EP1206813B1 - Transportable system and a method for producing communications connections - Google Patents

Abstract

Transportable, autonomously operating equipment as a network node between networks for transmitting analog, digital and/or pulse-modulated signals in communication connections between a satellite and exchanges for extension stations and/or terminal stations with antennas, modules, walls, doors and/or vent openings, as well as a method for establishing the communication connections by automatically leveling the equipment and calculating the data for controlling the satellite antenna and the north-south position of the equipment.

Description

The present invention relates to a portable System as a network node between networks for transmission analog, digital and / or pulse modulated signals in Communication links between communication satellite and exchanges for extensions and / or Terminals with antennas, location system, modules, walls, Lifting devices, doors and / or ventilation openings on or in a supporting frame.

The invention further relates to a method for Establishing communication links between Networking using an automatic and autonomous working network nodes for the transmission of analog, digital and / or pulse-modulated signals between Communication satellite and switching centers for Extensions and / or terminals with antennas, Location system, modules, walls, lifting devices, doors and / or ventilation openings on or in a support frame.

It is known with the help of standing alone Satellite ground stations communicate with satellites to operate. Such satellite ground stations exist in doing so from individual components and can only by one Special team installed, commissioned and serviced become. They mostly consist of the permanently installed one Satellite antenna and the receiving, processing and Forwarding modules in separate buildings be installed.

Because of their structure, especially the free-standing Satellite antenna is only used in certain Areas of the world possible or need additional Devices and instruments are installed.

A disadvantage of these systems is in particular that use of this in areas with heavy snowfall an antenna heater is required for the Satellite connection even under these weather conditions can be manufactured or maintained.

It is also known that satellite antennas have a different orientation to the usable and intended communication satellite at every point on earth. The alignment of the satellite antennas is currently carried out by hand in most stationary devices at transmission rates greater than 64 kbps.
It is particularly important at these transmission rates that the antenna must be precisely aligned for transmission by satellite over a greater distance, so that the required transmission quality is achieved.

However, there are also known smaller mobile systems based on are mounted on a vehicle and their antennas as well manually aligned.

A mobile telecommunications station according to WO 98/15027 is known for the transmission and reception of radio signals. This station consists of a metal container, inside which there is a lattice mast for the antennas and partition walls are available. In the separate rooms there are units and generators for the operation of the mobile station.
The lower platform of the metal container is releasably attached to the chassis of a vehicle, with retractable legs being arranged below the platform.
This arrangement of the legs is particularly disadvantageous because they are not integrated into the interior of the metal container. Transporting the container by train, plane, ship or on trucks with loading platforms is only possible to a limited extent, since the retractable legs would have to be removed for transport.
Another disadvantage is that devices and modules for directional radio transmission are present in the container, but the transmission links first have to be laboriously manufactured. The antennas have to be assembled on site on the extendable lattice mast and the alignment to the next radio station takes place manually.

Also according to US Pat. No. 4,320,607 it is known to support legs for the transportation of heavy large parts such as concrete slabs to install. A particular disadvantage here is that the arrangement of the support legs the width of the goods to be transported is enlarged and thus an even larger excess width arises.

The arrangement of small satellite receiving antennas for radio and television reception on vehicles is also known, as described in the German utility model GM 92 06 944 U1. The receiving antenna is located on the roof of the vehicle and the parabolic mirror can be folded so that the air resistance when driving is low. The parabolic mirror is set up and aligned with an additional lifting and rotating unit with servo motors, which can be operated from inside the vehicle. The height of the vehicle is increased by the lifting and rotating unit and the antennas.
This arrangement is only suitable for small receiving antennas and not for transmitting and receiving antennas with high transmission rates.

In this prior art, the invention Task based on a portable system as a network node between networks and a method of making Analog, digital and / or pulse modulated transmissions Signals in communication links between Communication satellites and switching centers for To create extensions and / or end stations that a automatic and independent commissioning of the systems of telecommunications and data transmission technology as well independent loading and unloading from the means of transport allows.

This object of the invention is achieved by a system and a method solved with the characteristic features of the main claims and their further embodiment in the further claims its distinctive features.

The invention is characterized above all by the fact that a network and communication infrastructure with high Transfer rates of over 64kbps can be built up quickly can, regardless of the location of the field of application no additional accommodation for the Indoor units of the ground station and none specifically trained personnel are required on site.

Due to the installed generator and the Air conditioning and the designed satellite antenna is the system according to the invention with its satellite, Telecommunications and data modules anywhere in the world applicable regardless of natural environmental parameters, like snowfall or high outside temperatures.

According to the requirements, the invention System with the satellite, telecommunications and Data modules with integration of DEC (digital European Cordless) and / or GSM (Global System for Mobile Communication) - solutions. But it is also one Integration of data solutions, video conference solutions and / or the transfer of medical technology Transfer solutions possible.

It is particularly advantageous that the invention Plant a portable plant on a support frame as Network nodes between networks for the transmission of analog, digital and / or pulse modulated signals in Communication links between communication satellites and switching centers for auxiliary systems and / or Terminals with antennas, location system, modules, Is lifting devices.

Another advantage of the invention is that the plant preferably has a size as the network node Dimensions that correspond to a standard 20 'container. Since no additional attachments or attachments in the Transport status exist, the transport is the System particularly easy and with all means of transport possible without any problems.

According to the invention, the system is a network node on or in a support frame, in which profile carriers are arranged in a force-locking manner. It has proven to be advantageous to arrange the profiled beams near the corners in the support frame and preferably parallel to the end faces. Lifting beams are slidably arranged in the profile beams and can be extended to the outside. The lifting devices are located at the outer ends of the lifting supports, and base plates can be attached to the lower edge of the lifting device rods. The motor and the actual lifting rod, which can be extended downwards, is in the retracted state above the lower edge of the lifting beam. The lower edge of the lifting device rod ends in the retracted state with the lower edge of the lifting beam.
According to the invention, it is thereby possible to retract the lifting supports with the arranged lifting devices to such an extent that they do not protrude beyond the external dimensions of the supporting frame in the retracted state, but are in the lifting device spaces on the outside of the system.

It is advantageous if the profile beams over the entire Width of the support frame and thereby the two outer edges of the support frame with the support bars are additionally connected.

It is particularly advantageous that the lifting supports with the lifting devices can be extended from the profiled supports to such an extent that the lifting device rods of the lifting devices are outside the loading width of the transport means in the extended state.
If necessary, floor slabs can then be connected to the lifting device rods, if the nature of the floor makes this necessary. Another advantage is that the base plates on the lifting device rods can be dismantled before the retraction, so that there are no space problems with the lifting devices in the lifting device space of the system.

The lifting devices according to the invention System after the lifting beams have been extended from Means of transport raised so that the means of transport can be removed without problems. That in the plant Integrated leveling module levels the system by controlling the individual lifting devices by the Lifting rods horizontally and horizontally Vertical horizontally exactly. This exact leveling is a prerequisite for the following Control calculations for automatic Alignment of the satellite antenna with the Communication satellites can take place.

A storage module for receiving the satellite antenna base and its stabilizing struts was arranged in the center across the entire width of the support frame. A satellite antenna which is designed as a multiband offset antenna system is preferably installed on the satellite antenna base. The orientation of the satellite antenna is controlled from the determined data of the integrated measuring and control module and the location system.
The geographic location of the system is preferably calculated in real time from the data of the Global Positioning System (GPS) and the north-south direction is determined from the compass data.
It is particularly advantageous if an electronic compass is used as the compass, in which the data of the local magnetic fields can also be taken into account.

The control of the alignment of the satellite antenna takes place after the leveling of the system and the subsequent comparison of the data of the geographical location with the north-south direction and the position of the communication satellite to be used.
After determining the coordinates, the control system automatically aligns the parabolic mirror of the antenna exactly to the position of the satellite to be used.

After which the communication link between satellite and plant has been produced, it is according to the invention also possible to connect the antenna through this nachzusteuern.

It has been shown that it is advantageous if the storage module of the satellite antenna has a maximum height such that the satellite antenna ends at a height below the inner roof edge during transport or in the idle state. The satellite antenna base is preferably in the middle and the stabilizing struts are preferably attached to the upper corners of the bearing module. However, other attachment points are also possible.
The bearing module can be additionally reinforced on the inside at the outer corners by load-bearing supports.

There is an openable roof above the satellite antenna. The roof is preferably opened approximately over the entire room in which the satellite antenna with the parabolic mirror and horn antenna are located during the rest position.
Roofs are preferred which are designed as folding or sliding roofs.

The parabolic mirror and horn antenna of the satellite antenna are vertical from the rest position up to 150 ° pivotable. However, it has been shown that Satellite antennas with a swiveling of the Parabolic mirror and the horn emitter preferred up to 132 ° become.

It is particularly advantageous if the satellite antenna on the satellite antenna base horizontally by 360 ° around the Axis is rotatable.

This is located on one side of the storage module Unit module, in which advantageously at least one Generator and / or an electrical connection and Distribution station are arranged.

In plants to be installed in areas in where high outside temperatures occur, is additional an air conditioning system installed, all modules and aggregates of the network node can cool.

The operator module is on the other side of the storage module with integrated measuring and control module and Positioning system arranged that also the communication links to the satellite and to PSTN (Public Switched Telephone Networks), ISN (Integrated Services Network) and / or ATM (Asynchronous Transfer Mode) processed the signals.

The operator module uses an antenna, it is advantageous to use an extendable omnidirectional antenna and / or to establish a cable network for communication with the end points, such as radio-controlled telephone booths, hand-held telephones or via line networks with computers, faxes, etc.
This network can also use the operator module to carry out communication between several end stations completely autonomously if it takes place locally.
The operator module preferably consists of a HICOM CORDLESS SYSTEM or GSM (Global System for Mobile Communication), but other systems are also possible.

The particular advantage of the method according to the invention is that that an automatic and autonomous production of Communication links with transmission rates of over 64 kbps can be manufactured and operated; there are but lower transmission rates are also possible.

According to the procedure, the system is called a network node, after he has reached his destination, either the electrical supply network connected or that in The existing generator is switched on.

According to the procedure, the lifting beams with the Lifting devices in the profile beams first extended and put into operation. The particular advantage is that through our own energy supply and lifting device the system from the transport vehicle without external aids can be removed.

According to the invention, after the removal of the means of transport, the leveling module integrated in the system of the network node is put into operation, which individually controls the motors of the lifting devices in such a way that the system is aligned exactly horizontally and vertically by means of the lifting device rods.
After receiving the data from the global positioning system (GPS), the method according to the invention enables the geographic location to be determined in real time. At the same time, the data of the north-south direction are determined using a compass, preferably an electronic compass.
The control data are calculated from the comparison of this data in the control module after the leveling of the system with the position of the communication satellite to be used, and the horizontal and vertical control of the satellite antenna is controlled by the control module so that it is exactly aligned with the communication satellite and the operator module the communication connection to the satellite and the PSTN (Public Switched Telephone Networks), ISDN (Integrated Services Digital Network) and / or ATM (Asynchronous Transfer Mode).

The received signals are sent to the operator module led, worked up there and then over a Antenna wireless to the end points, like wireless Hand-held telephones, telephone booths or via a line network Terminals such as computers, fax machines or the like directed.

Further advantages, details and essential to the invention Features emerge with reference to the accompanying Drawings.

The invention is intended in one Exemplary embodiment are explained in more detail:

Fig.1

Prinzipdarstellung der Anlage in Seitenansicht im Betriebszustand

Fig.2

Prinzipdarstellung der Anlage in Seitenansicht im Transport- oder Ruhezustand

Fig.3

Prinzipdarstellung der Hubvorrichtung im aus- und eingefahrenen Zustand

Show it:

Fig.1

Principle view of the system in side view in the operating state

Fig.2

Schematic representation of the system in side view in transport or idle state

Figure 3

Schematic diagram of the lifting device in the extended and retracted state

The system according to the invention essentially consists, as shown in FIG. 1, of a network node with walls 16 on a support frame. Profile supports 6 are arranged in a non-positive manner near the end walls.

As can be seen from Figure 3, the profile beams 6 are arranged over the entire width of the support frame and connect the two support bars 5,5 ' . The profile carriers 6, 6 'also have the function of guiding the lifting supports 23, 23' with the lifting devices 7, 7 ' . Thus, the lifting device 7 on the lifting bracket 23 can be moved outwards so far that the attached base plate 10 protrudes beyond the transport means, not shown. In the extended state C , the lifting process is carried out by means of the lifting device 7 and the lifting device rod 22 . In this example there is a detachable base plate 10 on each lifting device 7 , so that a secure stand is given according to the nature of the base. The lifting beam 23 'is in the retracted state D in the profile beam 6 and thus the lifting device 7' and the lifting device rod 22 are located in the lifting device space 21 within the external dimensions of the system.

As can also be seen from FIG. 1, a bearing module 1 is arranged in the center on the support frame with support bars 5 , on which the satellite antenna base 13 for the satellite antenna 11 is fastened. The fastening of the satellite antenna pedestal 13 is carried centrally on the support module 1 and is additionally secured by stabilizing struts 14 in the direction of all four corners on the storage modulus. 1 Parabolic mirror 15 and horn 17 are in the working position B.

In addition to the storage module 1, there is the unit module 2, in which there is a generator and an electrical connection and distribution station as well as an air conditioning system. The space 12 for the parabolic mirror 15 and the horn antenna 17 is located above the unit module 2 during transport or in the rest position A (see FIG. 2).

The operation module 8 with integrated measuring and control module and location system is located in a separate room.

After the system has been leveled horizontally and vertically with the aid of the leveling system and the control of the individual lifting devices 7 on the lifting device rods 22 , the integrated positioning system GPS determines the geographical location and the electronic compass in the measuring and control module determines the north-south direction of the plant network node. From the comparison of the data, the control module calculates the control data for the control of the satellite antenna after determining the position of the communication satellite to be used. After this data has been calculated, the roof 4 is opened, which in this example has been designed as a sliding roof.

After opening the roof 4 , the vertical and horizontal alignment of the parabolic mirror 15 takes place automatically based on the calculation by the integrated measuring and control system by means of the lifting and rotating unit with an integrated servomotor of the antenna on the satellite to be used, via which the connection to PSTN , ISN or ATM is established.

The signals are processed in the operator module 3, which is located on the other side of the storage module 1 , and then passed directly to the terminal 20 by means of an extendable omnidirectional antenna 18 or via a line network. In this example, a HICOM ™ CORDLESS SYSTEM was used as operator module 3 .

LIST OF REFERENCE NUMBERS

storage module

1

module of units

2

operator module

3

top, roof

4

supporting bars

5

profile support

6, 6 '

lifting device

7, 7 '

Access door to the operator module

8th

Access door to the engine room

9

baseplate

10

satellite antenna

11

Space for parabolic mirrors and horn radiators

12

Satellite antenna base

13

stabilizing struts

14

parade

15

wall

16, 16 '

horn

17

antenna

18

satellite

19

terminal

20

lifting device space

21, 21 '

lifting device rod

22, 22 '

lifting beam

23, 23 '

rest position

A

working position

B

Extended state

C

Retracted condition

D

Claims (11)

1. Transportable equipment as network node between networks for transmitting analog, digital and/or pulse-modulated signals in communication connections between a communication satellite and exchanges for extension stations and/or terminal stations with antennas, locating system, modules, walls, lifting devices, doors and/or vent openings at or in a supporting frame, characterised in that the equipment consists of

   a) profiled supports (6, 6'), which are disposed horizontally in a supporting frame, in which moveable lifting supports (23, 23') are located with non-positively disposed lifting devices (7, 7'),

   b) the leveling system, which controls the individual lifting device rods (22, 22'), separately by means of the lifting devices (7, 7'),

   c) a satellite antenna (11), which is disposed in the inactive state within the equipment undernearth a roof (4), which is to be opened, on a storage space module (1),

   d) an operator module (3) with an integrated measurement and control module and a locating system for calculating the geographic location in real time for determining the north-south direction and for calculating the data for controlling the satellite antenna (11) to the position of the communication satellite (19), which is to be used, after leveling and comparing the data of the location, the north-south direction, and the position of the position of the communication satellite (19), which is to be used.
2. The equipment of claim 1, characterised in that the lower edge of the lifting device (7) terminates with the lifting support (23) at the outer ends of the lifting support (23) in the retracted state and is located within the outer dimensions of the supporting frame.
3. The equipment of claim 1, characterised in that the lifting support (23) with the lifting devices (7) can be extended individually to the outside from the profiled supports (6) and the lifting device rods (22) can be controlled individually.
4. The equipment of claim 1, characterised in that the satellite antenna (11) preferably is a multiband offset antenna system.
5. The equipment of claim 1 and 4, characterised in that the satellite antenna (11) preferably is a 2.4 m multiband offset antenna system.
6. The equipment of claim 1, characterised in that the locating system is a global positioning system (GPS) and contains an electronic compass.
7. The equipment of claim 1, characterised in that the roof (4), which is to be opened, is a folding or sliding roof.
8. A method for producing communication connections between networks by means of a network node for transmitting analog, digital and/or pulse-modulated signals between a communication satellite and exchanges for extension stations and/or terminal stations with antennas, locating system, modules, walls, lifting devices, doors and/or vent openings at or in a supporting frame, characterised in that by the steps of

   leveling the equipment horizontally and vertically up to a level position,

   calculating the geographic location of the equipment from the data of the GPS (global positioning system) in real time,

   determining the north-south direction from the data of a compass,

   calculating the data for controlling the alignment of the satellite antenna (11) with the communication satellite (19) after comparing the data of the location, the north-south direction and the position of the communication satellite, which is to be used and

   aligning the satellite antenna with the communication satellite and establishing the communication connections with the PSTN (Public Switched Telephone Networks), the ISDN (Integrated Services Digital Network) and/or the ATM (Asynchronous Transfer Mode).
9. The method of claim 8, characterised in that the leveling of the equipment is controlled centrally and takes places separately over individual lifting devices (7, 7') with the lifting device rods (22, 22').
10. The method of claim 8, characterised in that for the determination of the geographic location, the signals, sent by the GPS satellite, are measured and processed in real time in the measurement module and the data for controlling the satellite antenna are calculated in the control module.
11. The method of claim 8, characterised in that preferably HICOM™ cordless systems (digital call handling devices for extension station facilities from Siemens) or GSM (global system for mobile communication) are used as operator module for establishing the communication connections.

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