Title of Invention	A MEDIUM OR HIGH - VOLTAGE SUBSTATION AND A METHOD OF TRANSMITTING A SIGNAL
Abstract	The communication device for transmitting signals between the substations control unit (4) and the control units (3) of the bay elements (1) comprises transceiving devices (6, 7) connected to the substation and the bay element control units (3), and a wave guide (5) enclosing and connecting antennas (9) of said transceiving devices. The transceiving devices (6, 7) produce electromagnetic radio frequency ain/vaves to communicate information between the control units. The wave guide (5) protects the waves against interference (12).

Title of Invention

A MEDIUM OR HIGH - VOLTAGE SUBSTATION AND A METHOD OF TRANSMITTING A SIGNAL

Abstract

The communication device for transmitting signals between the substations control unit (4) and the control units (3) of the bay elements (1) comprises transceiving devices (6, 7) connected to the substation and the bay element control units (3), and a wave guide (5) enclosing and connecting antennas (9) of said transceiving devices. The transceiving devices (6, 7) produce electromagnetic radio frequency ain/vaves to communicate information between the control units. The wave guide (5) protects the waves against interference (12).

Full Text	Field of the Invention The invention relates to the field of substation automation, control and monitoring. It relates to a communication device for transmitting signals between a control unit of a substation and a control unit of a bay of said substation and it further relates to a method for transmitting a signal between a control unit of a substation and control units of bay elements of said substation. Background of the Invention The main function of an electrical substation is to transfer and transform electrical power. A typical substation comprises a control unit and one or several bays consisting of one or several bay elements. The substation control unit usually comprises a control room from where a person can monitor and control the substation. The bays usually comprise bay elements such as disconnectors, circuit breakers, transfomiers etc. These bay elements are called primary appliances. On a single bay several different or similar primary appliances can be installed. Such primary appliances are connected to a control unit, which regulates, controls and monitors the primary appliances. For controlling and monitoring purposes, the control units of the bay elements have signal network connections between each other and to the substation control unit, via which e,g. signals from the control units and real-time data of the primary appliances are transmitted. Control units also may have communications interfaces to which a service computer can be connected and via which service-relevant status data and measurement data are transmitted. The communications interfaces are used to allow a service computer to be connected to the controller in the event of a fault or during maintenance of the primary appliances. Data stored in the controller can then be read out by means of the service computer in order, for example, to determine the cause of a fault, or in order to analyze a state of the primary appliances. High currents and voltages cause interference and electromagnetic noise in the vicinity of the substation. The low level signal connections between the control units need special attention regarding electromagnetic shielding against said noise. Fiber optics are secure In terms of interference and therefore often used for communication purposes within substation. Besides their resistance against electromagnetic interference fiber optics have the advantage of being electrical nonconductive. There is therefore no direct electric connection between two devices connected by fiber optics. The disadvantage of fiber optic signal connections is their complicated handling and the fact that a party line (bus) is hard to implement with fiber optics only. This means that for every bay of a substation or even for each bay element with its own control unit a dedicated fiber is needed, leading to an immense bay wiring effort. Wireless Local Area Networks (WLAN) as e.g. described by the IEEE 802.11 standard use e.g. electromagnetic radio frequency waves, to communicate Information from one point to another without relying on any physical connection. Radio frequency waves are often referred to as radio carriers because they simply perform the function of delivering energy to a remote receiver. The date being transmitted is superimposed on the radio carrier so that it can be accurately extracted at the receiving end. This is generally referred to as modulation of the carrier by the infomiatlon being transmitted. Once data Is modulated onto the radio carrier, the radk) signal occupies more than a single frequency, since the frequency or bit rate of the modulating information adds to the carrier. In a typical WLAN configuration, a transmitter/ receiver (transceiver) device, called an access point, connects to a server or a wired network. At a minimum the access point receives, buffers, and transmits data between the WLAN and the server or the wired network infrastructure. Other components access the WLAN through WLAN-adapters. These adapters provide an interface between the components operating system and the ainvaves via an antenna. Signal connections and networks via radio frequency system give a maximum of flexibility and reduce the costs for wiring. State of the art radio frequency systems like I Bluetooth, Wireless LAN or DECT allow short-range, point-to-multlpoint data transfer. Their nominal link ranges are from 10 cm to 10 meters, but can be extended to 100 meters by increasing the transmit power. But common radio frequency systems still have a rather low reliability caused by general-purpose interference. Manufactures of such systems try to increase the system availability and reliability by using intelligent modulation and coding systems (e.g. FHSS (Frequency Hopping Spread Spectrum) or DSSS (Direct Sequence Spread Spectnjm)). Nevertheless, transmission of critical signals in the presence of severe interference, as It can appear in a substation, via radio frequency systems Is still not generally accepted. Summary of the Invention One object of the invention is therefore to provide a communication device for transmitting signals between control units of a substation and a method for transmitting a signal between control units of a substation, which avoid the disadvantages mentioned above. This object is achieved by a communication device, together with a method having the features of patent claims 1 and 8, respectively. in one embodiment, the present invention Is a communication device comprising a first transceiver with an antenna for sending/ receiving radio frequency signals connected to the substation control unit, second transceivers v/ith antennas for sending/ receiving radio frequency waves connected to the bay element control units and a wave guide for transmitting said radio frequency waves enclosing the antennas of said first and second transceivers. The wave guide shields said radio frequency waves from interference in the vicinity of the substation, and also shields, or at least attenuates, the environment from electromagnetic emissions caused by the sender. This allows to even increase transmission power beyond levels that are normally used for non guided applications, or to use frequencies out of normal bands and therefore an increased bandwith can be used. Since several bays or bay elements are usually physically side by side their control units can easily be connected by one wave guide enclosing the several antennas. With very little effort a wireless party line (bus) can be realised. Also, additional bays or bay elements can be added to the party line by simply extending the wave guide. No extra wiring is needed. The wave guide can be an integral part of a bay or of a bay element, so the party line can be extended, by just placing the bay or the bay element in the right place. Best shielding against interferece is achieved with a tubular wave guide with a rectangular profile. On one side of the rectangular profile the wave guide has an opening through which the antennas are stuck into the interior of the wave guide. On both sides of the opening radiation protections are designed to improve shielding and reduce radiation. The radiation protections are preferably longer than the lengths of the opening in order to minimise radiation. in another embodiment, the present invention is a method to transmit the signals between the control unit of the substation and the control units of a bay or of a bay element. Said signal is first frequency modulated in the first transceiving device, is sent into the wave guide as a radio frequency wave, and is then received by the second transceiving device, in which the control signal is converted back Into an electrical signal, which is then finally processed by said bay control unit. Brief description of the Drawing Details and advantages of the present invention will become more fully apparent from the following description, the claims and the accompanying drawing in which Fig. 1 shows a part of a substation with switchgear bay elements and a communication device with transceiver devices according to the invention, and Figs. 2 a/ b show an enlarged view of two transceiver devices according to Fig. 1. Description of preferred embodiments Fig. 1 shows a possible embodiment of a part of a substation with three bay elements 1 that are located on a bay and a substation control unit 4. The switchgear devices 2 are connected to the three phases of a primary transmission line 10 and a secondary transmission line 11. Instead of switchgear devices, other so called primary appliances like transformers could be installed on the bays. The primary appliances need not to be the same on all the bays and the number of bays or bay elements Is In no way limited to three or less. Each of the bay elements 1 has a control unit 3 to control and monitor the primary appliances. The bay element control units usually comprise a processor unit, a memory for storage of monitoring data and some kind of an Interface, e.g. for mamter)ance purposes, and/or a protection relay. The substation control unit 4 comprises a computer-based server (and/or protection relay), which is network connected to the bay element control units 3 in order to exchange data and control signals. Connected to the server of the substation control unit as shown in Fig, 2 b is a transceiving device 7, which serves as the access point of a wireless network. Attached to the access point is an antenna 9 for sending electromagnetic radio waves with superimposed data signals. The bay element control unit 3 is connected to an other transceiving device 6 with an antenna 9 as shown in Fig, 2 a for sending and receiving control and real-time monitoring data signals. This transceiving device 6 is a wireless network adapter that sen/es as an interface between the airwaves and the bay element control units processor unit- In order to shield the transmitted signals against interference 12 a wave guide 5 is connecting the antennas 9 of the transceiving devices 6 and 7. The wave guide has basically a tubular shape with a rectangular profile. On one side the wave guide 5 has an opening through which the antennas of the transceiving devices 6 and 7 are stuck into. On both skies of the opening radiation protections are arranged. The length t of the radiation protections Is longer than the length s of the opening in order to keep the radiation on a negligible low level. The wave guide 5 is mounted onto the control units with holders 8 as shown In Figs. 2 a and 2 b. In most cases the wave guide connects bay element control units that are physically side by side. Even if the control units are not 100 per cent in line or there is some displacement between the dedicated devices it is possible to communicate in a reliable way. The wave guide needs to have no complicated design and is very easy to install. Any electromagnetic shielding material can be chosen for the wave guide, e.g. aluminum or copper. Reliable wave guides for a broad band of frequencies can be designed. Typical values of such a wave guide are width a of wave guide = 0.1 m height b of wave guide = 0.05 m length s of opening = 0.03 m Frequency = 2-3 GHz Attenuation = 14 dB/km Coupling Attenuation = 4-6 dB Material = Aluminum Profile The wave gukie 5 not only keeps interference out but it also makes sure the radio wave does not or only to a very limited extend propagate outside the wave guide. Therefore basically all frequencies that physically make sense can be used for this kind of communication, particularly others than the very narrow unlicensed 2.4 GHz frequency band which Is used for state of the art WLAN systems. By using two or more different frequencies very high data rates can be achieved without having to somehow split a frequency in one way or another. One possible setup could e.g. comprise transmission of real time data at 2 GHz, synchronisation impulses at 2.5 GHz and the nomial monitoring data at 2.4 GHz. By using more than just one frequency at the same time a very good real time synchronization is achieved along with a high redundancy. The communication device according to the invention is simple to extend to additional bays or bay elements without any inter bay wiring. Thanks to the state of the art wireless network protocols high bandwidth communication party lines (buses) can easily be implemented. Any state of the art or upcoming commercial wireless standard technology can be used in the communication device according to this Invention. While in Highvoltage-Substations communication between bay element control units of different elements of a bay (intra-bay) is necessary, in Middlevoltage-Substation this communication can be reduced to bay-to-bay (inter-bay) communication between bay control units and the substation control unit. List of Reference Signs 1 Switchgear bay element 2 Switchgear 3 bay element control unit 4 substation control unit 5 wave guide 6 transceiver, WLAN-adapter 7 transceiver, WLAN access point 8 mounting device, holder 9 antenna 10,11 power lines 12 electromagnetic noise, interference a, b, s, t Dimensions WE CLAIM : 1 A medium- or high-voltage Substation, comprising: at least one bay element (1) with at least one primary appliance (2) and a bay element control unit (3), a substation control unit (4), and a communication device, said communication device comprising a first transceiving device (7) connected to the substation control unit (4), a second transceiving device (6) connected to the bay element control unit (3), and signal transmission means (5) connecting said first and second transceiving devices, characterized in, that said first (7) and said second (6) transceiving devices are radio frequency modulating/demodulating devices for modulating an electrical signal onto demodulating an electrical signal from a radio frequency wave, said first (7) and said second (6) transceiving devices comprise antennas (9) for transmitting and/or receiving radio frequency waves, said signal transmission means comprise a waveguide (5) device for transmitting said radio frequency waves, and said waveguide device (5) encloses said antennas (9) of said first and second transceiving devices (7, 6) such that the waveguide (5) shields said radio frequency waves from interference in the vicinity of the substation and also shields or attenuates the electromagnetic emissions caused by the transceiving devices (116) in the environment of the substation. 2. The substation as claimed in claim 1 wherein said waveguide (5) has a basically tubular shape with a rectangular profile has two first opposite sides and two second opposite sides, and on one of said first opposite sides of the rectangular profile the waveguide (5) has an opening through which the antennas (9) are stuck into the interior of the waveguide (15) 3. The substation as claimed in Claim 2, wherein on both sides of the opening protruding radiation protections are designed to improve shielding and reduce radiation said radiation protections being parallel to said two second opposite sides 4. The substation as claimed in Claim 3, wherein the length (t) of said radiation protections is longer than the length of said opening, 5. The substation as claimed in any of the preceding claims wherein the waveguide (5) has a width of 0.1m, a height of 0.05 m, an opening width of 0.03 m and is made of Aluminum and a frequency between 2 GHz and 3 GHz is used. 6. The Substation as claimed in any of the preceding claims, wherein, said at least one bay element (1) and said substation control unit (4) are arranged physically side by side, and the antennas (9) of said first and second transceiving devices (7, 6) are in line in order to realize a wireless bus. 7. The substation as claimed in Claim 6, wherein the waveguide (5) is an integral part of a bay or of a bay element (1) such that the bus can be extended by just placing the bay or the bay element (1) in the right place. 8. The substation as claimed in any of the preceding Claims wherein the waveguide (5) is mounted onto the control units (3, 4) with holders (8). 9. The substation as claimed in any of the preceding Claims, wherein said waveguide (5) is made of electromagnetic shielding material, in particular of aluminum or copper. 10. The substation as claimed in any of the preceding Claims, wherein the bay element control unit (3) comprises a processor unit, a memory for storage of monitoring data and an interface, in particular for maintenance, or a protection relay and the substation control unit (4) comprises a computer-based server or protection relay, which is network-connected to the bay element control units (3) in order to exchange data and control signals. 11. The substation as claimed in any of the preceding Claims, wherein the first transceiving device (7) is connected to the server of the substation control unit (4) and serves as the access point of the wireless network, and attached to the access point is an antenna (9) for sending electromagnetic radio waves with superimposed data signals, and the bay element control unit (3) is connected to the second transceiving device (6) with an antenna (9) for sending and receiving control and real-time monitoring data signals, this second transceiving device (6) being a wireless network adapter that serves as an interface between the airwaves and the processor unit of the bay element control unit (3). 12. The substation as claimed in the preceding claims, wherein it comprises at least two bay elements (1), each with at least one primary appliance (2) and a bay element control unit (3), and a communication device comprising a first transceiving device (7) connected to the control unit (3) of a first of the bay elements, a second transceiving device (6) connected to the control unit (3) of a second of the bay elements, and signal transmission means (5) connecting said first and second transceiving devices (7, 6) wherein said first (7) and said second (6) transceiving devices are radio frequency modulating/demodulating devices for modulating an electrical signal onto/demodulating an electrical signal from a radio frequency wave, said first (7) and said second (6) transceiving devices comprise antennas (9) for transmitting or receiving radio frequency waves, and said signal transmission means comprise a waveguide (5) device for transmitting said radio frequency waves, and said waveguide device (5) encloses said antennas (9) of said first and second transceiving devices (7, 6) such that the waveguide (5) shields said radio frequency waves from interference in the vicinity of the substation and also shields or attenuates the electromagnetic emissions caused by the transceiving devices (7. 6) in the environment of the substation. 13. The substation as claimed in Claim 12 wherein said at least two bay elements (1) are arranged physically side by side, and the antennas (9) of said first and second transceiving devices (7, 6) are in line in order to realize a wireless bus. 14. The substation as claimed in any of Claims 12, 13 wherein at least three control units are connected to the waveguide, and said control units are connected to a wireless party line. 15. A method for transmitting a signal between a first and a second control unit (3, 4), said control units being the control unit of a substation (4) or the control units (3) of bay elements (1) of the substation, by using a communication device having signal transmission means (5) that comprise a waveguide (5) device for transmitting radio frequency waves, and said waveguide device (5) encloses antennas (9) of first and second transceiving devices (7, 6) such that the waveguide shields said radio frequency waves from interference in the vicinity of the substation and also shields or attenuates the electromagnetic emissions caused by the transceiving devices (7,6) in the environment of the substation wherein said electrical signal is modulated in a first transceiving device (7. 6) which is connected to a first control unit (3, 4) of bay elements (1) of the substation said signal is then sent into the waveguide (5) as a modulated electromagnetic wave by the antenna (9) of said first transceiving device (7, 6), said modulated electromagnetic wave is then received by the antenna (9) of the second transceiving device (7, 6) which is connected to a second control unit (4,3) of bay elements (1) of the substation, said electromagnetic wave is then converted back into an electrical signal, and said converted electrical signal is then processed by the second control unit. 16. The method as claimed in Claim 15, wherein the transmission power between the transceiving devices (7, 6) is increased beyond the levels that are normally used for non-guided applications, or radio frequencies out of normal bands are used. 17. The method as claimed in any of the Claims 15, 16, wherein two or more different frequencies are used in order to achieve very high data rates and in particular that transmission of real time data is Performed at 2 GHz. synchronization impulses are transmitted at 2.5 GHz and monitoring data are transmitted at 2.4 GHz. 18. A method for setting up a medium- or high-voltage Substation with a substation control unit (4) and a first transceiving device (7) connected to the substation control unit (4), and at least one bay element (1) with at least one primary appliance (2), a bay element control unit (3) and a second transceiving device (6) connected to the bay element control unit (3), wherein said transceiving devices (6, 7) are radio frequency modulating/demodulating devices for modulating an electrical signal onto/demodulating an electrical signal from a radio frequency wave comprising antennas (9) for transmitting or receiving radio frequency waves; and signal transmission means comprising a waveguide (5) connecting said first and second transceiving devices, said method comprising the steps of placing said bay elements and said substation control unit (4) side by side, connecting said control units (3, 4) by enclosing said antennas (9) with said waveguide (5) such that the waveguide (5) shields said radio frequency waves from interference in the vicinity of the substation and also shields or attenuates the electromagnetic emissions caused by the transceiving devices (7, 6) in the environment of the substation.

Full Text

Field of the Invention
The invention relates to the field of substation automation, control and monitoring. It relates to a communication device for transmitting signals between a control unit of a substation and a control unit of a bay of said substation and it further relates to a method for transmitting a signal between a control unit of a substation and control units of bay elements of said substation.
Background of the Invention
The main function of an electrical substation is to transfer and transform electrical power. A typical substation comprises a control unit and one or several bays consisting of one or several bay elements.
The substation control unit usually comprises a control room from where a person can monitor and control the substation.
The bays usually comprise bay elements such as disconnectors, circuit breakers, transfomiers etc. These bay elements are called primary appliances. On a single bay several different or similar primary appliances can be installed. Such primary appliances are connected to a control unit, which regulates, controls and monitors the primary appliances.
For controlling and monitoring purposes, the control units of the bay elements have signal network connections between each other and to the substation control unit, via which e,g. signals from the control units and real-time data of the primary appliances are transmitted. Control units also may have communications interfaces to which a service computer can be connected and via which service-relevant status data and measurement data are transmitted. The communications interfaces are used to allow a service computer to be connected to the controller in the event of a fault or during maintenance of the primary appliances. Data stored in the controller can then be read

out by means of the service computer in order, for example, to determine the cause of a fault, or in order to analyze a state of the primary appliances.
High currents and voltages cause interference and electromagnetic noise in the vicinity of the substation. The low level signal connections between the control units need special attention regarding electromagnetic shielding against said noise.
Fiber optics are secure In terms of interference and therefore often used for communication purposes within substation. Besides their resistance against electromagnetic interference fiber optics have the advantage of being electrical nonconductive. There is therefore no direct electric connection between two devices connected by fiber optics. The disadvantage of fiber optic signal connections is their complicated handling and the fact that a party line (bus) is hard to implement with fiber optics only. This means that for every bay of a substation or even for each bay element with its own control unit a dedicated fiber is needed, leading to an immense bay wiring effort.
Wireless Local Area Networks (WLAN) as e.g. described by the IEEE 802.11 standard use e.g. electromagnetic radio frequency waves, to communicate Information from one point to another without relying on any physical connection. Radio frequency waves are often referred to as radio carriers because they simply perform the function of delivering energy to a remote receiver. The date being transmitted is superimposed on the radio carrier so that it can be accurately extracted at the receiving end. This is generally referred to as modulation of the carrier by the infomiatlon being transmitted. Once data Is modulated onto the radio carrier, the radk) signal occupies more than a single frequency, since the frequency or bit rate of the modulating information adds to the carrier.
In a typical WLAN configuration, a transmitter/ receiver (transceiver) device, called an access point, connects to a server or a wired network. At a minimum the access point receives, buffers, and transmits data between the WLAN and the server or the wired network infrastructure. Other components access the WLAN through WLAN-adapters. These adapters provide an interface between the components operating system and the ainvaves via an antenna.
Signal connections and networks via radio frequency system give a maximum of flexibility and reduce the costs for wiring. State of the art radio frequency systems like

I
Bluetooth, Wireless LAN or DECT allow short-range, point-to-multlpoint data transfer. Their nominal link ranges are from 10 cm to 10 meters, but can be extended to 100 meters by increasing the transmit power.
But common radio frequency systems still have a rather low reliability caused by general-purpose interference. Manufactures of such systems try to increase the system availability and reliability by using intelligent modulation and coding systems (e.g. FHSS (Frequency Hopping Spread Spectrum) or DSSS (Direct Sequence Spread Spectnjm)).
Nevertheless, transmission of critical signals in the presence of severe interference, as It can appear in a substation, via radio frequency systems Is still not generally accepted.
Summary of the Invention
One object of the invention is therefore to provide a communication device for transmitting signals between control units of a substation and a method for transmitting a signal between control units of a substation, which avoid the disadvantages mentioned above.
This object is achieved by a communication device, together with a method having the features of patent claims 1 and 8, respectively.
in one embodiment, the present invention Is a communication device comprising a first transceiver with an antenna for sending/ receiving radio frequency signals connected to the substation control unit, second transceivers v/ith antennas for sending/ receiving radio frequency waves connected to the bay element control units and a wave guide for transmitting said radio frequency waves enclosing the antennas of said first and second transceivers. The wave guide shields said radio frequency waves from interference in the vicinity of the substation, and also shields, or at least attenuates, the environment from electromagnetic emissions caused by the sender. This allows to even increase transmission power beyond levels that are normally used for non guided applications, or to use frequencies out of normal bands and therefore an increased bandwith can be used.
Since several bays or bay elements are usually physically side by side their control units can easily be connected by one wave guide enclosing the several antennas. With very little effort a wireless party line (bus) can be realised. Also, additional bays or bay elements can be added to the party line by simply extending the wave guide. No extra

wiring is needed. The wave guide can be an integral part of a bay or of a bay element, so the party line can be extended, by just placing the bay or the bay element in the right place.
Best shielding against interferece is achieved with a tubular wave guide with a rectangular profile. On one side of the rectangular profile the wave guide has an opening through which the antennas are stuck into the interior of the wave guide. On both sides of the opening radiation protections are designed to improve shielding and reduce radiation. The radiation protections are preferably longer than the lengths of the opening in order to minimise radiation.
in another embodiment, the present invention is a method to transmit the signals between the control unit of the substation and the control units of a bay or of a bay element. Said signal is first frequency modulated in the first transceiving device, is sent into the wave guide as a radio frequency wave, and is then received by the second transceiving device, in which the control signal is converted back Into an electrical signal, which is then finally processed by said bay control unit.
Brief description of the Drawing
Details and advantages of the present invention will become more fully apparent from the following description, the claims and the accompanying drawing in which
Fig. 1 shows a part of a substation with switchgear bay elements and a
communication device with transceiver devices according to the invention, and
Figs. 2 a/ b show an enlarged view of two transceiver devices according to Fig. 1.
Description of preferred embodiments
Fig. 1 shows a possible embodiment of a part of a substation with three bay elements 1 that are located on a bay and a substation control unit 4. The switchgear devices 2 are connected to the three phases of a primary transmission line 10 and a secondary transmission line 11. Instead of switchgear devices, other so called primary appliances like transformers could be installed on the bays. The primary appliances need not to be the same on all the bays and the number of bays or bay elements Is In no way limited to three or less.

Each of the bay elements 1 has a control unit 3 to control and monitor the primary appliances. The bay element control units usually comprise a processor unit, a memory for storage of monitoring data and some kind of an Interface, e.g. for mamter)ance purposes, and/or a protection relay.
The substation control unit 4 comprises a computer-based server (and/or protection relay), which is network connected to the bay element control units 3 in order to exchange data and control signals. Connected to the server of the substation control unit as shown in Fig, 2 b is a transceiving device 7, which serves as the access point of a wireless network. Attached to the access point is an antenna 9 for sending electromagnetic radio waves with superimposed data signals.
The bay element control unit 3 is connected to an other transceiving device 6 with an antenna 9 as shown in Fig, 2 a for sending and receiving control and real-time monitoring data signals. This transceiving device 6 is a wireless network adapter that sen/es as an interface between the airwaves and the bay element control units processor unit-
In order to shield the transmitted signals against interference 12 a wave guide 5 is connecting the antennas 9 of the transceiving devices 6 and 7. The wave guide has basically a tubular shape with a rectangular profile. On one side the wave guide 5 has an opening through which the antennas of the transceiving devices 6 and 7 are stuck into. On both skies of the opening radiation protections are arranged. The length t of the radiation protections Is longer than the length s of the opening in order to keep the radiation on a negligible low level.
The wave guide 5 is mounted onto the control units with holders 8 as shown In Figs. 2 a and 2 b.
In most cases the wave guide connects bay element control units that are physically side by side. Even if the control units are not 100 per cent in line or there is some displacement between the dedicated devices it is possible to communicate in a reliable way. The wave guide needs to have no complicated design and is very easy to install.
Any electromagnetic shielding material can be chosen for the wave guide, e.g. aluminum or copper.
Reliable wave guides for a broad band of frequencies can be designed.

Typical values of such a wave guide are
width a of wave guide = 0.1 m
height b of wave guide = 0.05 m
length s of opening = 0.03 m
Frequency = 2-3 GHz
Attenuation = 14 dB/km
Coupling Attenuation = 4-6 dB
Material = Aluminum Profile
The wave gukie 5 not only keeps interference out but it also makes sure the radio wave does not or only to a very limited extend propagate outside the wave guide. Therefore basically all frequencies that physically make sense can be used for this kind of communication, particularly others than the very narrow unlicensed 2.4 GHz frequency band which Is used for state of the art WLAN systems. By using two or more different frequencies very high data rates can be achieved without having to somehow split a frequency in one way or another.
One possible setup could e.g. comprise transmission of real time data at 2 GHz, synchronisation impulses at 2.5 GHz and the nomial monitoring data at 2.4 GHz.
By using more than just one frequency at the same time a very good real time synchronization is achieved along with a high redundancy.
The communication device according to the invention is simple to extend to additional bays or bay elements without any inter bay wiring.
Thanks to the state of the art wireless network protocols high bandwidth communication party lines (buses) can easily be implemented.
Any state of the art or upcoming commercial wireless standard technology can be used in the communication device according to this Invention.
While in Highvoltage-Substations communication between bay element control units of different elements of a bay (intra-bay) is necessary, in Middlevoltage-Substation this communication can be reduced to bay-to-bay (inter-bay) communication between bay control units and the substation control unit.

List of Reference Signs
1 Switchgear bay element
2 Switchgear
3 bay element control unit
4 substation control unit
5 wave guide
6 transceiver, WLAN-adapter
7 transceiver, WLAN access point
8 mounting device, holder
9 antenna
10,11 power lines
12 electromagnetic noise, interference
a, b, s, t Dimensions

WE CLAIM :
1 A medium- or high-voltage Substation, comprising:
at least one bay element (1) with at least one primary appliance (2) and a bay element control unit (3),
a substation control unit (4), and
a communication device, said communication device comprising
a first transceiving device (7) connected to the substation control unit
(4),
a second transceiving device (6) connected to the bay element control unit (3), and
signal transmission means (5) connecting said first and second transceiving devices,
characterized in, that
said first (7) and said second (6) transceiving devices are radio frequency modulating/demodulating devices for modulating an electrical signal onto demodulating an electrical signal from a radio frequency wave,
said first (7) and said second (6) transceiving devices comprise antennas (9) for transmitting and/or receiving radio frequency waves,
said signal transmission means comprise a waveguide (5) device for transmitting said radio frequency waves, and
said waveguide device (5) encloses said antennas (9) of said first and second transceiving devices (7, 6) such that the waveguide (5) shields said radio frequency waves from interference in the vicinity of the substation and also shields or

attenuates the electromagnetic emissions caused by the transceiving devices (116) in the environment of the substation.
2. The substation as claimed in claim 1 wherein
said waveguide (5) has a basically tubular shape with a rectangular profile has two first opposite sides and two second opposite sides, and
on one of said first opposite sides of the rectangular profile the waveguide (5) has an opening through which the antennas (9) are stuck into the interior of the waveguide (15)
3. The substation as claimed in Claim 2, wherein
on both sides of the opening protruding radiation protections are designed to improve shielding and reduce radiation
said radiation protections being parallel to said two second opposite sides
4. The substation as claimed in Claim 3, wherein
the length (t) of said radiation protections is longer than the length of said opening,
5. The substation as claimed in any of the preceding claims wherein
the waveguide (5) has a width of 0.1m, a height of 0.05 m, an opening width of 0.03 m and is made of Aluminum and
a frequency between 2 GHz and 3 GHz is used.

6. The Substation as claimed in any of the preceding claims, wherein,
said at least one bay element (1) and said substation control unit (4) are arranged physically side by side, and
the antennas (9) of said first and second transceiving devices (7, 6) are in line in order to realize a wireless bus.
7. The substation as claimed in Claim 6, wherein
the waveguide (5) is an integral part of a bay or of a bay element (1) such that the bus can be extended by just placing the bay or the bay element (1) in the right place.
8. The substation as claimed in any of the preceding Claims wherein
the waveguide (5) is mounted onto the control units (3, 4) with holders (8).
9. The substation as claimed in any of the preceding Claims, wherein
said waveguide (5) is made of electromagnetic shielding material, in particular of aluminum or copper.
10. The substation as claimed in any of the preceding Claims, wherein
the bay element control unit (3) comprises a processor unit, a memory for storage of monitoring data and an interface, in particular for maintenance, or a protection relay and
the substation control unit (4) comprises a computer-based server or protection relay, which is network-connected to the bay element control units (3) in order to exchange data and control signals.

11. The substation as claimed in any of the preceding Claims, wherein
the first transceiving device (7) is connected to the server of the substation control unit (4) and serves as the access point of the wireless network, and attached to the access point is an antenna (9) for sending electromagnetic radio waves with superimposed data signals, and
the bay element control unit (3) is connected to the second transceiving device (6) with an antenna (9) for sending and receiving control and real-time monitoring data signals, this second transceiving device (6) being a wireless network adapter that serves as an interface between the airwaves and the processor unit of the bay element control unit (3).
12. The substation as claimed in the preceding claims, wherein it comprises
at least two bay elements (1), each with at least one primary appliance (2) and a bay element control unit (3), and
a communication device comprising a first transceiving device (7) connected to the control unit (3) of a first of the bay elements, a second transceiving device (6) connected to the control unit (3) of a second of the bay elements, and signal transmission means (5) connecting said first and second transceiving devices (7, 6) wherein
said first (7) and said second (6) transceiving devices are radio frequency modulating/demodulating devices for modulating an electrical signal onto/demodulating an electrical signal from a radio frequency wave,
said first (7) and said second (6) transceiving devices comprise antennas (9) for transmitting or receiving radio frequency waves, and

said signal transmission means comprise a waveguide (5) device for transmitting said radio frequency waves, and said waveguide device (5) encloses said antennas (9) of said first and second transceiving devices (7, 6) such that the waveguide (5) shields said radio frequency waves from interference in the vicinity of the substation and also shields or attenuates the electromagnetic emissions caused by the transceiving devices (7. 6) in the environment of the substation.
13. The substation as claimed in Claim 12 wherein
said at least two bay elements (1) are arranged physically side by side, and the antennas (9) of said first and second transceiving devices (7, 6) are in line in order to realize a wireless bus.
14. The substation as claimed in any of Claims 12, 13 wherein
at least three control units are connected to the waveguide, and said control units are connected to a wireless party line.
15. A method for transmitting a signal between a first and a second control unit (3,
4), said control units being the control unit of a substation (4) or the control units (3)
of bay elements (1) of the substation, by using a communication device having signal
transmission means (5) that comprise a waveguide (5) device for transmitting radio
frequency waves, and said waveguide device (5) encloses antennas (9) of first and
second transceiving devices (7, 6) such that the waveguide shields said radio
frequency waves from interference in the vicinity of the substation and also shields or
attenuates the electromagnetic emissions caused by the transceiving devices (7,6) in
the environment of the substation wherein

said electrical signal is modulated in a first transceiving device (7. 6) which is connected to a first control unit (3, 4) of bay elements (1) of the substation
said signal is then sent into the waveguide (5) as a modulated electromagnetic wave by the antenna (9) of said first transceiving device (7, 6),
said modulated electromagnetic wave is then received by the antenna (9) of the second transceiving device (7, 6) which is connected to a second control unit (4,3) of bay elements (1) of the substation,
said electromagnetic wave is then converted back into an electrical signal, and said converted electrical signal is then processed by the second control unit.
16. The method as claimed in Claim 15, wherein
the transmission power between the transceiving devices (7, 6) is increased beyond the levels that are normally used for non-guided applications, or radio frequencies out of normal bands are used.
17. The method as claimed in any of the Claims 15, 16, wherein
two or more different frequencies are used in order to achieve very high data rates and
in particular that transmission of real time data is Performed at 2 GHz. synchronization impulses are transmitted at 2.5 GHz and monitoring data are transmitted at 2.4 GHz.
18. A method for setting up a medium- or high-voltage Substation with
a substation control unit (4) and a first transceiving device (7) connected

to the substation control unit (4), and at least one bay element (1) with at least one primary appliance (2), a bay element control unit (3) and a second transceiving device (6) connected to the bay element control unit (3), wherein said transceiving devices (6, 7) are radio frequency modulating/demodulating devices for modulating an electrical signal onto/demodulating an electrical signal from a radio frequency wave comprising antennas (9) for transmitting or receiving radio frequency waves; and
signal transmission means comprising a waveguide (5) connecting said first and second transceiving devices, said method comprising the steps of
placing said bay elements and said substation control unit (4) side by side,
connecting said control units (3, 4) by enclosing said antennas (9) with said waveguide (5) such that the waveguide (5) shields said radio frequency waves from interference in the vicinity of the substation and also shields or attenuates the electromagnetic emissions caused by the transceiving devices (7, 6) in the environment of the substation.

Documents:

1385-chenp-2003-abstract.pdf

1385-chenp-2003-claims.pdf

1385-chenp-2003-correspondnece-others.pdf

1385-chenp-2003-correspondnece-po.pdf

1385-chenp-2003-description(complete).pdf

1385-chenp-2003-drawings.pdf

1385-chenp-2003-form 1.pdf

1385-chenp-2003-form 18.pdf

1385-chenp-2003-form 26.pdf

1385-chenp-2003-form 3.pdf

1385-chenp-2003-form 5.pdf

1385-chenp-2003-pct.pdf

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Patent Number

223655

Indian Patent Application Number

1385/CHENP/2003

PG Journal Number

47/2008

Publication Date

21-Nov-2008

Grant Date

19-Sep-2008

Date of Filing

02-Sep-2003

Name of Patentee

ABB RESEARCH LTD

Applicant Address

AFFOLTERNSTRASSE 52, CH-8050 ZURICH

Inventors:

#	Inventor's Name	Inventor's Address
1	LEHMANN, JOSEF	BLOIS STRASSE 62, 79761 WALDSHUT-TIENGEN
2	SABBATTINI, BRUNO	ZENTRALSTRASSE 98, CH-5430 WETTINGEN,
3	DECK, BERNHARD	SCHEUERACKER 5, 79809 WEILHEIM,
4	RUDOLF, PAUL	JOSEBODENWEG 13A, CH-5234 VILLIGEN,

PCT International Classification Number

H04B3/52

PCT International Application Number

PCT/CH02/00137

PCT International Filing date

2002-03-06

PCT Conventions:

#	PCT Application Number	Date of Convention	Priority Country
1	01810233.5	2001-03-07	EUROPEAN UNION