EP3841647A1 - Method and device for determining the grid state of a low-voltage grid of an energy supply system - Google Patents

Abstract

The invention relates to a method for determining the grid state of a low-voltage grid of an energy supply system (2), comprising a gateway (3) and a monitoring device (4). The energy supply system (2) has grid lines (311-319) with respective smart meters (101-109), which form a grid topology of the low-voltage grid (1). Communication paths are formed between the smart meters (101-109) and the gateway (3) by applying powerline communication technology to the grid lines (311-319), said paths together forming a communication grid with a communication topology, and communication properties, comprising routing information (RI) which describes the communication path between the gateway (3) and the respective smart meter (101-109), are ascertained as at least one communication parameter by means of the respective smart meter (101-109), the communication topology being determined from said communication parameter. The grid state of the low-voltage grid (1) is determined from a comparison of the grid topology with the communication topology by means of the monitoring device (4), wherein a change in the structure of the communication topology with respect to the structure of the grid topology is analyzed, and in the event of a change in the structure of the communication topology, a comparison is carried out with weather data and is taken into consideration when determining the grid state.

Description

 Method and device for determining the network status of a low-voltage network of an energy supply system

The invention relates to a method for determining the network state of a low-voltage network of a power supply system, comprising at least one gateway and a monitoring device, and the power supply system has power lines with respective smart meters, which form a network topology of the low-voltage network, and communication paths between smart meters and at least one gateway are generated by using powerline communication technology on the network lines, which together form a communication network with a communication topology, and properties of the communication, comprising routing information which defines the communication path between the at least one gateway and the respective Smartme

describe as at least one communication parameter is determined by the respective smart meter from which the communication topology is determined, and the network state of the low-voltage network is determined by comparing the network topology with the communication topology by the monitoring device, with a change in the structure of the communication topology compared to the structure of the network topology.

The gateway and smart meter can communicate with one another by means of at least one remote inquiry process, each comprising an inquiry telegram and a reply telegram.

The following process steps can be carried out: a) sending the query telegram of the remote query process to a first smart meter and at least one second smart meter, b) determining properties of the communication between the at least one gateway and the first smart meter and / or the at least one second smart meter as at least one communication parameter from at least one query telegram by the respective smart meter, c) transmitting a response telegram of the remote query process to a monitoring device of the energy supply system, which comprises the at least one communication parameter, d) detecting the communication topology of the first smart meter and the at least one second smartmeters from the at least one response telegram by the monitoring device, e) determining the network status of the low-voltage network from the at least one communication parameter, the network topology and the communication topology by the monitoring device.

The invention further relates to a device for determining the network state of a low-voltage network of a power supply system, comprising at least one gateway and a monitoring device, and the power supply system having power lines with respective smart meters, which form a network topology of the low-voltage network, and the power supply system is set up for this: a) To create communication paths between smart meters and at least one gateway using powerline communication technology on the network lines, which together form a communication network with a communication topology, and b) properties of the communication, comprising routing information, which describe the communication path between the at least one gateway and the respective smart meter, as at least one communication parameter by the respective smart meter, and to determine the communication topology by the monitoring device, and c) to determine the network state of the low-voltage network from a comparison of the network topology with the communication topology by the monitoring device, a change in the structure of the communication topology compared to the structure of the network topology being analyzed.

Low-voltage networks are nowadays partly old and prone to failure, which can lead to undesired failures in the supply of consumers, as well as to costly maintenance and repair work on the power lines.

 It is often difficult to identify future network malfunctions or failures in the course of maintenance work, for example to preventively replace a component that is in danger of failing. In other words, it is very difficult to predict a failure. In most cases, an unfounded, preventive replacement of components is not economically sensible.

 Furthermore, it is often necessary for a consumer to report a malfunction or a failure of the network, for example by telephone, before a corresponding repair can be started. This can undesirably increase downtime.

In addition, it can be difficult for a network operator of a low-voltage network to determine which active network supply lines actually supply the network takes place, since this can depend on the manual configuration of line switches, which can be switched between several power lines, the switching assignment of which can usually not be queried remotely. Knowledge of the currently active power lines is important, for example, for maintenance or repair work.

 US 2014/278162 A1 and EP 2 608 417 A2 each disclose methods for determining the network state from various communication parameters, which were recorded by measurements based on powerline communication (PLC) via network lines. However, the measured values determined here may be subject to inaccuracies or the superposition of several unfavorable effects on the respective communication, so that the meaningfulness of a measurement is not always high and therefore a network fault is not always determined with sufficient reliability.

 It is an object of the invention to overcome the disadvantages mentioned and to provide a method which detects a network state with a network fault with high reliability.

 The object is achieved by a method of the type mentioned in that, when the structure of the communication topology is changed, a comparison is made with weather data, in which a temporarily changed communication topology with geographic and temporally assigned weather data, which is preferably transmitted by the monitoring device via data interface are received, connected and this is taken into account when determining the network status, preferably from the communication topology.

It is clear that the temporarily changed communication topology with geographically and temporally assigned weather data on those segments of the communication topology or se of the communication network is compared or correlated at which the temporary change in the communication topology occurs.

 The weather data can be received by the monitoring device via a corresponding data interface, for example from online services for weather forecasting and / or weather data acquisition or corresponding sensors which are connected to the monitoring device.

 Nowadays, intelligent electricity meters, so-called smart meters, are often used in low-voltage networks. Such low-voltage networks are referred to as intelligent low-voltage networks or smart grids, in which, for example, a simple and inexpensive remote reading of the meter reading of an intelligent electricity meter is possible.

 A measuring method for determining communication parameters can be carried out with a smart meter or also with other measuring devices with a corresponding communication interface for communicating with a smart meter, for example with a measuring device for determining line parameters. Consequently, the term smart meter also includes other suitable measuring devices and the energy supply system can also include combinations of smart meters and other measuring devices.

Information from the individual smart meters or the analysis of the data transmission quality or the topology of the data transmission network from remote access processes should be used to estimate the network status of the low-voltage network. It is also possible to draw conclusions about the current network status, for example switch settings in the low-voltage network, this information also being sent to a SCADA system (Supervisory Control and Data Acquisition). sition) can be forwarded. Unsupported networks could be automatically recognized by appropriate algorithms within the monitoring device.

 The use of technologies of neural networks is conceivable, whereby, for example, the selection of further network lines, which are subsequently to be analyzed, can be initiated automatically on the basis of an individually determined critical supply state of an individual network line.

Changes in the communication quality of intelligent electricity meters, taking into account the connection and communication topology and linking with additional data (such as weather information), allow conclusions to be drawn about the supply status in the network. This makes it possible to avoid malfunctions by means of appropriate forecasting.

The method according to the invention makes it possible for the supply status of individual, several or even all network lines in the low-voltage network to be determined in a targeted manner and, if appropriate, appropriate measures to be taken. By using the electronic remote query of smart meters, the method according to the invention is extremely easy to integrate even in existing smart grids.

By means of the method it can be achieved that, for example, the network status can be determined in a simple manner by means of remote queries from a central monitoring device, which has a computing unit and a memory, and corresponding maintenance, servicing and repair work before the emergence of a potential partial o - the total power failure can be planned and carried out. Material fatigue or wear of transformers, switches or lines or parts thereof can be detected with a certain probability in advance. The network status is determined by analyzing a change in the structure of a communication topology compared to the structure of a network topology.

In addition, communication parameters that change over time, for example in the quality of the communication, can give an indication of a defect or aging in a line, a switch or the like. The change over time can be observed and analyzed over a short period as well as over a long period of time.

For example, weather influences, seasonal or working time influences, or also operational influences can be compared with a change in the structure of a communication topology by associating a temporarily changed communication topology with the geographically and temporally assigned weather data provided.

The weather data can, for example, be provided by databases or online services using a database and stored in a memory of the monitoring device. A time and / or a time span, as well as a location and / or an area are linked for each weather data record. Each weather data record can be correlated or compared with a segment of the network topology and communication topology. Each weather data record can relate to future (for example, predicted by weather models with artificial intelligence), current or past (for example, recorded and recorded by sensors) times. The method can also use a combination of several weather data sets in order to carry out an analysis of the network status based on the communication topology. In a development of the invention, it is provided that more than one network line or more than one communication path is correlated with corresponding weather data. This can further improve the reliability of the method.

 The result of this is that a detected change in the communication topology is verified by an independent, further measurement variable in the form of weather data and the detection of a network fault can be carried out more reliably than in the prior art.

 It is clear that the time and location of the network disruption and the corresponding weather data are closely related, for example directly or predicted.

 It is also clear that an associated location can be determined in a simple manner for a segment of a communication path that has been determined to be faulty, for example by looking at maps or maintenance tables.

 It is also possible that changes in the network topology are recorded if, for example, repair work is carried out in the low-voltage network and a network line is therefore switched off. A power line can also be switched off for targeted troubleshooting. In these cases, a change in the communication topology can be determined on the changed network topology and examined.

For example, combinations of several communication parameters of different network lines can also give an indication of a fault, in particular a time history of changes in the communication parameters.

In an analogous manner to the method according to the invention, the object of the invention is also achieved by a device of the The type mentioned above is solved in that when the structure of the communication topology is changed, it is compared with weather data, in that a temporarily changed communication topology is associated with geographically and temporally assigned weather data, which are received by the monitoring device via a data interface, and this is taken into account when determining the network state, preferably from the communication topology.

 Advantageous refinements and developments of the inven tion are specified in the dependent claims. The advantages arise both for the method according to the invention and for the device according to the invention.

The at least one communication parameter can be from a link quality index parameter of the respective Smartme

be determined.

The link quality index parameter can be determined from the signal-to-noise ratio of a remote inquiry process.

The at least one communication parameter and / or the communication topology can be determined from routing information which describes the communication path between the at least one gate way and the respective smart meter.

The at least one communication parameter can be determined from the duration of the time difference between sending the at least one query telegram and receiving the associated response telegram of a respective remote query process.

A first remote query process and at least one second remote query process can be carried out repeatedly, with the first remote query process and the at least one second Remote inquiry process a change in the communication topology and / or the network topology can be determined, from which the network state is determined.

The network topology is detected by the monitoring device. This enables a configuration of the low-voltage network to be stored in a simple manner for use in the method according to the invention. It is advantageous if the network topology is stored in the form of a list in a data storage device of the monitoring device and can be changed.

It is advantageous if the query telegram comprises a counter status query or an operating status query of the respective smart meter. As a result, the at least one communication parameter can be determined in a particularly simple manner.

In a development of the invention, it is provided that the determination of the at least one communication parameter is carried out by querying the meter reading or querying the operating state of the respective smart meter, thereby reducing the communication. PLC communication on power networks often has a very low data transfer rate.

 Further advantageous properties of the invention result from its exemplary explanation with reference to the figures. The figures show in

 La is a block diagram of a first game Ausführungsbei a low-voltage network,

 1b shows a schematic representation of a network topology of the low-voltage network according to FIG.

1c shows a schematic representation of a communication topology of the low-voltage network according to FIG. 2a is a block diagram of a second exemplary embodiment of a low-voltage network,

 2b is a schematic representation of a network topology of the low-voltage network according to FIG. 2a,

2c is a schematic representation of a communication topology of the low-voltage network according to FIG. 2a,

3a is a block diagram of a third exemplary embodiment of a low-voltage network,

 3b is a schematic representation of a network topology of the low-voltage network according to FIG. 3a,

3c is a schematic representation of a communication topology of the low-voltage network according to FIG. 3a,

Fig. 4 is a schematic representation with an embodiment

 example of a query procedure for a smart meter,

 5a is a schematic representation for a remote query operation with telegrams according to FIGS. La-lc,

2a-2c and 3a-3c,

 5b is a schematic representation of a further exemplary embodiment for a remote inquiry process with telegrams,

 5c is a schematic illustration of a further exemplary embodiment for a remote inquiry process with telegrams,

 Fig. 5d is a schematic representation of another exemplary embodiment from a remote inquiry process with telegrams.

The exemplary embodiments show important parts of the invention, it being clear that further components may be necessary for the method and the device according to the invention, such as electrical end consumers, generally known infrastructure for operating a low-voltage network, such as transformers or circuit breakers, but also control and data processing devices. For a better overview, these components are not shown.

 In Fig. La is a first embodiment of a device for determining the network state of a low voltage network 1 of a power supply system 2 shows schematically ge.

The energy supply system 2 has a first network line 111 with a first smart meter 101 and a plurality of second network lines 112-119 with associated second smart meters 102-109. Electrical consumers can be connected to the smart meters 101-109.

With the respective smart meters 101-109, for example, the power consumption of the consumer can be measured by remote reading from a remote data processing device, or the consumer can be connected to the low-voltage network 1 or separated from the network by remote control from a remote control device.

Instead of or in addition to the respective smart meters 101-109, other measuring devices with a corresponding communication interface can also be used, for example measuring devices for determining special line parameters. These measuring devices can, for example, be temporarily integrated into the low-voltage network 1 to assist in troubleshooting. However, this aspect is not dealt with in more detail in this exemplary embodiment. The first power line 111 and the second power lines 112-119 form a network topology 110 of the low-voltage network 1, which is shown separately in FIG. 1b.

The power supply system 2 also has a communication system with a gateway 3 and a smart grid server 5. The smart grid server 5 supports the electronic operation of the energy supply system 2, that is to say, for example, by electronic remote reading of the meter values of the individual smart meters 101-109 or by the general control of the smart meters, such as switching on and off a single power line 111-119.

Alternatively, not shown here, the monitoring device 4 can be connected to the smart grid server 5, wherein communication via the gateway 3 can take place by means of the smart grid server 5. This can simplify the system.

 The gateway 3 can, for example, be an IP router based on powerline communication (PLC) technology, the communication taking place via the electrical supply network of the low voltage network 1.

 In this exemplary embodiment, the smart meters 101-109 are connected to the gateway 3 in a star or tree shape by the power lines 111-119.

 In this example, in the tree hierarchy of the low-voltage network 1 secondary network lines 116-118, the slave smart meter 106-108 with the master smart meter 102 or the secondary network line 119 of the slave smart meter 109 with the master Smartmeter 105 connected.

With master smart meters 101-105, smart meters are in the first hierarchical level of a tree, i.e. in a star-shaped Order meant. In other words, those that can communicate directly with the gateway 3.

 Slave smart meters 106-109 refer to smart meters in the second hierarchical level of the tree, but in practice many more hierarchical levels can be used in trees. In other words, those who cannot communicate directly with the gateway 3, but only via a master smart meter 102, 105.

 Communication between the gateway 3 and the slave smart meter 109 thus takes place by routing via the master smart meter 105, that is to say via the power lines 115 and 119.

The communication system is set up to connect the first smart meter 101 and the second smart meter 102-109 to the gateway 3 via a respective communication path and to communicate by means of at least one remote inquiry process 10, 20, 30, 40, 50, 60. The communication system is based on Powerline Communication (PLC) technology.

The gateway 3 can be connected to the smart grid server 5 via a wired or wireless broadband data line.

The communication paths form a communication network with a communication topology 120, which is shown separately in FIG. 1c. In this exemplary embodiment, the network topology 110 corresponds to the communication topology 120.

The remote query processes 10, 20, 30, 40, 50, 60 each include a query telegram 11, 21, 31, 41, 51, 61 and a response telegram 12, 22, 32, 42, 52. The query Telegram 11, 21, 31, 41, 51, 61 also has a meter reading query or an operating status query of the respective smart meter 101-109. Examples of remote inquiry processes 10, 20, 30, 40, 50, 60 are shown in FIGS. 5a-5d.

 In Fig. 2a is a second embodiment of a device for determining the network state of a low-voltage network 1 of a power supply system 2 shows schematically ge. A network topology 210 with network lines 211-219 is identical to the network topology 110 of FIG. 1 a, as can be seen in FIG. 2 b.

However, a communication topology 220 differs from the communication topology 120.

The communication path 125 to the smart meter 105 from the first exemplary embodiment is disturbed in the second exemplary embodiment. Instead, the smart meter 105 communicates via the communication path 224 and 225.

The fault can be caused, for example, by aging of components of the low-voltage network, weather influences or seasonal influences. Furthermore, malfunctions due to operational or load-dependent influences are possible, which occur, for example, during working hours and not on weekends.

Operational influences include maintenance and repair work, the replacement of parts of the low-voltage network, the switching over of power lines, for example from alternative transformers or lines.

Load-dependent influences include the switching on of consumers with high interference voltages at specific frequencies, which can be coupled into the low-voltage network and the quality of the communication network. can adversely affect zes, as well as the addition and disconnection of large consumers.

The quality of the communication network can be influenced, for example, by changing the signal transit times (round trip), the number of tree levels in a communication topology (number of hops in a connection) or a poor signal-to-noise ratio.

In addition, the communication path 128 to the smart meter 105 of the first exemplary embodiment could not be established, but rather the smart meter 108 communicates in the second exemplary embodiment via the communication paths 224, 225 and 228.

The network topology 210 of the second embodiment with the network lines 211-219 corresponds structurally to the network topology 110 of the first embodiment.

The tree-like communication topology 220 of the second exemplary embodiment is shown in FIG. 2c. An additional level can be seen in the communication topology 220 compared to the communication topology 120, which is caused by the communication path 225.

 In Fig. 3a is a third embodiment of a device for determining the network state of a low-voltage network 1 of a power supply system 2 shows schematically ge.

As can be seen in FIG. 3b, a network topology 310 with network lines 311-319 to network topology 110 of FIG. La differs in that network line 125 to smart meter 105 of the first exemplary embodiment in FIG. La is interrupted. Subsequently, the power line 119 to the smart meter 109 is also interrupted. Thus, the third exemplary embodiment in FIG. 3a has only power lines 311-314 and 316-318.

However, a communication topology 320 differs significantly from the communication topologies 120 and 220. The smart meter 109 is connected to the smart meter 108 via a communication path 319, in spite of a faulty network line. The smart meter 109 can thus communicate with the gateway 4 via the communication paths 322, 328 and 329.

The network topology 310 of the third exemplary embodiment thus differs structurally from the network topologies 110 and 210.

The tree-like communication topology 320 of the third exemplary embodiment is shown in FIG. 3c. An additional level can be seen in the communication topology 220 compared to the communication topology 120, which is caused by the communication path 329.

The energy supply system 2 also has a monitoring device 4 with a computing unit and a memory, which is connected to the at least one gateway 3.

The energy supply system 2 is set up to carry out the following method steps of a method 500: a) Sending 510 a query telegram 11, 21, 31, 41, 51, 61 of a remote query process 10, 20, 30, 40, 50, 60 to the first smart meter 101 and the at least one second

Smart meter 102-109, b) determining 520 properties of the communication between the at least one gateway 3 and the first smart meter 101 and / or the at least one second Smart meter 102-109 as at least one communication parameter from at least one query telegram 11, 21, 31, 41, 51, 61 by the respective smart meter 101-109, c) transmitting 530 a response telegram 12, 22, 32, 42, 52 of the remote query process 10, 20, 30, 40, 50, 60 to the monitoring device 4, which comprises the at least one communication parameter, d) acquiring 540 the communication topology 120, 220, 320 of the first smart meter 101 and the at least one second Smart meters 102-109 from the at least one response telegram 12, 22, 32, 42, 52 by the monitoring device 4, e) determining 550 the network state of the low-voltage network 1 from the at least one communication parameter 6, the network topology 110, 210, 310 and the communication topology 120, 220, 320 by the monitoring device 4.

The method 500 is shown separately in FIG. 4. In this example, the method steps are carried out by the monitoring device 4, but can also be carried out by other suitable system parts if no special monitoring device should be provided and only a logical assignment of system parts seems to make sense.

5a shows a counter reading query for the remote query processes 10, 20, 30.

In the remote inquiry process 10, a meter reading query “MeterRead” from the smart meter 109 takes place in the query telegram 11, which delivers a return parameter set in the response telegram. Depending on the configuration of the smart meter 109, different response telegrams 12, 22, 32 can be sent. The response telegram can also be configured directly in the query telegram. This aspect is not shown in the figure.

The at least one communication parameter in the form of a parameter set can be determined from a link quality index parameter LQI, which the respective smart meter 101-109 can determine. Alternatively, corresponding parameters can be determined in the gateway 3, stored there and called up by the monitoring device 4.

The link quality index parameter LQI can be determined from the signal-to-noise ratio at least from parts of at least one remote inquiry process 10, 20, 30, 40, 50, 60.

The at least one communication parameter and / or the communication topology 120 can include routing information RI.

The routing information RI describes the communication path between the gateway 3 and the respective smart meter 101-109 and can be determined by the respective smart meter 101-109.

5a, the smart meter 109 is configured such that the return parameter set in the respective response telegram 12, 22, 32 provides routing information RI via which communication paths the communication with the smart meter 109 took place. The respective response telegram 12, 22, 32 can be enriched by the gateway 3 with the routing information RI, or the gate way 3 can send a separate query of smart meter parameters to a smart meter, and the respective response telegram 12 , 22, 32 from the routing information RI, which were determined by the gateway 3, and put together the smart meter parameters from the separate query.

In the response telegram 12, the parameter set contains the counter number 109, the counter value 500.0 kWh and the routing information RI. In this first example, communication took place via communication paths 125 and 129.

The parameter set contains the counter number 109, the counter value 500.0 kWh and the routing information RI in the response telegram 22. In this second example, communication took place via communication paths 224, 225 and 229.

The parameter set contains the counter number 109, the counter value 500.0 kWh and the routing information RI in the response telegram 32. In this example, communication took place via communication paths 322, 328 and 329.

5b shows a counter reading query for the remote query process 40.

In the remote inquiry process 40, a meter reading query “MeterRead” from the smart meter 109 takes place in the inquiry telegram 41, which delivers a return parameter set in the reply telegram 42.

In the example of FIG. 5b, the smart meter 109 is configured such that the return parameter set in the response telegram 42 supplies a link quality index value LQI via which communication paths the communication with the smart meter 109 took place.

In the response telegram 42, the parameter set contains the counter number 109, the counter value 500.0 kWh and the LQI value 0.47.

5c shows an operating status query for the remote query process 50. In the remote inquiry process 50, an inquiry of the operating status “ping” of the smart meter 109 takes place in the inquiry telegram 51, which delivers a return parameter set in the answer telegram 52. The parameter set contains the counter number 109 and the number in the answer telegram 52 Routing information RI. In this example, communication took place via communication paths 122 and 126.

The at least one communication parameter can also be determined from the duration of the time difference between sending T_START of the query telegram 51 and receiving T_STOP of the associated response telegram 52 of the remote query process 50.

FIG. 5d shows an example of a further remote inquiry process 60. The method steps a) to e) can also be carried out repeatedly, for example in the form of a first remote inquiry process and a second remote inquiry process.

For example, a change in the communication topology 120, 220, 320 and / or the network topology 110, 210, 310 from which the network status can be determined can be determined from the first remote inquiry process and the second remote inquiry process.

If no corresponding response can be received to the query telegram 61 of the remote query process 60 (that is to say a "timeout" has been determined), the communication system can continue for a predetermined time after the T_START has been sent after the query telegram 61 terminate further reception and the unanswered query telegram 61 of the remote query process 60 accordingly pretend. Optionally, query telegram 61 can be transmitted repeatedly.

A missing response telegram in the remote inquiry process 60 can be interpreted as a transmission error in the respective network line and the remote inquiry process 60 can be regarded as complete.

The network topology 110 or its changes can be recorded manually by a user in the monitoring device 4, or, for example, also via a corresponding data interface with other devices for maintaining, monitoring or controlling the low-voltage network 2.

The storage of the network topology 110 can follow it in the form of a list in a data memory of the monitoring device 4.

The determination of the supply status of the low-voltage network can be done in different ways, as explained in more detail below.

 For example, a change in the communication path 125 of FIGS. 1a-1c to the communication path 224, 225 of FIG

2a-2c the conclusion that the power line 215 is disturbed by a consumer or weather influences. If the temporarily changed communication topology 220 is associated with geographically and temporally assigned weather data, it can be concluded, for example, that the line 215 or its connections are better against rain or

Storm must be protected. This conclusion can be strengthened by the fact that the smart meter 108 now communicates via the communication path 228 via the line 218 that is close to the storm.

In further examples, not shown, the communication parameters can also be combinations of the communication parameters. be meters. Furthermore, other communication parameters, which are not detailed, can also be used for the method according to the invention, which describe the transmission quality of the data communication of a remote inquiry process between a smart meter and the gateway via network lines.

In the preceding figures, it is not separately illustrated how the comparison of the communication topology 120, 220, 320 with weather data takes place according to the invention in the monitoring device 4.

 If such a change in the communication topology 120, 220, 320 is detected, its geographical location is determined and corresponding weather data at the respective location at the time of the network disruption from a corresponding online service, a database of weather forecasts or weather recordings stored, seasonal weather information from an experience -Database or similar determined.

 The change in the structure of a communication topology 120, 220, 320 is compared with the determined weather influences or seasonal influences, in that a temporarily changed communication topology is associated with geographically and temporally assigned weather data, and this when determining the network status from the communication topology 120 , 220, 320 is taken into account.

In other words, when the structure of the communication topology is changed, a comparison with weather data is carried out in that a temporarily changed communication topology is associated with geographic and temporally assigned weather data, which are received by the monitoring device 4 via a data interface, and this during the determination the network status is taken into account. Reference symbol list:

 1 low voltage network

 2 energy supply system

 3 gateway

 4 monitoring device

 5 smart grid servers

 10, 20, 30,

 40, 50, 60 remote access operation

 11, 21, 31,

 41, 51, 61 query telegram

 12, 22, 32,

 42, 52 response telegram

101-109 smart meter

 110, 210, 310 network topology

 111-119, 211-219,

 311-318 power lines

 120, 220, 320 communication topology

 121-129, 221-229,

 321-329 communication path

 500 procedures

 510, 520, 530,

540, 550 process steps

LQI Link Quality Index

RI routing information

 T START send timestamp of a query

Telegram

 T_STOP receive timestamp of a reply

Telegram

Claims

Claims

1. A method for determining the network state of a low-voltage network (1) of an energy supply system (2), and the energy supply system (2) has network lines (111-119, 211-219, 311-319) with respective smart meters (101-109), which form a network topology (110, 210, 310) of the low-voltage network (1), and communication paths between smart meters (101-109) and at least one gateway (3) using powerline communication technology on the network lines (111-119,

211-219, 311-319) are generated, which together form a communication network with a communication topology (120, 220, 320), and properties of the communication, comprising routing information (RI), which defines the communication path between the at least one gateway (3) and the respective smart meter (101-109) describe, as at least one communication parameter determined by the respective smart meter (101-109), from which the communication topology (120, 220, 320) is determined, and the network status of the Low-voltage network (1) is determined by comparing the network topology (110, 210, 310) with the communication topology (120, 220, 320) by the monitoring device (4), a change in the structure of the communication topology compared to the structure of the network topology being analyzed is characterized in that when the structure of the communication topology is changed, it is compared with weather data by a temporarily changed co Communication topology with geographically and temporally assigned weather data, which are received by the monitoring device (4) via a data interface, is connected and this is taken into account when determining the network status.

2. The method according to the preceding claim, wherein more than one network line (111-119, 211-219, 311-319) or more than one communication path is correlated with corresponding weather data.

3. The method according to any one of the preceding claims, wherein the determination of the at least one communication parameter by a meter reading query or an operating status query of the respective smart meter (101-109).

4. Device for determining the network state of a low-voltage network (1) of an energy supply system (2), comprising at least one gateway (3) and a monitoring device (4), and the energy supply system (2) network lines (111-119, 211- 219, 311-319) with respective smart meters (101-109), which form a network topology (110, 210, 310) of the low-voltage network (1), and the energy supply system (2) is set up for this: a) Communication paths between smart meters ( 101-109) and the at least one gateway (3) using powerline communication technology on the network lines (111-119, 211-219, 311-319), which together form a communication network with a communication topology ( 120, 220, 320), and b) properties of the communication, comprising routing information (RI), which describe the communication path between the at least one gateway (3) and the respective smart meter (101-109), as at least one Communication parameters through the respective smart meter (101-109) to determine from which the communication topology (120, 220, 320) is to be determined by the monitoring device (4), and c) the network state of the low-voltage network (1) from a comparison of the network topology (110, 210, 310) with the communication topology (120, 220, 320) by the monitoring device (4), wherein a change in the structure of the communication topology compared to the structure of the network topology is analyzed, characterized in that a change in the structure of the communication topology It is compared with weather data by associating a temporarily changed communication topology with geographically and temporally assigned weather data, which are received by the monitoring device (4) via a data interface, and this is taken into account when determining the network status.