WO2008019635A1

WO2008019635A1 - Method and system for monitoring a power supply network

Info

Publication number: WO2008019635A1
Application number: PCT/DE2006/001447
Authority: WO
Inventors: Rainer Krebs; Siegfrid Lemmer; Dietmar Retzmann; Michael Weinhold
Original assignee: Siemens Aktiengesellschaft
Priority date: 2006-08-15
Filing date: 2006-08-15
Publication date: 2008-02-21
Also published as: DE112006004070A5

Abstract

The invention relates to a method for monitoring a power supply network, in which at least one possible state of the power supply network is simulated based on a structure (140) of the power supply network and at least one predefined parameter (120) of the power supply network. By determining a measure of similarity (130) between the actual (100) and the predefined network parameter (120, 121), a warning message (16) for a possible critical network state can be issued based on the degree of deviation between said network parameters if the predefined network parameter is linked to a critical network state. This applies in case there is a great measure of similarity (130) between the predefined and the actual network parameter. Control-based systems, especially expert systems, make it possible to determine a respective measure of similarity and present a possible option for action to overcome a detected critical network state to the operator in order to monitor the power supply network.

Description

description

Method and system for monitoring a power supply network

The invention relates to a method for monitoring an energy supply network, wherein at least one possible network state of the energy supply network is simulated on the basis of a network structure of the energy supply network and at least one predeterminable network parameter of the energy supply network. Furthermore, the invention relates to a system for monitoring a power supply network and a corresponding data processing program.

Energy supply networks, in particular electrical high-voltage networks, are highly complex networks that can only be monitored and controlled by means of a high outlay. In addition, the liberalization of energy markets and the decentralization of production units, such as additional wind farms in an energy supply network, to the fact that the load and the stability of the energy supply network can vary considerably in terms of space and time. This requires an increased effort in terms of monitoring and regulating the load flows within a power supply network in order to avoid overuse up to total failure of the network system.

Conventionally, the state of a power supply network based on measurement data of certain parameters of the power grid, such as the current, the voltage and / or the phase angle between the current and the voltage, over a certain period of time and measured, usually 30 seconds. Subsequently, the averaged measurement data are sent to a control room. In the control room With the help of his many years of experience, an operator evaluates and interprets these measured data, most of which are visualized as alphanumeric values or as graphs, and uses these data bases to make any necessary changes to the network configuration.

Thus, as an example of the prior art, EP 1 408 595 A1 describes a method for determining parameters of an equivalent circuit diagram of the transition section of an electrical network. According to the invention there, a possible voltage instability is analyzed by means of the measurement of voltages and currents within the network. Based on a mathematical formula, a so-called instability parameter is generated using the measured voltages and currents within the network. The instability parameter determined in this way then allows conclusions to be drawn regarding the stability of the energy supply network in accordance with the invention there. The same is disclosed in EP 1 217 709 as a method and apparatus for evaluating the stability of an energy transmission system.

A parameter estimation for a power grid is also disclosed in US Pat. No. 1,381,132 A1. As part of the process there, a large number of measured data is measured at different points in the energy supply network. By means of a mathematical model, the dependence of the load on the current frequency within the power grid and the dependence of the voltage on the current frequency is determined.

A disadvantage of all known in the prior art monitoring method of a power supply network that the network stability is determined on the basis of selected network parameters and the operator of the power grid Although a large amount of additional information is displayed on the basis of the network state determined in this way, this information continues to be used mainly as a basis for the decision based on the personal experience of the operator for possible changes in the network parameters. The handling of the operator with this information displayed is thus subjectively subject to the respective operator and possibly of its daily form, which may be detrimental to the simultaneous increase in the complexity of Netzkon- configuration due to the increased network requirements.

The object of the present invention is therefore to provide a method for monitoring a power supply network, which sustainably supports the operator in his or her decision-making when monitoring the power supply network. The object is achieved by the features of patent claims 1 and 20. According to the invention, at least one current network parameter is compared with the predeterminable network parameter taking into account the network structure and a similarity measure is generated as degree of deviation between the predefinable network parameter and the current network parameter, upon detection of a possible critical network condition, a warning message is output taking into account the similarity measure.

Network parameter in the sense of the present invention is any physical variable possible for direct or indirect characterization of the network state. In particular, in the case of an electrical energy supply system, these are directly basic variables, such as current and voltage, or the physical variables derived therefrom indirectly, such as frequency and / or phase angle between the current and the voltage in a high-voltage network. The same applies if for other power grids, such as a gas pipeline system, in the corresponding physical variables, such as the flow rate of the gas per unit time, correspondingly definable network parameters are.

The determination of the similarity measure as degree of deviations between a predefinable and a current network parameter offers the possibility of estimating the quality of the correspondence between current and predefinable network parameters. In the event that on the basis of the prescribable

Network parameters a possible critical network state is simulated on the basis of the current network structure, can be concluded in connection with a similarity measure of high quality between the current and the predetermined network parameters as it were to a critical network state of the current power supply network. In this case, a warning message is issued.

For the operator for monitoring the power supply network, this procedure has the advantage that a possible critical network state is not first detected by the operator as previously due to the interpretation of the visualized network parameters, but that the operator in the case of a high degree of similarity and one with the predetermined network Parameter associated critical network state can easily be displayed the explosiveness of the critical network state. By means of these measures according to the invention, the operator is made aware of possible critical network conditions and supported in the decision-making for possible changes of the network parameters.

By combining the model simulations that precede the monitoring or the simultaneous modeling of the network status for certain network parameter conversions. figurations, a data pool of possible critical network states can be generated on the basis of the simulated network parameters and the simulated network structure in advance and independently of network operation.

Since a direct comparison of the current network parameter configurations on the basis of the current network structure with the simulated network states may not be possible, the determination of a similarity measure between the current and the predeterminable network parameters offers the option of determining the degree of correspondence between the simulated and the current network state , The operator not only has the possibility of monitoring the energy supply network on the basis of his personal experience, but can at the same time access a data pool of already simulated network states with regard to the predefinable network parameters and the network structure used for this simulation.

In an advantageous embodiment of the method, it is provided that the current network parameter is continuously determined and permanently compared with a predefinable network parameter. This ensures that the monitoring of the power supply network is compared virtually online with the predetermined network parameters. In the presence of a high

Similarity measure between the predefinable and the current network parameters in conjunction with a classified as critical in the context of the network state in conjunction with the predetermined network parameters, the operator to monitor the power supply network can be pointed very quickly to the critical network state.

It is considered an advantage that previous network parameters are stored in a database and used as the basis for the mulation of the possible network state as now predeterminable network parameters compared with current network parameters and corresponding similarity measures are generated. This ensures not only a comparison of the current network parameters with simulated network parameters, but also a comparison with real network parameters that have occurred in the past.

The operator for monitoring a power supply network is given access to a comprehensive data pool by the method according to the invention, which however does not overload the operator with additional information, as hitherto, but supports him in the decision-making for monitoring and controlling the energy supply network. The possible network states stored in the database are, on the one hand, possibly occurring critical network states in the past with corresponding predefinable network parameters derived therefrom, as well as simulation results of possible network states on the basis of freely chosen or predetermined network parameters derived from the network. Likewise, the respective network structure for the respective network parameters is taken into account in the simulation of the possible network states and their linking in the database.

In the presence of a warning message based on the simulated possible critical network condition, at least one control command for a relevant network device in the energy supply network and / or an action option for an operator is calculated. The selection of the relevant network devices is based on the current network structure, the current network configuration and the current network state advantageously by means of an expert system, using neural networks and / or fuzzy logic systems. By the ad The user not only receives an indication of a possible critical network state from possible options for action to accompany the critical network state, but also determines control commands for a network device interacting with the energy supply network on the basis of the critical network state, if necessary to prevent or terminate the classified network state.

Advantageously, the current network parameter is transmitted to a central processing unit and the similarity measure is calculated by the central processing unit. Alternatively, it is provided that the current network parameter is transmitted within a communication network between at least two computing units and the similarity measure is calculated by a computing unit with available computing capacity. The advantage of the alternative solution is that in particular peer-to-peer network configurations can be used to provide the necessary computing capacity for the similarity measure calculation.

It is regarded as an advantage of the method according to the invention that the current network parameter and / or the predefinable network parameter are filtered according to predetermined filter methods. By means of the predetermined filtering method, the measured data quantity to be processed can be reduced to determine the current network parameter or the predefinable network parameter. At the same time, this also makes it possible to execute the method in conjunction with a reduced computing capacity for simulating the possible network state and for determining the similarity measure between current and predefinable network parameters in comparison to an unfiltered measurement data determination. In an advantageous embodiment of the method, the possible network state is used as the basis for calculating an index of the network state as a measure of the security of supply and / or the network stability of the energy supply network. The simulation of the possible network states not only serves to determine the potentially critical network conditions, but is also used for optimal use in the sense of the greatest possible security of supply and / or optimal network stability of the energy supply network. As a result, options for the operation of an optimized supply network can be provided on the basis of an optionally possibly not optimal network configuration.

The current network parameter is advantageously stored in a database and subsequently used as a predefinable network parameter on the basis of the network structure for calculating the possible network state of the energy supply network. By establishing a database of network conditions that have occurred in the past and their network parameters, the database available to the operator for monitoring the energy supply network contains not only simulation results, but also data about network states that have occurred in the past. These possible critical or optimal network states are thus not only available to the operator as a pure accumulation of data, but are used above all for the direct warning of possible critical network states and for decision-making for the operator. An interpretation of the network parameters and network states thus presented by the operator is thus not necessary since the possible critical network states are linked to a respective warning message in accordance with the method according to the invention. The similarity measure and / or the control commands and / or action options on the basis of a possibly classified as critical network state are calculated by expert system, neural networks and / or fuzzy logic systems. These "intelligent" systems make it possible to analyze the fuzziness of the differences between the current and predefinable network parameters, as well as between the simulated and current network structure, and options for action and / or control commands for relevant network devices due to detected critical network conditions, such as a warning message. In this case, the network parameter is advantageously the phase angle between the current and the voltage within the power supply network or at least one power supply parameter of a power supply unit interacting with the energy supply network or at least one state parameter, such as the temperature of the protection device, one with the power supply network Interaction of standing power supply.

It is furthermore regarded as an advantage that the network parameter with different sampling rates is sampled in the network device interacting with the energy supply network and thus used to calculate the possible network state in different frequency ranges of the energy supply network. Furthermore, it is regarded as an advantage that a plurality of network parameters, which are optionally determined independently of one another, are used to jointly calculate the possible network state of the energy supply network. The control commands and / or options for action derived from the possible network state in conjunction with the similarity measure can advantageously be used directly to control the network device interacting with the energy supply network. At the same time, the control command can also be used as an instruction for the operator to monitor the power supply network. This makes it possible for the control commands to be used directly as input control to a relevant network device in the energy supply network. As far as the complete decision sovereignty of the operator to monitor the power grid should remain, the control commands and / or options can be displayed to the operator directly and thus presented to the operator as action suggestions for network control.

It is regarded as an advantage that the possible network states are modified by a simulation unit due to variations of the boundary conditions, such as the network configuration and / or the network structure, and simulated independently of the current network state.

Advantageously, the operator as the basis for the simulation, the measurement data used or derived therefrom, such as network parameters, network structure, and the conclusions derived therefrom, such as the similarity between the current and the predetermined network parameters and in the case of a high similarity measure in conjunction with a critically determined network state in conjunction with the specifiable network parameter derived control commands and / or action options provided as background information.

The object is also achieved in that, according to the invention, a comparison operator compares at least one current network parameter with the predefinable network parameter taking into account the network structure, and a computing unit generates a similarity measure as the degree of deviation between the predefinable network parameter and the current network parameter. riert, wherein in the detection of a possible critical network state, taking into account the similarity measure, the computing unit outputs a warning message.

The present invention may be implemented in the form of hardware, software or a combination of hardware and software. For this purpose, any type of system or any other device adapted to carry out the method according to the invention is suitable. A typical combination of hardware and software could be a general-purpose computer system with a computer program that loads and executes into the general-purpose computer system and controls the computer system to execute an application created by the described method. In a further combination of hardware and software, for example for monitoring a power supply network, a predefinable network parameter can be simulated in a simulation unit and a computing unit determines a degree of similarity as a degree of deviation between the predefinable network parameter and the current network parameter, wherein upon detection of a possible critical network condition taking into account the similarity measure, the computing unit issues a warning message, while the remaining layers are executed on conventional PC hardware. The present invention may also be incorporated into a computer program product incorporating all features that enable it to implement the computer-aided methods described herein, and which, upon loading into a computer system, is capable of performing these methods.

As used herein, the terms computer program means, computer program, and computer application means any term in any computer language, code, or notation of a set of instructions that includes a Computer system to enable data processing and so to perform a specific function. The computer program, the computer program or the computer application is executable on the computer system either directly or after being converted into another language, code, notation or by displaying it in a different material form.

Further advantageous embodiments will become apparent from the dependent claims.

The invention will be described in more detail with reference to exemplary embodiments in the figures. Show it:

1 shows a flow chart of selected aspects of the method according to the invention;

FIG. 2 a schematic representation of the data preparation according to the method according to the invention; FIG.

Fig. 3 is a schematic representation of the determination of the current and the predetermined network parameter from a database.

FIG. 1 shows a flowchart of selected process sequences of the method according to the invention. After the start of the method, the current network parameters 100 of the energy supply network are determined. If there are no current network parameters 100, a renewed interrogation of the network parameters by a comparison operator 110 is initiated. In case of current network parameters

100, the similarity measure 130 of the current network parameter 100 is determined with a predefinable network parameter 120. For this purpose, the predefinable network parameter 120 is read from a database 11. Which predefinable network parameters 120 from the data tenbank 11 can be selected, is freely selectable. The selection of the predeterminable network parameters 120 can be carried out either from the viewpoint of the associated possible critical network states. Furthermore, it is provided that the predefinable network parameters 120 are selected on the basis of optimal network stability indices and compared with current network parameters 100. With the determination of the similarity measure 13ß the network structure 140 of the power grid is determined simultaneously. In a subsequent comparison operation 150, the current network parameter becomes

100 with the predeterminable network parameter 120 - taking into account the underlying similarity measure 130 - determined.

The network structure 140 of the network structure linked to the predetermined network parameters 120 is likewise stored in the database 11. In the example shown in FIG. 1, the current network structure 140 of the energy supply network corresponds to the network structure stored on the database for the predeterminable network parameters 120, so that the similarity measure of the current network structure 140 completely coincides with the network structure stored on the database 11. Alternatively, it is possible for a similarity measure 130 for the current 140 as well as the network structure stored on the database 11 to be determined simultaneously for the network parameter 140 during the determination of the similarity measure 130 and used as a basis for the comparison operation 150. If the comparison operation 150 reveals that the current network parameter 140 does not correspond to a predefinable critical network parameter stored in the database 11, a renewed query of the current network parameter 100 is initiated. Should a possible critical predefinable network parameter 120 be exceeded, a corresponding warning message 160 is output and in the example selected a control command 170 determined. This control command 170 can be used directly for a relevant power supply unit 15 within the power supply network or visualized as an action option 180 to the operator.

FIG. 2 shows a schematic representation of the data flow according to the method according to the invention. The data basis used is measurement data from measuring devices 101a, 101b, 101c for selected measured variables of the energy supply network, some of which have different time sampling rates (see timeline indicated below). Thus, either measured values via relays and disturbance recorder from a measuring device 101a in a protective device as a power supply unit 15 (not shown), determined phase angle between current and voltage of a phase angle device 101b, as well as measured values of arranged in the power grid transmitter as a measuring device (101c) in different time sampling rates for Calculation of the network parameter 100. Ideally, the determined network parameters 100 represent a compressed image of the current network state. A computing unit 10 compares the current network parameters 100 with the predeterminable network parameters 120 from the first database 11 or with predefined network parameters 121 already modeled independently of the current network state second database 12 compared. The database 11 and 12 can also be combined in a database 11. In the case of a determined high similarity measure 130 (not shown) between the current network parameter 100 and a predefinable network parameter 120 from the database 11 or a modeled network parameter 121 of a possible critical network state of a second database 12 determined from the simulation, a warning 160 is output. either as an option to an operator as an option 180 is updated or used as control commands 170 for a power supply unit 15.

FIG. 3 shows a schematic representation for determining the current 100 and the predefinable network parameter 120 in the database 11. The method according to the invention can also run simultaneously in two parallel methods and thus provide the operator with the greatest possible access to the existing data pool. The currently determined network parameter 100 is compared with predefined network parameters 120, for example critical network parameters, in conjunction with the determined network structure 140, and a corresponding similarity measure 130 and, derived therefrom, a comparison 150 between the current 100 and predefinable network parameters 120 are determined. At the same time, based on the currently determined

Network parameters 100 and the network structure 140 on already performed and stored in a database 12 network simulations accessed via a simulation unit 14. The simulation varies the modeled mesh parameters 121 within certain limits and within certain boundary conditions. Thus, it is conceivable that the simulation unit 14 simulates a partial failure of the network, for example due to a single network station failure, and determines the resulting possible network states in conjunction with the respective simulated network parameters 121. The same applies to the simulation of the associated network structure, so that possible extreme situations, such as the partial failure of the network structure due to an earthquake, are taken into account in the simulations. On this basis, a corresponding degree of similarity 130 is determined and a corresponding comparison operation 150 (not shown) between current 100, predefinable 120 and possibly simulated network parameters 121 is determined. This dichotomy of the system makes it possible to Raraeter 120, 121 compare in a corresponding procedure with current network parameters 100 and this possibly prioritized to visualize an operator can.

At the same time, possible network conditions which are critical and / or optimal for network operation can be determined in parallel by means of the simultaneous simulation. In the arithmetic unit 10, the data of the network parameters 100, 120, 121 determined in this way can be evaluated, compared with one another and, if appropriate due to a prioritization, output differently in time as warning messages 160 of a possible critical network condition. This warning message 160 subsequently serves as the basis for the visualization of an action option 180 for an operator in the event of a critical network state or control commands 170 for a relevant network device 15 for the purpose of settling or avoiding a critical network state.

LIST OF REFERENCE NUMBERS

10 arithmetic unit

11 Database of predefined network parameters 12 Database of modeled network parameters of simulated network states

13 rule-based system

14 simulation unit

15 Power Supply 100 Power Parameters

101a, 101b, 101c Measuring device for measuring data of

Power supply system

110 Comparison operator current network parameters

120 predefinable network parameters 121 modeled network parameters

130 Determination of the similarity measure

140 Determination of the current network structure

150 comparison operator network parameters

160 Warning message 170 Control command for relevant power supply unit

180 option for action

Claims

claims

1. A method for monitoring an energy supply network, wherein at least one possible network state of the energy supply network is simulated on the basis of a network structure (140) of the energy supply network and at least one predeterminable network parameter (120) of the energy supply network, characterized in that at least one current network parameter (100) with the predeterminable network parameter (120, 121) taking into account the network structure (140) is compared and a similarity measure (130) is generated as the degree of deviation between the predeterminable (120, 121) network parameter and the current network parameter (100), wherein upon the detection of a possible critical network state taking into account the similarity measure (130), a warning message (160) is output.

2. Method according to claim 1, characterized in that the current network parameter (100) is continuously determined and permanently compared with the predefinable network parameter (120, 121).

3. The method according to any one of claims 1 or 2, characterized in that the possible network state in a database (11, 12) stored and the basis of the simulation of the possible critical network state predetermined network parameters (120, 121) from the database (11, 12) is compared with the current network parameter (100) and a similarity measure (130) is generated.

4. The method according to any one of claims 1 to 3, characterized in that in the presence of a warning message (160) on the basis of the possible critical network state, at least one control command (170) for a relevant network device (15) in the energy supply network and / or an action option (180) for an operator for monitoring the energy supply network are calculated.

5. Method according to one of claims 1 to 4, characterized in that the current network parameter (100) is transmitted to a central processing unit (10) and the similarity measure (130) is calculated by the central processing unit (10).

6. The method according to claim 1, wherein the current network parameter is transmitted within a communication network between at least two arithmetic units and the similarity measure is calculated by a computing unit having available computing capacity.

7. The method according to claim 1, wherein the current network parameter and / or the predefinable network parameter are filtered according to predetermined filter methods.

8. The method according to any one of claims 1 to I ₁ characterized in that the possible network state is used as a basis for calculating an index of the power grid as a measure of the greatest possible security of supply and / or optimal network stability of the power grid.

9. The method according to any one of claims 1 to 8, characterized in that the current network parameters (100) stored in a database (12) and then as a predetermined network parameters (120, 121) on the basis of the network structure (140) for calculating the possible network state of the power grid is used.

10. The method according to any one of claims 1 to 9, characterized in that the similarity measure (130) and / or the control command (170) and / or the action option (180) by rule-based systems (13), in particular expert systems, neural networks and / or Fuzzy logic systems to be calculated.

11. The method according to any one of claims 1 to 10, characterized in that the network parameters (100) of the phase angle between the current and voltage within the power grid or at least one power supply parameter (101b) of an interacting with the power grid power supply unit (15) or at least one state parameter (101c) of a power supply unit (15) interacting with the energy supply network.

12. The method according to claim 1, wherein the network parameter (100) with different time sampling rates is used to calculate the possible network state of the energy supply network.

13. The method according to any one of claims 1 to 12, characterized in that several network parameters (100) are used to calculate the possible network status of the energy supply network.

14. The method of claim 4, wherein the control command can be used to control the relevant network device that interacts with the energy supply network.

15. The method of claim 4, wherein the control command and an action option are provided to the operator to monitor the power grid.

16. The method according to claim 1, wherein the possible network state of the energy supply network is simulated on the basis of a simulated network structure and the predefinable network parameter (120, 121) of the energy supply network.

17. The method according to claim 1, wherein the simulated network structure and / or the predefinable network parameter are automatically varied and determined by a computing unit within a boundary condition to be specified by a user.

18. The method according to any one of claims 1 to 17, characterized in that the possible network state and / or the predetermined network parameters (120,121) and / or the current network parameters (100) and / or the similarity measure (130) and / or the network state and / or the control command (170) and / or the action option (180) are visualized.

19. Method according to claim 1, wherein the current network structure (140) is taken into account for the calculation of the current similarity measure (130).

20. System for monitoring a power supply network, wherein at least one possible network state of the power supply network on the basis of a network structure (140) of the power supply network and at least one predetermined network parameter (120, 121) of the energy supply network in a simulation unit (14) is simulated, characterized in that a Comparison operator (150) compares at least one current network parameter (100) with the predefinable network parameter (120, 121) taking into account the network structure (140), and a rule-based system (13) compares a degree of similarity (130) as the degree of deviation between the predefinable network parameter (120, 121 ) and the current network parameter (100), the rule-based system (13) issuing a warning message (160) when detecting a possible critical network state, taking into account the similarity measure (130).

21. System according to claim 20 with means for carrying out the method according to one of claims 1 to 19.

22. A data processing program for execution in a data processing system, wherein the data processing program

Portions of a source code for carrying out the method according to any one of the preceding claims 1 to 19, when the program is running in a computer.

A computer program product stored in a computer readable medium and comprising computer readable program means for causing a computer to perform a method as claimed in any one of the preceding claims 1 to 19 when the program is run in the computer.