DD240461B3 - METHOD FOR TESTING PRIMARY DEVELOPMENTS OF INDUCTIVE VOLTAGE TRANSFORMERS - Google Patents

Abstract

These windings are to be tested for latent defects, particularly shorted turns and layers. The principle of this test procedure consists in suitably activating masked defects in primary windings of inductive voltage transformers consisting of many turns of a thin wire, in such a manner that they can be detected by conventional measuring instruments without a special test set-up. This is achieved by shorting the primary winding already installed in the device and heating it up with an alternating voltage by excitation of another winding and raising it to a temperature which is within the permissible operating temperature. The primary winding is then heated in intervals with relatively high direct currents in such a manner that the temperature rise lies on the straight-line slope of the heating curve. Immediately after the test temperature has been reached, a continuous alternating voltage is applied, maximum stresses being generated during this loading by adding and disconnecting impedances in the exciter circuit.

Description

For this 1 page drawing

Field of application of the invention

The invention relates to a method for testing primary windings of inductive voltage transformers for latent fault locations.

Characteristic of the known technical solutions

In addition to the usual prescribed by international and national standards tests of inductive voltage transformers with AC, switching and lightning voltage and the measurement of the loss factor tan δ and the partial discharges is the control of the relatively high number of turns with a small conductor cross-section prepared primary winding on latent flaws, in particular Winding and ply closure, of particular importance. Through this winding and ply closures in the primary winding of an inductive voltage converter it comes in the operation of the same usually only after a certain period of operation to local overheating and possibly arcing in the primary winding, charring the most organic insulation occurs with gas formation, and it comes in extreme cases an explosive destruction of the entire voltage converter.

There are already known manufacturing and device-related methods for error assessment and arrangements. Thus, for example, in partial discharge measurements, the difference method is used, in which a device prepared for this special case without error is compared with the device to be tested. Another way to detect faults is to use an E.R.A. Discharge Dedector, which catalogs the characteristic appearances of faults on the individual windings, compares them with already tested windings and thus allows a pictorial comparison in the form of a fault atlas. In DE-PS 1 041154 a method for testing coils on Windungsschluß is described, in which the coil to be tested is magnetically coupled via an open yoke with an audio-frequency-fed resonant circuit coil. However, this and the aforementioned methods are only suitable for coils with a small number of turns and a larger conductor cross section and for coils with low dielectric strength. Further, the DE-PS 1178938 can be seen as technical information that can be tested by means of a device electrical coils under normal load by determining the ratio of coil voltage to coil current to Windungsschluß. It is based on the assumption that occur only when loaded with normal current winding turns of coils in appearance. However, practice has shown that testing under normal operational loads alone is not sufficient to detect latent faults in the primary winding of an inductive voltage converter. Compared with other electrical windings, the primary winding of such a transformer with an input voltage> 10 kilovolts represents an electrically and geometrically very compact structure. This makes it possible to determine a short-circuited winding both at a ratio of 1: 30,000, based on the total number of windings, and across the component the scattering of a winding with a wire diameter of 0.15 ... 0.24 millimeters η in a total winding cross section of about 10000 square millimeters, which corresponds to a ratio of 1: 350000, very difficult.

For these reasons, all direct measuring methods, such as power measurement, resistance measurement R and Z, error measurement, resonance method, etc., are not applicable or sufficient to reliably detect hidden faults, in particular turns in primary windings of inductive voltage transformers. In addition, the normal operating state with its possible heating represents only an insufficient static stress by pressure and electrical voltage. This results from the fact that the permissible overtemperature of a winding according to TGL 39759 of 65 Kelvin in the normal operating case and an ambient temperature of 35 ° C (24-hour average) must not be exceeded, so that certainly in normal operation, the permissible temperature Winding wires according to the heat resistance class according to TGL 8402 is not achieved. (This is, for example, 155 ° C. for the generally used copper enamelled wire with or without covering).

The time until the permissible winding overtemperature is reached is determined by the temperature time constant of the respective device, which can be determined according to Gotter, "Heating and Cooling of Electrical Machines" (Springer-Verlag 1954).

There are a variety of methods and arrangements for partially or fully simulating the operation and / or test case of electrical equipment:

In one known from DD-PS 214 697 (G 01 R 31/00) method for testing the thermal stability of high-voltage capacitor bushings two bushings are mounted on a test container, their current conductor connected to the conductor loop, inductively fed into this test current and at the same time test voltage to this Conductor loop laid, d. H. Again, there is essentially a high voltage test under operating conditions. In one of DD-PS 220724 (G 01 R 35/02) known method for testing inductive voltage transformers with low-power energy sources by secondary side excitation two high-voltage side interconnected inductive voltage converter of the same design are tested simultaneously and mutually, the voltage converter without distortion by applying a variable in height and frequency voltage is excited while the other voltage transformer of the signal extraction and the voltage measurement is used, ie, it is also here above all to the measurement of existing errors.

The current state of the art in testing for position or Windungsschluß in primary windings of inductive voltage transformers and other similar electrical devices is always based on existing, so-called rich conclusions, which is to be found with more or less success. Preemptive testing of primary windings for covert faults is not carried out and the previous test methods fail completely.

Object of the invention

The aim of the invention is the detection of latent winding and ply closures in primary windings of inductive voltage transformers consisting of many turns of thin wire.

Essence of the invention

The invention has for its object to find a test method for primary windings of inductive voltage transformers, with the hidden defects by a comprehensive stress of the individual turns and winding layers including their isolation are activated so that they can be determined by conventional measuring methods. The object is achieved in that after reaching the operating temperature

- the grounding of the high voltage terminal of the primary winding is canceled,

- That thereafter to the primary winding, a DC voltage source or an AC source frequency <50Hz connected and the primary winding a stream of a size that is at least one power of ten above the operationally permissible, are sent at intervals, the number and the duration of the intervals chosen be that on the one hand the temperature rise in the winding wire is almost in the rectilinear part of the rise of the heating curve and on the other hand, the permissible for the winding wire temperature is not exceeded and thirdly held in the primary winding, the temperature level reached for the winding wire admissible temperature,

- What immediately switched off after reaching this maximum temperature, the supply voltage and a nennfrequente, the maximum permissible continuous voltage for the voltage converter is applied

- And that in addition to this constant AC voltage by switching on and off of impedances in the primary winding circuit in the primary winding overvoltages are generated whose height in relation to the alternating voltage with a variable impedance so adjusted that the primary winding is exposed to a multiple test load.

As a result of winding closures, which occur when the breakdown voltage between the wires decreases, short-circuited windings heat up correspondingly to P = U ² / R. The turns heat up in such a way that oil evaporates, paper of the layer insulation charred and adjacent turns are heated above the permissible limit temperature. The vaporized oil is forced into the edge field along the layers, and the gas bubbles present create partial discharges that can be detected with conventional detectors. The test method according to the invention provides information about the insulation behavior of the primary winding at any time.

The lifetime loss associated with this test method, characterized by the temperature-time integral over the entire test period, including heating and cooling, is very small compared to the overall life of the insulation and thus negligible.

embodiment

Reference to an embodiment, the invention will be explained in more detail. The drawing shows a test circuit structure for carrying out the test method. The invention is explained for a voltage converter for 123 kV.

According to the invention, the primary winding, preferably by short-circuiting another, is heated by means of alternating current to the permissible excess temperature. The permissible overtemperature of a winding according to TGL 39759 of 65 K must not be exceeded for the specified load cases and an ambient temperature of 35 ° C (24-hour average). The heating time is determined by the temperature time constant of the device (see Gotter, "Heating and Cooling Electrical Machines") .The primary winding is then energized with relatively high DC values or an AC <50Hz with current densities at least one order of magnitude higher than the operational allowable The intervals allowed for the winding wire used are heated at intervals so that the temperature rise is nearly in the rectilinear rise of the heating curve, and the intervals are chosen such that the temperature increase does not exceed 3 K / min during the heating phase of 5 min, whereby the temperature in the winding can be equalized and the temperature level reached can be maintained, followed by a second heating for a period of 10 minutes, whereby the permissible temperature of the heat resistance class according to TGL 8402 (Wickel wires) of the enameled wire used by z. B. 155 ° C is not exceeded. Immediately after reaching the test temperature, a duration AC voltage of e.g. 123kV, which may occur in networks with an isolation voltage 123 N for 2 hours according to TGL 20445/02, and by switching on and off of impedances in the exciter circuit overvoltages which are suitable for repetitive tests of e.g. 123 kV devices must not exceed the value defined by TGL 39759 of 23OkV 0.9. According to the drawing, the primary winding of the inductive voltage converter 9 is secondarily short-circuited with the switches, and it is energized when the switch 12 is closed via the transformers 1 and 16 of the high-voltage transformer 17.

In this case, the switch 15 is kept closed by the control device 14, and the separator 10 is also closed, the separator 8 is opened. With the transformers 1 and 16 of the required for the heating of the voltage converter 9 current is set. After the required temperature is reached in the primary winding of the voltage converter 9, the transformer 1 is set to zero and the separator 10 is opened, after which the switch 12 opens and the switch 2 closes simultaneously. After opening the switch 11 and closing the disconnector 8 so that the conditions for the heating of the primary winding of the voltage converter 9 are given with DC. The outgoing of the transformers 1 and 3 current is rectified by means of rectifier 4 and fed via the separator 8 of the primary winding of the voltage converter 9. In this circuit, by adjusting the transformer 1, the heating of the primary winding in several time intervals, until the required test temperature is reached. Here, the resistor 5 as a discharge resistor for the smoothing capacitor 6 is effective, and the voltage divider 7 is used to measure the DC voltage. After setting the transformer 1 to zero by opening the disconnector 8 and the switch 2 and closing the disconnector 10 and the switch 12, the switching to perform the test of the voltage converter 9 to Windungsschluß in heated primary winding. With the transformers 1 and 16, the selected overvoltage is set for the voltage converter 9, wherein the switch 15 is closed via the control device 14. With the same setting of the transformers 1 and 16 and open switch 15 is set with the adjustable resistor 13, the test voltage. In order to generate overvoltages at the voltage converter 9, the switch 15 is actuated several times within the test procedure by the control device 14. At the same time it comes to transient effects of the exciting current, which cause the normal values are exceeded by a multiple and the primary winding of the voltage converter is simultaneously exposed to a multiple Prüfbeanspruchung. Thus, the individual windings and their isolation by temperature, stresses and electromechanical forces are claimed. This combination stress is an essential prerequisite for the activation of latent defect sites.

Claims (1)

Method for activating latent winding and ply terminations in the primary winding of a finished inductive high-voltage converter, in which the high-voltage converter with grounded high voltage terminal of the primary winding is heated to operating temperature by excitation of the secondary winding with alternating current, characterized in that after reaching the operating temperature - the grounding of the high voltage terminal of the primary winding is canceled, - That thereafter to the primary winding, a DC voltage source or an AC source frequency <50Hz connected and the primary winding a stream of a size that is at least one power of ten above the operationally permissible, are sent at intervals, the number and the duration of the intervals chosen be that on the one hand, the temperature rise in the winding wire is almost in the rectilinear part of the rise of the heating curve and on the other hand, the permissible for the winding wire temperature is not exceeded and thirdly held in the primary winding, the temperature reached the permissible temperature for the winding wire, - What immediately switched off after reaching this maximum temperature, the supply voltage and a nennfrequente, the maximum permissible continuous voltage for the voltage converter is applied - And that in addition to this constant AC voltage by switching on and off of impedances in the primary winding circuit in the primary winding overvoltages are generated whose height in relation to the alternating voltage with a variable impedance so adjusted that the primary winding is exposed to a multiple test load.