WO1995002286A1

WO1995002286A1 - Mains cable transmission system with external time frame determination

Info

Publication number: WO1995002286A1
Application number: PCT/DE1994/000763
Authority: WO
Inventors: Reinhold Schulte
Original assignee: Siemens Aktiengesellschaft
Priority date: 1993-07-05
Filing date: 1994-07-01
Publication date: 1995-01-19
Also published as: DE4322350C1

Abstract

In order to simplify the design of a ripple control transmission installation, a command telegram send from a central (3) to a substation (7) is provided with a set time. The set time is compared in the substation (7) with a real time. When the times match, a release signal is emitted to drive a ripple control emitter (9). The real time is preferably derived from the navigation signal of a GPS signal.

Description

NETWORK LINE TRANSMISSION SYSTEM WITH EXTERNAL TIME FRAME DETERMINATION

The invention relates to a method for operating a ripple control transmitter according to the preamble of claim 1. It also relates to a substation for operating a ripple control transmitter.

The so-called ripple control is often used to control consumers in electrical supply networks. The supply network also serves as an information network for transmitting control commands for ripple control. With the aid of ripple control transmitters, the control commands are overlaid with audio frequency signals of the AC voltage of the supply network and are received again at any point in the supply network with ripple control receivers, decoded and converted into switching operations. The entry points in the supply network can be at high, medium or low voltage levels.

If the ripple control transmitter system is not controlled and monitored exclusively on site with the help of the associated substation, this is usually done with a ripple control command device from a network control center. Such a ripple control command device is connected to any number of ripple control transmission systems by means of information transmission devices, for example alternating current telegraphy devices, telecommunication lines or other messages. If necessary, a data connection can also be provided for communication between the ripple control command device and a computer of the network control center. Control commands can be sent directly from the central computer to the ripple control transmission system via this data connection. Since, on the one hand, the feed points of the respective ripple control transmitter systems can be spatially far apart and, on the other hand, the control commands in various supply networks, with every possible and operational network configuration, should reliably address ripple control receivers distributed in the supply network, they must do so Control commands are introduced as synchronously as possible at the feed points. The control commands are formed in the ripple control transmitter system from the "ripple control bit pattern" and the actual "ripple control frequency" (110 to 1600 Hz). They are therefore also referred to as a "control pulse sequence" and must be superimposed frequency, phase and εendetaktε synchronous to the network frequency, especially in meshed supply networks.

To generate the ripple control frequency, the so-called master frequency was previously transmitted on a separate transmission path (EP 420 270 A2). This master frequency must meet very high requirements with regard to its accuracy so that a phase-accurate feeding of the ripple control signal is possible. In addition, the ripple control transmitters distributed locally in the supply network must also be able to be precisely adjusted with respect to the phase relationship of their transmission signals. Depending on the type and length of the data connection between the ripple control command device and ripple control transmitter system, distortions and delay delays occur which not only have a negative effect on the frequency and phase synchronization, but also on the transmit clock synchronization.

To improve the master frequency it is already known from DE-92 14 314 U1 to use a navigation signal, in particular the GPS signal from satellites, as the time signal. However, this only provides a more precise time stamp. DE-Z: wt 4/90, pp. 59 to 61, P. Fritschi: "GPS NAVSTAR - the navigation system of the future" contains more details on the GPS system. Out EP 0 326 402 A1 discloses the use of the GPS system for time synchronization in the field of energy supply, in particular protection technology.

A ripple control device according to the preamble of claim 1 is known from DE 27 10 698 C3.

A ripple control arrangement is known from DD 237 405 A1, in which a ripple control system transmits a command code as information to ripple control receivers by means of a transmitter via a supply network. If the command code is identical to a code stored in the receivers, the consumers are switched off. The respective code is used to selectively switch off selected consumers. The ripple control system is activated by a network control center.

The invention is based on the object of providing a method and a substation for the improved operation of a ripple control system, wherein an exact adjustment of the phase position of the transmit signals of the individual ripple control transmitters is no longer necessary and wherein there are no distortions and delay times between the ripple control command device and the ripple control system occur.

The first object is achieved with the features of claim 1.

With this method it is possible to dispense with the frequency, phase and transmission clock synchronization of the ripple control command device in the conventional manner. The master frequency transmission from the control center to the ripple control system is no longer necessary. There is no need for additional transmission channels for the master frequency. A control command can be executed precisely in time, regardless of the speed of the transmission way. This is particularly important if, in meshed networks, the ripple control transmitters are widely distributed locally and are intended to transmit at the same time. Differences in transit times or distortions on the transmission paths between the individual ripple control systems no longer have any effects. The synchronization can generally be carried out more precisely than before, in particular if control pulse sequences of the network frequency are superimposed.

Since no ripple control concerns need to be taken into account in the data communication between the network control center and the ripple control transmitter systems in the direction of command and signaling, the computer of the network control center can also take over the tasks of ripple control directly, if necessary in conjunction with the station control technology. A special ripple control command device can be dispensed with. If necessary, appropriate interfaces must be provided for coupling the respective components. The control commands are preferably structured according to the IEC 870-5 protocol (DIN 19244). In this way, standardized time identification of the control command is possible.

It is advantageous if the actual time required in the ripple control system is derived from a navigation signal, in particular the GPS signal, from a satellite transmitter. Further advantageous designs, as well as a substation operating according to the method, are specified in the remaining claims. The invention and further advantages are explained in more detail below in an exemplary embodiment with reference to the drawing.

The figure shows a schematic structure of an arrangement with a ripple control system.

The figure shows an electrical supply network 1 to which a ripple control transmitter system 2 is connected is. The supply network 1 represents a meshed network in which any number of ripple control receivers E are distributed locally. The ripple control transmitter system 2 is controlled by a computer 3 (control center) in a network control center. The computer 3 can be designed as a network control computer or as a ripple control command device. As indicated, several ripple control transmitter systems can be connected to the computer 3, which are coupled to the supply network 1 in a distributed manner. The connection to the computer 3 takes place via appropriate interfaces, for. B. so-called telecontrol heads, which may also be adaptable to different telegram or data structures.

Since the computer 3 and the ripple control transmitter system 2 are usually arranged far apart from one another, a suitable transmission path 5 is provided for the data transmission. This can be designed according to the respective requirements. For this purpose, for example, a telephone line, a TFH connection, a digital path or, as shown, a wire line 12 with assigned transmission devices 13 (eg alternating current telegraph devices) can be provided. Other known types of transmission, e.g. B. can be used via radio or optical fiber. If necessary, the transmission devices should be operable in the direction of command and signal (as indicated by the arrows).

The data communication between the computer 3 and the ripple control transmitter 2 takes place in the command and signal direction, preferably according to the IEC 879-5 protocol (DIN 19244). The telegram structure standardized there allows a precise assignment of a predetermined target time to a corresponding control command or telegram. If necessary, however, other telegram structures can also be used. The ripple control transmitter system 2 comprises a so-called substation 7, the actual ripple control transmitter 9 and a coupling device 10. The coupling device 10 only serves to adapt the output of the transmitter 9 to the electrical data of the supply network 1 is formed, for example, by a telecontrol device or a station control device. This arrangement is only used if a station control device connected to a network control center is present anyway and this is used only as a transmission path for the ripple control transmitter system 2.

The substation 7 receives a time signal, which contains the actual time, via a time signal receiver 15 provided with an antenna 17. The time signal transmitter 15 is preferably designed to receive a navigation signal, in particular the GPS signal, from a satellite transmitter.

In the substation 7, the actual time is now compared with the target time received in information or in a telegram. If the actual time reaches the specified target time (this can be minute, second or millisecond, depending on the specification), a ripple control meter received with the information is sent to the ripple control transmitter 9 with the aid of a release signal, which sends this into the supply network 1 feeds in as a control command for the ripple control receiver E. The sub-station 7 may also have memory devices in order to store control signals received well before the actual time. On this

In this way, control commands can also be sent far before the desired time, so that no time-critical transmission has to take place. If necessary, the transmission of a control command can also take place when the transmission path z. B. for station routing purposes is not required. The substation can also have a further comparison device 21 which, for. B. a voltage signal of the supply network 1 is supplied. In this way, a synchronization of the ripple control signal with a network variable, e.g. B. the frequency or a zero crossing of the voltage possible. Accordingly, it is also conceivable with current values.

Claims

claims

1. A method for controlling a ripple control transmitter (9) which can be connected to a supply network (1), wherein a information transmitted from a control center (4) to a substation (7) of the ripple control transmitter (9) is provided, characterized in that one with the information received target time is compared with an actual time and a signal is generated to control the ripple control transmitter (9) if the time is the same.

2. The method of claim 1, d a d u r c h g e ¬ k e n n z e i c h n e t that the signal serves as a release signal for outputting a bit pattern for controlling the ripple control transmitter (9).

3. The method of claim 2, d a d u r c h g e ¬ k e n n z e i c h n e t that the enable signal is linked or synchronized with a zero crossing of the network frequency of the network voltage or a multiple thereof.

4. Method according to one of claims 2 or 3, ie that the bit pattern is part of the information received.

5. Method according to one of claims 1 to 4, that the actual time and / or a master frequency is derived from a navigation signal from a satellite transmitter.

6. The method of claim 5, d a d u r c h g e ¬ k e n n z e i c h n e t that serves as a navigation signal to indeεt a GPS signal.

7. The method according to Anεpruch 5 or 6, characterized in that the release signal with a zero crossing of the master frequency or a multiple thereof is linked or synchronized.

8. Claim according to one of the claims 1 to 7, that the information is contained in a protocol with a three-layer data structure.

9. substation (7) for a ripple control transmitter system (2) with an information interface and an input time input, a comparator (19) for comparing the actual time with a target time received via the interface contained in a command telegram and provided with the same time an enable signal for driving a ripple control transmitter (9) is generated.

10. The substation according to claim 9, wherein a comparison device (21) is provided which serves to link or synchronize the release signal with a measured variable of the supply network.

11. Substation according to claim 9 or 10, wherein a Zeitzeichenempfang (15) delivers an actual time to the actual time input, which is derived from a received satellite signal.

12. Substation according to claim 11, wherein at least one GPS signal is used as the satellite signal.