EP3928271A1

EP3928271A1 - Method for maintaining an electrical component

Info

Publication number: EP3928271A1
Application number: EP19716812.3A
Authority: EP
Inventors: Christoph Armschat; Markus Distler; Jörg HAFERMAAS; German KUHN; Nicolas Söllner; Anna SÖRGEL; Uwe WEIGT
Original assignee: Siemens Energy Global GmbH and Co KG
Current assignee: Siemens Energy Global GmbH and Co KG
Priority date: 2019-03-28
Filing date: 2019-03-28
Publication date: 2021-12-29
Also published as: US20220187142A1; WO2020192918A1

Abstract

The invention relates to a method for maintaining a first electrical component. In the method according to the invention, temperature measurement values recorded at the first electrical component are stored as a first set of measurement data, wherein temperature measurement values recorded at least at one second and one third electrical component are stored as second and third sets of measurement data, and, taking into account the three sets of measurement data, a verification is carried out to determine whether a maintenance operation is necessary at the first component. The invention also relates to a data-processing system for carrying out the method according to the invention.

Description

Method for maintaining an electrical component

The invention relates to a method for maintaining a first electrical component.

Such an electrical component can be, for example, a component of a high-voltage DC transmission system, a switchgear, a surge arrester, a transformer or the like. Further examples are capacitors in a capacitor bank or devices that are installed in three-phase networks as three single-phase individual devices, such as chokes, filter resistors or air-insulated switches. Failures of such components, in particular high-voltage or medium-voltage components, usually only rarely occur. However, a single component failure can lead to the failure of the entire system, the functional part of which is the electrical component.

Corresponding electrical components have a permissible temperature range during operation. If the components are operated outside the permissible temperature range, the service life consumption and the risk of failure increase considerably. To ensure compliance with the temperature range, the components are usually designed or manufactured with suitable reserves. The risk of component overloading is greatly reduced by this oversizing of the components, but not completely eliminated. In addition, the manufacturing costs increase accordingly.

The object of the invention is to propose a method mentioned at the beginning that enables the electrical component to operate as efficiently and reliably as possible.

The object is achieved according to the invention by a method for withstanding a first electrical component in temperature measurement values recorded on the first electrical component are stored as first measurement data, temperature measurement values recorded on at least one second and third electrical component are stored as second and third measurement data and, taking into account the three measurement data, it is checked whether a maintenance process is carried out

and / or a control measure on the first component is necessary. Maintenance is based on temperature measurements that are recorded on the electrical components. The temperature measurement values can originate from one or more temperature sensors which are arranged at one or more locations of the respective component. The temperature sensors are suitably set up for use on components, possibly also at high voltage potential, to transmit the recorded temperature measurement values wirelessly, suitably by radio. The received data is saved accordingly. The sensors can be arranged, for example, on the surface of the relevant component, so that it measures a surface temperature. However, it is also conceivable that a temperature in the interior of the respective component is detected by means of the sensor or sensors. For example, the temperature of an inner conductor of the component can be detected, the inner conductor being surrounded on the outside by an outer insulator. When using high-voltage potential, the sensor can be protected from damage by a protective circuit. This is particularly useful when using sensors that are connected to an external sensor node. In the simplest case, this can be done using a Zener diode or a low-pass filter. When positioning the sensors, possible electrical or electromagnetic effects must be taken into account so that the sensors are not disrupted or the systems are affected. To this end, electrical, magnetic and electromagnetic emissions must be limited. This can be done by the following measures (individually or in any combination): Positioning the sensor nodes in the field shadow, eg in the field shadow of a corona ring, positioning in strong areas alternating magnetic fields protected by a magnetic shield plate, positioning with only minor surface changes in the electrostatic field, if necessary using a passively controlled surface contour with suitably set permittivity, positioning with particularly high-frequency electromagnetic fields. In the context of the invention, the temperature measurement values can be given by direct measurements or also, for example, by measurement data averaged over time or location. Such averaging has the advantage of a smaller amount of data transmitted. Accordingly, it is also conceivable to appropriately select the transmitted temperature measured values for the measurement data in another way, at least before they are stored, in order to reduce the amount of data. The measurement data are suitably stored successively in a temporal arrangement of individual measurement data points (tuples of one measurement data point and one time specification are also conceivable) in a storage medium of a data processing system (or distributed over several data processing systems). An essential advantage of the invention lies in the use of the measured temperature values for the maintenance of the first electrical component (in particular through the comparison with the other components, whereby outliers can be identified, for example). In this way, laborious manual measurements and evaluation on site can be avoided, which allows particularly efficient maintenance. In addition, the measurement data can be evaluated continuously, so that suitable maintenance and repair measures can be carried out at any time. This increases the reliability of the first electrical component in operation. The method can also be carried out accordingly with regard to the at least three electrical components. The number of components is of course not limited to three.

To check whether a maintenance process is necessary on the first component, the measurement data from at least a second and a third component are also used according to the invention electrical components (expediently components of the same type) are also taken into account. The invention is therefore based on the knowledge that the monitoring of only one electrical component only allows reliable maintenance to a limited extent. The reason for this is that, in particular, long-term changes in the environment and the entire system influence the measurements and require adjustments to any operating points and operating ranges that are barely or not at all recognizable when measuring an individual component. In contrast, the use or consideration of three or more components, for example but not necessarily one and the same high or medium voltage system, allows a reliable detection of maintenance requirements or errors of the first component (or all of the components considered). The at least three electrical components can expediently be components of a so-called cluster, such as capacitors of a capacitor bank, power modules of a modular converter, arrester housing of an arrester bank or the like. This has the advantage that the ambient conditions for all components are comparable and can therefore be calculated out or neglected in a suitable manner.

Apart from a maintenance process, a control measure can be recognized as necessary or desirable. One possible control measure can, for example, be the activation of the component for overload operation at low component temperatures. Alternatively, for example, a reduction in the highest permissible operating temperature is also conceivable.

According to one embodiment of the invention, the measurement data are compared with one another and the checking is carried out taking into account measurement data differences. The measurement data differences can be determined as differences between the measurement data or from a predetermined or determined value, for example an average value. Appropriately, individual measurement data points are compared with one another, which correspond to measurements at the same points in time (or measurement data points which correspond to measured values recorded at different times, but where the time differences are not greater than a predetermined difference in time). The consideration of the measurement data differences allows a simple and effective detection of noticeable changes in the temperatures of the components with respect to one another or with one another.

A measurement data mean value and a first measurement data difference are preferably formed between the first measurement data (the measurement data values) and the measurement data mean value, the checking comprising a comparison of the first measurement data difference with a difference threshold value. The measured data mean value thus forms a further time series because the mean values are calculated from the respective measured data of the at least three components in accordance with the temporal arrangement. If the difference threshold is exceeded, a change in the operating properties of the component of a cluster or an error state can be concluded. In many cases, especially with components of the same type and sensors installed in the same way that deliver the measurement data, a comparison measurement is sufficient to detect anomalies. The outlier is identified and, if necessary, the component can be specifically checked on site in the event of a brief operational interruption. The accuracy of the individual measurements takes a back seat.

According to one embodiment of the invention, checking comprises forming a temperature change from the first measurement data. By considering the rise or fall in temperature, a more precise assessment of abnormalities of the first component can be carried out. An evaluation of the trend behavior of the measurement data can be particularly advantageous. The checking preferably includes a comparison of the temperature rise with a reference temperature rise (that is, a typical time constant of the component, environmental conditions included or taken into account). In this way, long-term changes can advantageously be taken into account in the evaluation.

It is considered to be advantageous if the checking includes comparing the first measurement data with ambient temperature measurement data recorded on the first component. For example, a surface temperature can be compared with an associated ambient temperature. Depending on how high the surface temperature is and how great the difference to the ambient temperature, various measures can be useful or a further analysis of the measurement data can be performed. Furthermore, a calibration can be carried out in such a way that temperature measurements are carried out in a test field at different ambient temperatures. The characteristic curves obtained in this way are saved and taken into account when analyzing the measurement data.

The checking is preferably carried out taking into account operating data of the electrical component. The operating data can in particular be current and voltage (a current flowing through the component, a voltage dropping across the component). In this way, an even more precise picture of the load condition of the component can be obtained.

The checking can be carried out taking into account a calibration of the temperature measurement. As far as this appears before geous, a calibration can be carried out in a test field. The various methods for determining the temperature can be measured in the test field with a certain number of operating states. Correction curves for a variable to be measured, measured value and influencing environmental parameters (e.g. ambient air, its temperature, humidity, etc.) can be created will. These correction curves are then also saved and taken into account when evaluating the measurement data. A particularly high level of accuracy and reliability of the method can thus be achieved.

It can suitably be checked whether the measurement data or a variable derived therefrom satisfy a plurality of predetermined conditions, each condition being assigned a separate maintenance instruction or control measure, which is triggered when the assigned condition is present. Accordingly, several conditions are defined, each of the conditions being assigned to a separate maintenance instruction. The fulfillment of a first condition can, for example, be linked to the maintenance instruction to place the component under special observation, a second condition can be linked to the maintenance instruction to clean the component or the outer insulator, and a third condition can be linked to the maintenance instruction to replace the component, etc.

The invention also relates to a data processing system.

The object of the invention is to propose a data processing system by means of which efficient maintenance of an electrical component is made possible.

The object is achieved according to the invention by a data processing system which is set up to carry out a method according to the invention.

The advantages of the data processing system according to the invention result in particular from the advantages that have already been described in connection with the method according to the invention. The invention is further explained below with reference to exemplary embodiments, which are shown in Figures 1 to 3 Darge.

FIG. 1 shows an example of electrical components which are suitable for maintenance by means of the method according to the invention;

FIG. 2 shows a first exemplary embodiment of a method according to the invention;

Figure 3 shows a second embodiment of the fiction, contemporary method.

An arrester bank 1 with twenty surge arresters 2 of the same type is shown in FIG. Each surge arrester comprises an outer insulator 3 and a high-voltage terminal 4 for connection to a high-voltage line 5. At the high-voltage terminal 4, the temperature is measured on each surge arrester by means of a dedicated sensor 6 and is sent as measurement data to an evaluation unit in the form of a data processing system 7 Posted. By comparing the measurement data, it can be checked whether the surface temperature of one of the surge arresters deviates from the rest and whether a maintenance process is therefore necessary.

FIG. 2 shows a schematic representation of the course of an evaluation of the measurement data that have been transmitted by three electrical components. In a first method step 101, first measurement data Thl of a temperature sensor of a first component are stored (as a data series Thl (t)). Correspondingly, second and third measurement data Th2 and Th3 of a second and a third component are stored in two method steps 102 and 103, which are executed simultaneously or consecutively, for example. In a fourth method step 104, an average value ThM (t) is used as 1/3 * (Thl (t) + Th2 (t) + Th3 (t)). In a fifth method step 105, a first measurement data difference DeltaThl (t) = Thl (t) - ThM (t) is calculated. A distinction is made below between two cases: If a check 106 shows that the first measurement data difference reaches or exceeds a predetermined difference threshold value x, then in a seventh method step 107 a maintenance instruction is output or the measurement data is analyzed more precisely. If the check 106 shows that the measured data difference is below the difference threshold value, then in an eighth method step 108 information is displayed that the first component does not require any maintenance measures.

Another possibility of evaluation is shown schematically in FIG. In a first method step 201, measurement data transmitted by a sensor of a first electrical component, in particular a measurement data point Th, are stored in a memory of a data processing system. In a second method step 202 it is checked whether the measured data point value reaches or exceeds a maximum temperature Tmax. If this is the case, further analysis of the measurement data is carried out in a third method step 203. If this is not the case, then in a fourth process step 204 an absolute difference dTh is formed between the measuring point of an outside temperature Ta measured on the component and averaged: dTh = | Th - Ta | . In a fifth method step, it is checked whether the absolute difference dTh is below a lower limit value TI, equal to or above an upper limit value T2, or is between the lower and upper limit value TI <= dTh <T2. If dTh> = T2, then further analysis is carried out in method step 203 in order to check the case and, if necessary, the measures to be taken more precisely. It is true that dTh <

TI, in a sixth method step 206, information is provided that a higher capacity utilization is possible for the first component or the system in which the component is used. If TI <= dTh <T2, then in a seventh method step 207 provides information that the component can be operated in rated load operation. Another conceivable variant is provided with the arrangement of the temperature sensor directly on the active part of the component. Depending on the application, more precise information about the condition of the component can be obtained if the temperature sensor is installed at the hot point of the active part of the component. In this case, the comparison procedure described above can be used to identify an impending error, although, for example, components operating in partial load operation have not (yet) reached the maximum permissible temperature limits.

The two procedures of FIGS. 2 and 3 are not necessarily alternative and can be combined within the scope of the invention.

Claims

1. A method for maintaining a first electrical component in which

- Temperature measured values recorded on the first electrical component are stored as first measured data,

- Temperature measurement values recorded on at least a second and a third electrical component are stored as second and third measurement data,

- It is checked, taking into account the three measurement data, whether a maintenance process and / or a control measure is necessary on the first component.

2. The method according to claim 1, wherein the measurement data are compared with one another and the checking is carried out taking into account measurement data differences.

3. The method according to claim 2, wherein a measurement data mean value is formed and a first measurement data difference is formed between the first measurement data and the measurement data mean value, wherein the checking comprises a comparison of the first measurement data difference with a difference threshold value.

4. The method according to any one of the preceding claims, wherein the checking comprises forming a temperature change from the first measurement data.

5. The method of claim 4, wherein the checking comprises a comparison of the temperature rise with a reference temperature rise.

6. The method according to any one of the preceding claims, wherein the checking comprises comparing the first measurement data with ambient temperature measurement data recorded on the first component.

7. The method according to any one of the preceding claims, wherein the checking is carried out taking into account operating data of the electrical component.

8. The method according to any one of the preceding claims, wherein the checking is carried out taking into account a calibration of the temperature measurement.

9. The method according to any one of the preceding claims, wherein it is checked whether the measurement data or that derived therefrom

Sufficient size of a plurality of predetermined conditions, each condition being assigned a separate maintenance instruction which is triggered when the assigned condition is present.

10. Data processing system (7) which is set up to carry out a method according to claims 1 to 10.