WO2020193057A1

WO2020193057A1 - Electrical energy transmission device and analysis method

Info

Publication number: WO2020193057A1
Application number: PCT/EP2020/055219
Authority: WO
Inventors: Stefan Giere; Matthias Heinecke; Thomas Hilker; Robert Knuth; Benjamin Zaedow
Original assignee: Siemens Aktiengesellschaft
Priority date: 2019-03-28
Filing date: 2020-02-28
Publication date: 2020-10-01
Also published as: EP3928393A1; DE102019204313A1; CN113812050A

Abstract

The invention relates to an electrical energy transmission device having a condition detection arrangement, which electrical energy transmission device comprises a switching unit (8) and at least a first data deliverer (6a) and a second data deliverer (6b). Both data deliverers (6a, 6b) are connected to a first interface (7) of the switching unit (8).

Description

description

Electrical energy transmission device and analysis method

The invention relates to an electrical energy transmission device with a state detection arrangement having a switching device and at least one first data supplier, which is connected to a first interface of the switching device.

An electrical energy transmission device is used to transmit electrical energy. It is known to equip electrical energy transmission devices with a state detection arrangement which has a switching device and at least one first data supplier which is connected to an interface of the connecting device. With increasing automation, it is desirable to receive a large number of information from an electrical power transmission device and to process them accordingly. With increasing amounts of information, greater demands are placed on the performance of the switching devices. Correspondingly, the effort for an improved information acquisition at Elektroenergieübertra transmission devices increases.

Therefore, the object of the invention is to provide an electrical energy transmission device which enables an improved use of a switching device with an increased number of information supplied.

According to the invention, the object is achieved with an electrical energy transmission device of the type mentioned at the outset in that a second data supplier is connected to the first

Interface is connected.

Electrical energy transmission devices are devices which are used to transmit electrical energy. Electrical Energy transmission devices are, for example, disconnectors, earthing switches, load switches, circuit breakers, instrument transformers, gas-insulated switchgear, outdoor bushings, surge arresters, transformers in outdoor and indoor versions, etc. Driven by a voltage difference, an electrical current is carried within a phase conductor. The phase conductor must be electrically insulated accordingly. The operational safety of an electrical energy transmission device is determined, among other things, by the insulation strength of the insulation medium used (electrically insulating medium). In this respect, the condition of the insulation medium is important information for making statements regarding the operational safety of the electrical energy transmission devices. The insulation media generally extend over greater distances, so that on the one hand monitoring that is as precise as possible is desired, but on the other hand the effort for such monitoring is high. Fluids that wash around a phase conductor, for example, are used as the insulation medium. Gaseous fluids in particular have proven to be suitable. These are to be housed accordingly in capsule housings, within which a phase conductor is at least partially arranged. There the electrically insulating medium washes around the phase conductor and ensures electrical insulation.

By means of a first data supplier, data on the condition of the insulating medium or other information on the condition, such as temperatures, changes in mass, arcing phenomena, etc., can be recorded. When using a first data supplier and a second data supplier, it should advantageously be provided that the data suppliers who are connected to the same interface allow the detection of similar states (Zu

status information). For example, the first data supplier and the second data supplier can determine data relating to the density of an electrically insulating serving medium. Alternatively, the first and the second data provider can also provide different status information. It is also possible, for example, for several data providers, which are assigned, for example, to electrically insulating media that act independently of one another, to transmit data about similar states of the respective media to the first interface. For example, it can be provided that, in the case of electrical insulation of an electrical energy transmission device, several electrically insulating gas spaces sealed off from one another with corresponding enclosed electrically insulating fluids are used, whereby the information about the state, in particular the density of the electrically insulating fluid in mutually different gas spaces is recorded will. Thus, for example, with multi-phase electrical power transmission devices, for example with DC transmission, a phase conductor to the forward and a phase conductor to the return of an electric current from the first data supplier and the second data supplier can be monitored. In the case of a multiphase AC voltage system, for example, different phases of the AC voltage system can be monitored by the first and the second data provider. Accordingly, it is possible to feed information from the first data supplier and the second data supplier into one and the same interface and thus monitor several sections.

The switching device can have a first interface and, in addition to the first interface, further interfaces. Thus there is the possibility of one

Use the interface of the switching device to record several data suppliers and thus, for example, carry out a local division and / or a logical link between the individual data suppliers. The first or a further interface can be analog interfaces or digital interfaces. However, it is preferable to use an analogue interface. hen to connect several data providers with one and the same analog interface. A connection can be made wired or wired free. A switching device can be designed, for example, in the form of a so-called data gateway, within which the information of the data providers that acts in different ways or is provided in different formats is concentrated. Preprocessing can take place in the switching device, and the data supplied by the data providers can, if necessary, be temporarily stored and / or formatted. For example, it is possible to use the switching device as an interface and to connect it to a computer cloud, for example, in order to be able to process data there about a state of an electrically insulating fluid. The computer cloud can then, for example, serve as a processing device in order to undertake a further evaluation of the possibly preprocessed data. The processing device can also provide the data supplied with a time marker.

It can further be provided that the first and the second data supplier simultaneously provide complementary data to the first interface.

The data transmitted from the first and second data suppliers to the first interface can be made available to the first interface at the same time. It can happen that these data are superimposed on one another and made available to the first interface in superimposed form. In the case of an analog interface in particular, the analog signals supplied by the data suppliers can complement or compensate each other, so that the resulting information from the first and second data suppliers is transferred to the first interface of the switching device. By selecting the limit values accordingly, it can be ensured that, for example, if a limit value is exceeded, at least one of the data lines feranten, even after the information (data) supplied by the two data suppliers to the first interface is superimposed, the limit value can be found to be exceeded. Particularly in the case of an analog evaluation, provision should be made for similar information supplied by the first data supplier and the second data supplier to complement each other in a positive and negative sense (same polarity), thus ensuring reliable evaluation of faults in the electrical energy transmission device is secured.

For example, analog measured values that are supplied by the data suppliers can be transmitted in phase to the first interface from the first and the second supplier. This enables the information supplied by the first interface and the second interface to be continuously added.

A further advantageous embodiment can provide that data from the first and second data suppliers are made available to the first interface in a timed manner.

The data supplied by the first and second data suppliers can be made available to the first interface in a timed manner. For example, the information from the first and second data suppliers can be transmitted to the first interface in succession. This avoids overlaying the information supplied by the data provider to the same interface. For example, this can be done in such a way that a multiplexer is used to assign information from the first data supplier and the second data supplier to the interface over time. Instead of a multiplexer, clocking can also be done by the data providers themselves. In order to enable the data to be identified and to keep the data processing effort low (regardless of how the clocking takes place), a time signal can be assigned to the respective information from the first data supplier or from the second data supplier and this time signal can also be assigned to higher-level processing devices are transmitted, so that a temporal breakdown of the information supplied by the first and second data providers is possible, please include.

A further advantageous embodiment can provide that the data from the first and second data suppliers are clocked in an asymmetrically distributed manner.

In addition to symmetrical clocking, i.e. H. The data from each data supplier is provided with an equally large time window for transmission to the first interface; asymmetrical clocking can also be provided. I.e. one of the data providers is assigned a different time interval. The other data provider (s) can each be allocated the same time window. Thus, it is possible to identify a starting point from a sequence of information from Datenliefe that are clocked in time and to carry out an automated reset even if the system falls out of step in order to, for. B. to trigger a restart of the system. Furthermore, the asymmetrical clocks can also regularly check and compare the transmitted information, since the different time clock can be used as test information.

A further advantageous embodiment can provide that the first and the second data supplier are connected to the switching device via a common line, a security device being arranged in the common line. When several data suppliers are connected to one and the same interface, in particular at an analog interface, the superimposition of several signals supplied by the data suppliers z. B. in the case of simultaneous transmission or incorrect timing, an electrical overload of the line can occur. Particularly in the case of simultaneous transmission and a parallel arrangement of a large number of data providers at one and the same interface, the permissible load values with regard to a current intensity on the common line can be exceeded. By means of an appropriate safety device, it is possible to prevent electrical overloading of the line and to prevent damage to the line.

It can advantageously be provided that the fuse device has a current divider.

The signal transmitted from the data provider to the switching device can be in the form of a variable electrical current. The addition of currents can, under certain circumstances, lead to an electrical line overload. By using appropriate resistors, the maximum current to be fed into the interface can be limited. This normalizes the maximum permissible current strength at the first interface, which is an analog interface, for example. The flow divider should advantageously be designed in such a way that when a single data supplier is addressed, its full bandwidth with regard to the input flows supplied is permitted. In particular with an electrical parallel connection of several data suppliers, for example density sensors, overloading of the first interface can thus be prevented. A further advantageous embodiment can provide that the first and the second data supplier deliver status information via an electrically insulating medium.

In particular, status information about an insulation medium is important for a description of the operational safety of an electrical energy transmission device. For example, the temperature of the insulation medium or the density of the insulation medium can provide information on whether the insulation strength of the same is still given. In particular, in the case of fluid insulation media, the density allows sufficient information about the insulation strength. The density enables temperature and pressure-independent information about the insulation strength of the insulating medium. If necessary, a standardized detection of the pressure based on a standardized temperature (for example 20 ° C. ambient temperature) can also take place, so that information about the insulation strength of the insulating medium can also be obtained in this way.

For example, it is possible to record the density of an insulating medium with several data suppliers, so that on the one hand, for example, a redundant system can be created in which several data suppliers monitor the same electrically insulating medium. However, it can also be provided that different insulating media or insulating media separated from one another are monitored by different sealing suppliers and their information is transferred to one and the same interface of the switching device. For example, it is possible to monitor different phase conductors, which are electrically isolated from one another by means of an insulating medium, with regard to their insulation strength by different data providers, and to feed this information into one and the same interface. This is particularly advantageous when a multi-phase electrical power transmission system is used, the several phases of which are electrically separated from separate insulating media to be isolated. In this case, the failure or impairment of an insulation resistance on one of the phases is a sufficient criterion to question the transmission security of the entire multi-phase AC voltage system. Alternatively, several isolation media that act individually from one another can also be used along one and the same phase conductor, each of which is in turn monitored in sections by a separate data supplier.

Another object of the invention is to provide an analysis method for the state of an electrically insulating medium of an electrical energy transmission device in a suitable manner, which method makes inexpensive, simple statements about the state of the electrically insulating medium.

According to the invention, the object is achieved in an analysis method of the state of an electrically insulating medium of an electrical energy transmission device in that data on the state, in particular the insulation strength of an electrically insulating fluid are received from a processing device, that the transferred data are processed and output in a chronological sequence and when at least one first limit value is reached and / or when at least one first limit value is predicted to be reached, a warning is output.

An electrically insulating medium ensures the electrical insulation of a phase conductor. Depending on external influences, the insulation strength of the electrically insulating medium can be impaired. For example, contamination on solid insulators or fluid insulating media can reduce their insulation strength. However, the loss of insulation media, for example through leaks in containers that house a fluid insulation medium, or through abrasion on solid insulators, can lead to restrictions in terms of insulation strength. lead activity. Data on the condition, in particular the insulation resistance of an electrically insulating fluid z. B. represented by a density, for example, a switching device is made available by data providers. Standardization and transmission of data to a processing device can take place via the switching device. The processing device is supplied with the data either indirectly or directly from the switching device, so that the processing device can process the data on the state of the electrically isolating medium. In particular, the transferred and / or processed data can be sequenced over time. For example, it is possible to show the changes over time in the transferred or processed data and the changes over time in the transferred or processed data. A temporal assignment of the data can take place, for example, in a switching device from which data is transferred directly or indirectly. By using a first limit value, it is possible to issue a warning when the same is reached by the transferred data or the processed data. In addition to reaching the limit value by the transferred or processed data themselves, a predicted reaching of the first limit value can also be determined and a warning can also be issued when the predicted data reaches the first limit value. In particular, if a limit value is predicted to be reached, the point in time of which is far in the future, the issuing of a warning can be suppressed. For example, it is possible to define a period within which a predicted reaching of a limit value must lie in order to issue a warning. For example, this period can be several days, e.g. B. several 10 days, such as 90 days from the current date, are in the future. The transferred or processed data can be displayed consecutively in time. For example, certain status information can be displayed at certain times. so that a change over time can be recognized. For example, it is possible to display the course of the insulation strength of the electrically insulating fluid and, on the basis of the data transferred, to make a prognosis for the future of how z. B. the density of the electrically insulating fluid will change.

A graphic representation for outputting the chronological sequence can preferably be provided. If necessary, different time periods can be displayed: z. B. predefined time periods, week, month, year or a free definition of the desired period.

The data received and processed by the processing device can be stored locally and can also be used again. The data are preferably available in a computer cloud so that simplified access to them is guaranteed.

Furthermore, it can advantageously be provided that a location coordinate is assigned to the data of the time sequence.

In addition to information about the density of the electrically insulating fluid, the data of the time sequence can be assigned a location coordinate. This assignment can already be contained in the transferred data, for example in the data transferred from a switching device, so that the data can be clearly identified locally. This makes it possible, for example, to be able to provide further information, in particular with regard to a prognosis of the development of the density of the electrically insulating fluid. For example, the location coordinates corresponding climatic conditions such. B. Temperatures at the time of the acquisition of the data, weather phenomena such as lightning strikes or the like assigned and taken into account in the prognosis. Another advantageous embodiment can provide that the first limit value has a first and a second stage.

The first limit value can have a first stage and a second stage. For example, depending on the definition of the levels, a warning can be issued when the first level is reached, whereas when a second level is reached, in addition to the warning, for example, an instruction can be issued. For example, it is only possible to give a warning only when the first level is reached, for example in order to carry out increased observation, whereas a shutdown can be triggered when the second level is reached. The two-stage approach enables preventive measures to be taken in order to prevent the second stage from being reached. It is thus possible, for example, to use a prognosis of the second stage to predict a time window within which a repair or maintenance of the monitored electrical energy monitoring device is to be provided. If necessary, time windows can be defined for outputting forecasts of the achievement of the first and second stage. If necessary, with reaching the level limit z. B. checklists, training videos etc. are provided, which contain the necessary instructions for the operator.

By linking location coordinates, further instructions can also be made available (via the respective local event) for a group of sections of the electrical energy transmission system.

For example, in the event of a local event in a switching station, situation-dependent maintenance can be triggered for the entire switching station.

A further advantageous embodiment can provide that a forecast of the development of the insulation strength is below Consideration of switching operations of the electrical energy transmission device takes place.

The electrically insulating medium can be changed in its insulating properties by switching operations of the electrical energy transmission device. If switching operations of the electrical energy transmission device are carried out accordingly, a faster aging of the electrically insulating fluid can be expected, for example. Based on the nature of the switching operations or the frequency or the intensity of the switching operations, conclusions can be drawn about changes in the electrically insulating fluids, so that the cause can be taken into account or, for example, when forecasting the achievement of limit values the switching operations expected in the future can flow into the prognosis, so that a more precise prediction of the attainment of the first limit value or the two stages of the first limit value can be made.

The prognosis can be checked and adjusted accordingly depending on the switching operations that actually occur.

It can also be provided that an expected change in the insulation strength is stored within a certain period of time.

Due to the natural aging of the electrically insulating fluid, the insulation strength of the fluid can change. For example, the electrically insulating fluid may naturally volatilize. This leads to an expected change in density within a certain period of time. This expected change in density can be taken into account for correcting or evaluating the state of the electrically insulating fluid. For example, it is possible to store the expected change in density and to compare the expected change in density with the actually occurring change in density during a certain time interval. Correspondingly, conclusions can be drawn as to whether it is an expected change in density or a disruption-related change in density.

A further advantageous embodiment can provide that a prognosis is carried out by mathematical extrapolation and / or by simulation data and / or by machine learning and / or physical models.

A forecast of the future course z. B. the density within future time intervals can be done using mathematical extrapolation. In a simple case, this is possible in that the trend is recorded from the data already known and a forecast is extrapolated.

For this purpose, at least data / measured values should preferably be available from at least 30 days, in particular 90 days, with at least one measured value per day being available. However, it can also be provided that a simulation z. B. the density curve is made. To determine the future density curve, physical models can also be used, which allow a more precise prediction of the density curve, taking into account the configuration of the electrical energy transmission device and the physical properties of the electrically insulating fluid used. Machine learning algorithms can also be used to generate forecasts. For example, a neural network with memory (recurrent neural network (RNN)) with long-short-term memory (LSTM cells) is particularly suitable in this case, which trains on the basis of the data history and converts it into a sufficiently precise prediction model (prognosis ) can be transferred.

A further advantageous embodiment can provide that data which were determined at specific interval times are used for trend analysis. In general, a change in the insulation strength of an electrically insulating medium represents a long-term effect. Accordingly, it is possible to determine the data at times that are comparatively far apart. The interval times can be determined, for example, in days or weeks. If necessary, the external influences, for example the time of year, can also be used in order to only take into account data that were determined at interval times that have comparable ambient conditions. For example, it is possible to only use data that are available at certain times of the day, e.g. B. occur at night or with similar loads of the Elektroenergie transmissionein direction or at the same time of year. It is thus possible to make a selection of data for the prognosis and to eliminate error sizes in a simple manner, for example by reducing the effects of climatic fluctuations from the outset.

A further advantageous embodiment can provide that a historical data analysis is taken into account in a comparison.

In addition to the data determined for the respective electrical energy transmission device, historical data analyzes can be used which, for example, are already templates for other electrical energy transmission devices of the same or similar design. For example, it is possible to evaluate certain aging phenomena, which do not always occur linearly, in an improved form and to increase the forecast quality of a trend analysis or the forecast for the future course of the insulation strength or density course. It can be provided that the historical data analysis is a data analysis which was created in the past for exactly the same electrical energy transmission device. A historical data analysis and a current data analysis can, for example, be displayed in a common graphic representation.

Another advantageous embodiment can provide that site-specific climate information is taken into account in the analysis.

The data that are recorded at the electrical power transmission device are preferably also provided with a location coordinate in addition to a time stamp. It is therefore possible to supplement the framework conditions or the ambient conditions at the time the data is recorded with climate information and, if necessary, to hide or lower any disturbances that are caused by the climate in the forecast. Thus, for example, fluctuations occurring at certain points can be traced back to climatic events and the output of a warning or the prognosis that a limit value will be reached can be made more precise.

A further advantageous embodiment can provide that a representation takes place in the form of a standardized print.

In addition to a display of the density or a change in density to map the insulation strength, this can also be shown converted to a standardized pressure. Here, for example, a conversion to a pressure equivalent at 20 ° C is possible. Depending on requirements, different normalizations can be used to map or predict the state of the insulation strength of the electrically insulating fluid.

Another object is to specify a computer program product which, when the program is executed on a data processing system, is designed to carry out a method according to the steps described above. A computer program product can be used to continuously monitor an electrical energy transmission device. The monitoring can take place at specific time intervals, and the computer program product can run on different computers. For example, a computer cloud can be used to make computing power available in a distributed manner and to be able to carry out the analysis of the data and make a forecast quickly.

In the following, an embodiment of the invention is shown cally in a drawing and described in more detail below be. The

Figure 1 shows an electrical power transmission device which

Figure 2 is a switching device with parallel connected NEN data suppliers that

Figure 3 shows a switching device with data providers that are connected via a multiplexer, the

FIG. 4 shows asymmetrical timing, FIG. 5 shows symmetrical timing, and FIG

FIG. 6 shows a chronological sequence of data.

Figure 1 shows an electrical energy transmission device in detail. This is an electrical energy transmission device which transmits a three-phase AC voltage system by means of three phase conductors la, lb, lc. In FIG. 1, three phase conductors 1 a, 1 b, 1 c are shown symbolically as a single line diagram. Each of the three phase heads la, lb, lc is structured in the same way. In the course of the phase conductors la, lb, lc there is an isolating switch 2a, 2b, 2c arranged. A circuit breaker 3a, 3b, 3c is then arranged in the course of the phase conductors la, lb, lc. For the electrical insulation of the phase conductors la, lb, lc, disconnectors 2a, 2b, 2c and power switches 3a, 3b, 3c, the use of an electrically insulating fluid is provided. Each of the phase conductors la, lb, lc is assigned a fluid volume which is separated from the fluid volumes of the other phase conductors la, lb, lc. In order to make this separation, the phase conductors la, lb, lc with disconnectors 2a, 2b, 2c and circuit breakers 3a,

3b, 3c each arranged within an encapsulating housing 4a, 4b, 4c.

The encapsulation housings 4a, 4b, 4c are essentially tubular and structurally identical, with an electrically insulating fluid being enclosed in the interior of the respective encapsulation housing 4a, 4b, 4c. The electrically insulating de fluid washes around the phase conductors la, lb, lc and the isolating switches 2a, 2b, 2c and the circuit breakers 3a, 3b, 3c. If necessary, the electrically insulating fluid can also act as an extinguishing gas for switching arcs that may occur. If necessary, each of the encapsulating housings 4a, 4b, 4c can in turn be subdivided into different sections, so that in addition different insulating gas volumes separated from one another can be arranged consecutively within a phase conductor la, lb, lc.

The aging of the electrically insulating fluid can reduce its insulation strength. Aging phenomena can be caused, for example, by arcs or partial discharges, which can occur inside the electrically insulating fluid. Furthermore, the electrically insulating fluid can also volatilize from the encapsulation housing 4a, 4b, 4c. For example, due to the aging of sealants, loss of electrically insulating fluid can occur. Such sealants are for example in the range of To provide flanges 5a, 5b, 5c in order to assemble encapsulating housings 4a, 4b, 4c from several sealed sub-elements.

To monitor the electrically insulating fluid, data suppliers 6a, 6b, 6c are attached to the respective encapsulating housing

4a, 4b, 4c arranged. The data suppliers 6a, 6b, 6c determine data about the state of the electrically insulating fluids of the respective encapsulating housing 4a, 4b, 4. The data suppliers 6a, 6b, 6c can preferably be so-called density monitors, which measure the density of the electrically insulating fluids, which in the respective encapsulating housing 4a, 4b,

4c are included. A density monitor has the advantage that regardless of the external surroundings, i.e. H. in particular regardless of the temperature, an image of the insulation strength by the data suppliers 6a, 6b,

6c can be obtained.

The data suppliers 6a, 6b, 6c are analogue sensors, which output a proportionally changing electrical variable, for example an electrical current, proportional to the change in the density of the electrically insulating fluid being monitored in an encapsulating housing 4a, 4b, 4c. The data suppliers 6a, 6b, 6c are corresponding converters which convert a density of the electrically insulating medium proportionally into an electrical current, in particular direct current.

In the figure 2 is a connection of the data suppliers 6a, 6b,

6c to a first interface 7 of a switching device 8 is shown symbolically. The three data suppliers 6a, 6b, 6c are supplied with a variable input voltage, for example in the range from 10 to 32 V DC. This voltage supply can, for example, via the first

Interface 7 of the switching device 8 provided who the. The three data suppliers 6a, 6b, 6c are electrically connected in parallel to the first interface 7 of the switching device 8. A first data supplier 6a is thus connected to the first interface 7 and a second data supplier 6b is connected to the first interface 7. A third data supplier 6c is also connected to the first interface 7. All of the data suppliers 6a, 6b, 6c deliver their measured values in parallel in the form of an electrical current to one and the same first interface 7. The data suppliers 6a, 6b, 6c are designed in such a way that the currents output add up with the same polarity. This ensures that measurement streams from data suppliers 6a, 6b, 6c are not neutralized.

In order to counteract an overload of the first interface 7 of the switching device 8, a safety device 9 is in a reverse current line, d. H. in a Sammellei device in which the flows of the data suppliers 6a, 6b, 6c add to each other, arranged. The safety device 9 has a resistor RI and a resistor R2. The maximum current intensity with which the first interface 7 can be applied is normalized via the resistor RI, and overcurrents can be deflected via a second resistor R2, which is connected to ground potential. Thus, a flow divider is formed in a simple manner, which represents a safety device 9 for the first interface 7 of the switching device 8.

When several data suppliers 6a, 6b, 6c are connected to a common first interface 7, simultaneous delivery of data by all data suppliers 6a, 6b, 6c to the first interface 7 is provided. The data supplied by the data suppliers 6a, 6b, 6c complement each other. So with it is possible to draw conclusions on a disturbance or a change in the insulation strength / the density of an electrically insulating fluid in the encapsulation housings 4a, 4b, 4c when a certain limit value is exceeded. Individual monitoring of the encapsulation housings 4a, 4b,

4c does not take place, however. Rather, a cost-effective solution is created here to connect via a single interface 7 a switching device 8 several encapsulating housings 4a, 4b,

4c or electrically insulating fluids enclosed therein. Thus, using inexpensive switching devices 8, an increased number of

electrically insulating fluids, which are enclosed in different caps selungsgehäusen 4a, 4b, 4c, are monitored.

In addition to the monitoring of electrically insulating fluids shown in FIG. 1, which electrically isolate different phases la, lb, lc, it can also be provided that Isolierflui de, which are enclosed in an encapsulation housing 4a or encapsulation housing 4b or encapsulation housing 4c, but in the Course of the respective phase conductor la or lb or lc are divided into different sections to monitor.

The switching device 8, as known from FIG. 1, can have several interfaces. In this way, groups of data suppliers 6a, 6b, 6c can share a common

Interface 7 can be assigned. Preferred are those

Interfaces designed as analog interfaces. However, it can also be provided that digital interfaces are involved. The number of interfaces, both analog and digital interfaces or several types of interfaces, can be designed on a switching device 8 depending on requirements and computing capacity.

The switching device 8 should also be assigned a device for detecting a location coordinate, so that the information supplied to the respective interfaces can be spatially assigned in the switching device 8. For example, it is possible to combine data supplied by the data providers 6a, 6b, 6c in the switching device 8 with location information. If necessary, the respective temperature on site, in particular on the switching device 8, can be recorded and also with the data supplied by the feranten 8a, 8b, 8c supplied data are combined. Furthermore, time markers can be assigned in the switching device 8 to the data supplied by the data suppliers 6a, 6b, 6c.

A more convenient method of controlling data suppliers 6a, 6b, 6c is shown in FIG. There, too, a first data supplier 6a, a second data supplier 6b and a third data supplier 6c are connected to the switching device 8 known from FIG. Here, too, the switching device 8 has a first interface 7. The first interface 7 is an analog one in this case too

Interface. The data suppliers 6a, 6b, 6c are in turn connected in parallel to the first interface 7 of the switching device 8. However, the use of a multiplexer 10 is now provided, which enables clocking via a clock 11. Via the multiplexer 10, depending on the desired time intervals, one of the data suppliers 6a, 6b, 6c can be alternately controlled to the first interface 7. It is thus possible, taking into account the clock impressed by the clock 11 of the multiplexer 10, to carry out an individual resolution of the data supplied by each individual data supplier 6a, 6b, 6c. Accordingly, the time signal of the clock 11 of the multiplexer 10 can be provided with asymmetrical clocking, d. H. As shown in FIG. 4, for example, a larger time window can be provided for the first data supplier 6a than for the second and third data supplier 6a,

6b, 6c. This time signal can be processed in the switching device 8 together with the data supplied by the data supplier 6a, 6b, 6c. Such an asymmetrically distributed clocking has the advantage that an automated or independent restart can take place even if the clock falls out of sync, since due to the asymmetry the respective clock of the first data supplier 6a can be identified due to its increased time interval . Alternatively, as shown in FIG. 5, symmetrical clocking with regular time intervals can also take place over the sequence of the three data suppliers 6a, 6b, 6c.

The data acquired by the switching device 8 about the state of the electrically insulating medium, in particular the insulation strength, are transferred to and received by a processing device. In the processing device, the data recorded by the data suppliers 6a, 6b, 6c can be saved e.g. B. regarding the density of the

electrically insulating fluids are further processed. A supplement to the data supplied by the data suppliers 6a, 6b, 6c can preferably already be added in the switching device 8

Data, for example, to place coordinates, temperature, atmospheric pressure, time markers, etc. can be made. These possibly supplemented data are transferred directly or indirectly to the processing facility. The processing device can for example comprise a computer cloud or be a local computer. The transferred data are then processed by the processing device and output in a chronological sequence, for example in the form of a diagram in a graphic surface. A corresponding representation is made in FIG. In this case, the transferred data are possibly already further processed, converted and prepared for a suitable graphic representation in the processing device. Up to the point in time t1, which represents the current point in time, the previous time course of the density is mapped as an image of the insulation strength in one or in selected gas spaces. Should the data determined by the data suppliers 6a, 6b, 6c already fall below a first

If limit value 12 occurs, a warning is issued.

The first limit value 12 has a first stage 12a and a second stage 12b. The first level 12a is an alarm level at which a significant loss of density has already been determined. The second stage 12b represents a disturbance stage which already casts doubt on the electrical operational safety of the electrical energy transmission device.

In order to guarantee a sufficient advance warning time, the analysis method also provides for a prognosis of the development of the insulation strength / density. This takes into account, for example, how often / intensely switching within an electrically insulating fluid or faults within the electrically insulating fluid have occurred in the past. In addition to the currently occurring switching behavior or occurrence of switching arcs within the electrically insulating fluid, a leakage rate is known depending on the design of the electrical energy transmission device, which causes a decrease in density and thus the insulation strength of the electrically insulating medium as the age of the electrical energy transmission rate advances . Correspondingly, this variable can also be included in the prognosis of the future course of the density development of the electrically insulating medium.

In a simple case, the analysis method can perform a mathematical extrapolation of the data already recorded. If necessary, simulation data can also be taken into account through the use of simulation methods in order to map the trend of changes in electrical insulation strength. Physical models are particularly suitable for this. Through the use of machine learning algorithms, i. H. Self-learning algorithms, which draw conclusions about the behavior of the current electrical energy transmission device from a large number of data that are already known, a future density profile of the monitored, electrically insulating medium can be predetermined.

In order to stabilize the analysis, it can be provided that only selected data from a data series are used as a basis for an analysis; Can be determined on the day. So it is, for example, possible, preferably in certain load situations of the electrical power transmission device or certain Umge ambient situations, eg. B. at night, only these data to process at predetermined intervals or interval times. Since a change in density usually involves very long-term effects, data recorded at certain times of the year can also be compared with one another, so that relatively long-term intervals can be used to forecast the density profile of the monitored electrically insulating medium.

Another advantageous embodiment can provide that historical data analyzes of similar electrical energy transmission devices are used. In particular, non-linear processes, as they can occur again and again in everyday life, can be better taken into account, so that the forecast quality for the insulation strength / the density of the electrically insulating medium can be improved again.

Since the switching device 8 is set up to provide the data it collects with a location coordinate, information about the climatic condition at the respective point in time at which the data is recorded (time marker) can also be determined in a simple manner from databases. For example, information on temperatures or lightning effects in the vicinity of the monitored electrical energy transmission device can be assigned. This makes it possible, for example, to provide data that are taken into account in the forecast with different weightings and thus improve the quality of the forecast.

Advantageously, the switching device 8 can be designed as a so-called Internet-of-Things (IoT) gateway, so that, starting from the switching device 8, the data recorded there are transferred to a computer cloud (processing device). and experience processing there. Part of such a computer cloud can be, for example, a portable computer which has a graphical surface and thus provides a human-machine interface (HMI). On this interface, for example, the graphical representation of the density profile already determined and the predicted density profile with corresponding forecasts for reaching the first limit value 12 with its first stage 12a and its second stage 12b can be provided, as shown in FIG. Starting from the current point in time t1, the point in time t2 for an alarm and the points in time t3 for a significant disturbance can be predetermined. Even before an actual warning value is reached, that is to say the first stage 12a of the first threshold limit value 12, there is the possibility of taking measures, such as intensified observation or maintenance work. If necessary, recommendations for action can already be given for the respective electrical energy transmission system. These recommendations for action can relate to the operation of the same, for example reducing the thermal load, reducing the voltage, reducing the current load, etc. However, indications can also be given as to the form in which maintenance is to be carried out in order to positively influence a prognosis and to shift the prognosticated point in time of reaching the first limit value 12 further into the future.

Claims

1. Electric energy transmission device (la, lb, lc, 2a, 2b,

2c, 3a, 3b, 3c, 4a, 4b, 4c) with a state detection arrangement having a switching device (8) and at least one first data supplier (6a), which is connected to a first interface (7) of the switching device (8) that a second data supplier (6b) is connected to the first interface (7).

2. Electrical energy transmission device (la, lb, lc, 2a, 2b,

2c, 3a, 3b, 3c, 4a, 4b, 4c) according to claim 1,

d a d u r c h e k e n n n n z e i c h n e t, that the first and the second data supplier (6a, 6b) simultaneously provide complementary data to the first interface (7).

3. Electrical energy transmission device according to claim 1 or

2,

d a d u r c h e k e n n n z e i c h n e t, d a s s

Data from the first and second data suppliers (6a, 6b) are made available to the first interface (7) in a timed manner.

4. Electric power transmission device according to claim 3, d a d u r c h g e k e n n z e i c h n e t, d a s s a timing of the data from the first and second data suppliers (6a, 6) distributed asymmetrically.

5. Electrical energy transmission device according to one of claims 1 to 4,

characterized in that the first and the second data supplier (6a, 6b) are connected to the switching device (8) via a common line, a security device (9) being arranged in the common line.

6. Electrical energy transmission device according to claim 5, d a d u r c h g e k e n n z e i c h n e t, d a s s the safety device (9) has a current divider.

7. Electrical energy transmission device according to one of claims 1 to 6,

d u r c h e k e k e n n n z e i c h n e t that the first and the second data supplier (6a, 6b) supply status information via an electrically insulating medium.

8. Analysis method of a state of an electrically insulating medium of an electrical energy transmission device, that is, that is

Data on the state, in particular the insulation strength, of an electrically insulating fluid of a processing device are received that

the received data are processed and output in a chronological sequence and a warning is output when at least one first limit value (12) is reached and / or when at least one first limit value (12) is predicted to be reached.

9. Analysis method according to claim 8,

d u r c h e k e n n n z e i n e t, that a location coordinate is assigned to the data in the chronological order.

10. Analysis method according to claim 8 or 9,

d u r c h e k e n n n z e i c h n e t, that the first limit value (12) has a first and a second stage (12a, 12b).

11. Analysis method according to one of claims 8 to 10, characterized in that a prognosis of the development of the insulation strength taking into account switching operations of the electrical energy transmission device is made.

12. Analysis method according to one of claims 8 to 11, d a d u r c h g e k e n n z e i c h n e t, d a s s an expected change in the insulation strength is stored within a certain period of time.

13. Analysis method according to one of claims 8 to 11, d a d u r c h g e k e n n z e i c h n e t, d a s s a prognosis by mathematical extrapolation and / or by simulation data and / or by machine learning and / or physical models.

14. Analysis method according to one of claims 8 to 13, d a d u r c h g e k e n n z e i c h n e t, d a s s

Data that were determined at certain intervals can be used for trend analysis.

15. Analysis method according to any one of claims 8 to 14, that is, a historical data analysis is taken into account in a comparison.

16. Analysis method according to one of claims 8 to 15, d a d u r c h g e k e n n n z e i c h n e t, that site-specific climate information is taken into account in the analysis.

17. Analysis method according to one of claims 8 to 16, d a d u r c h g e k e n n z e i c h n e t, d a s s a representation in the form of a standardized pressure.

18. Computer program product which, when the program is running in a data processing system, is designed to carry out a method according to one of claims 8 to 17.