WO2012143061A1 - Monitoring a graphic representation of an electrical energy supply network - Google Patents

Abstract

In order to specify a method for monitoring representation information indicating a graphic representation of an electrical energy supply network (10), which method can be carried out with great reliability and minimal expenditure of time and cost, according to the invention topology information is provided, which comprises a specification of the structure of the energy supply network (10) in the form of an object-oriented model description, in which the primary components of the energy supply network (10) are indicated by corresponding objects of the model description, and the representation information is provided, which comprises a specification of the structure of the energy supply network (10) in graphic form, in which the individual primary components of the energy supply network (10) are each assigned graphic object representations. For monitoring the representation information, variations between the representation information and the topology information are determined by comparing the graphic object representations contained in the representation information and the respective connections existing therebetween with the objects contained in the topology information and the respective linkages existing therebetween, data about the determined variations are stored as representation discrepancy information, and the representation discrepancy information is displayed by means of a display device of the data processing device (16). The invention also relates to a correspondingly designed data processing device (16).

Description

description

Checking a graphic representation of an electrical energy supply network

The invention relates to a method for checking representation information indicating a graphic representation of an electrical energy supply network by means of a data processing device and to a data processing device with which such a method is carried out.

So-called network control centers are used to control and monitor electrical energy supply networks. For this purpose, the network control centers are supplied with information about the state of the energy supply network. In such a state ^¬ information may be, for example measurements of currents, voltages and power, with sensors (eg transducers) tapped from the power grid and provided special in the vicinity of the primary components of the energy supply network measuring equipment (eg control center equipment, protective devices or so-called Remote Terminal Units - RTU). In addition, it may also be the information is event messages that certain te events during operation of the power supply system is ben ^¬ (for example, exceeding a threshold value), and have been produced at game as ^¬ of the above-mentioned measuring devices. Based on the information supplied to a complex control software can perform analyzes and evaluations of the current state of the power grid and forecasts derive ^¬ about possible future states of the power supply network. Such results of further processing of the status information should collectively be referred to as derived information. The state information and the information derived will be the operator of the network control center via Anzeigeein ^¬ directions shown (eg, large-screen monitors, surface projections), so that the operating personnel necessary Steuerhand- can make any necessary payments, as control commands from the control center to special near the power supply ^¬ network provided control devices are transmitted in order to bring about a desired change of state there. Such control commands may, for example, cause the opening or closing of switches or the insertion of active line filters. An example of a control software for network control centers is given by the product marketed by the Applicant Software "Spectrum Power". In order to ensure proper operation of the network control center, it must be ensured that the Bedienperso ^¬ nal provided to the network management graphical displays with the actual conditions of the energy supply network. in particular, to warranty th that is a graphical representation of the structure of Ener ^¬ gieversorgungsnetzes, for example a so-called network diagram, actually present in the power supply system primary components (such as bus bars, wires, switches, transformers, generators and inverters) and their links, so the existing between these primary components electrical connections, reflects, otherwise the operator an incorrect impression about the state of the power grid can be generated and in the worst most cases incorrect control actions occur, which can lead to disturbances in the operation of the power supply network ^¬.

Under certain circumstances it may namely happen that the presence in an engineering database of the control software graphical representation of the power supply system (hereinafter referred to as a representation of information) indicating a structure and a topology of the Energieversor ^¬ supply network in a graphical way, of the actual structure of the energy Supply network deviates. This can be in a different type used in the control software graphics data format (eg car ^¬ CAD) occur for example in the transfer of representation of information between different versions of tax software or data import of representation information from a third party system, such as a geographical information system. In addition to the representation information with the graphical representation of the network structure usually there is a topology information, an indication of the structure of the power grid in an object-oriented format

(for example, according to the CIM format required by the standard IEC 61970, CIM = Common Information Model). Often the representation information and the topology information from different sources are transferred to the control software, which also brings with it the risk of deviations. to

To ensure perfect operation, the conformity of the representation information with the actual expansion of the energy supply network must be guaranteed. So far, such a safeguard has been achieved by performing ^manual checks of the representation ^information and the topology information in advance of the commissioning of the control software. However, such a manual check is again susceptible to error and also associated with a high expenditure of time and thus high costs.

The invention is therefore based on the object of specifying a possi ^¬ ability with which a review of the representation information with high reliability and low time and cost can be performed.

To solve this problem, a method is proposed for checking a representation information indicating a graphic representation of an electrical energy supply network by means of a data processing device in which topology information is provided in a memory area of the data processing device an indication of the structure of the energy supply network in the form of an object-oriented model description, in the primary components of the power supply network are given by corre ^¬ chende objects of the model description, and in a further memory area of the data processing device, the representation information is provided, an indication of the structure of the power grid in graphical form includes, in which the individual primary components of the energy supply network are each assigned graphic object representations. In order to check the representation information by means of a computing device of the data processing device, deviations between the representation information and the topology information are found by comparing the graphic object representations contained in the representation information and the respective connections between them with the objects contained in the topology information and between them existing respective links; Information about the deviations found is stored as representation disparity information and the

Representation humor information displayed by means of a display device of the data processing device.

The particular advantage of the process of loading the invention is the fact that formation through the automated comparison between the representation of information and the Topologiein- consuming manual verification is unnecessary, so that on the one hand are errors in the manual review of out ^¬ closed and also time and cost savings can.

An advantageous embodiment of the method provides that are assigned to the comparison of the representation information with the topology information on the one hand the graphical object representations contained in the representation of information their corresponding objects in the topology information and not ^¬ executable mappings information on the question graphic Object representations are stored in the representation representation information, and on the other hand the objects contained in the topology information their corresponding representation information contained in the graphical representations of objects are assigned and stored in unworkable assignments information about the objects in question in the representation of disparity information. In addition, on the one hand the respective existing between the individual graphical object representations connections then be examined whether they exist corresponding Ver ^¬ knotting between the respective graphical object representations associated objects, and information about such links between graphical object representations in the Repräsentationsunstimmigkeitsinformation abgespei- chert, which investigated no corresponding linking zugeord ^¬ Neten objects exist, and on the other hand, the respective existing between the individual objects links to determine whether they exist corresponding connections between the assigned to the respective objects graphical object representations, and information on such links between objects in the Repräsentationsunstimmig- keitsinformation stored for which there is no corresponding connection of associated graphical object representations.

In this way a comparison of the representation of information and the topology information is quasi performed in both directions so that both deviations in the representa ^¬ tion information as well as such can be detected in the topology information in a simple manner.

A further advantageous embodiment of the invention ^shown SEN procedure provides that the topology information is examined for inconsistencies by the links of described within the topology information objects for inadmissible or missing links are checked and information about and recognized invalid or missing encryption knots are stored in the representation of disparity information.

As a result, the reliability in the verification of the representation information can be increased even further, since inconsistencies in the topology information can also be detected by the additional checking of the topology information. In this context may be specifically provided that the individual objects of the topology information are linkage points associated with that indicate at which points the question ^¬ union objects can be connected to other objects, and the tie points are assigned property values, which is a kind of possible linkages and / or specify technical properties of the primary components of the power supply network corresponding to the objects. In the Un ^¬ tersuchung the topology information such links between two objects are detected as inadmissible, in which connection points are connected with conflicting property values and recognize these links as missing, in which connection points are connected to any other object. This makes it possible to carry out the verification of the topology information in a simple and reliable manner.

A further advantageous embodiment of the invention ^shown SEN method is that sunstimmigkeitsinformation an automatic or manual correction of the set ^¬ fundenen disagreement is caused on the basis of Repräsentation- means of the data processing device.

For certain deviations that can be resolved in a unique way, an automatic correction can be performed by the data processing device. By displaying the representation of disparity information, the engineering staff will also be able to offset to make a manual correction. To simplify this ^further , one or more possibilities for correction can be proposed by the data processing device so that an operator of the data processing device can correct the discrepancy by selecting a correction option.

According to a further advantageous embodiment of the method according to the invention, it is further provided that the data processing device detects a user selection of that part of the representation information that is to be subjected to a check by the data processing device and limits the checking of the representation information to the selected part.

In this way, the operator of the data processing ^{device can} set the relevant part of the representation ^information to be examined in advance of the check.

According to a further advantageous embodiment of the method according to the invention, it is provided that, after the check, the topology information and the representation information are stored in a database of a network control center installation and used to control and monitor the electrical power supply network.

In this way, after completion of review and possible both the representation of information and the topology information of the control software of the Netzleitstel ^¬ le made available correction.

The above object is also achieved by a Datenverarbei ^¬ processing device for checking a graphical representa- tion of an electrical power supply network with a

Computer solved, which is adapted to carry out a method according to one of claims 1 to 8. The invention will be explained in more detail below with reference to Ausführungsbei ^¬ games. Show this

Figure 1 is a schematic representation of a control workstation system for controlling and Moni ^¬ monitoring of an electrical power supply network;

FIG. 2 shows a schematic process flow chart for explaining the checking of a representation information and a topology information;

FIG. 3 shows an exemplary embodiment of topology information;

FIG. 4 shows a representation information representing a correct reproduction of the topology information according to FIG. 3;

Figure 5 is a representation of information representing a first embodiment of an error ^¬ adhere reproduction of Topologieinformati- on Figure 3;

FIG. 6 shows an assignment scheme for explaining the

 Procedure for checking the representation information according to FIG. 5; Figure 7 is a view of a graphical output of

 Results of the verification of the representation information according to FIG. 5;

Figure 8 is a representation of information representing a second embodiment of an error ^¬ adhere reproduction of Topologieinformati- on Figure 3; FIG. 9 shows an allocation scheme for explaining the

 Procedure for checking the representation information according to FIG. 8; and

Figure 10 is a view of a graphical output of

Results of verifying the information representation of Figure 9. Figure 1 shows a schematic view of a - merely exemplary indicated - electrical power supply ^¬ network 10 for transmitting electrical energy. The energy ^¬ supply system 10 includes primary components such as busbars, cables, switches, transformers, reindeer generators and inverters, which are connected in a certain manner. With the power supply network 10 are in not shown in Figure 1 manner measuring devices IIa in combination. The measuring devices IIa can be, for example, control center devices, protective devices or so-called RTUs (RTU = Remote Terminal Unit). The width ^¬ ren associated with the power supply mains 10 ECUs IIb in connection by means of which 10 (for example by the opening or closing of a switch or by changing a transformer tap changer) can be herbeige ^¬ leads to influence the state of individual primary components of the power supply network.

The measuring devices IIa and the controllers IIb are connected to a communication network 12, which in turn is connected to a network control center 13 for monitoring and controlling the electrical power supply network 10. The shown in Figure 1 annular communication network 12 is merely as a way of the communication link between the measurement devices IIa and IIb the control devices on the one hand and the network control center 13 on the other hand anzuse ^¬ hen. Instead, for example, a communication ^¬ bus, a star-shaped communication network or a Hardwired with point-to-point connections be provided.

The network control center 13 includes a server device 14 in which the you need in order to operate the power supply system ^¬ th information (for example, the state information and the above-mentioned information derived) are stored in the form of data in different formats. On the server device 14 can be accessed by means of workstations 15 ^¬ . The workstations 15 illustrate the working ^¬ places of the operating personnel of the network control center and thus form the interface between the human and the system. On the server 14 and the workstations, a complex control software of the control center takes place that performs the Pro ^¬ processes for controlling and monitoring of the power supply ^¬ network. To operate the control software and thus to control and monitor the power supply network 10 15 work plans are displayed with the workstations, which give the structure of the power supply network 10 in graphical form ^¬ . In the network maps the state of the power supply system may also be displayed, for example, can positions of switches by corresponding switching symbols and Lastflüs ^¬ se in the energy supply network 10 by different color environments of the individual network components depicted and measuring ^¬ values are displayed. From the operator of the network control center can also be made directly on the network control actions are triggered by the control commands, which are again ^¬ transmitted to the corresponding control units IIb. The respective network plans are kept by the control software as representation information, which are stored for example on the server device 14 and the workstations are provided. In addition, a topology information is managed by the control software, the gieversorgungsnetzes 10 in object oriented form in ^¬ play, according to the specified by the standard IEC 61970 CIM model, indicating the structure of the energy. The network control center 13 further comprises an associated temporary or DAU ^¬ nently with the server device 14 Engineering calculator 16, which is adapted for start-up, diagnostic and maintenance of the control software.

For safe operation of the network control center must be ensured that the networks displayed with the workstations 15 match the actual structure of the power grid.

The method described below for checking a graphical representation of a power supply network is therefore geared to finding discrepancies between the representation information used for the representation of the networks and the actual structure of the energy supply network 10. For this purpose, the method uses the topology information, with which the structure of the power supply network is described in an object-oriented form. Sources of possible discrepancies may e.g. lie in an incorrectly executed topology information, to which the representation information refers, but they can also be based in an incorrectly executed representation information. Such discrepancies may arise, for example, if the data for the topology information and / or the representation information are imported from different sources or entered by different persons.

In checking the representation information, the present representation information and the present topology information are analyzed and examined for discrepancies by comparisons. The results are displayed in ge ^¬ suitable manner the engineering staff so that - if necessary - a correction can be made.

In general, there may be inconsistencies in the topology information or in the representation information or in both. Disagreements in both cases lead to a negative influencing the operation of the network control center and possibly incorrect operator actions by the operator of the network control center. The general approach to the review of the ^¬ repre sentation information for discrepancies is shown in the process flow diagram in FIG. 2 According to the first Schrit ^¬ th 20a and 20b for this purpose both the representation information and the topology information memory areas are in a data processing device in the form of the engineering computer 16 provided. The representa ^¬ tion information and the topology information represent files or groups of files, which are usually stored in Datenspei ^¬ chereinrichtungen and freigege- ben for editing.

In a step 21, first the topology information is checked for discrepancies. This has the advantage that even those discrepancies can be detected that are based on the topology information itself, and not just in the representation information. In this case, discrepancies are sought within the topology ^information described according to the CIM data model. Such inconsistencies may include, for example, the following situations:

- Two objects of topology information belonging to different voltage levels are directly linked.

 - Two objects are directly linked to each other with different electrical phases (e.g.

 electric phase A of the first object directly with the electric phase B of the second object).

- An object is not completely linked to other objects, eg if an object that can be linked to other objects via two possible links is only linked to another object via a link. Specifically, the verification of the topology information can be performed by checking the links of objects described within the topology information for invalid or missing links. In this case, the individual objects of the topology information are assigned link points which indicate at which points the objects in question can be linked to other objects. The tie points can still be associated with property values that the nature of the possible links and / or technical properties of the corresponding to the respective objects primary components of the energy supply network is ^¬ ben. For example, an object of the topology information describing a circuit breaker may be assigned two connection points, since the circuit breaker can be connected to other objects in two places. For example, voltage levels or, in the case of a multi-phase energy supply network, the designations of the individual phases can be assigned to the connection points as property values. When examining the topology information, such links between two objects are recognized as inadmissible, in which link points are associated with conflicting property values. In the above example, such a link would be recognized as inadmissible, indicating a direct electrical connection of different phases or different voltage levels of the power grid. In addition, during the check, such links are recognized as missing, in which an existing link point of an object is not linked to any other object.

Information on the retrieved in this way Unstimmigkei ^¬ th in a further step 22 sunstimmigkeitsinformation as Repräsentation- in a corresponding file in a memory area of the engineering computer stored.

The steps 21 and 22 are to be regarded as optional and therefore indicated in dashed line. In a following step 23, the representation information itself is checked. In the representation information, for example, the following inconsistencies may occur:

- Two graphic object representations are graphically interconnected, but in the topology information the corresponding objects are not linked.

 - Two objects in the topology information are linked, but the connection between the graphical object representations in the representation information is missing.

 - An object present in the topology information can not be assigned a graphic object representation in the representation information.

 No graphic object representation in the representation information can be assigned to any object in the topology information (for example, if the object in question has indeed been deleted from the topology information, but the associated graphical object representation has not been removed from the representation information).

In the case of graphic object representations, which represent lines or transformer windings, part of the graphic object representation may be outside the representation ^information currently to be checked (for example, if a line extends over two networks).

Specifically, to find deviations between the representation information and the topology information, a comparison between the two can be carried out by checking whether corresponding objects from the topology information can be assigned to all the graphic object representations contained in the representation information and, on the other hand, if all in the topology information holding objects corresponding graphical object representations can be assigned from the representation information. Information on graphical object representations, where no corresponding object from the topology information may be assigned, and information about objects to which no entspre ^¬ sponding graphical object representation can be assigned from the representation of information are, in step 24, in addition to the possibly found in steps 21 and 22 Inconsistencies regarding topology information are stored as representation mismatch information.

In addition, the respective connections existing between the individual graphical object representations are examined to see whether they have corresponding links between the corresponding objects in the topology information. The respective links present between the individual objects are then examined as to whether they have corresponding connections between the corresponding graphical object representations from the representation information. Information about such object representations for which there is no corresponding linkage of assigned objects from the topology information, and information about such linkages between objects for which there is no corresponding connection of associated graphical object representations, are also stored in the representation mismatch information in step 24. To examine the links, so-called link nodes (connectivity nodes) are used in the topology information, which are used as elements for the links between individual objects. Connectors are used in the representation information in a corresponding manner.

Since some discrepancies between the representation information and the topology information may be recognized as a result of multiple comparisons, the representation mismatch information will typically have multiple redundant indications of the same mismatch. In order to give the engineering staff as clear as possible, but To be able to present a complete list of identified discrepancies, there is a reduction in the number of discrepancies detected in the representation of disagreement information, using the following two rules:

Disagreements concerning incorrect connections between electrical connections and objects or object representations from the point of view of the linking nodes or the connectors are removed from the representation information information or are not stored at all in the representation since these discrepancies also ^depend on the page respective object or the object representation are detected.

- objects or object representations that are properly connected to ei ^¬ nem link node or a connector are also not included in the sunstimmigkeitsinformation Repräsentation- if the link node or connector in question in addition connected to a wrong thing, or the wrong object representation is.

By applying these two prescriptions, redundant information can be removed from the representation information or it is not stored in it at all.

In a further step 25, the representation hull information is displayed with a display device of the engineering computer, so that the engineering staff receives an overview of the discrepancies found. This display can be done, for example, in the graphical representation of the representation information by a corresponding hatching or coloring of the object representations that are not displayed correctly. In addition, a text-based list of discrepancies can be output, which can be processed step by step by the engineering staff. Such a text-based listing can on the one hand provide a comprehensive overview of all discrepancies found; In addition, it can also be given the opportunity to focus on individual primary components of the considered power supply network to allow the engineering personnel a detailed error analysis and rectification.

In a correction step 26, the representation mismatch information triggers a correction of the discrepancies, which is carried out automatically or manually depending on the nature of the discrepancy. In addition, the engineering personnel can be assisted in the manual correction by suggestions from the engineering computer, which offer possible remedies for the discrepancies.

It is here deliberately not fully automatic correction of discovered discrepancies instead because certain inconsistencies can be tolerated depending on the type of graphical network representation given by the representation of information or that may wish for a better overview (eg skipping certain object ^¬ representations or the combination of individual compounds). Therefore, the possibility of a manual or semi-automatic (manual selection of predetermined possible solutions) the engineering staff in most FAEL ^¬ len is given correction. In the semi-automatic correction, the engineering staff is guided step by step through the disagreements found using a suitable dialog box displayed by the display device, giving him choices for resolving the inconsistencies that he can accept by user input (eg, mouse click on a corresponding button).

The automation level of the correction is determined by the type of inconsistency. Wrong graphical symbols for the object representations (eg, bad switch symbol), for example, automatically corrected ^¬ to. In addition, incorrect parameter settings (eg the connection of different electrical phases by a single electrical connection) can be resolved fully automatically, if a clear solution of the wrong parameterization can be seen (eg which of two electrical phases is meant). Conflicting or not eindeu ^¬ term situations, the corresponding discrepancies must always be manually or semi-automatically set by the operator ^¬ triggers. The corrected representation information (and possibly the kor ^¬-corrected topology information) is then stored in a database of the control center (eg, in the server device) and made available to the control center software for proper operation of the control center. A review, however, can regularly (eg when you made changes to the structure of the power supply system or during commissioning ei ^¬ ner new version of the control center software) are repeated.

The engineering staff can also limit by an act concluded before reviewing selecting a range of representation information checking on these selected range to check the complete repre ^¬ sentation information, rather than each time. In the following, the verification of a representation information will be explained in more detail on the basis of two examples.

For this first 3 shows a topology information of a so-called "half-breaker" superstructure of a waste section of a power supply network. The Topolo ^¬ gieinformation shown consists of an object-oriented representation of individual objects 31. The topology information shown in Figure 3 includes as objects 31 busbars

("Busl" and "Bus2"), lines ("ACLinel", "ACLine2") and power switches ("CB1", "CB2", "CB3"). Between the objects are logic nodes 32 ("CN1", "CN2"). Each object 31 also has link points 33, which indicate at how many places a link of the link respective object 31 is possible with other objects. There is always a link node 32 between two linked objects 31. The linking points 33 can also be assigned property values which specify, for example, an electrical phase and / or a voltage level. Notwithstanding the representation in FIG. 3, the topology information can also be specified in purely textual form (eg in the form of an XML file). Figure 4 shows a correctly engineered Repräsentationsinfor ^¬ mation, illustrating the structure of a power supply system described by the topology information in accordance with Figure 3 graphically. The representation information here comprises graphic object representations 41, which correspond to the objects 31 from the topology information according to FIG. Consequently, in the representation information according to FIG. 4, object representations 41 for busbars ("BusRl", "BusR2"), lines ("Linel", "Line2") and circuit breakers ("BR1", "BR2", "BR3") can be seen The object representations 41 are represented by connectors 42 ("CNR1", "CNR2", "CNR3", "CNR4"), which correspond to the logic node 32 of the topology information according to FIG.

In contrast, FIG. 5 shows an incorrectly executed representation information, in which the object representations 51 for the switches "BR1" and "BR3" have been interchanged in deviation to the topology information according to FIG. The remaining object representations 51 and connectors 52 are executed correctly.

FIG. 6 shows an allocation scheme which illustrates the procedure for checking the topology information according to FIG. 3 and the incorrect representation information according to FIG. In accordance with the procedure already described for FIG. 2, a check first takes place as to whether each object representation 51 (see FIG. 5) of the representation information can be assigned a corresponding object 31 (see FIG. 3) of the topology information. This over- Examination is indicated by the double arrows 61 in Figure 6. In addition, a check of the conformity of the connections (connectors) between the object representations 51 with the links (linking nodes) of the objects 31 takes place. With regard to the connectors, deviations are found which are highlighted in FIG. 6 by double arrows 62 marked with a question mark. Since the object images 51 of "BR1" and "BR3" switch are reversed in the Rep ^¬ räsentationsinformation of Figure 5, resulting in this test with respect to deviations of the compounds in question object representations. On the side of the topology information, corresponding deviations from the representation information are found, which are highlighted in FIG. 6 by dashed double arrows 63 marked with a lightning symbol. Finally, during the check it is also ascertained that in the topology information according to FIG. 3 the objects of the lines "ACLinel" and "ACLine2" are each not linked to another object via a link node. This fact is highlighted by dashed double arrows 64 marked with a question mark.

Without consideration of redundant information, the representation mismatch information would be included as the result of the verification of the following information:

- busbar "Busl" / "BusRl": In the topology Informa ^¬ tion associated with switch "CB1" / "BR1", connected in the representation of information with switch

 "CB3" / "BR3".

- busbar "Bus2" / "BusR2": In the topology Informa ^¬ tion associated with switch "CB3" / "BR3", in the repre sentation information ^¬ connected to switch

 "CB1" / "BR1".

 - Line "ACLinel" / "Linel": In the topology information linked to switch "CB1" / "BR1", in the representation information connected to switch "CB3" / "BR3".

- Line "ACLinel" / "Linel": Incomplete link in the topology information. - line "ACLine2" / "Line 2": In the topology information associated with switch "CB3" / "BR3", in a repre ^¬ tion information associated with switch "CB1" / "BR1".

- Line "ACLine2" / "Line2": Incomplete link in the topology information.

 - Link node "CN1" / Connector "CNR1": In the topology information linked to switch

 "CB1" / "BR1", in the representation information associated with switch "CB3" / "BR3".

 - Link node "CN2" / Connector "CNR2": In the topology information linked to switch

 "CB3" / "BR3", in the representation information associated with switch "CB1" / "BR1".

 - Link node "CN3" / Connector "CNR3": In the topology information linked to switch

 "CB1" / "BR1", in the representation information associated with switch "CB3" / "BR3".

 - Link node "CN4" / Connector "CNR4": In the topology information linked to switch

 "CB3" / "BR3", in the representation information associated with switch "CB1" / "BR1".

 - Switch "CB1" / "BR1": In the topology information linked to line "ACLinel" / "Linel" and busbar "Busl" / "BusRl", in the representation information connected to line "ACLine2" / "Line2" and busbar "Bus2 "/" BusR2 ".

 - Switch "CB3" / "BR3": In the topology information linked to line "ACLine2" / "Line2" and busbar "Bus2" / "BusR2", in the representation information connected to line "ACLinel" / "Linel" and busbar "Busl "/" BusRl ".

Accordingly, according to the information in the (unaddressed) representation mismatch information, all the object representations 51 and connectors 52 present in the representation information, with the exception of the object representation of the power switch "BR2", would be marked as defective by hatching or coloring Consequently, work with great effort, the individual inconsistencies, although only the two object representations of the switches "BR1" and "BR3" are reversed. Therefore, the list of information listed in the representation disparity information is reduced by the application of the above-mentioned rules for reducing redundant information. Following the application of these rules, the following information will remain as inconsistencies in the representation disparity information:

- Line "ACLinel" / "Linel": Incomplete link in the topology information.

 - Line "ACLine2" / "Line2": Incomplete link in the topology information.

 - Switch "CB1" / "BR1": In the topology information linked to line "ACLinel" / "Linel" and busbar "Busl" / "BusRl", in the representation information connected to line "ACLine2" / "Line2" and busbar "Bus2 "/" BusR2 ".

 - Switch "CB3" / "BR3": In the topology information linked to line "ACLine2" / "Line2" and busbar "Bus2" / "BusR2", in the representation information connected to line "ACLinel" / "Linel" and busbar "Busl "/" BusRl ".

It can be seen that by using the two above-mentioned regulations, the extent of the information present in the representation mismatch information can be significantly reduced. Figure 7 shows a representation of a repre ^¬ tion information from Figure 5, in which the faulty components are highlighted by hatching 71st

In the display of the representation mismatch information, in addition to this information in support of a semi-automatic correction, there are also choices which can be used to correct the connection of the object representations of the object representations

Switch "BR1" and "BR3" and a jump to another representation information or topology information for the open connections of the lines "ACLinel" and "ACLine2". These can be accepted by the engineering staff and thus implemented semi-automatically. In the case of a rejection, the engineering computer does not make a correction, this then remains a manual action of the Bedienperso ^¬ nals left.

FIG. 8 shows a second exemplary embodiment of a representation information which is faulty with regard to the topology information according to FIG. According to this second embodiment, instead of the object representation of the switch

"CB3" / "BR3" uses an object representation of a switch "BR4" that does not exist in the topology information The other object representations and connections are executed correctly.

Figure 9 shows a corresponding mapping scheme, the ent ^¬ speaking the explanations of FIG 6, the procedure for verification of the topology information and the information represen- tation illustrates inconsistencies. It can be seen that when checking whether objects of the topology information corresponding to all object representations of the representation information can be assigned, for this purpose a new object "CB4" highlighted in FIG. 9 with dash-lined border would have to be introduced in the topology information, whereas in the representation information The object representation "CB3" can not be assigned. Entspre ^¬ accordingly arise with respect to all connectors of the representation of information that are comparable linked with the object representation "BR4" disagreements (double arrows 91) that apply in ent ^¬ speaking manner to the fictitious inserted object "CB4" in the topology information (double arrows 92). Inconsistencies arise in the topology information additionally with respect to missing links of the fictitious inserted object "CB4" (double arrows 93) as well as with respect to the representation information which does not correspond to links between the object "CB3" and further objects (double arrows 94). Those already mentioned in the previous For example, inconsistencies found in the incomplete connections of the "ACLinel" and "ACLine2" lines (double arrows 95) are again found in this review.

In the course of the review he fathered ^¬ to this embodiment and sentationsunstimmigkeitsinformation by applying the above requirements, reducing redundant data adjusted repre- include the following information:

- Switch "CB3" No corresponding object representation included in the representation information.

 - Switch "CB4" / "BR4": Not linked to any object of topology information.

 - Line "ACLinel" / "Linel": Incomplete link in the topology information.

 - Line "ACLine2" / "Line2": Incomplete link in the topology information.

As correction options for a semi-automatic correction, the engineering personnel would be shown buttons to include the missing object representation of the switch "BR3" with correct connections in the representation information and to remove the redundant switch "CB4" / "BR4". In addition, a jump to another representa ^¬ tion information and topology information for the open connections of the lines "ACLinel" and "ACLine2" would be offered.

Finally, FIG. 10 shows a representation of the incorrect representation information according to FIG. 8, in which the detected discrepancies with hatchings 101 are highlighted.

Claims

claims

1. A method for checking a representation information indicating a graphic representation of an electrical energy supply network (10) by means of a data processing device (16), in which

 - in a memory area of the data processing device (16) a topology information is provided, which includes an indication of the structure of the power supply network (10) in the form of an object-oriented model description in which primary components of the power supply network (10) are indicated by corresponding objects of the model description; and

- in a further memory area of the data processing means (16) the representation of information is provided that includes an indication of the structure of Energieversor ^¬ supply network (10) in graphical form, in which a ^¬ individual primary components of the power supply network (10) respectively associated with graphical object representations are;

wherein for checking the representation information by means of a computing device of the data processing device (16), the following steps are carried out:

 Finding deviations between the representation information and the topology information by comparing the graphical object representations contained in the representation information and the respective connections therebetween to the objects contained in the topology information and the respective links existing therebetween;

- storing information about the found deviations as representation misinformation; and

 - Displaying the representation of disparity information by means of a display device of the data processing device.

2. The method according to claim 1,

characterized in that - When comparing the representation information with the topology information

 the graphic object representations contained in the representation information are assigned their corresponding objects contained in the topology information, and in the case of non-executable assignments, information about the graphic object representations in question is stored in the representation information information;

 the objects contained in the topology information are assigned their corresponding graphical representations of objects contained in the representation information, and in the case of unavailable assignments, information about the objects in question is stored in the representation mismatch information;

- the respective existing between the individual graphical object representations are being explored to determine whether they exist appropriate links between the respective graphical object representations associated objects, and information about such links between graphical object representations in the Repräsentationsunstimmigkeitsinformation be saved, for which no corresponding Ver ^¬ linkage of associated objects exists; and

- the respective existing between the individual objects links are examined to determine whether they appropriate connections between the associated the respective objects graphical object representations exist, and information about such links between objects in the Repräsentationsunstimmigkeitsin- formation are stored for which no entspre ^¬-reaching combination of associated graphical object representations exists.

3. The method according to any one of claims 1 or 2,

d a d u r c h e c e n c i n e s that

- the topology information is also examined for discrepancies by linking the links from within the topology gieinformation described inadmissible or missing links are checked and stored information on recognized impermissible or missing links in the representation disparity information.

4. The method according to claim 3,

d a d u r c h e c e n c i n e s that

 - The individual objects of the topology information associated with linking points that indicate where the objects in question can be linked to other objects, and the linking points property values are assigned, the one type of possible links

and / or indicate technical properties of the primary components of the energy supply network corresponding to the objects;

 - In the investigation of topology information such links between two objects are recognized as inadmissible, in which link points are associated with conflicting property values; and

- such links are recognized as missing, where link points are not linked to any other object.

5. The method according to any one of the preceding claims,

d a d u r c h e c e n c i n e s that

an automatic or manual correction of the detected discrepancies is initiated by means of the data processing device (16) on the basis of the representation mismatch information.

6. The method according to any one of the preceding claims,

d a d u r c h e c e n c i n e s that

- the data processing device (16) detects a user selection of that part of the representation information which is to be subjected to a check by the data processing device (16) and limits the verification of the representation information to the selected part.

7. The method according to any one of the preceding claims,

d a d u r c h e c e n c i n e s that

- after checking the topology information and the representation of information in a database of a network control point (13) are stored and for controlling and monitoring ^¬ over the electrical power supply network (10) are pulled ^¬ zoom.

8. Data processing device (16) for checking a graphical representation of an electrical power supply network (10) with a computing ^device which is directed to the execution of a method according to one of claims 1 to 7 ^¬ .