EP4115484A1

EP4115484A1 - Monitoring an electrical energy transmission device

Info

Publication number: EP4115484A1
Application number: EP21715144.8A
Authority: EP
Inventors: Richard Schulz; Mathias DORNIG; Matthias Heinecke; Thilo Nehring
Original assignee: Siemens Energy Global GmbH and Co KG
Current assignee: Siemens Energy Global GmbH and Co KG
Priority date: 2020-04-09
Filing date: 2021-03-10
Publication date: 2023-01-11
Also published as: CN115516727A; WO2021204486A1; US20230168131A1; DE102020204609A1

Abstract

The invention relates to a method for monitoring an electrical energy transmission device (1), wherein time-resolved operating state data (3, 4) relating to current, past and/or future operating states of the electrical energy transmission device (1), environment status data (5, 6) relating to current, past and/or future environment statuses in an environment of the electrical energy transmission device (1), and/or sensor data (7) detected by at least one sensor of the electrical energy transmission device (1) is recorded. By means of a computational model (9) processing the operating state data (3, 4), environment status data (5, 6) and/or sensor data (7), a temperature curve (10) of current, past and/or future temperatures of at least one module (2, 2.1, 2.2, 2.3) of the electrical energy transmission device (1) is calculated and, based on the calculated temperature curve (10), a thermal load capacity of the module (2, 2.1, 2.2, 2.3) is determined according to a thermal load threshold for the module (2, 2.1, 2.2, 2.3).

Description

description

Monitoring an electric power transmission device

The invention relates to a method for monitoring an electrical energy transmission device, in particular a switchgear.

A limiting factor for the current-carrying capacity of electrical energy transmission devices such as switchgear, in particular high-voltage switchgear, is the heating of components due to electrical losses. Due to the lack of feedback about an actual heating of components of an electrical energy transmission device, an electrical energy transmission device is usually operated well below its actual thermal load limit for safety reasons. In other words, electrical energy transmission devices are often not operated at a maximum permissible current for a current ambient temperature, so that the actual heating of components of the electrical energy transmission device can often be far below the permissible heating.

In addition, electrical energy transmission devices often have such a high thermal capacity that they can withstand electrical currents for a short time that significantly exceed a nominal current. This potential of an electrical energy transmission device is usually not used.

One problem that conflicts with the utilization of the actual thermal load capacity of an electrical energy transmission device is that the temperature of some components (for example electrical conductors) cannot currently be measured using measurement technology. This means that in the event of an error, it cannot be recognized when the permissible temperature limit values are exceeded.

The invention is based on the object of a method for monitoring an electrical energy transmission device. give that an operation of the electrical energy transmission device up to its maximum thermal load capacity it allows.

The object is achieved according to the invention by a method with the features of claim 1, a computer program with the features of claim 15 and an electrical energy transmission device with the features of claim 16.

Advantageous refinements of the invention are the subject matter of the subclaims.

In the method according to the invention for monitoring an electrical energy transmission device, in particular a switchgear, time-resolved operating status data on current, past and / or future operating states of the electrical energy transmission device, environmental status data on current, past and / or future environmental conditions in an environment of the electrical energy transmission device and / or sensor data which are detected and / or detected by at least one sensor of the electric power transmission device. Using a calculation model that processes the operating status data, environmental status data and / or sensor data, a temperature profile of current, past and / or future temperatures of at least one module of the electrical power transmission device is calculated, and the calculated temperature profile is used to calculate a thermal load on the module as a function of a thermal load limit determined for the module.

The method according to the invention enables precise determination of temperature profiles of the temperatures of individual modules by taking into account time-resolved operating status data on operating statuses of the electrical energy transmission device, environmental status data on environmental conditions in the vicinity of the electrical energy transmission device and / or sensor data. Taking time-resolved data will be This is understood to mean data to each of which a point in time is assigned, for example in that the data each have a digital time stamp. By taking into account the time-resolved operating status data and the environmental status data, sensor data recorded at individual measuring points on or in the electrical energy transmission device, with which temperatures can be determined directly or indirectly at these measuring points, can be used to measure temperatures at other locations in the electrical energy transmission device and to calculate and in particular to forecast temperature curves of individual modules. As a result, only a few sensors are required to determine the temperature curves of individual modules, and temperatures and temperature curves can also be calculated for locations or modules where temperatures are not or cannot be recorded using measurement technology.

This precise and comprehensive calculation of the Temperaturverläu fe individual modules enables in particular an operation of the electrical energy transmission device at its thermal load limit and a short-term overload operation of the electrical energy transmission device, so that the thermal load capacity and thus the actual potential of the electrical energy transmission device can be used to the maximum. In addition, it enables an improvement in the operational safety of the electrical energy transmission device in that local overheating of the electrical energy transmission device can be recognized and eliminated or predicted and prevented. The calculation of the temperature profiles of individual modules can also be used advantageously as a basis for improved regulation of active cooling of the electrical energy transmission device.

In one embodiment of the invention, the calculation model mathematically simulates the operation of at least one module, has a mathematical model of at least one module and / or evaluates module data on geometric, physical and / or chemical properties of at least one module the end. As a result, the accuracy of the temperature calculation can advantageously be increased by taking into account the specific properties of individual modules in the calculation model.

In a further embodiment of the invention, a current and / or at least one past and / or future degree of utilization of the electrical energy transmission device is determined as a function of the thermal load limit of at least one module based on at least one calculated temperature profile. The degree of utilization of the electrical energy transmission device is understood to mean utilization of the electrical energy transmission device in relation to a maximum permissible utilization. For example, the degree of utilization is defined by a thermal utilization in relation to a maximum permissible thermal utilization. The determination of the degree of utilization advantageously enables a quantitative assessment of the utilization of the electrical energy transmission device and thereby facilitates its optimization.

In a further embodiment of the invention, a thermal utilization of at least one module is visualized as a function of its thermal load limit and / or the degree of utilization of the electrical energy transmission device. For example, the visualization includes a color representation of at least one module, the color of which is assigned to a temperature calculated for the module as a function of the thermal load limit of the module. Furthermore, it can be provided that a period of time for which the thermal utilization of at least one module and / or the degree of utilization of the electrical energy transmission device is visualized can be set. Such visualizations advantageously allow a quick overview of the thermal load and the utilization of the electrical energy transmission device and, in particular, the recognition of modules that are thermally heavily loaded and possible optimization of the operation of the electrical energy transmission device. In a further embodiment of the invention, the thermal load limit of a module is defined as a temperature threshold value specific to the module. This realizes an expedient and simple quantitative definition of a load limit.

In a further embodiment of the invention, a warning is generated when the temperature curve calculated for a module exceeds the temperature threshold value defined for the module. As a result, an over-load operation of the electrical energy transmission device can be automatically pointed out or a warning can be given of an overload of the electrical energy transmission device.

In a further embodiment of the invention, a tolerance period is defined and a warning is only output if the temperature curve calculated for a module exceeds the temperature threshold value defined for the module for longer than the tolerance period. As a result, an only brief and therefore uncritical overloading of a module can advantageously be tolerated, so that unnecessary shutdown of the module or the entire electrical energy transmission device can be avoided.

In a further embodiment of the invention, a warning is output if a temperature of a module calculated by means of the calculation model for a point in time deviates from a temperature of the module measured at this point in time by more than a specifiable absolute or relative tolerance value. This advantageously points out possible errors in the calculation model or calculations carried out with the calculation model.

In a further embodiment of the invention, at least one module-dependent operating settings for the electrical power transmission device are defined and operating instructions on the operating settings in Output depending on at least one calculated temperature profile and / or operating settings made automatically as a function of at least one calculated temperature profile. This enables the automatic generation of information about an optimization of the operation of the electrical energy transmission device or even an automated optimization of the operation of the electrical energy transmission device.

In a further embodiment of the invention, the operating status data have information about a switching state of at least one electrical switching unit, an operating state of at least one active cooling device and / or an electrical operating current and / or an electrical power of at least one component of the electrical energy transmission device and / or the entire Electric power transmission device on. These operating status data are particularly relevant operating status data for determining the thermal load on the electrical energy transmission device and are therefore particularly suitable for calculating the temperature profiles.

In a further embodiment of the invention, the ambient state data have information about a temperature, a wind speed, precipitation, air humidity and / or a radiation intensity of electromagnetic radiation in the vicinity of the electrical energy transmission device. These environmental status data are particularly relevant environmental status data for determining the thermal load on the electrical power transmission device and are therefore particularly suitable for calculating the temperature profiles.

In a further embodiment of the invention, the sensor data include temperatures recorded at at least one measuring point on or in the electrical energy transmission device. This advantageously enables the consideration and evaluation Processing of actual temperatures of the electrical energy transmission device for calculating the temperature profiles.

In a further embodiment of the invention, the calculation model has a modular structure with libraries for taking individual modules into account. As a result, the calculation model can advantageously be adapted to a change in the electrical energy transmission device and used for different electrical energy transmission devices.

In a further embodiment of the invention, the operating status data, environmental status data and / or sensor data are at least partially recorded in a data cloud and / or the temperature profile of at least one module is calculated in a data cloud using the calculation model. As a result, the operating status data, environmental status data and / or sensor data and / or the calculated temperature profiles can advantageously be retrieved and used independently of location and user. Furthermore, it can be provided that operating status data, environmental status data and / or sensor data and / or the calculated temperature profiles can be downloaded from the data cloud and used offline.

A computer program according to the invention comprises commands which, when the computer program is executed by a control unit or in a data cloud, cause the control unit to execute the method according to the invention.

An electrical energy transmission device according to the invention comprises a control unit on which a computer program according to the invention is executed, or a connection to a data cloud in which a computer program according to the invention is executed.

The properties, features and advantages of this invention described above and the manner in which they are achieved will become clearer and more clearly understood in connection with the following description of exemplary embodiments. games, which are explained in more detail in connection with the drawings. Show:

1 shows a structure diagram of an embodiment of the method according to the invention for monitoring an electrical energy transmission device,

2 shows a first visualization of an electrical energy transmission device with a representation of temperatures of modules of the electrical energy transmission device,

3 shows a second visualization of an electrical energy transmission device with a representation of temperatures of modules of the electrical energy transmission device,

4 shows a visualization of time curves of a degree of utilization and an input current of an electrical energy transmission device.

FIG. 1 (FIG. 1) shows a structure diagram of an exemplary embodiment of the method according to the invention for monitoring an electrical energy transmission device 1 with various modules 2 (see FIG. 2).

In the method, time-resolved operating status data 3 on current and past operating statuses of the electrical power transmission device 1, operating status data 4 on future operating statuses of the electric power transmission device 1, environmental status data 5 on current and past environmental statuses in the vicinity of the electrical power transmission device 1, environmental status data 6 on future environmental statuses in an environment of the electrical energy transmission device 1, sensor data 7 that are recorded and / or were recorded by at least one sensor of the electrical energy transmission device 1, and module data 8 on geometric, physical and / or chemical properties of at least one module 2 recorded, for example in a data cloud.

Using one of the operating status data 3, 4, ambient status data 5, 6, sensor data 7 and module data 8, the calculation model 9 is used to calculate a temperature profile 10 of current, past and / or future temperatures for different modules 2 of the electrical power transmission device 1. Based on the calculated Temperaturver courses 10, thermal loads of the modules 2 are determined as a function of thermal load limits for the modules 2. The calculation model 9 is executed, for example, in a data cloud. A thermal load limit of a module 2 is defined, for example, on the basis of a data sheet describing the module 2, a safety regulation and / or a standard. The thermal load limit of a module 2 is defined as a temperature threshold value specific to module 2.

Furthermore, a current and / or at least one past and / or future thermal utilization level of at least one module 2 depending on its thermal load limit and / or a current and / or at least one past and / or future thermal utilization level are based on the calculated temperature profiles 10 D of the electrical energy transmission device 1 determined as a function of the thermal load limits of the modules 2. A degree of utilization of a module 2 is defined, for example, as a deviation of a temperature calculated for module 2 from the temperature threshold value defined for module 2 or as a ratio of this deviation to the temperature threshold value. The determined utilization rates and utilization rates D are visualized with a visualization 11, see FIGS. 2 to 4 and their description.

Furthermore, it can be provided that a warning notice 12 is generated if the temperature curve 10 calculated for a module 2 exceeds the temperature threshold defined for the module 2. value exceeds. Alternatively or additionally, it can be provided that a tolerance period is defined and a warning 12 is only output if the temperature curve calculated for a module 2 exceeds the temperature threshold value defined for module 2 for longer than the tolerance period. As a result, an only brief and therefore uncritical overload of a module 2 can advantageously be tolerated, so that unnecessary shutdown of the module 2 or the entire electrical energy transmission device 1 can be avoided. A warning 12 can also be output if a temperature of a module 2 calculated by means of the calculation model 9 for a point in time deviates from a temperature of the module 2 measured at this point in time by more than a predeterminable absolute or relative tolerance value.

Furthermore, operating settings dependent on the temperatures of the modules 2 are defined for the electrical energy transmission device 1 and operating instructions 13 are generated on the operating settings as a function of the calculated temperature curves 10 and / or operating settings are made automatically as a function of the calculated temperature curves 10. Such operating settings are, for example, changing an electrical operating current of a component of the electrical energy transmission device 1 and / or of the entire electrical energy transmission device 1 or switching an active cooling device on or off. In addition, an operating note 13 can, for example, recommend the maintenance or replacement of one or more individual components of the electrical power transmission device 1, for example a busbar replacement.

The operating state data 3, 4 contain information, for example, about a switching state of at least one electrical switching unit, an operating state of at least one active cooling device and / or an electrical operating current and / or an electrical power of at least one component of the electrical energy transmission device 1 and / or the entire electric power transmission device 1. The operating state data 3 on current and past operating states of the electrical energy transmission device 1 are provided, for example, by a control unit controlling the electrical energy transmission device 1. The operating status data 4 on future operating statuses of the electrical energy transmission device are taken, for example, from a manually or automatically generated operating specification 14 for the operation of the electrical energy transmission device 1 and / or the generated operating instructions 13.

The environmental status data 5, 6 have information on, for example, a temperature, a wind speed, precipitation, air humidity and / or a radiation intensity of electromagnetic radiation (for example solar radiation) in the vicinity of the electrical energy transmission device 1. The environmental status data 5 on current and past environmental statuses in the vicinity of the electrical power transmission device 1 are provided, for example, from a weather station, separate measuring devices and / or from a database of a data cloud. The environmental status data 6 on future environmental statuses in the vicinity of the electrical energy transmission device 1 are taken, for example, from a weather forecast 15 for the surroundings of the electrical energy transmission device 1 and / or a user input 16 made manually by a user or operator of the electrical energy transmission device 1.

The sensor data 7 include in particular temperatures recorded at at least one measuring point on or in the electrical energy transmission device 1.

The module data 8 for a module 2 are taken, for example, from a data sheet describing the module 2.

FIGS. 2 and 3 (FIG. 2 and FIG. 3) each show a visualization 11 of an electrical energy transmission device 1 with a representation of temperatures of modules 2 of the electrical energy transmission device 1. The electrical energy transmission device 1 in this example is a switchgear, the modules 2 of which include disconnector modules 2.1 with switch units designed as disconnectors, circuit breaker modules 2.2 with switch units designed as circuit breakers and output modules 2.3 with switching units designed as earthing switches. Figure 2 shows a three-dimensional visualization 11 with a realistic representation of the electrical power transmission device 1, Figure 3 shows a two-dimensional visualization 11 in the form of a circuit diagram of the electrical power transmission device 1 is shown, the color in which a module 2 is shown, the temperature calculated for the module 2 as a function of the thermal load limit of the module 2 is assigned. For example, 2 temperature intervals are defined for each module depending on the thermal load limit of module 2 and a color is assigned to each temperature interval. For example, a module 2 is displayed in red if the temperature calculated for module 2 exceeds the temperature threshold value defined for module 2. Correspondingly, a module 2 can, for example, be shown in green if the temperature calculated for module 2 is significantly below the temperature threshold defined for module 2, yellow for higher temperatures below the temperature threshold and orange for temperatures within a temperature interval, its upper limit is the temperature threshold defined for module 2. The different colors are shown in FIGS. 2 and 3 by different hatching.

Figure 4 (Figure 4) shows an example of a visualization of a degree of utilization D and an input current I of an electrical energy transmission device 1 in the form of curves D (t) of the degree of utilization D and I (t) of the input current I as a function of a time t. A period At for which the Gradients D (t) and I (t) are determined and displayed, can be set. Furthermore, variables can be selected via a selection menu 20 with buttons 21 to 25, the temporal progressions of which are shown alternatively or additionally in the time period At. For example, a button 21 is assigned to the degree of utilization D of the electrical energy transmission device 1, a button 22 is assigned to the input current I of the electrical energy transmission device 1 and the other buttons 23 to 25 are each assigned to a further variable, for example a variable that characterizes an ambient condition such as a temperature, a wind speed, a precipitation, a humidity or a radiation intensity in the environment of the electrical energy transmission device 1 or an operating parameter of the electrical energy transmission device 1 such as a switching state of a switching unit or a thermal degree of utilization of an individual module 2 of the electrical energy transmission device 1. Although the Invention has been illustrated and described in detail by preferred embodiment examples, the invention is not limited by the examples disclosed and other variations n can be derived from this by the person skilled in the art without departing from the scope of protection of the invention.

Claims

1. A method for monitoring an electrical energy transmission device (1), in particular a switchgear, wherein

- Time-resolved operating status data (3, 4) on current, past and / or future operating statuses of the electrical energy transmission device (1), environmental status data (5, 6) on current, past and / or future environmental conditions in the vicinity of the electrical energy transmission device (1) and / or sensor data (7) which are recorded and / or recorded by at least one sensor of the electrical energy transmission device (1) are recorded,

- By means of one processing the operating status data (3, 4), environmental status data (5, 6) and / or sensor data (7)

Calculation model (9) a temperature profile (10) of current, past and / or future temperatures of at least one module (2, 2.1, 2.2, 2.3) of the electrical energy transmission device (1) is calculated and

- Based on the calculated temperature profile (10), a thermal utilization of the module (2, 2.1, 2.2, 2.3) is determined as a function of a thermal load limit for the module (2, 2.1, 2.2, 2.3).

2. The method according to claim 1, wherein the calculation model (9) mathematically simulates the operation of at least one module (2, 2.1, 2.2, 2.3), a mathematical model of at least one module (2, 2.1, 2.2, 2.3) and / or Module data (8) on geometric, physical and / or chemical properties of at least one module (2, 2.1, 2.2, 2.3) is evaluated.

3. The method according to claim 1 or 2, wherein based on at least one calculated temperature profile (10) a current and / or at least one past and / or future degree of utilization (D) of the electrical energy transmission device (1) depending on the thermal load limit of at least one module (2, 2.1, 2.2, 2.3) is determined.

4. The method according to any one of the preceding claims, wherein a thermal load of at least one module (2, 2.1, 2.2, 2.3) is visualized as a function of its thermal load limit and / or a degree of utilization (D) of the electrical energy transmission device (1).

5. The method according to claim 4, wherein the visualization (11) comprises a color representation of at least one module (2, 2.1, 2.2, 2.3), the color of which is a function of a temperature calculated for the module (2, 2.1, 2.2, 2.3) is assigned to the thermal load limit of the module (2, 2.1, 2.2, 2.3).

6. The method according to any one of the preceding claims, wherein the thermal load limit of a module (2, 2.1, 2.2,

2.3) is defined as a temperature threshold value specific to the module (2, 2.1, 2.2, 2.3).

7. The method according to claim 6, wherein a warning (12) is generated when the temperature curve (10) calculated for a module (2, 2.1, 2.2, 2.3) is the same as for the module (2, 2.1, 2.2, 2.3) exceeds the defined temperature threshold.

8. The method according to claim 7, wherein a tolerance period is defined and a warning (12) is only output if the temperature curve (10) calculated for a module (2, 2.1, 2.2, 2.3) corresponds to that for the module (2, 2.1 , 2.2, 2.3) exceeds the defined temperature threshold longer than the tolerance period.

9. The method according to any one of the preceding claims, wherein of the temperatures at least one module (2, 2.1, 2.2,

2.3) dependent operating settings for the electrical energy transmission device (1) are defined and operating instructions (13) on the operating settings as a function of at least one calculated temperature profile (10) are output and / or operating settings as a function of at least one calculated temperature profile (10) can be made automatically.

10. The method according to any one of the preceding claims, wherein the operating status data (3, 4) information about a switching state of at least one electrical switching unit, an operating state of at least one active Kühleinrich device and / or an electrical operating current and / or an electrical power of at least one component of the electrical system have energy transmission device (1) and / or the entire electrical energy transmission device (1).

11. The method according to any one of the preceding claims, wherein the environmental status data (5, 6) information about a

Temperature, wind speed, precipitation, humidity and / or radiation intensity of electromagnetic radiation in the vicinity of the electrical energy transmission device (1).

12. The method according to any one of the preceding claims, wherein the sensor data (7) at at least one measuring point on or in the electrical power transmission device (1) include temperatures recorded.

13. The method according to any one of the preceding claims, wherein the calculation model (9) is constructed modularly with libraries for consideration of individual modules (2, 2.1, 2.2, 2.3).

14. The method according to any one of the preceding claims, wherein the operating status data (3, 4), environmental status data (5,

6) and / or sensor data (7) are at least partially recorded in a data cloud and / or the temperature profile (10) of at least one module (2, 2.1, 2.2, 2.3) is calculated using the calculation model (9) in a data cloud.

15. Computer program, comprising instructions which, when the computer program is executed by a control unit or in a data cloud, cause the control unit to carry out the method according to one of claims 1 to 14.

16. Electrical energy transmission device (1) with a STEU on which a computer program according to claim 15 is carried out, or with a connection to a data cloud in which a computer program according to claim 15 is executed.