TAP CHANGER WITH VACUUM INTERRUPTERS

Abstract

The invention relates to a tap changer having vacuum interrupters for switching over between winding taps of a tapped transformer without interruption. The tap changer according to the invention having vacuum interrupters is based on the general idea of combining the functionalities of at least one conventional vacuum switching contact which switches under load and a further mechanical switching means according to the prior art in just one single vacuum interrupter with two separately moving contact systems.

Description

The invention relates to a tap changer with vacuum-switching tubes for interrupted changeover between winding taps of a tapped transformer.

A tap changer is known from DE 20 21 575 that comprises, in total, four vacuum-switching tubes per phase. Provided in each of the two load branches are a respective vacuum-switching tube as a main contact and a respective further vacuum-switching tube, in series connection with a switch-over resistance, as a resistance contact.

When uninterrupted load changeover from the previous winding tap n to a new, preselected winding tap n+1 takes place initially the main contact of the side switching off is opened and thereupon the resistance contact of the side taking over closes so that a compensating current limited by the switch-over resistors flows between the two taps n and n+1.

After the previously closed resistance contact of the side switching off has opened, the main contact of the side taking over then closes so that the entire load current is conducted from the new winding tap n+1 to the load diverter; the changeover is concluded.

However, in various cases of use such known tap changers with vacuum-switching tubes for regulation of power transformers a high surge voltage strength, up to 100 kV and significantly above that, is required. Such undesired surge voltages, the level of which is substantially dependent on the construction of the tapped transformer and the winding parts between the individual tap stages, are on the one hand lightning surge voltages that result from lightning strikes in the mains. On the other hand, switching surge voltages caused by unpredictable switching surges in the mains to be regulated can also occur.

In the case of insufficient surge voltage resistor of the tap changer a temporary tap short circuit or an undesired break-through at the ceramic member or the attenuating screen of vacuum-switching tubes in the load branch not conducting the load current can happen that not only can cause long-term damage thereof, but in general is undesired.

This leads in many cases in the design of the switching paths and thus particularly also of the vacuum-switching tubes to over-dimensioning so that these reliably withstand the described voltage loading. Not only the small constructional space currently available with modern apparatus, but also the economics as well as serviceability of such vacuum-switching tubes cause such over-dimensioning to appear disadvantageous.

A tap changer is proposed in DE 10 2010 024 255 (not prior-published) in which a first winding tap of a first main current branch is connected with a load diverter by way of a series connection consisting of a first mechanical changeover switch and a first switching means, i.e. a vacuum-switching tube or alternatively a semiconductor component. In a symmetrical form of construction analogous thereto a second winding tap of the second main current branch is similarly connected with the load diverter by way of a series connection consisting of a second mechanical changeover switch and a second switching means, i.e. a second vacuum-switching tube or alternatively a second semiconductor component. Moreover, a first auxiliary current branch with an included resistor is branched off between the first winding tap and the first mechanical changeover switch, by means of which an electrical connection with the second mechanical changeover switch of the second main current branch is producible, and a second auxiliary current branch with a further included resistor is branched off between the second winding tap and the second mechanical changeover switch, by means of which an electrical connection with the first mechanical changeover switch of the first main current branch is producible.

In other words: a mechanical changeover switch that is connected in series with the respective vacuum-switching tube and that ensures complete electrical separation of the respective unconnected winding tap and thus a high surge voltage resistor, is present in the known tap changer in each main and auxiliary current branch.

All tap changers known from the prior art require several vacuum-switching tubes and additional mechanical switching elements per phase that due to the large amount of space required by the individual switching means and the accompanying constructional mechanical outlay is disadvantageous and, above all, costly. Not least this is also because for a changeover process a plurality of requisite individual components is needed in the tap changer for switching sequence realization that then have to interengage within a few tenths of a second in a changeover process precisely defined in terms of time.

It is therefore the object of the present invention to indicate a tap changer with vacuum-switching tubes for uninterrupted changeover between winding taps of a tapped transformer, which enables reduction in the complexity and the required individual components, in that case, in particular, makes mechanical switching means redundant and in addition, however, has a high surge voltage resistor.

This object is fulfilled by a tap changer with vacuum-switching tubes with the features of the first claim. The subclaims in that case relate to particularly preferred developments of the invention.

The tap changer according to the invention with vacuum-switching tubes is based on the general idea of combining into only one single vacuum-switching tube with two separate movable contact systems the functionalities of at least one conventional vacuum switching contact switching under load and a further mechanical switching means according to the prior art. In other words: In the tap changer according to the invention the at least two previously separate required switching means, namely the at least one vacuum-switching tube switching under load and the further mechanical switching means, are no longer constructed—as in accordance with the prior art—as individual subassemblies and separately incorporated in the tap changer, but are combined into only a single vacuum-switching tube with two vacuum switching contacts. The mechanical switching means, which in the tap changer according to the invention is now an integral component of the vacuum-switching tube, can in that case act not only as a simple on/off switch, but also as a changeover switch.

According to a preferred form of embodiment of the invention the switching chambers of the vacuum-switching tube for the vacuum switching contact switching under load and the further vacuum switching contact switching without load, which functionally replaces the previous mechanical switching means, are respectively arranged in a separate vacuum chamber of mutually sealed construction. The constant dielectric strength of the vacuum chamber, the vacuum switching contact replacing the mechanical switching means, is thus guaranteed, since no metallization, which occurs as a consequence of changing over carried out under load, can deposit in this vacuum chamber at the insulating paths.

Vacuum-switching tubes with two contact positions are already known per se.

DE 3344367 relates to a vacuum-switching tube with two contact pairs that are connected in series and actuatable simultaneously, in a single vacuum chamber.

DE 197 56 308 C1 relates to a similar vacuum-switching tube with two switching paths arranged on a common axis, wherein internally disposed contact compression springs are provided.

EP 0 258 614 B1 describes the combination of a vacuum-switching tube and a specific electrical connection at a tap changer. In this case, several switching paths are arranged in a vacuum chamber, which causes a complicated construction of the vacuum-switching tube annular fixed contacts.

Finally, DE 10 2006 033 422 B3 describes a further vacuum-switching tube with multiple functionalities, wherein here as well not only annular fixed contacts, but also internally disposed contact compressions springs are required.

The invention will be explained in still more detail by way of example in the following on the basis of figures, in which:

FIG. 1 shows a tap changer according to the prior art,

FIG. 2 shows a vacuum-switching tube according to the invention for a tap changer, in a schematic illustration,

FIG. 3 shows a form of embodiment of a vacuum-switching tube according to the invention for a tap changer, in a schematic form of embodiment,

FIG. 4 shows a further tap changer known from the prior art and

FIG. 5 shows a further form of embodiment of a vacuum-switching tube according to the invention for a tap changer.

A tap changer known from the prior art is illustrated in FIG. 1. The selector of the tap changer, which prior to the actual load changeover undertakes power-free selection of the new winding tap—here n+1—to be switched over to, is not shown. The load changeover switch has two load branches A and B that are respectively electrically connected with a winding tap n or n+1. The tap changer has a main current branch and an auxiliary current branch in each load branch.

The first main current branch produces an electrical connection from the winding tap n via a mechanical changeover switch U₁ and a vacuum-switching tube V₁, which is connected in series therewith, to the load diverter LA. In a symmetrical mode of construction analogous thereto the second main current branch similarly produces an electrical connection from the winding tap n via a mechanical changeover switch U₂, which is connected in series, and a vacuum-switching tube V₂ to the load diverter LA.

A first auxiliary current branch with an included resistor R₁ is branched off between the winding tap n and the mechanical changeover switch U₁ of the first main current branch, by means of which auxiliary current branch an electrical connection with the mechanical changeover switch U₂ of the second main current branch is producible. In a further mode of construction analogous thereto a second auxiliary current branch with an included resistor R₂ is branched off between the winding tap n+1 and the mechanical changeover switch U₂ of the second main current branch, by means of which auxiliary current branch an electrical connection with the mechanical changeover switch U₁ of the first main current branch is producible. Depending on the setting of the respective switching means the first auxiliary current branch can thus produce an electrically conductive connection from the winding tap n via the resistor R₁ and the switching means connected in series therewith, namely the mechanical changeover switch U₂ and the vacuum-switching tube V₂, to the load diverter LA, and the second auxiliary current branch from the winding tap n+1 via the resistor R₂ and the switching means connected in series therewith, namely the mechanical changeover switch U₁ and the vacuum-switching tube V₁.

The stationary operation of the electrically connected winding tap n is shown in FIG. 1, in which the load current flows from the winding tap n via the mechanical changeover switch U₁ and the closed vacuum-switching tube V₁ directly to the load diverter LA. Since the current selects the path of the lowest internal conduction resistance, only a negligibly small proportion of the load current flows from the winding tap n via the branched-off first auxiliary current branch to the load diverter LA.

FIG. 2 shows a vacuum-switching tube according to the invention. It comprises two separate contact systems 1 and 11 arranged in separate vacuum chambers 10 and 20, wherein the contact system 1 realizes a mechanical changeover switch denoted in FIG. 1 by U₁ or U₂ and the contact system 11 realizes a vacuum-switching tube denoted in FIG. 1 by V₁ or V₂. In that case, a common housing 1 enclosing the entire vacuum-switching tube is provided. Provided centrally in the rotationally symmetrical longitudinal axis s₁ is an upper, movable plunger 2 and, at the opposite end, a lower, movable plunger 3 that in the interior of the housing 1 carry contact members 4 and 5 in a manner known per se. The two contact members 4 and 5 can be brought into electrical connection with a corresponding fixed contact 6 or 7 separately and independently of one another by actuation of the respective plunger 2 or 3. On the side opposite the fixed contact 6 only the movable contact 4 can be brought into connection with a further contact 11. In addition, the upper fixed contact 6 is electrically connected with a first upper plate 12 and the lower fixed contact 7 with a second lower plate 13. The two plates 12 and 13 project in such a manner beyond the side wall of the housing 1 that electrical terminals can be mounted thereat. The known contact springs that co-operate with the plungers 2 and 3, are, for reasons of clarity, not illustrated here. However, an upper bellows 7 and a lower bellows 8, which can be of the same or also different construction, are illustrated. In addition, several insulating ceramic members 9 are also illustrated here.

With the vacuum-switching tube according to the invention in the contact system 1, a mechanical changeover switch is thus functionally replaced by a vacuum switching contact that switches without load. If the described vacuum-switching tube is mirrored on a tap changer of FIG. 1, then according to the invention the two previously separate switching elements V₁ and U₁ or V₂ and U₂ are now combined in a single vacuum-switching tube with the separately controllable contact systems 1 and 11. If an electrically conductive connection is created of the contact 11 of the vacuum-switching tube according to the invention via a resistor R₂ with the winding tap n+1, the upper electrically conductive plate 12 with the winding tap n, the lower electrically conductive plate 13 with the load diverter LA and between the lower plate 13 and the upper plunger 2 then the tap changer described in FIG. 1 can thereby be mechanically realized in particularly simple manner.

A first form of embodiment of a vacuum-switching tube according to the invention is shown in FIG. 3. In departure from FIG. 2, in the form of embodiment of FIG. 3 the enclosing housing 1 is of two-part construction in such a manner that the contact system 1 is enclosed by a first housing part 1.1 and the contact system 11 by a second housing part 2.2. The upper plunger 2 is in that case fixedly connected with the first housing part 1.1 so that a movement of the plunger 2 executed along the axis s₁ of symmetry can thereby be transmitted to the first housing part 1.1 and in the case of a corresponding switching setting the upper fixed contact 6 is electrically connectable with either the contact 11 or the movable contact member 4. In addition, the upper fixed contact 6 and the lower fixed contact 7 are in constant electrical connection with one another.

In the case of this form of embodiment, as well, with the vacuum-switching tube according to the invention in the contact system 1 a mechanical changeover switch is functionally replaced by a vacuum switching contact that switches without load. If the contact 11 of the vacuum-switching tube according to the invention is connected with the winding tap n, the upper plunger 2 via a resistor R₂ with the winding tap n+1 and the lower plunger 3 with the load diverter LA then the tap changer described in FIG. 1 can thereby be mechanically realized in particularly simple manner.

A further tap changer known from the prior art is shown in FIG. 4. It has a first load branch in which a vacuum-switching tube V₃ acting as a main contact and a mechanical changeover switch U₃ connected in series therewith as well as a switch-over resistor R₃ parallel thereto and a vacuum-switching tube V₄ acting as a resistance contact are present. The second load branch comprises, in entirely analogous manner, a vacuum-switching tube V₆ and a mechanical changeover switch U₄ connected in series therewith as well as parallel thereto a further switch-over resistor R₄ and a vacuum-switching tube V₅.

FIG. 5 shows yet a further form of embodiment of a vacuum-switching tube, in which the contact system 1 functionally replaces the two vacuum-switching tubes V₃ and V₅ or V₆ and V₄ of the tap changer of FIG. 4 and the contact system 11 forms the respectively associated changeover switch U₃ or U₄. This form of embodiment also comprises two physically separate vacuum chambers 10 and 20 that receive the respective contact system 1 or 11. In that case, a common housing 1 enclosing the entire vacuum-switching tube is provided. Provided centrally in the rotationally symmetrical longitudinal axis s₁ is an upper, movable plunger 2 and, at the opposite end, a lower, movable plunger 3 that in the interior of the housing 1 carry contact members 4 and 5 in a manner known per se. The two contact members 4 and 5 can be brought into electrical connection with a corresponding fixed contact 6 or 7 separately and independently of one another by actuation of the respective plunger 2 or 3. On the side opposite the fixed contact 6 the movable contact 4 can be brought into connection with a further contact 11, so that the movable contact 4 can thus electrically co-operate with either the fixed contact 6 or the further contact 11. In addition, the upper fixed contact 6 and the lower fixed contact 7 are in electrical connection. Arranged therebetween is a metallic plate 14 that separates the two vacuum chambers 10 and 20 from one another. The known contact springs, which co-operate with the plungers 2 and 3, are here, for reasons of clarity, not illustrated. However, an upper bellows 7 and a lower bellows 8, which can be of the same or also different construction, are illustrated. In addition, several insulating ceramic members 9 are illustrated here.

If the vacuum-switching tube described in FIG. 5 is mirrored on a tap changer of FIG. 4, then according to the invention the two previously separate switching elements V₃, V₅ and U₃ or V₆, V₄ are now combined in a single vacuum-switching tube with the separately controllable contact systems 1 and 11. If the contact 11 of the vacuum-switching tube illustrated in FIG. 5 is electrically conductively connected by way of a resistor R₄ with the winding tap n+1, the upper plunger 2 with the load diverter LA and the lower plunger 3 with the winding tap n then the tap changer described in FIG. 4 can be mechanically realized in particularly simple manner.

Claims

1. A tap changer with vacuum-switching tubes for uninterrupted changeover between winding taps of a tapped transformer, the tap changer comprising: two load branches for each phase to be switched, each load branch having in a main current branch a vacuum switching contact that acts as a main contact and a mechanical switching means connectable therewith in series,an auxiliary current branch for each phase to be switched and connectable in parallel with the respective load branch, each auxiliary current branch in the current-conducting state having at least one switch-over resistor and a vacuum switching contact acting as an auxiliary contact, anda common load diverter connectable not only with the main current branch but also with the auxiliary current branch of each load current branch, at least one of the vacuum switching contacts of the main or auxiliary current branch and the respective mechanical switching means being combined into a single vacuum-switching tube with two first and second separately movable contact systems.

2. The tap changer according to claim 1, wherein the first contact system forms the mechanical switching means and the second contact system forms the vacuum switching contact.

3. The tap changer according to claim 1, wherein the first contact system comprises the two vacuum switching contacts and the second contact system forms a mechanical switching means.