DE4104921A1 - Metal-clad gas-insulated HV switchgear - has reference electrode set into opening of cladding for capacitive measurement of partial discharges at points along rod insulator - Google Patents

Abstract

An opening (2) is made in the metallic cladding (1) for an insulated reference electrode (12) which forms with the high-voltage conductor (6), and/or an electrode (5) at the same potential, a capacitance substantially free from partial discharges. A capacitive measuring electrode (9) surrounds the other end of the insulator (3) on which the conductor (6) is supported. Current pulses proportional to partial discharges therein are picked of (10, 11) for evaluation by a resistance-capacitance bridge circuit. ADVANTAGE - All dielectrically weak points can be located with precision both in mfg. quality control and in continuous monitoring during opertion.

Description

The invention is based on a metal-enclosed gas-insulated high-voltage system with one in the metal encapsulation filled with insulating gas arranged high-voltage current conductor, one from Potential of the conductor to the potential of the Metal encapsulated insulator and with a Device for determining partial discharges with a insulated against the metal encapsulation and Partial discharges of the insulator-detecting measuring electrode.

STATE OF THE ART

The invention relates to a prior art, as it results for example from US-A-42 77 746. In this patent publication is a metal encapsulated gas-insulated high-voltage system described in the Inside the metal gas-filled encapsulation Has high voltage potential current conductor. This conductor is from a disc-shaped insulator  worn, which led out of the metal encapsulation The outer edge is insulated from the metal encapsulation Measuring electrode used for the detection of partial discharges wearing. Such partial discharges can be caused, for example are caused by manufacturing defects, by damage in the Operation or conductive particles that build up during the Operation of the system on the surface of the isolator or other insulating, dielectric loaded parts of the Have high-voltage system attached. Partial discharges can to breakdown and ultimately failure of the isolator or any of the other insulating parts. At The measurement of the partial discharges is carried out by the Partial discharges produced very short breakdowns in the high-voltage system above the one formed here capacitive displacement current decoupled. Here is however, it cannot be ruled out that the measuring electrode Current pulses detected, which from the outside in the High voltage system enter or which of Partial discharges on any of the other insulating Parts are created.

SUMMARY OF THE INVENTION

The invention has for its object a metal-encapsulated gas-insulated high-voltage system from Specify the type mentioned, in which all dielectric vulnerable areas of isolation both at the Quality control in production, during on-site inspection as well as with constant monitoring in the company great security and accuracy can.  

The advantage of the invention can be seen in particular in that even in a large high voltage plant with many dielectric insulators not only with great safety of the partial discharge leading insulator specified, but also the location of this isolator can be located on the basis of local conductive Areas where these partial discharges occur.

Embodiments of the invention and the achievable therewith Advantages are explained in more detail below with the aid of drawings explained.

BRIEF DESCRIPTION OF THE DRAWINGS

Exemplary embodiments of the invention are shown in the drawings represented schematically, namely:

Fig. 1 is a plan view of a section through a circuit breaker designed as part of a metal-enclosed gas-insulated high voltage plant according to the invention,

Fig. 2 is an equivalent circuit diagram of the high voltage apparatus shown in Fig. 1,

Fig. 3 is a diagram of a usable in the high-voltage installation according to Fig. 1 partial discharge measuring device,

Fig. 4 is a circuit diagram of a loss factor measuring bridge which can be used in the high-voltage system according to Fig. 1, and

5 is a diagram of a usable in the high-voltage installation according to Fig. 1 loss factor measuring bridge with which the occurrence of a partial discharge in addition to the loss factor and the intensity of the partial discharge can be determined Fig. At the same time.

WAYS OF CARRYING OUT THE INVENTION

In the high-voltage system shown in FIG. 1, 1 denotes an essentially cylindrical metal encapsulation and filled with SF ₆ of a few bar pressure. The metal encapsulation 1 has an opening 2 on the end face, through which an insulator 3 designed as a switching rod is guided in a gas-tight manner to a drive 4 arranged outside the metal encapsulation 1 . The insulator 3 acts on a current conductor 6 which is surrounded by a fixed electrode 5 which is at high voltage potential and which is designed as a movable contact of a switching point of a circuit breaker and is at the same potential as the electrode 5 . The electrode 5 is of essentially cylindrical symmetry and is arranged coaxially with the metal encapsulation 1 and the insulator 3 . The opening 2 is delimited by a hollow cylindrical insulator 7 fastened to the metal encapsulation 1 , on the inner lateral surface of which a connecting flange 8 fastened at the end of the insulator 3 is mounted in a gas-tight sliding manner in the direction of movement of the insulator 3 which can be displaced by the drive 4 .

In the insulator 7 , a capacitive-acting measuring electrode 9 is attached to the insulator 3 at its end facing away from the electrode 5 . Partial discharges in the isolator 3, which are determined by the measuring electrode 9, are measured at an output 10 . Reference number 11 relates to an outgoing contact connected to the metal encapsulation 1 . At a largely partial discharge-free location of the system, an opening (not designated) is provided in the outer surface of the metal encapsulation 1 , in which a capacitively acting reference measuring electrode 12 is inserted in an electrically insulated manner from the metal encapsulation 1 . Reference current pulses can be tapped off at an output 13 of this measuring probe.

The operation of this system is explained below using the equivalent circuit diagram shown in FIG. 2. In this equivalent circuit diagram:
C ₁ the capacitance between the electrode 5 which is at high voltage potential and the current conductor 6 which is at the same potential and the metal encapsulation 1 ,
C ₂ the capacitance between the electrode 5 at high voltage potential and the current conductor 6 at the same potential and the measuring electrode 9 along the insulator 3 ,
C ₃ the parasitic capacitance between the measuring electrode 9 and the metal encapsulation 1 ,
C _{4 is} the parasitic capacitance between the electrode 5 at high voltage potential and the current conductor 6 at the same potential and the reference electrode 12 , and
C ₅ the capacitance between the reference electrode 12 and the metal encapsulation 1 .

When there is a partial discharge in the insulator 3 or on its surface, voltage breakdowns occur briefly. These are coupled out with the measuring electrode 9 for measurement as a capacitive displacement current. Current pulses occurring at the output 10 of the measuring electrode 9 are essentially proportional to the capacitance C ₂ and the intensity of the partial discharges occurring. In contrast, current pulses occurring at the output 13 of the reference electrode 12 are essentially proportional to the capacitance C ₄ .

To assess the insulation quality of the Isolators both in quality control in the Manufacturing, in the on-site inspection as well as in the permanent On the one hand, monitoring in operation becomes a Partial discharge measurement and on the other hand one Loss factor measurement carried out.

In the partial discharge measurement, the current pulses generated by partial discharges in the insulator 3 and on its surface and detected with the measuring electrode 9 are fed via the output 10 of the measuring electrode 9 to an input of the partial discharge measuring device 14 shown in FIG. 3. The outgoing contact 11 connected to the metal encapsulation 1 is connected to the other input of the partial discharge measuring device 14 connected therewith via the input impedance 15 .

When measuring the dissipation factor, only the dissipation losses implemented in the insulator 3 and on its surface are recorded. The parasitic, gas-insulated capacitance C _{4 of} the reference electrode 12 serves as the capacitive, lossless high-voltage normal element. For example, the measuring bridge 16 according to Schering shown in FIG. 4 can be used for the measurement. This measuring bridge has four bridge branches and a bridge diagonal which brings the two connection points of two bridge branches into operative connection with one another. The connection point arranged on the left in FIG. 4 is connected to the output 10 of the measuring electrode 9 , whereas the connection point arranged on the right in FIG. 4 is connected to the output of the reference electrode 13 . A minimum or zero voltage detector 17 is included in the bridge diagonal. Trimming resistors and / or capacitances are arranged in each of the two bridge branches below the bridge diagonals, whereas one of the two capacitors C ₂ or C _{4 is} arranged in each of the two bridge branches above the bridge diagonals. The voltage supply of the measuring bridge 14 is ensured via the electrode 5, which is at high voltage potential, and the outgoing contact 11 of the metal encapsulation 1 , which leads to the connection point of the two bridge branches lying below the bridge diagonal. After adjustment to the minimum voltage in the bridge diagonal, the loss factor tan δ of the isolator 3 can then be determined from the impedances of the four bridge branches.

The loss factor determined in this way represents a very sensitive measured variable for conductive areas along the surface of the insulator 3. The conductive areas need not necessarily have ohmic contact with the electrode 5 or measuring electrode 9 which is at high voltage potential. On a 220 mm long and when shift rod of a circuit breaker insulator 3 was executed so conductive surface areas with a surface area of approximately 110 mm x 20 mm with a surface resistivity between 15 °. . . 30 · 10 ⁹ Ω mm / mm can be clearly identified.

However, the measuring bridge 18 according to FIG. 5 can also advantageously be used to measure the loss factor. This measuring bridge corresponds in substantial parts to the measuring bridge 16 according to FIG. 4. In contrast to this measuring bridge, however, in the bridge diagonal it has a voltage measuring device 19 connected in parallel to the detector 17 , with which the effective value of the bridge diagonal voltage can be determined. Such a measuring bridge makes it possible to record both the partial discharges and the loss factor at the same time. Since the fast capacitive current pulses caused by the partial discharges approximately have an average current value identical to zero, they are of no importance for the bridge adjustment. In contrast, the RMS value of the bridge diagonal voltage is influenced by the partial discharges. The detected rms value of the bridge diagonal voltage is thus a measure of the partial discharge intensity in the insulator 3 and the loss factor of the insulator 3 can be determined by comparing the measuring bridge 18 . If the measuring device 19 is replaced by a measuring device measuring the time course of a signal with a simultaneously high input resistance, the detected signals additionally provide locating information about the measured partial discharges.

Label list

1 metal encapsulation
2 opening
3 isolator
4 drive
5 electrode
6 conductors
7 isolator
8 connecting flange
9 measuring electrode
10 exit
11 outgoing contact
12 reference electrode
13 exit
14 partial discharge measuring device
15 input impedance
16 measuring bridge
17 detector
18 measuring bridge
19 voltage measuring device

Claims (5)

1. Metal-encapsulated gas-insulated high-voltage system with a high-voltage conductor ( 6 ) arranged in the insulating gas-filled metal enclosure ( 1 ), an insulator ( 3 ) guided from the potential of the conductor ( 6 ) to the potential of the metal enclosure ( 1 ) and with a device for determining partial discharges partial discharges mounted with insulated from the metal enclosure (1) of the insulator (3) detected measuring electrode (9), characterized in that the metal enclosure (1) having an opening for receiving an insulated from the metal enclosure (1) disposed reference electrode (12) Which, together with the current conductor ( 6 ) and / or an electrode ( 5 ) located at its potential, forms a first capacitance (C ₄ ) largely free of partial discharges, and that, in addition to one provided for determining the partial discharges and from the output signals of the measuring electrode ( 9 ) acted on partial discharge meter t (14) is an applied from the output signals of the measurement (9) and the reference electrode (12) measuring bridge (16, 18) provided for determining the loss factor of the insulator (3). 2. High-voltage system according to claim 1, characterized in that the measuring bridge ( 16 ) is a Schering measuring bridge fed with high voltage, in which a second capacitance (C ₂ ) which is at the high voltage potential of the electrode ( 5 ) and at the same potential current conductor ( 6 ) and the measuring electrode ( 9 ) along the insulator ( 3 ) is formed, with the first capacitance (C ₄ ) is compared. 3. High-voltage system according to claim 2, characterized in that at a bridge diagonal having a minimum voltage in the bridge diagonal, in which a minimum voltage detecting detector ( 17 ) is arranged, two inputs are arranged diagonally opposite one another, one of which has a first output signal of the measuring electrode ( 9 ) and a second, the output signal of the reference electrode ( 12 ) is supplied. 4. High-voltage system according to claim 3, characterized in that a voltage measuring device ( 19 ) is connected in parallel with the detector ( 17 ) determining the effective value of the bridge diagonal voltage and / or detecting the exact time profile of the bridge diagonal voltage. 5. High-voltage system according to one of claims 1-4, characterized in that the insulator ( 3 ) is rod-shaped and is movably arranged with respect to the metal encapsulation ( 1 ) and at its end facing away from the current conductor ( 1 ) and / or the electrode ( 5 ) is surrounded by the fixed measuring electrode ( 9 ).