HIGH VOLTAGE INSTRUMENT TRANSFORMER AND METHOD FOR PARTIAL DISCHARGE RECOGNITION

Abstract

A high voltage instrument transformer includes a measuring assembly and isolator, with at least one sensor for partial discharge measurements. A method for partial discharge recognition in high voltage instrument transformers includes a detection of a signal from at least one sensor for partial discharge measurements, particularly a Transient Earth Voltage sensor.

Claims

1. A high voltage instrument transformer, comprising: a measuring assembly, an isolator, and at least one sensor for partial discharge measurements.

2. The high voltage instrument transformer according to claim 1, wherein the at least one sensor is a Transient Earth Voltage sensor.

3. The high voltage instrument transformer according to claim 1, wherein the at least one sensor is arranged on or directly arranged on a ground screen.

4. The high voltage instrument transformer according to claim 1, wherein the at least one sensor is electrically connected to a ground screen.

5. The high voltage instrument transformer according to claim 1, wherein an outer shield of a bushing of the instrument transformer is electrically connected to a ground screen.

6. The high voltage instrument transformer according to claim 1, wherein the at least one sensor is arranged on or directly arranged on an outside surface of the isolator.

7. The high voltage instrument transformer according to claim 1, wherein the at least one sensor is arranged inside of the isolator.

8. The high voltage instrument transformer according to claim 1, wherein the at least one sensor is connected to a monitoring system, or to a continuous and/or online monitoring system.

9. The high voltage instrument transformer according to claim 8, wherein the monitoring system, or the continuous and/or online monitoring system, comprises a computer, and/or elements in the cloud, and/or mobile elements, for continuous monitoring and/or monitoring according to service intervals.

10. The high voltage instrument transformer according to claim 1, wherein the instrument transformer is designed for voltages in a range of a kilovolt up to 1200 kV.

11. A method for partial discharge recognition in high voltage instrument transformers according to claim 1, comprising: detecting a signal from at least one sensor for partial discharge measurements.

12. The method according to claim 11, comprising: transforming detected signals from time domain to frequency domain, cutting frequencies above a defined threshold value resulting in truncated signals, retransforming the truncated signals from frequency domain to time domain, and determining and comparing of information content of the detected signals and the truncated signals.

13. The method according to claim 12, wherein signals with comparable information content of the detected signal and the truncated signal are identified as noise, and/or signals with lower information content of the truncated signal compared to detected signal information content are identified as a signal including partial discharge information.

14. The method according to claim 12, wherein the determination of information content is performed by a calculation of Shannon entropy.

15. The high voltage instrument transformer according to claim 7, wherein the at least one sensor is arranged directly on a surface of the isolator.

16. The high voltage instrument transformer according to claim 10, wherein the instrument transformer is designed for voltages in a range of 15 kilovolt up to 1200 kV.

17. The method according to claim 11, wherein the sensor comprises a Transient Earth Voltage sensor.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0030] The present invention is further described hereinafter with reference to an illustrated embodiment shown in the accompanying drawing, in which

[0031] FIG. 1 shows in sectional view a high voltage instrument transformer 1 according to the present invention, with a Transient Earth Voltage sensor 9 on the ground screen 10 to measure partial discharge.

DETAILED DESCRIPTION OF INVENTION

[0032] In FIG. 1 a high voltage instrument transformer 1 according to the present invention is shown. The high voltage instrument transformer 1 comprises a housing 2 with isolator 5 and vessel 6, particularly a high-pressure vessel. The isolator 5 is hollow, columnar, with rips on the outer surface to increase leakage current lengths. The columnar isolator 5 is arranged upstanding on the vessel 6, with excess pressure means 8, particularly a bursting disc, and high voltage terminals 12 on top. High voltage in the range of kilovolt up to 1200 kV can be applied to the high voltage instrument transformer 1 via terminals 12, to measure for example voltages in the grid and/or at electrical lines, and/or at electrical units like bushings, high voltage switches, transformers, and/or surge arresters.

[0033] The isolator 5 is made of materials and/or comprises materials as for example ceramic, silicone and/or composite materials. The vessel 6 is made of materials and/or comprises materials as for example metals like aluminum, steel, and/or cast iron. The vessel 6 is arranged on a base with earth connection 7, for example made of steel on a concrete basement. Outside the vessel 6 a terminal box 13 is arranged with for example electric terminals and/or electronics, for example to measure voltages, process signals and transfer signals/information to monitoring devices. For example, computer, sense boxes, data receiver and/or transmitter for particularly online monitoring like mobile units and/or data cable units/online units for internet, are arranged in terminal box 13.

[0034] A measuring assembly to measure high voltages is arranged for example in the vessel 6, comprising particularly a primary winding 3 and a voltage transformer core 4. High voltage terminals 12 of the high voltage instrument transformer 1 on top of the isolator 5 are electrically connected via a bushing 11, particularly comprising a metal bar made of aluminum, steel and/or copper, to the measuring assembly in the vessel 6. The metal bar is surrounded by control electrodes embedded for example in isolator paper, not shown in FIG. 1 for reasons of simplicity, and at the passage from isolator 5 to vessel 6 a ground screen 10, for example made of a metal like copper, aluminum and/or steel, is arranged. Isolator 5 and vessel 6 are particularly filled by a fluid for isolation 15, for example an isolation gas like SF.sub.6, Clean Air and/or an isolation liquid like oil.

[0035] According to the present invention, a partial discharge sensor 9, particularly a Transient Earth Voltage sensor, is arranged at, particularly directly on the ground screen 10 and/or electrical connected to the ground screen 10. Partial discharges preferably propagate along capacitive paths. When a partial discharge incepts in or at the isolator 5, the partial discharge propagates through the bushing capacitance, for example represented by aluminum multi-shields, to the shielded ground, creating a closed circuit. A signal, after flowing through the bushing, passes through the screen to “close” the electrical circuit, enabling a reliable partial discharge measurement.

[0036] Alternatively, and/or additionally, not shown in FIG. 1 for reasons of simplicity, an outer shield of the bushing of the high voltage instrument transformer can be electrically connected to ground screen. Alternatively, and/or additionally, not shown in FIG. 1 for reasons of simplicity, further sensors can be arranged, particularly directly arranged on the outside surface of the isolator 5, and/or inside of the isolator 5, particularly directly on the surface of the isolator.

[0037] The partial discharge sensor 9, particularly Transient Earth Voltage sensor, is electrically and/or optically connected for example by a connection wire 14 to terminal box 13. Signals measured with sensor 9 are directly or processed transmitted to terminal box 13, for example to be processed further and transmitted to a central control room, to mobile devices and/or to be locally displayed for example at an alarm light. A monitoring, continuously or in particularly predefined periods of time, of the condition of the high voltage instrument transformer 1 is possible with sensor 9, for example via mobile and/or cable/internet connection to a central control and/or devices in the cloud.

[0038] The partial discharge is a localized dielectric breakdown of the electrical isolation at high voltages between electrical poles, introducing alternating voltages and/or currents in or at the isolator 5. Partial discharge signals are for example measured in form of voltage with time. The partial discharge signal is small compared to the high voltage at terminals 12, with high voltage for example in the range of a kilovolt up to 1200 kV, compared to some picocoulomb signals of partial discharge, i.e. small voltage and current signals. The partial discharge at or in the isolator 5 starts for example within voids, cracks, contaminants or inclusions, particularly at conductor-dielectric interfaces, and in liquids partial discharge starts particularly in bubbles, contaminants and/or inclusions. The partial discharge is only limited to a portion of isolation. The discharge is only partially bridging the distance between the poles respectively between electrical conductors.

[0039] As the partial discharge is initiated, high frequency transient current pulses appear and persist for nano- to microseconds. Then the current pulses disappear and reappear repeatedly as for example a sinewave passes through the zero crossing. The partial discharge signals are short in duration and exhibit rise times of currents in the range of nanoseconds. High levels of electrical background noise, for example due to corona, crosstalk and other effects, make a correct measurement and simple recognition and determination of partial discharge within a measured signal of high voltage/currents difficult.

[0040] Due to the short duration and due to rise times in the range of nanoseconds of partial discharge currents in high voltage applications, a visualization and distinguishing between noise and partial discharge in voltage/current against time plots is difficult. To identify partial discharge and/or to determine a value of partial discharge, according to the present invention the information content I of a signal S is investigated. Measured signals with time S(t) are transformed from time to frequency domain for example by Fourier Transform and/or Discrete Cousin Transform. Frequencies f above a predefined frequency limit f.sub.lim are cut off and truncated signals are obtained, by removing the signal components at frequencies higher than f.sub.lim. The value of frequency limit f.sub.lim is for example defined every time at the beginning of a monitoring activity respectively measurement. In a step after removing frequencies f above a predefined frequency limit f.sub.lim, signals are transformed back respectively retransformed from frequency to time domain.

[0041] Partial discharge signals contain an information, while noise signals do not contain information. Noise signals are completely uncorrelated among themselves. By switching from the time domain to the frequency domain, each component has a part of the global information I.sub.i. By cutting off parts of the signal above frequency limit f.sub.lim, information is lost, if the measured signal comprises partial discharge and does not consist only of noise. According to the present invention the method respectively algorithm is to extract the information from the sampled signals, for example by calculating the Shannon entropy, and compare the information content of the sampled signal with the information content of the truncated signal, derived by cutting off frequencies of the signal above frequency limit f.sub.lim.

[0042] The information content of the measured respectively sampled signals is calculated, particularly by a computer locally and/or in the cloud, as described above for example by calculating the Shannon entropy, and the information content of the truncated signal respectively signal after cutting off frequencies is calculated, particularly by a computer locally and/or in the cloud, likewise as described above for example by calculating the Shannon entropy. Both calculations are for example performed in time with measurements or separately one after another, or in a predefined order. After removing frequency components, a time domain signal for the truncated signal is obtained for example by the inverse integral transform, particularly by Fourier Transform and/or Discrete Cousin Transform. The determination of information content of measured and truncated signals is analogous, for example in both cases by calculating the Shannon entropy.

[0043] A comparison of information content of the measured and truncated signals results in a recognition and/or determination of partial discharge. A comparison is performed for example manually and/or automatically, for example by a computer and/or in the cloud. Methods to compare signals include for example division and/or subtraction of the information content of the measured and truncated signals. For division a result is smaller than one, if a measured signal comprises partial discharge. Without partial discharge is a division result, which is exactly or mainly one, since a signal consists only of noise, and no information is lost by cutting off frequencies.

[0044] A recognition and/or determination of partial discharge has advantages as described above, for example a warning can be provoked and/or transmitted and further actions triggered, for example switching off voltage and/or disconnecting high voltage units from the grid, to avoid damage and/or destruction/failure of the units. Partial discharge measurements are also providing quality assessment and diagnostic results. The partial discharge is for example an indicator for the status of the high voltage instrument transformer 1 under test. It is performed in factory quality tests, to show proper function of produced units. In operation in the grid, with a lot of background noise, an online monitoring on high voltage units, for example high voltage switches, bushings, and/or transformers, is possible.

[0045] The above described embodiments of the present invention can be used also in combination and combined with embodiments known from the state of the art. For example, partial discharge can be detected by once performing the steps, particularly all steps as described before. A higher reliability is reached by performing the steps, particularly all steps as described before, repeated. An iteration method to determine partial discharge can include determining a value of frequency limit f.sub.lim. An iteration method can comprise repeating steps according to the present invention, and changing cut off frequency limit f.sub.lim, till a change of Shannon entropy occurs and/or no change of Shannon entropy occurs with changed frequency limit f.sub.lim.

[0046] Additional sensors, particularly Transient Earth Voltage sensors, optical, acoustic, and/or electrical sensors, can be comprised by the high voltage instrument transformer 1 and/or combined used with external sensors, to improve sensitivity and/or reliability, and to add additional information to measuring signals, enabling a high sensitivity, continuous measuring with time, with simple equipment at low cost and complexity, to reliably detect and determine partial discharge, with advantages as described above, for example prevention of damage and/or destruction of electrical units and/or the grid.

TABLE-US-00001 List of Reference Characters 1 high voltage instrument transformer 2 housing 3 primary winding of measuring assembly 4 voltage transformer core of measuring assembly 5 isolator 6 vessel 7 base with earth connection 8 excess pressure means, particularly bursting disc 9 partial discharge sensor 10 ground screen 11 bushing 12 high voltage terminals 13 terminal box 14 electrical connection of the terminal box with the partial discharge sensor 15 fluid for electrical isolation, particularly isolation gas and/or oil