated March 20, 2018 claims a satellite dish anti-icing system against snowmelt. The system includes a heater, a rain and snow sensor, a control automation controller, a temperature sensor, a temperature data acquisition unit and a power supply module, the back of the reflection plane of the satellite dish is provided with a heated board, and the heated board is a sealed space with the back of the reflection plane of the satellite dish, in the sealed space, the circumference of the satellite dish is evenly provided with a heater, and the sector at each location of the heater is a heating channel, which is provided with a temperature sensor. The main reflective surface of the satellite dish is equipped with a rain and snow sensor, the heater and the rain and snow sensor are connected to the controller, and the temperature sensor is connected to the temperature data acquisition unit, and the temperature data acquisition unit is connected to the controller, and the power supply is the power source of the controller. The disadvantage of the technical solution of this device lies in the efficiency of the device: the main reflective surface of the antenna is heated by heated plates, that is, due to thermal conductivity, because of this, heating occurs unevenly.

From the patent of the Russian Federation No. 2207668 C2 06/27/2003, a method for thermal stabilization of a parabolic antenna and a device for its implementation are known, in which the antenna reflector is fixed on a frame implemented in the form of radially arranged stiffeners, which are made airtight with the formation of air channels in the form of sectors covered with a metal sheet . Between the sheet and the heat-insulating cover mounted on the frame, there is an auxiliary cavity connected to the cavity for blowing air along the edge of the reflector and in the central part. The composition of the heat-stabilizing system of a parabolic antenna with a reflector mounted on a frame made in the form of radially arranged stiffeners includes a heat-insulating cover, temperature sensors, main and backup fans, an electric heater, and a control unit. The heat-insulating cover is installed on the frame with the formation of a thermostatic cavity (in which the reflector and frame are blown) and an auxiliary cavity, which are separated by a metal sheet with a high coefficient of thermal conductivity and which are interconnected along the edge of the reflector, as well as in its central part using an inserted pipe, in which the main and additional fans are installed, after which the electric heater is also installed. The radially located frame stiffeners are made airtight with the formation of air channels in the form of sectors. The disadvantage of the technical solution of this invention is that it is applicable only to a certain design of the frame of the reflector (main mirror), implemented in the form of radially arranged stiffeners.

In the patent for the invention of the Russian Federation No. 2233018 C1 dated 18.08.2003, a method for de-icing a ground-based parabolic antenna and a device for its implementation are described. The essence of which lies in the fact that blowing with heated air is carried out in the lower part of the reflector in the direction orthogonal to its rear surface. The fan heater is installed in the lower part of the reflector with the direction of the air flow orthogonal to the rear side of the reflector. A power voltage regulator connected to temperature sensors is introduced into the switching unit of the control system. The disadvantage of this device lies in the inefficiency of heating: the heated air heats the reflector inside the thermal cover as a whole, which requires an additional amount of heat.

Patent RU No. 2 233 018 C1 describes a radar absorbing device with anti-icing properties, which can be used in aircraft equipment as protective equipment that reduces the level of electromagnetic radiation back reflection, while having protection from icing. The use of such material in ground stations of satellite systems as an anti-icing system is meaningless, since the main mirror of the antenna system should reflect the radio signal, and not absorb, this property of this material is a disadvantage.

In patent RU No. 36572 U1, an anti-icing device for an antenna is disclosed, containing a reflector with a radio-reflective shell and a heating element, characterized in that the heating element is made in the form of a resistive layer of woven carbon material and is located inside the radio-reflective shell over its entire area, while in the resistive layer current leads are pressed in to connect an electric current source with a given voltage. The disadvantage of this device is labor-intensive repair in case of breakage or failure of the heating element, as well as manual control of the device.

The objective of the present invention is to eliminate the above disadvantages.

The technical result is to simplify the design and increase the efficiency of anti-icing for the main reflector of the antenna system.

The problem is solved using an anti-icing system for satellite communication stations, including a casing fixed on the back side of the reflector, containing thermal air heaters placed inside the protective casing, precipitation and temperature sensors located over the entire working surface of the reflector (main mirror) of the antenna system from the back side , and, if necessary, a counter-reflector (additional mirror) and an irradiator, and an automation controller for satellite communication stations, connected, respectively, to precipitation and temperature sensors, and air heaters. The protective casing of the main mirror can be made, in particular, of galvanized aluminum steel, which is coated on the inside with penefol to retain and reflect heat. Inside, the casing is divided sectorally into four quadrants with the help of stiffening ribs, which are also covered with penofol from the front sides. Each quadrant houses at least one thermal air heater, which in a particular case can be turned with its back side to the mirror, so that the process of heating the mirror inside the quadrants occurs by means of reflected warm air from the protective casing. The high efficiency of heating inside the quadrants is achieved due to the reflective and heat-retaining abilities of the penofol covered with aluminum foil.

The anti-icing system is used to ensure continuous round-the-clock operation of the satellite communication station in the autumn, winter and spring periods (during periods of the probable possibility of precipitation in the form of snow). The system also prevents the formation of ice on the surface of the antenna when the dew point is reached.

The technical result is achieved due to the fact that precipitation and temperature sensors are located over the entire working surface of the main mirror (reflector) of the antenna system on the back side, and, if necessary, an additional mirror (counter-reflector) and an irradiator, a protective cover attached to the back side of the reflector, and a set of thermal air heaters placed inside the protective casing.

In more detail, the present invention is explained on the basis of the figures, which show:

- Fig. 1 is a schematic view through the rear wall of the casing (3), divided into quadrants (4) by partitions (5), with a heater (1) in each of the quadrants (4) to the rear side of the reflector, with precipitation and temperature sensors (2) installed on it ).

- Fig. 2 is a schematic side view of an arbitrary quadrant of the casing (3) in one embodiment, in which the heater (1) is located with its back to the back surface of the main mirror (6), and the protective casing (3) on the inside and partitions (5), covered with foam (7) and aluminum foil (8).

The protective casing of the main mirror is made of galvanized aluminum steel, which is covered on the inside with foam with aluminum foil to retain and reflect heat. Inside, the casing is divided sectorally into four quadrants with the help of stiffeners, which are also covered on the front sides with foam foam with aluminum foil. At least one thermal air heater is placed in each quadrant, and in such a way that it is turned with its back side to the mirror, so that the process of heating the mirror inside the quadrants occurs by means of reflected warm air from the protective casing. The high efficiency of heating inside the quadrants is achieved due to the reflective and heat-retaining abilities of the penofol covered with aluminum foil.

The protective cover can be made in an airtight design.

The anti-icing system automation controller is located in a separate telecommunication cabinet and is connected to precipitation and temperature sensors, as well as to a set of heaters, due to which the latter are controlled. The controller reads real-time readings from precipitation and temperature sensors and, if necessary, controls the thermal air heater in the desired quadrant of the protective casing. When snow sticks to the reflector of the antenna system, precipitation and temperature sensors transmit information to the controller, after processing this information, the controller decides in which quadrant it is worth turning on the thermal air heater to prevent icing of the reflector of the antenna system.

Claims (5)

1. Anti-icing system for satellite communication stations, including a casing fixed to the rear side of the reflector, containing thermal air heaters placed inside the protective casing, precipitation and temperature sensors located over the entire working surface of the reflector of the antenna system from the back side and, if necessary, a counter-reflector and an irradiator, and an automation controller for satellite communication stations, connected, respectively, to precipitation and temperature sensors and air heaters, characterized in that the protective casing inside is divided into quadrants and at least one thermal air heater is located in each quadrant. 2. The system according to claim. 1, characterized in that the protective casing is made in an airtight design. 3. The system according to claim 1 or 2, characterized in that the thermal air heaters are located with their back to the mirror so that the heating process works due to the reflected warm air. 4. The system according to claim 1 or 2, characterized in that the protective casing is covered on the inside with foam and aluminum foil to retain and reflect the warm air received from the heaters. 5. The system according to claim 1 or 2, characterized in that the system is configured to take information from precipitation and temperature sensors, read in real time and, in the event of icing on one of the reflector quadrants, turn on the corresponding thermal air heater.

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