DE102007029905B4 - Method for operating an electrical transformer - Google Patents

Abstract

Method for operating an electrical transformer (10), wherein the transformer (10) is provided with at least two windings (15, 16), a selector switch (12) and a load switch (13), the load switch (13) having at least one over-resistance ( 22), and wherein the windings (15, 16) and the over-resistance (22) are accommodated in a common transformer housing (11) which is filled with a transformer oil (25), characterized in that before starting the transformer (10 ) the operating parameters of a non-permissible operating state in which the temperature of the over-resistance (22) reaches or exceeds a predetermined threshold, are determined by testing that the operating parameters of the non-permissible operating state are stored, and that during operation of the transformer (10) the occurrence of the non-permissible operating state is prevented.

Description

The invention relates to a method for operating an electrical transformer according to the preamble of claim 1. Such a transformer is for example from the DE 71 11 290 U out.

It is known, the windings and the selector switch of a transformer in a transformer housing and the load switch with the one or more switching resistors in accommodate a separate switch housing. The two casing are separated from each other with a transformer oil and a switch oil filled. If now during operation of the transformer arcs in the load switch or overheating the switching resistances arise, so this can - if at all - only to do so to lead, that the switch oil in the switch housing is damaged by outgassing or depositions. Because of the separation the two housings can the arcs or overheating however, do not cause that the transformer oil in the transformer housing is impaired. The transformer oil reserves thus, among other things, its insulating properties almost unchanged. With that you can the high requirements regarding the insulation of the windings the transformer also over to be fulfilled over a long period of time.

One Disadvantage of the known arrangement is that two housing provided Need to become, which is obviously associated with a lot of effort.

To overcome this disadvantage, it is known as a circuit breaker encapsulated To use component, such as an encapsulated vacuum switching device or an encapsulated thyristor circuit. Furthermore, the transfer resistances can not within the switch housing, but outside be placed in air. The generated by the switching operations electric arc then arise within the encapsulated component and have it no influence on the switch oil. Likewise, overheating the switching resistance to none damage of switch oil to lead, since she does not over the switch oil, but be discharged directly into the ambient air.

One Disadvantage of this arrangement is that the electrical connection the air-cooled switching resistors with an increased Effort is connected, and that the air cooling as such is not very is effective.

task The invention is a method for operating a transformer to overcome that overcomes the above disadvantages.

The Invention solves This object is achieved by a method for operating an electrical Transformer according to claim 1.

According to the invention Windings and the switching resistance of the transformer housed in a common transformer housing, that with a transformer oil filled is. So it is only a single case available that with a transformer oil filled must become. This represents a much lower cost than in the prior art. It is using the method of the invention guaranteed that overheating the switching resistors even can not occur so that in this respect no damage of the transformer oil can arise.

All in all This creates a transformer that has only a single housing, but still the high requirements in terms of insulation his windings too met a long period of time.

Procedural is provided according to the invention, that before commissioning of the transformer, a non-permissible operating state determined and stored by testing, at which the temperature of the overvoltage resistance reaches or exceeds a predetermined threshold, and that in operation of the transformer, the occurrence of this non-permissible operating state is prevented.

In order to Is it possible, during operation of the transformer, the determined non-permissible operating states targeted to prevent. This can be done in different ways.

So it is particularly advantageous if the non-permissible operating state explicitly is excluded from the operating range of the transformer. This ensures that the transformer operated only in the way is that non-permissible operating conditions of at the outset can not arise.

at In another advantageous embodiment, the temperature of the over-resistance is determined. Based on this temperature can then be determined whether a non-permissible operating state present or expected.

Especially is appropriate it then, if after detecting a non-permissible operating state an associated one Countermeasure is performed. This ensures that as possible already prevented the emergence of a non-permissible operating state becomes.

Further Features, applications and advantages of the invention will become apparent from the following description of exemplary embodiments of the invention, which are shown in the drawing.

The single figure of the drawing shows a schematic block diagram an embodiment an electrical transformer according to the invention.

In the figure is an electrical transformer 10 shown, which is a transformer housing 11 in which a selector switch 12 , a load switch 13 and two windings 15 . 16 are housed. The first winding 15 has a first turn number W1 and is connected to the second turn 16 having a second winding number W2, electromagnetically coupled. The second winding 16 has a plurality of taps 17 on, in each case over a certain number of stages of the turns W2 of the second winding 16 can be tapped.

The taps 17 are the selector switch 12 supplied with the two of the taps 17 can be selected in a manner not shown. The selector switch 12 is with the load switch 13 connected, so with the help of the load switch 13 between the two selected taps 17 can be switched. On the output side, the load switch 13 for example, with a star point 19 be connected, as indicated in the figure.

The load switch 13 contains at least one encapsulated vacuum switching device 21 and at least one over-resistance 22 , Instead of the vacuum switching device 21 It is also possible to provide another encapsulated component with which a load current can be interrupted, for example a thyristor circuit or the like.

The electrical connection of the vacuum switching device (s) 21 and the one or more switching resistors 22 can be realized in many ways. A good example is the circuit of the DE 23 21 369 directed.

The entire transformer housing 11 is with a transformer oil 25 filled. This means that the two windings 15 . 16 , the selector switch 12 and the load switch 13 all within the same transformer oil 25 are located. In particular, this means that the one or more switching resistors 22 in the same transformer oil 25 are like the windings 15 . 16 ,

Before being put into operation, the electric transformer shown in the figure 10 tested and tested. In particular, the transformer 10 tested for operating conditions in which the temperature of the or the switching resistors 22 reaches or exceeds a predetermined threshold.

This threshold is chosen such that the transformer oil 25 is not exposed to negative influences as long as the temperature of the switching resistors 22 not reached this threshold. In particular, the threshold value is chosen such that no harmful gas from the transformer oil 25 indicates as long as the temperature of the switching resistors 22 falls below the threshold. Also, the threshold is chosen so that no substances or particles from the transformer oil 25 be deposited as long as the temperature of the switching resistors 22 not reached the threshold. The threshold value is thus selected such that the occurrence of a temperature which is less than the threshold value does not lead to any damage to the transformer oil 25 leads.

For all those operating conditions of the transformer 10 in which the aforementioned threshold value is reached or exceeded, the associated operating parameters are now determined and stored.

By way of example, this may be an operating state in which the transformer 10 operated for more than 10 minutes with an overload of 140%. Or it may be an operating condition in which the load switch 13 of the transformer 10 performs more than 10 circuits in 3 minutes. Or it may be an operating condition in which the load switch 13 of the transformer 10 two circuits within 30 seconds. All these operating conditions are - as I said - in common that they cause the temperature of the switching resistors 22 at least reaches or even exceeds the explained threshold value.

These operating conditions will therefore be considered inadmissible below Operating states called.

In operation of the electric transformer 10 The figure is now ensured that the aforementioned non-permissible operating conditions in which the temperature of the switching resistors 22 reaches or exceeds the threshold, does not occur. This can be done in different ways.

The non-permissible operating states are explicitly excluded from the permissible operating range of the transformer 10 locked out. The remaining permissible operating range is communicated to the transformer operator. The transformer 10 can thus only be used for a case of application the one in which the non-permissible operating states do not occur. Or it must be the operator of the transformer 10 Make sure that the operation of the transformer 10 is monitored in such a way that, in the event of a foreseeable occurrence of a non-permissible operating state, suitable measures are immediately taken to prevent the occurrence of the non-permissible operating state.

Alternatively or additively, it is possible for the transformer 10 is monitored continuously with the help of an automated higher-level device. If the facility foresees that an inadmissible operating condition occurs, the facility will take appropriate countermeasures to prevent the occurrence of the non-permissible operating condition.

The device may be, for example, a computing device, in particular the switching operations of the circuit breaker 13 monitored and / or possibly also controls. If the probable occurrence of a non-permissible operating state is detected by the device, appropriate countermeasures may be stored in the device for each non-permissible operating state, which countermeasures are then executed.

Thus, it is possible that when exceeding a predetermined number of switching operations per unit time is provided as a countermeasure to increase the time interval of successive switching operations. This then leads to the one or more switching resistors 22 have more time to cool down so that their temperature drops or at least does not increase any further.

The device can also be, for example, electromechanical components, in particular the selector switch 12 act, and the example, too fast or too frequent switching the selector switch 12 prevent. It may also be electrical components that cause, for example, a current and / or voltage limitation or suppress current and / or voltage spikes.

Alternatively or additionally, it is possible that the one or more switching resistors 22 are provided with at least one temperature sensor. It is understood that the temperature of the one or more switching resistors 22 can also be measured in other ways. So it is possible by model calculations, the temperature of a transfer resistance 22 from other operating variables of the transformer 10 derive.

Reaches the temperature of the over-resistance 22 the predetermined threshold, this means that there is a non-permissible operating state. This can be detected with the aid of the temperature sensor, and preferably already when it is foreseeable that the reaching of the threshold value is imminent.

Of the Temperature sensor can with a parent Device connected. Is detected that a non-permissible operating state is imminent, so the facility can take appropriate countermeasures to meet. These can be countermeasures as they already are been explained are.

It is also possible that the temperature sensor has a direct influence, for example, on the time interval of the successive switching operations of the circuit breaker 13 or the selector switch 12 Has. For example, the temperature sensor may be a component of that electrical circuit with which the vacuum switching device 21 of the circuit breaker 13 is controlled.

Furthermore, it is alternatively or additionally possible that the one or more switching resistors 22 are provided with one or more devices that counteract heating thereof. These devices may be, for example, in a simple implementation of cooling fins or the like, with which the switching resistors 22 are provided. It is also possible with regard to these devices that the individual switching resistors 22 so mechanically with the transformer housing 11 are connected, that at least a part of the respective switching resistance 22 generated heat directly through this preferably metallic connection to the transformer housing 11 and from there to the ambient air is derived.

Claims (6)

Method for operating an electrical transformer ( 10 ), the transformer ( 10 ) with at least two windings ( 15 . 16 ), a selector switch ( 12 ) and a load switch ( 13 ), the load switch ( 13 ) at least one switching resistor ( 22 ), and wherein the windings ( 15 . 16 ) and the switching resistance ( 22 ) in a common transformer housing ( 11 ) housed with a transformer oil ( 25 ), characterized in that before commissioning of the transformer ( 10 ) the operating parameters of a non-permissible operating condition in which the temperature of the over-resistance ( 22 ) reaches or exceeds a predetermined threshold, is determined by testing that the operating parameters of the non-permissible operating state are stored, and that during operation of the transformer ( 10 ) the occurrence of the non-permissible operating state is prevented. Method according to claim 1, wherein the operating parameters of the non-permissible operating state are explicitly determined from the operating range of the transformer ( 10 ) are excluded. The method of claim 1 or 2, wherein the prospective Occurrence of a non-permissible Operating state is detected, and wherein after detecting a non-permissible Operating state an associated Countermeasure is performed. The method of claim 3, wherein the prospective Occurrence of a non-permissible Operating state is detected by the operating parameters. Method according to one of claims 3 or 4, wherein the temperature of the over-resistance ( 22 ) is detected, and it is detected by the temperature that a non-permissible operating state is imminent. Electric transformer ( 10 ), in which by a method according to claim 1, the occurrence of a non-permissible operating state is prevented.