WO2001067630A1

WO2001067630A1 - Coupling of a head station to a low-voltage power supply network

Info

Publication number: WO2001067630A1
Application number: PCT/CH2000/000130
Authority: WO
Inventors: Hanspeter Widmer
Original assignee: Ascom Powerline Communications Ag
Priority date: 2000-03-08
Filing date: 2000-03-08
Publication date: 2001-09-13
Also published as: CN1451207A; BR0017145A; EP1264419A1; IL151506A0; AU2000227915A1

Abstract

At least one head station (8) and a plurality of subscriber stations (16.1, 16.2, 16.3) are connected to a low-voltage power supply network (3) for distributing electricity from a transformer station (1) to a plurality of consumers in homes (12, 13) or factories (14). Said head station (8) is capacitively coupled to the distributor device (7) in the transformer station (1) and controls or monitors the exchanging of data between the subscriber stations (16.1, 16.2, 16.3). The head station (8) is also connected to other communications networks (10, 11) by a router (9), for information transmission (9). Through the low-voltage power supply network (3), the subscriber stations (16.1, 16.2, 16.3) can communicate a) with the head station (8) b) with each other, directly or indirectly through the head station (8) and c) with subscribers in the other communications networks (10, 11), through the head station.

Description

Coupling a head-end station to a low-voltage power supply network

Technical field

The invention relates to a circuit arrangement for coupling in and out a high-frequency message signal from at least one head-end station into and out of a low-voltage power supply network, and a corresponding method. State of the art

Electrical energy is typically not produced where it is needed. After generation, it is therefore transformed to high voltage for transport and, after or during distribution in mostly several network nodes and different stages, transformed back from high to low voltage. The fine distribution of the energy to the various end consumers takes place in the low-voltage power supply network, which has a tree-like structure for this purpose. The supply signal is from the root, i.e. a central point, e.g. B. a transformer station in a residential area, distributed over a plurality of branches to the individual blocks of flats. Within one apartment block there is a further branching to the individual apartments and within one apartment to the various sockets and other network access.

It is known to also transmit messages such as telephone calls, fax copies, digital data, etc. via low-voltage power supply networks. For this purpose, the messages are encoded and a high-frequency carrier signal in a known manner, for. B. imprinted by frequency modulation. This message signal is coupled into the low-voltage power supply network by the transmitter, and decoupled again by the receiver and then decoded. Communication systems that use a power supply network in this way are e.g. B. described in WO A95 / 29537.

In order to keep the connection paths as short as possible, the transmitters and receivers are connected as close as possible to one another on the power grid. However, this makes communication with stations that are connected to another branch of the network more difficult. In addition, this requires a plurality of decentralized network transitions for data transmission from or to other communication networks. Presentation of the invention

The object of the invention is to provide a circuit arrangement of the type mentioned at the outset which avoids the problems existing in the prior art and in particular permits energy and effort-efficient message transmission within a power supply network and also from or to other communication networks.

The solution to the problem is defined by the features of claim 1. According to the invention, the low-voltage power supply network comprises a network node for coupling a high-frequency message signal from at least one head station into and out of the low-voltage power supply network. The network node, for example a transformer or a distribution station, has a distribution device for distributing the network current to a plurality of supply lines. The head station, via which the message signal is coupled into or out of the low-voltage power supply network, is connected to the distributor device.

The transmission of the message signal takes place between the head-end station and a plurality of subscriber stations, which are typically located in the area of the branches of the low-voltage power supply network, e.g. B. are connected to an electrical outlet in an apartment or at a distribution box in a house to the low-voltage power supply network. On the one hand, the head-end station communicates with the subscriber stations and, on the other hand, controls and controls the communication between the subscriber stations. In addition, data is transferred from or to other communication networks such as the telephone network or the Internet via the head-end station.

With the circuit arrangement according to the invention, all subscriber stations which are either connected to the same branch or even to different branches of the low-voltage power supply network can be reached via a head station. Due to the central location, the head-end station can also be reached in the opposite direction from all subscriber stations. All participants also receive messages from or be able to transmit to other communication networks, a single network transition implemented at the head-end station is therefore sufficient.

By connecting the head-end station to the low-voltage power supply network, not only is the message signal transmitted, but at the same time the head-end station is also supplied with electrical energy from the low-voltage power supply network.

The head station is preferably capacitively coupled to the distribution device. The high-frequency message signal is switched into or out of the distribution device, for example via a high-pass filter. decoupled from it. The high-pass filter also prevents the low-frequency but high-energy mains current from entering the data path of the head-end station.

To distribute the mains current, the distributor device has a current input, a distributor and at least one current output. The mains current to be distributed is fed to the distributor via the current input. The mains current is then distributed to the individual supply lines via the current outputs branching off from the distributor, which are each connected to a current output for this purpose.

In the case of multi-phase mains currents, the distributor, for example a busbar, has a correspondingly multipole design. He has z. B. each have its own busbar for the three phases and the neutral conductor of a three-phase mains current. To an electricity consumer resp. To be able to connect a subscriber station to a supply line or to transmit a message signal via it, it must have at least two current conductors, ie a neutral conductor and at least one phase conductor. Accordingly, each current output of the distributor device must also have at least two current conductors, each of which is connected to a corresponding pole of the distributor. Depending on the subscriber stations to be communicated with and the supply lines to which they are connected, there are several ways in which the head-end station can be connected to the low-voltage power supply network.

In a preferred embodiment of the invention, the head-end station is connected to the distributor.

To connect the head station to the distributor, this has at least two poles, one for the neutral conductor and at least one for a phase conductor, and the head station has at least two connection contacts. The head-end station is accordingly connected to one pole of the distribution device with one connection contact each.

In a second preferred embodiment of the invention, the head-end station is connected to at least one current output of the distributor device, that is to say in the direction of subscriber stations virtually behind the distributor.

This means that all stations connected to the same branch can be easily reached from the head-end station. But even subscriber stations that are connected to another branch can either be reached via the distributor, or the same message signal is transmitted simultaneously from different head lines to different supply lines by a head station connected to several current outputs. The same naturally applies to the accessibility of the head-end station by the subscriber stations and the communication with subscribers from other networks.

In a preferred variant of this embodiment, a plurality of head stations are connected to exactly one supply line each. This means that a different message signal can be sent on different branches.

The head station in turn has at least two connection contacts and a current output comprises at least two current conductors, ie a neutral conductor and at least one phase conductor. The head-end station is connected to a power conductor of a supply line with one connection contact each. In a further circuit arrangement, the head station is preferably connected to at least two current outputs, a switch arrangement being connected between the head station and the current outputs. The switch arrangement is designed in such a way that the head-end station can optionally be coupled to one or to several current outputs at the same time. The head-end station can thus optionally couple a message signal onto one or more supply lines at the same time.

As already mentioned, each current output comprises at least two current conductors. In order to prevent or at least limit damage in the event of malfunctions such as, for example, short circuits, individual or all current conductors of a supply line are advantageously protected against overcurrents with an overcurrent breaker. The overcurrent breaker, i. H. the fuse is located, for example, directly when a current output is connected to the distributor.

Switching, echoes or crosstalk from other supply lines can cause interference that can have a negative impact on message transmission. To suppress such interference, one or more current conductors of a current output are preferably connected to the distributor via a low-pass filter. However, this low-pass filter not only suppresses interference from outside, but at the same time prevents the propagation of the message signals coupled into the power supply network in undesired directions.

In the case of current conductors which are connected to the distributor via an overcurrent breaker and at the same time via a low-pass filter, the low-pass filter is preferably integrated in the overcurrent breaker. This means that the low-pass filter, for example a choke coil with suitable inductance, is integrated in the housing of the fuse or, more generally, that the low-pass filter and the overcurrent breaker are housed in the same housing. This ensures that there is no additional effort when installing a low-pass filter in existing systems, only the old fuse has to be replaced by a new fuse with an integrated filter. The inductance of the choke is chosen so that its impedance low-frequency signals like hardly affects the mains current, but is very large for high-frequency signals such as the message signal or corresponding interference signals.

For data transmission via a low-voltage power supply network, e.g. For example, a 230V / 400V power supply network with a network frequency below 1 kHz, the message signal preferably has a frequency between 1 MHz and 60 MHz. That is, the messages are modulated onto a carrier with a carrier frequency between 1 MHz and MHzO MHz.

In a preferred circuit arrangement, in addition to the at least one head station, a plurality of subscriber stations are connected to the low-voltage power supply network.

The head station is advantageously designed such that the subscriber stations can exchange message signals on the one hand with the at least one head station and on the other hand with one another via the at least one head station.

For the transmission of messages from or to a head or a subscriber station to or from external (in relation to the low-voltage power supply network) subscribers, the head station is preferably connected to a further communication network in addition to the low-voltage power supply network.

A method having the features of claim 15 is preferred for sending or receiving a message from a head station via a low-voltage power supply network which has a network node with a distribution device and in which the head station in the network node is connected to the distribution device used.

The distribution device in the network node serves to distribute network current over a plurality of supply lines. The network node is, for example, a transformer station for the energy supply of a residential area or a distribution station for the energy supply of the individual houses on a street. When a message is sent, a high-frequency message signal is generated in the head-end station by modulating a high-frequency carrier signal with the message and is capacitively coupled into the distribution device. Similarly, when a message signal transmitted via the low-voltage power supply network is received, the head-end station capacitively couples it out and the message is recovered by means of demodulation of the message signal.

The messages to be sent are typically generated by a data terminal, for example a computer connected to the head-end station or to a subscriber station, and are generally coded or decoded before the modulation or after the demodulation and finally processed further by the receiver as desired.

The method can in particular be carried out with circuit arrangements of the type described above.

A message signal coupled into the low-voltage power supply network via two current conductors of a current output, in particular a message signal with a frequency greater than 1 MHz, can propagate in the network in various ways: directly on the supply line which is connected to this current output Current output via the distributor to other current outputs or even via the distributor towards the current input. The signal path from a current output back via the distributor to the other current outputs or even to the current input is generally undesirable. Therefore, low-pass filtering is preferably carried out in at least one of the at least two current conductors of the corresponding current output with a low-pass filter located between the distributor and the connection point of the head-end station, and the message signal is filtered out. At the same time, this low-pass filter can also suppress unwanted interference, on the one hand from the distributor and on the other hand from the current output.

But even with a head-end station connected to the distributor, the coupled-in message signal may only be transmitted via certain supply lines. Low-pass filters placed in this way are also useful in this case. additionally In such a case, the current input of the distribution device could also be provided with a low-pass filter.

By using several head stations, each of which is connected to one or more power outputs, several subscriber stations connected to different branches can be supplied with different message signals at the same time. It is also advantageous here to carry out low-pass filtering in the current conductors between the distributor and the respective connection point of the head-end station, so that the message signals do not interfere with one another.

In order to prevent damage which can occur, for example, in the event of short circuits or other malfunctions, the current outputs or the individual current conductors of a current output are preferably protected against overcurrents between the distributor and the head-end station. That is, An overcurrent breaker is inserted in at least one current conductor between the distributor and a connection point of the head-end station.

As already described briefly, a head-end station, such as is used to couple a high-frequency message signal into or out of a low-voltage power supply network, corresponds to a transceiver with additional functions. With such a transmitting / receiving device, electrical signals are capacitively coupled into or out of a power supply network. The additional functions include, for example, the coordination of the communication of other transmitting / receiving devices with one another.

Such a head-end station is preferably used to couple a high-frequency message signal into or out of a low-voltage power supply network by connecting the head-end station to a distribution device which is located in a network node of the low-voltage power supply network for distributing mains power to a plurality of supply lines serves. From the following detailed description and the entirety of the claims, further advantageous embodiments and combinations of features of the invention result.

Brief description of the drawings

The drawings used to explain the exemplary embodiment show:

1 shows a schematic representation of a low-voltage power supply network with a network node and a plurality of supply lines,

2 shows a circuit arrangement according to the invention with a distributor device and a head station connected to the distributor,

3 shows a detailed section of the circuit arrangement from FIG. 2,

4 shows a circuit arrangement according to the invention with a distributor device and a head station connected to a current output,

5 shows a detailed section of the circuit arrangement from FIG. 4,

6 shows a circuit arrangement according to the invention with a distributor device and a head station connected to a plurality of current outputs,

7 shows a circuit arrangement according to the invention with a distributor device and a head station connected to a plurality of current outputs via a switching device, 8 shows a circuit arrangement according to the invention with a distributor device and a plurality of head stations each connected to a current output

In principle, the same parts are provided with the same reference symbols in the figures

Ways of Carrying Out the Invention

FIG. 1 shows a schematic illustration of a low-voltage power supply network 3 with a local network transformer station 1 and a plurality of supply lines 2 1, 2 2, 2 3, 2 4 and 2 5. The transformer station 1 is fed via a medium-voltage line 5, the medium voltage in the transformer station 1 being transformed down to low voltage with a transformer 6. The low voltage is distributed to the individual supply lines 2 1 to 2 5 via a distributor device 7

A head station 8 is connected to the distribution device 7 and is connected to two further communication networks 10 and 11 via a router 9

The supply lines 2 1 to 2 5 lead to a plurality of electricity consumers. Supply line 2 1 leads, for example, into a residential area with two houses 12 and 13, the rooms of which are supplied with electrical energy from the low-voltage power supply network 3 via corresponding power lines. Supply line 2 2 leads into Industrial area, which is indicated by a factory 14, which is connected to the low-voltage power supply network 3

In addition, a subscriber 15 1 is shown in house 12, a subscriber 15 2 in house 13 and a subscriber 15 3 in factory 14, each of which is connected to the low-voltage power supply network 3 via a subscriber station 16 1, 16 2 or 16 3 This offers the three participants 15 1 to 15 3 (for example computers with their users or other data terminals) a variety of communication options Each participant 15.1 to 15.3 can exchange data with the other users via the head-end station 8. The participants 15.1 and 15.2 can communicate via the supply line 2.1 either via the head station 8 or directly with one another and finally all participants 15.1 to 15.3 can transmit messages from participants to the other communication networks 10 and 11 via the head station 8 and the router 9 receive this. If the communication networks 10 or 11 are, for example, a telephone network or the Internet, the participants 15.1 to 15.3 can make a telephone call with another participant in the communication network 10 or they can use the various Internet services via the low-voltage power supply network 3.

FIG. 2 shows a circuit arrangement according to the invention as a section of the transformer station 1. The distributor device 7 comprises a current input 17, a distributor 18 and a plurality of current outputs 19, 20, 21, 22 and 23. The head station 8 is capacitively connected to the distributor 18. The capacitive coupling is indicated by a capacitance 24 between the head-end station and the distributor. The supply lines 2.1 to 2.5 are connected to the current outputs 19 to 23, which are each protected by overcurrent breakers 25.

FIG. 3 shows part of the circuit arrangement from FIG. 2 using the example of a single-phase power network. The current input 17 of the distributor device 7 comprises a neutral conductor 26 and a phase conductor 27. Both are connected to a busbar 28.1 and 28.2, which together form the distributor 18. Several current conductors, ie neutral conductors 26.1, 26.2 and phase conductors 27.1, 27.2 branch off from each busbar 28.1 or 28.2, each of which is protected by an overcurrent breaker 25. A neutral conductor and a phase conductor together form a current output. Neutral conductors 26.1 with phase conductors 27.1 form the current output 22 and neutral conductors 26.2 with phase conductors 27.2 form the current output 23. Corresponding supply lines 2.1 and 2.2 are connected to each current output 22 or 23. The head station 8 has two connection contacts 29.1, 29.2, which are each capacitively coupled to a busbar 28.1, 28.2. In this figure, too, the capacitive coupling is represented by a respective capacitance 24.

FIG. 4 shows another type of coupling for connecting the head station 8 to the distributor device 7. In this example, the head station 8 is not connected to the distributor 18 but to a current output 23.

As shown in FIG. 5, the connection contacts 29.1 and 29.2 of the head station 8 are accordingly connected to the neutral conductor 26.2 and the phase conductor 27.2 of the current output 23, respectively. In addition to the overcurrent breakers 25, a filter 30 is shown in each conductor. This prevents message signals from or to the head station 8 from going in the wrong direction, namely in the direction of the distributor 18.

A further type of coupling for the head station 8 is shown in FIG. The head-end station 8 is connected to several current outputs 19 to 23 of the distribution device 7 at the same time. The connection of the connection contacts 29.1, 29.2 of the head station 8 to the individual current conductors of each current output 19 to 23 is realized according to FIG. 5. A filtering of the message signals with filters 30 as in FIG. 5 is not shown in FIG. 6, but would be easily implemented by interposing corresponding filters in individual or all current outputs 19 to 23.

In FIG. 7, the head station 8 is also connected to a plurality of current outputs 19 to 23. However, the coupling does not take place directly, but via a switching device 31. The head station 8 is connected on one side of the switching device 31 and the current outputs 19 to 23 are connected on the other side. The switching device 31 can be used, for example, to control which of the current outputs 19 to 23 connected to the switching device 31 is to be coupled into a message signal emitted by the head station 8 or to which current output 19 to 23 the head station 8 is to be connected for the purpose of receiving a message signal , The switching device 31 can also be controlled from the outside, ie by the head station 8 itself or by other devices or persons. In the connections between the current outputs 19 to 23 and the switching device

In addition to a capacitance 24 for the capacitive coupling, 31 is an amplifier circuit

32 shown. On the one hand, this amplifies the transmitted signals in both directions and, on the other hand, serves to adapt the terminating impedance to the line impedance of the current outputs 19 to 23 or the supply lines 2.1 to 2.5 connected to them.

It should be noted that both an overcurrent breaker 25 and a filter 30 are present in each current output 19 to 23. The special feature of the illustrated embodiment is that the filter 30 is integrated in the corresponding overcurrent breaker 25.

FIG. 8 shows how a plurality of head stations 8.1, 8.2, 8.3, 8.4, 8.5 are connected to exactly one current output 1 to 23. This enables the sending or receiving of different message signals by a head-end station 8.1 to 8.5 on resp. from the various current outputs 19 to 23 or supply lines 2.1 to 2.5. The filters 30 integrated in the overcurrent breakers 25 prevent the message signals which are coupled in on a specific current output from spreading unintentionally via the distributor 18 and disrupting the message transmission on the other current outputs.

The coupling of the individual head stations 8.1 to 8.5 to the respective current output 19 to 23 takes place analogously to the coupling of the head station 8 to the current output 23 in FIG. 4 or FIG. 5.

A protective conductor can of course also be provided to protect the circuits. The procedure for securing, for example with protective earth, is known to the person skilled in the art. For the sake of clarity, however, the ground conductors and the groundings of the individual circuit arrangements have been omitted in the figures. In summary, it can be stated that the invention with one or more appropriately placed head stations connected to a low-voltage power supply network allows a large number of subscribers connected to this low-voltage power supply network both among themselves and via a network transition to a different communication network can exchange data electronically with other participants in those networks

Claims

claims

1 circuit arrangement for coupling or decoupling a high-frequency night signal from at least one head station (8) into or out of a low-voltage power supply network (3), the low-voltage power supply network comprising a network node (1) with a distributor device (7) for distributing Mains current to a plurality of supply lines (2 1 - 2 5) and the head station is connected to the distribution device

Circuit arrangement according to claim 1, characterized in that the at least one head station is capacitively coupled to the distributor device

Circuit arrangement according to claim 1 or 2, characterized in that the distributor device has a current input (17), a distributor (18) and at least one current output (19-23) and the at least one head-end station is connected to the distributor

Circuit arrangement according to Claim 3, characterized in that the distributor has at least two poles (28 1, 28 2) and the at least one head station has at least two

Has connection contacts (29 1, 29 2), the at least one head station having one connection contact each being connected to a pole of the distributor

Circuit arrangement according to Claim 1 or 2, characterized in that the distributor device has a current input, a distributor and at least one current output and the at least one head station is connected to at least one current output

Circuit arrangement according to claim 5, characterized in that a plurality of head stations is connected to exactly one current output each

7. Circuit arrangement according to one of claims 5 to 6, characterized in that the at least one current output has at least two current conductors and the at least one head station has at least two connection contacts, the at least one head station with the at least two connection contacts each being connected to one of the at least two current conductors is.

8. Circuit arrangement according to one of claims 5 to 7, characterized in that the at least one head station is connected via a switch device (31) to at least two current outputs, the switch device having means for selectively coupling the at least one head station to or at the same time multiple current outputs.

9. Circuit arrangement according to one of claims 1 to 8, characterized in that the at least one current output comprises at least two current conductors and at least one current conductor is connected to the distributor via an overcurrent breaker (25).

10. Circuit arrangement according to one of claims 1 to 9, characterized in that the at least one current output comprises at least two current conductors and at least one current conductor is connected to the distributor via a low-pass filter (30).

11. Circuit arrangement according to claim 9 and 10, characterized in that the low-pass filter is integrated in the overcurrent breaker.

12. Circuit arrangement according to one of claims 1 to 1 1, characterized in that the message signal is generated at a frequency between 1 MHz and 60 MHz.

13. Circuit arrangement according to one of claims 1 to 12, characterized in that a plurality of subscriber stations (16.1-16.3) connected to the low-voltage power supply network is provided and the at least one head station is designed such that the subscriber stations transmit message signals with the at least one head station and can exchange with each other via the at least one head-end station.

14. Circuit arrangement according to one of claims 1 to 13, characterized in that the at least one head station for transmitting messages in addition to the low-voltage power supply network is connected to a further communication network (10, 1 1).

15. A method for sending or receiving a message from a head-end station (8) via a low-voltage power supply network (3) with a network node (1) comprising a distribution device (7) for distributing network power to a plurality of supply lines (2.1-2.5). , wherein a high-frequency message signal is generated in the head-end station by modulating a high-frequency carrier signal with the message and the message signal is capacitively coupled into the distributor device, or a message signal transmitted via the low-voltage power supply network is capacitively coupled out of the distributor device and the message in the head-end station Demodulation of the message signal is recovered.

16. The method according to claim 15, characterized in that the distributor device has a current input (17), a distributor (18) and at least one current output (19-23) which comprises at least one current output at least two current conductors and in at least one of the at least two Low-pass filtering is carried out between the conductor and the head-end station, the message signal being generated at a frequency in particular greater than 1 MHz.

17. The method according to claim 15 or 16, characterized in that the distributor device has a current input, a distributor and at least one current output, which comprises at least one current output at least two current conductors and at least one of the at least two current conductors between the distributor and the head station secured against overcurrents becomes.

18. Use of a head-end station (8) for coupling a high-frequency message signal into or out of a low-voltage power supply network (3) by connecting the head-end station to a distribution device (7) which is located in a network node (1) of the low-voltage Power supply network for distributing mains power to a plurality of supply lines (2.1 - 2.5) is used.