RU2506699C1 - Mobile satellite communication station - Google Patents

Abstract

FIELD: radio engineering, communication.

SUBSTANCE: invention relates to radio engineering and specifically to satellite communication, and can be used to provide direct communication of officials on mobile facilities, link subscribers on mobile facilities to public communication networks, facilitate telephone conversations and transmission of different information. The station has a frame on a wheel base, a container with an equipment rack with a shock-absorbing system, an electrical power supply system with an electrical generator, a satellite communication antenna with drives and position fixing devices, systems of cable power and information inputs, an air conditioning system and a system for directed air cooling of the equipment. The container is divided into insulated equipment and aggregate compartments; the former houses the equipment rack, the air conditioning system and a converter stand and automatic equipment of the electric power supply system; the latter houses the electrical generator of the power supply system, the systems of cable power and information inputs. Outputs of the air conditioning system and the system for directed air cooling of the equipment are linked with the equipment compartment, and the base of the satellite communication antenna is placed on the upper panel of the container, which is linked to the frame by fastening elements.

EFFECT: enabling operation in difficult climatic conditions, shorter deployment time, high degree of operational readiness, increased self-containment, high reliability of operation in said conditions.

10 cl, 5 dwg

Description

The invention relates to telecommunication technology. A mobile satellite communication station can be used to provide direct communications of officials of mobile objects, organize the binding of subscribers of mobile objects to public communication networks, conduct telephone conversations and transmit various information and data through established communication channels. A mobile satellite communication station can be used as a terminal or transit station for the restoration of damaged trunk lines, as well as for the organization of new communications (especially in areas with an absent or poorly developed terrestrial communications infrastructure).

A feature of the proposed mobile satellite communication station is its spatial isolation (i.e., some spatial remoteness, sometimes amounting to several hundred meters) from the moving object for which it is intended to work.

A mobile satellite communications station is intended primarily for working with such moving objects as various command posts, mobile control and supervisory control centers, mobile laboratories, mobile operating rooms, etc. in a wide range of climatic conditions.

The implementation of the requirement of spatial isolation (remoteness) of a mobile satellite communication station from a mobile object with the placement of its equipment on a separate trailer (trailer) is due to the following main reasons:

- the need to ensure the spatial independence of the station from a moving object;

- the need to protect personnel and equipment of the moving object from the radio frequency radiation of the station;

- the need to protect station equipment from interference caused by equipment of a moving object;

- the need to increase the secrecy of the moving object by eliminating the exact determination of its coordinates from the radio frequency radiation of the station;

- the need to ensure the quick replacement of a mobile station (with full or partial loss of its operability) by a backup station by car towing the latter to the place of use or by delivering the backup station to the specified location by any available means of transport (air, rail, road).

A mobile satellite communication station is known, comprising a wheelbase frame, a satellite communication system fixed to the frame, equipped with a satellite communication antenna, a power supply system with an electric generator, retractable stabilization bearings, a transport coupling device (US patent 4856838, cl. 296/14 op. 15.08. 89).

A disadvantage of the known satellite communication station is the low security of its electrical and electronic equipment in the case of transportation and deployment of the station in adverse weather conditions, since the known station does not have a protective container common to the equipment and there are no life support systems for equipment in difficult climatic conditions (too high or too low temperature, high humidity, prolonged precipitation). Thus, the well-known station is not provided with the possibility of its operation in difficult climatic conditions.

Closest to the claimed one is a mobile satellite communications station, comprising - a wheelbase frame, a container with a hardware rack and a shock absorber system equipped with fixation devices on the frame, a power supply system with an electric generator, a satellite communication antenna with drives and fixation devices for its position, a cable entry system , retractable stabilization bearings, transport coupling device (US patent No. 7852274, CL 343/713 op. 14.12.10). In the well-known station, due to the presence of a protective container in which there is a hardware rack with basic telecommunication equipment, the disadvantages inherent in the previous analogue have been partially eliminated.

However, the well-known satellite communications station also has low security of its electrical and electronic equipment when transporting to the deployment site and the deployment of the station itself is carried out under adverse weather conditions (too high or too low ambient temperature, high humidity, prolonged rainfall), significantly different from the conditions that are working for such equipment. The result is too much time required to bring the station to operating mode. Thus, the degree of operational readiness of the station to work is significantly reduced.

The claimed invention solves the problem of creating a mobile satellite communications station capable of functioning in accordance with its purpose in adverse climatic conditions in any region of the Russian Federation.

The technical result achieved by using the claimed solution is to enable the station to operate in difficult climatic conditions, to reduce the deployment time of the station and bring it to operating mode, to increase the operational readiness of the station for work, to increase the station's autonomy, to increase the reliability of the station in these conditions.

The specified technical result is achieved by the fact that a mobile satellite communication station containing a wheelbase frame, equipped with fastening devices on the frame, a container with a hardware rack equipped with a damping system, a power supply system with an electric generator, a satellite communication antenna with drive devices and fixing its position, cable systems power and information inputs, in accordance with the present invention, further comprises an air conditioning system and a directional blowing system about ore, the container is divided into hardware and aggregate compartments isolated from each other, in the first of which there is a hardware rack, an air conditioning system and an additionally introduced rack of converters and automation of the power supply system, and in the second - an electric generator of the power supply system, as well as cable power and information systems the inputs, the output of the air conditioning system and the output of the directional blowing system of the equipment are communicated with the hardware compartment of the container and the base of the antenna is satellite A new connection is placed on the top panel of the container, which is connected to the frame by means of power fastening elements.

The indicated result is also achieved by the fact that the air conditioning system contains an automobile air conditioner and a remote wireless control unit, the output of the air conditioning system is made in the form of two ducts, one of which is inserted into the equipment rack, and the second into the rack of converters and automation of the power supply system.

The indicated result is also achieved by the fact that the system of directional blowing of equipment is located in the aggregate compartment of the container.

The indicated result is also achieved by the fact that the directional blowing system of the equipment contains an autonomous diesel heater connected to the fuel tank, and a power level controller equipped with a temperature sensor connected to the heater by a control cable, the system output through the duct channel communicates with the hardware compartment of the station container.

The indicated result is also achieved by the fact that an equipment electrical heating system is introduced into the hardware compartment.

The indicated result is also achieved by the fact that the electrical heating system of the equipment is made in the form of an explosion-proof electrical heater connected by a power cable to the rack of converters and automation of the power supply system.

The specified result is also achieved by the fact that the generator of the power supply system is made remote.

The indicated result is also achieved by the fact that the station is equipped with a fire extinguishing system, the output of which is communicated with the hardware compartment of the container.

The specified result is also achieved by the fact that the power supply system further comprises an autonomous guaranteed power supply system.

The indicated result is also achieved by the fact that the system of autonomous guaranteed power supply is battery-powered.

The drawings show the design of a mobile satellite communications station (MSS).

Fig. 1 shows a general view of a station in a transport (collapsed) state; Fig. 2 shows a general view of a station in a working (expanded) state; Fig. 3 shows a general view of the layout of the station equipment (top view in section); 4 shows a directional blowing system of the equipment of the PSSS hardware compartment as part of the station equipment. Figure 5 shows the air conditioning system (with two ducts) as part of the equipment of the station.

The mobile satellite communications station contains a metal frame 1 (Fig. 1) mounted on a wheelbase 8, equipped with devices 7 for attaching to the frame 1, a protective container 2 with a hardware rack 10 (Fig. 2), equipped with a shock absorption system 9, a power supply system with an electric generator 20 (Fig. 3), a parabolic antenna 3 of satellite communication with 4 drive devices 5 located at its base and fixing its position, i.e. antenna system (such systems are widely known and described in the literature - see, for example, V. Bobkov’s article “Earth Station Antenna Systems”, “Connect” magazine, No. 4, 2007, pp. 112-116).

The mobile satellite communications station also contains systems of cable power inputs 13 and cable information inputs 14.

Container 2 performs the functions of: protecting the electronic and other equipment of the station from mechanical influences; protection of electronic and electrical equipment of the station from adverse natural and climatic influences such as precipitation, wind, high humidity, accompanied by a decrease in temperature by the precipitation of water condensate; protection of electronic equipment from electrical and radio interference, as well as lightning protection function.

The container 2 can be made welded, all-metal or prefabricated from separate panels, for example, from sandwich panels: upper and lower horizontal, as well as side and lower mechanically connected to them. At least one layer in the applied sandwich panels must be electrically conductive (for example, metal) to provide the ability to shield the station equipment from electrical and radio interference, as well as to enable the grounding of the container. To this end, ensure constant and reliable electrical contact of all panels with each other and with the electrically conductive (metal) frame 1. Sandwich panels can also include heat-insulating layers that provide temperature stabilization of the equipment located in the container. The assembly of the container panels of the station can be carried out by known methods, for example, as described in the patent of the Russian Federation No. 2364539, cl. B62D 33/00, op. August 20, 2009. The degree of tightness (impermeability) of the container 2 is selected depending on the operating conditions for which the mobile satellite communication station is calculated. So, for example, the container 2 can be made airtight for rainfall falling at an angle from 0 to 75 degrees to the vertical, and at the same time permeable to air in the container, due to the presence of an exhaust fan 37 with a protective (non-return) valve.

The container 2 is divided by a partition 38 into at least two compartments isolated from each other - a hardware 19 and an aggregate 18, in the first of which there is a hardware rack 10 with telecommunication equipment and a rack 26 of converters and automation of the power supply system, and in the second - an electric generator 20 power supply systems designed to ensure its autonomy, for example, in the form of a diesel generator. The partition 38 can also be made in the form of a sandwich panel with an electrically conductive (metal) layer, which is electrically connected to a common electrical circuit, which includes a sandwich panel and a frame. The equipment of the sandwich panel of the partition 38 with an insulating layer increases the temperature stability in the hardware compartment 19 and further reduces the level of electrical and radio interference in this compartment.

The stand 26 of the converters and automation of the power supply system contains at least a block of inverters (voltage converters) used to convert power supply voltage of 220 V AC to power supply voltage of 24 V DC, as well as for reverse conversion; devices for distributing electrical energy of alternating and direct current to consumers, made, for example, in the form of input / output electrical terminals (electrical connectors) and electrical power cables connected to them, connected, in particular, with a hardware rack 10, a system of 13 cable power inputs of an aggregate compartment 18, self-contained electric generator 20, guaranteed power supply system 23, air conditioning 24, device 29 on / off directional blowing system equipment, explosion-proof a heater 33 and an exhaust fan 37; switching devices (in the simplest case, switches) of electric energy sources, which serve to select a public network or an autonomous power source (electric generator or guaranteed power supply) as the source of electric energy with the output of the voltage of the selected sources to the output terminals (sockets) of the rack 26; standard devices (apparatuses) for protecting power circuits against overloads and short circuits; devices for monitoring the technical condition of the equipment of the rack 26 converters and automation of the power supply system (made, for example, in the form of a system of light indicators); a system for ensuring the electrical safety of personnel serving the station (made, for example, according to the scheme described in RF patent No. 2161098, class B60L 3/02, op. 27.12.2000); air temperature sensor in the hardware compartment 19 of the station.

The base 4 of the satellite communication antenna 3 (as shown in figures 1 and 2) is placed on the upper horizontal panel of the container 2, which is connected to the frame by means of power fasteners (not shown). Such an arrangement of the antenna 3 and its base 4, in which the drive device 5 and fixing the position of the antenna 3 are located, provides optimal conditions for the container 2 to fulfill its protective function.

The hardware rack 10 of the station is designed to accommodate mainly telecommunication equipment. The composition of telecommunication equipment located in the hardware compartment 19, is determined by the purpose of the mobile satellite communications station and is not the subject of the present invention. At the same time, as an example of telecommunication equipment located on a mobile satellite communications station, we can cite the following well-known equipment used to build VSAT terminals: satellite modem, router (for example, Cisco), switch (for example, D-Link ), a station management and control server (for example, Hewlett-Packard), a controller for the automatic antenna control system (for example, General Dynamic). The described VSAT terminal can be built according to one of the well-known schemes: see, for example, US patent No. 8032073, class. H04H 20/74, op. 10/04/2011.

The hardware rack 10 and the rack 26 of the converters and automation of the power supply system are equipped with control panels to which the controls for equipment located in the indicated racks are displayed.

A mobile satellite communications station is equipped with an air conditioning system (shown in FIG. 5), made, for example, in the form of an air conditioner 24 (in particular, an automobile) equipped with a control unit 34, for example, a wireless remote control unit. The output of the air conditioning system, in the most general case, can be communicated with the hardware compartment 19 of the container 2. In the preferred embodiment of the mobile satellite communications station, the hardware rack 10 and the rack 26 of the converters and automation of the power supply system are provided with their own cases (not shown), and the output air conditioning systems can be structurally made in the form of two ducts 35, one of which is inserted into the cavity of the housing of the hardware rack 10, and the second into the cavity of the housing of the rack 26 of the conversion applicants and automation of the power supply system as shown in Fig.5.

In the hardware compartment 19, an additional heating system for the equipment located in this compartment (Fig. 4) can be placed, which can be made in the form of an explosion-proof electric heater 33 connected by a power cable 32 with 220 V power terminals (sockets) of the rack 26 of converters and automation power supply systems.

The power supply system of the station includes at least a rack 26 of converters and automatics, a stand-alone electric generator (for example, a diesel generator) 20, a system of power cables (not shown) and a system of cable power inputs 13, as well as a battery system 23 of guaranteed power supply ( see, for example, RF patent No. 49403, class H04M 1/60, op. 10.11.2005).

In the particular case, an autonomous generator (diesel generator) 20 of the power supply system can be made remote, thereby achieving a reduction in the total noise and electrical noise in the area of the mobile satellite communications station and the mobile object for which it is intended to work. At the same time, the operating conditions of the electric generator itself (diesel generator) 20 are improved, both for its cooling and for the intake of air at the inlet. An autonomous electric generator (diesel generator) 20, when a mobile satellite communication station is moved outside the container 2, is connected to the latter using electric power cables 17 through a system of cable power electrical inputs 13.

The station is equipped with a directed equipment blowing system located in the aggregate compartment 18 (Fig. 4), containing an autonomous diesel heater 21 for indirect air heating, for example, of TERMIBILE (see publication http://www.zlatoheat.ru/data/cat/030/ tmob-im.htm) located in the protective box 36, the fuel tank 27 connected to the heater 21 by means of the fuel hose 28 and the on / off device 29 with adjustment (setting) of the power level emitted by the heater, connected to the heater 21 by the control cable 30. Directional airflow system output I through the duct 31 through the partition 38 is sealed into the cavity of the hardware compartment 19 of the container 2. An exhaust fan with a protective (check) valve 37 is installed in the hole of the outer wall of the hardware compartment 19, which prevents the backflow of air from the atmosphere into the cavity of the specified compartment.

The aggregate compartment 18 is equipped with a compartment for accommodating communication information cables 16 and electric power cables 17 located, for example, on rotating coils.

The frame 1 is equipped with front (along the transportation of the station) fixed support 11 of the stabilization of the station and the rear support 12 of the stabilization of the station, which are provided with extendable rods 15 to ensure the required stability from the wind when the antenna is in the deployed position. Also, frame 1 is equipped with a transport coupling device 6.

The stabilization supports 11 and 12 are made of jack-type pairs with the placement of the supports of each pair symmetrically with respect to the longitudinal axis of the station. One pair of supports 11 is rigidly fixed to the frame 1, and the other pair of supports 12 is fixed on the pull-out rods 15, in the extended form, allowing to increase the station support base in the transverse direction. This solution fully ensures stabilization of the station’s position, its stability and operability under conditions of wind load for various climatic zones of the Russian Federation.

To improve the safety and reliability of the station, it is equipped with an automatic fire extinguishing system 22 (see, for example, US patent No. 6131667, class A62C 13/00, op. 17.10.2000), the output of which is communicated with the hardware compartment 19 of container 2. The system 22 fire extinguishing can be located both in the aggregate compartment 18, and in the hardware compartment 19 of the station.

On the sides of the small container equipped with special hermetically sealed hatches 39, designed to provide access to the control panels of equipment and equipment installed in the telecommunications rack 10 and rack 26 of the converters and automation, as well as to ensure the possibility of removal (return to place) of an autonomous generator 20 (diesel -generator) and the possibility of connecting separately carried cable and other equipment to the station systems (see, for example, AS USSR No. 1345533, class B64C 1/14, op. September 27, 2004). The necessary protection of the equipment of the aggregate 18 and the hardware 19 compartments from dust and moisture is ensured by the fact that it is equipped with a dust and moisture protection system made in the form of sealing shutters 25 (for example, tarpaulin or type of brush seal) located around the perimeter of the front panels of the equipment and equipment and separating the inner the cavity of the hardware compartment 19 from the environment.

In order to reduce the likelihood of damage to the equipment of the station during transportation, its wheelbase 8 is made at least biaxial with the rolling brake system (brake system not shown).

A mobile satellite communications station is delivered to the deployment site and prepared for operation as follows.

When transporting the mobile station to the place of deployment and use, the satellite dish parabolic antenna 3 on the base 4 is in the folded position, which is fixed by the drive and position fixing devices 5 of the antenna, as shown in Fig. 1. The transport coupling device 6 connected with the frame 1 is connected to the reciprocal coupling device of a moving object (not shown) transporting the station and working with it. The rolling brake system, which is equipped with the wheelbase of the 8th station, prevents damage to the mobile satellite communications station and / or mobile object during sudden braking, which provides higher mobility and transportability of the station, allows it to be delivered to its destination faster, and thus faster complete its deployment and prepare the station for work.

Hatches 39 during transportation of the mobile station to the place of deployment and use are in the closed position.

At low ambient temperatures (for example, at temperatures below +5 degrees Celsius), when moisture condensation is possible on the equipment elements of the hardware compartment 19, an autonomous diesel heater 21 of the directional equipment blowing system is constantly turned on, which operates as follows. Before starting transportation of the station using the device 29 on / off system directional blowing equipment set the specified power level of an autonomous diesel heater 21 system directional blowing equipment. Through the fuel hose 28, fuel from the fuel tank 27 enters the combustion chamber of the heater 21. The heat from the combustion of the fuel through the heat exchanger is transferred to the air taken from the atmosphere. The resulting warm dry air is supplied through the duct 31 to the hardware compartment 19, where it circulates heats and drains the equipment located in the hardware compartment 19, in particular, in the hardware rack 10 and rack 26 of the converters and automation of the power supply system. The exhaust air through the opening of the exhaust fan 37 is removed from the hardware compartment 19. New portions of air necessary for the operation of the diesel heater 21 of the directional blowing system of the equipment are constantly supplied through openings (not shown) specially arranged in the aggregate compartment. The exhaust gases of the autonomous diesel heater 21 are released into the atmosphere. Box 36, in which the diesel heater 21 is located, in addition to its main (protective) function, also plays the role of a heat shield protecting the equipment of the aggregate compartment 18 from excess heat.

Upon arrival at the station’s work (deployment) site, maintenance personnel (station operator) disconnect the transport coupling device 6 from the moving object. The station is installed at a predetermined distance from the movable object, which is connected to it by information communication cables 16 through cable information inputs 14.

When deploying the station put forward a pair of stabilization supports 12 located on the pull-out rods 15, and jacking up both pairs of supports 11 and 12, achieve a stable horizontal position of the station.

Without fail, with the help of known means, protective grounding of the frame 1 and container 2 of the station is carried out and additionally (in the summer) they deploy a lightning protection system (see, for example, RF patent No. 2128390, class H02G 13/00, op. 27.03.1999) .

To gain access to the control panels of the hardware rack 10 and the rack 26 of the converters and the automation of the power supply system, the hatches 39 are opened. At the same time, the sealing shutters 25 prevent the penetration of dust, precipitation and cold air into the internal cavities of the aggregate 18 and the hardware 19 of the container compartments 2.

Using electric power cables 17 connect the station through a system of 13 electrical cable entries to a public utility AC 220 V, and in the absence of it, to a remote electric generator (diesel generator) 20. Then, using switching devices for electrical energy sources, there are 26 converters and automation of the power supply system in the rack; they supply power of the required ratings to the equipment rack 10 with telecommunication equipment.

If the ambient temperature is too low, in order to accelerate the output of the station to operating mode, in addition to the stand-alone diesel heater 21 of the directional equipment blowing system, already parked, cable 32 supplies power to the explosion-proof electric heater 33 of the equipment electrical heating system located in the hardware compartment 19 The specified heater is placed in the hardware compartment 19 of the station so that the heat flux emitted by it is directed primarily to the hardware rack 10 and the converter rack 26 her and the automation of the power system. Upon reaching a predetermined temperature in the equipment compartment 19 of the station, the electric heater 33 of the equipment’s electrical heating system is turned off, and the autonomous diesel heater 21 of the directional equipment blowing system is switched to the airflow mode without supplying fuel to its combustion chamber.

On the contrary, if the temperature of the environment surrounding the station is too high, in order to maintain a predetermined air temperature inside the hardware compartment 19 (and, above all, in the hardware rack 10 and in the rack 26 of the converters and automation of the power supply system), the air conditioning system 24 is switched on manually with using the control unit 34 of the air conditioning system or in automatic mode using temperature sensors (not shown) installed in the rack 26 of the converters and automation of the power supply system. Cooled air, in particular, through the air ducts 35 is directed, first of all, to the equipment of the hardware rack 10 and rack 26 of the converters and automation of the power supply system.

The readiness of the station for operation is judged by the following parameters (characteristics): the green indication of readiness for operation, located on the control panel of rack 26 of the converters and the automation of the power supply system, is lit, which signals the presence of power supply to the equipment, correct grounding, and the set temperature mode in the hardware compartment 19. In case of type malfunctions: lack of power supply to the equipment, violation of grounding circuits or deviation from the set temperature mode on the control panel When the rack is on, the corresponding red indicator lights up.

Using the controls on the control panel of the hardware rack 10, the telecommunication equipment located in the specified rack of the hardware compartment 19 is turned on and put into operating mode. The devices 5 for fixing the position of the satellite communication antenna 3 are released. Turn on the controller of the automatic antenna control system (the system is not shown), which is located in the hardware rack 10 and provides guidance of the antenna 3 to the desired satellite with its further accompaniment. After that, they ensure that the station operates in the normal mode in accordance with the functions listed above when describing the scope of the MSS.

Claims (10)

1. A mobile satellite communication station containing a wheelbase frame, a container with a hardware rack equipped with a shock absorption system, a power supply system with an electric generator, a satellite communication antenna with drive devices and fixing its position, cable power and information inputs, equipped with fastening devices on the frame, characterized in that the station additionally contains an air conditioning system and a system of directional blowing of equipment, the container is divided into isolated from each other storage and assembly compartments, in the first of which there is a hardware rack, an air conditioning system and an additionally introduced rack of converters and automation of the power supply system, and in the second - an electric generator of the power supply system, as well as cable power and information inputs, the air conditioning system output and the system output directional blowing equipment communicated with the hardware compartment of the container, and the base of the satellite communications antenna is located on the top panel of the container, which A number of power fasteners are connected to the frame. 2. The mobile satellite communications station according to claim 1, characterized in that the air conditioning system comprises a car air conditioner and a remote wireless control unit, the output of the air conditioning system is made in the form of two ducts, one of which is inserted into the equipment rack, and the second into the converter rack and automation of the power system. 3. The mobile satellite communications station according to claim 1, characterized in that the directional blowing system of the equipment is located in the aggregate compartment of the container. 4. The mobile satellite communications station according to claim 1, characterized in that the directional blowing system of the equipment comprises an autonomous diesel heater connected to the fuel tank and a power level controller equipped with a temperature sensor connected to the heater by a control cable, the system output through the duct hardware compartment of the container station. 5. The mobile satellite communications station according to claim 1, characterized in that an equipment electrical heating system is introduced into the hardware compartment. 6. The mobile satellite communications station according to claim 5, characterized in that the equipment’s electrical heating system is made in the form of an explosion-proof electric heater connected by a power cable to the rack of converters and automation of the power supply system. 7. The mobile satellite communications station according to claim 1, characterized in that the electric generator of the power supply system is made remote. 8. The mobile satellite communications station according to claim 1, characterized in that it is equipped with a fire extinguishing system, the output of which is communicated with the hardware compartment of the container. 9. The mobile satellite communications station according to claim 1, characterized in that the power supply system further comprises an autonomous guaranteed power supply system. 10. The mobile satellite communications station according to claim 9, characterized in that the autonomous guaranteed power supply system is battery-powered.

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