ON-LOAD TAP CHANGER

Abstract

The invention relates to an on-load tap changer for switching among winding taps of a step transformer without interruption. According to the invention, in each auxiliary current branch of the on-load tap changer, which operates with vacuum switching tubes as switching elements, additional switches are provided in series with the vacuum switching tubes and the respective winding tap. Said additional switches cause a complete galvanic isolation of the vacuum switching tubes in the auxiliary current branches in steady-state operation.

Description

The invention relates to an on-load tap changer for uninterrupted switching over between winding taps of a tapped transformer.

On-load tap changers have been known for many years; although they previously had mechanical contacts, which operate under oil, for load changeover, numerous more recent apparatus have vacuum switching tubes. The use of vacuum switching tubes for load changeover prevents formation of arcs in the oil and thus oil contamination of the load changeover switch oil. It thus allows lengthened maintenance intervals.

On-load tap changers with vacuum switching tubes are known with numerous different circuits with two, three, four or even more switching vacuum switching tubes per phase. A typical circuit, here with three vacuum switching tubes per phase, is shown by DE 10 2007 004 530 A1.

However, in various cases of use of such known on-load tap changers with vacuum switching tubes for regulation of power transformers a high surge-voltage strength of up to 100 kV and significantly above that is required. Such undesired surge voltages, the height of which is substantially dependent on the construction of the tapped transformer and the winding parts between the individual tap steps, are on the one hand lightning surge voltages which result from lightning strikes in the mains. On the other hand, switching surge voltages can also occur which are caused by unpredictable switching surges in the mains to be regulated. In the case of insufficient surge-voltage strength of the on-load tap changer a transient step short-circuit or undesired disruption of the ceramic or the damping screen of vacuum switching tubes in the load branch not conducting the load current can occur, which not only can cause long-term damage thereof, but also is generally undesirable. This leads in many cases in the design of the switching paths and thus particularly also the vacuum switching tubes to over-dimensioning so that these safety 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 have the consequence that such over-dimensioning appears to disadvantageous.

In order to combat excessive surge-voltage loads it is already known from DE 2357209 A and DE 2604344 to provide protective spark gaps or voltage-dependent resistors between the load branches; however, these means are, in various cases, insufficient and are unable to exclude or completely exclude harmful surge-voltage loads in their effect.

The object of the invention is therefore to avoid such over-dimensioning of the vacuum switching tubes, but still ensure the requisite voltage strength in an on-load tap changer according to the invention.

This object is fulfilled by an on-load tap changer with the features of the first claim. The subclaims relate to advantageous developments of the invention.

The general inventive idea consists of displacing the described voltage load from the vacuum switching tubes to contact arrangements arranged in series therewith. After successful switching off or switching over—depending on the circuit—by the vacuum switching tubes the additional contact arrangements, according to the invention, switching free of current subsequently thereto ensure complete separation of potential. Before the next load changeover, i.e. before switching on the vacuum switching tubes, the potential is connected again in reverse sequence initially by the contact arrangements according to the invention.

The contact arrangements according to the invention can be realized as mechanical contacts directly in the insulating oil, but they can also be realized as further vacuum switching tubes or in semiconductor technology.

The invention is explained in the following by way of embodiments, in which:

FIG. 1 shows the circuit of a first on-load tap changer according to the invention,

FIG. 2 shows the switching sequence thereof and

FIG. 3 shows the circuit of a further on-load tap changer according to the invention.

An on-load tap changer, the load changeover switch of which uninterruptedly switches over between two winding taps A, B is shown in FIG. 1. The electrical path which in stationary operation conducts the load current is illustrated in the middle. It comprises a first vacuum switching cell MSV and, in series therewith, a mechanical contact MTF, which depending on the switch can connect each of the two winding taps A and B with the first vacuum switching cell MSV. Shown on the left and right thereof are the two auxiliary current paths which produce the uninterrupted switching-over of the load current; during the load changeover, they can be briefly connected between the taps and the load shunt LA and temporarily conduct the circular current. They each consist of a further vacuum switching tube TTV_A or TTV_B and, in series therewith, a switch-over resistor R.

According to the invention, connected between each of the connectable winding taps A, B and vacuum switching tube TTV_A or TTV_B in the auxiliary current paths in series therewith is a respective contact SCV_A or SCV_B which in stationary operation completely electrically isolates, as an auxiliary contact which switches free of current, the vacuum switching tube TTV_A or TTV_B and realizes a separation of potential. A secure protection of these vacuum switching tubes from excess voltages, for example surge voltages, is thus guaranteed in simple, but effective manner.

FIG. 2 shows the actuation sequence of this load changeover switch according to the invention. It can be seen that the contacts SCV_A and SCV_B according to the invention prior to the start of the actual switching-over produce the necessary electrical use of the vacuum switching tube TTV_A or TTV_B in the respective current-conducting auxiliary branch and after the conclusion of the switching-over again separate the potential at the then other auxiliary branch.

FIG. 3 shows a modified form of embodiment of a load changeover switch according to the invention of an on-load tap changer. In this case, the mechanical contacts SCV_A and SCV_B according to the invention are constructed not as individual contacts, but as changeover contacts. Such an embodiment enables advantageous actuation of these contacts, the function and effect of which does not otherwise change.

It is to be emphasized that the function of the contacts according to the invention, which are provided in an auxiliary current circuit in series with each vacuum switching tube and which in the embodiments are denoted by SCV_A and SCV_B, are not bound to a specific circuit or number of vacuum switching tubes. Numerous other circuits are possible and feasible within the scope of the invention.

Claims

1. An on-load tap changer for interrupted switching over between winding taps of a tapped transformer, the tap changer comprising a selector for power-free preselection of the new winding tap to be switched over to, anda load changeover switch for the actual uninterrupted load changeover, the load changeover switch having at least one main current branch that in stationary operation conducts the load current from the connecting winding tap to a load shunt through at least one vacuum switching tube,at least two auxiliary current branches each consisting of a series connection of an additional vacuum switching tube and at least one switch-over resistor and each between a respective one of the winding taps and the load shunt, andan additional separately actuatable contact separate from contacts of the selector and in series in each of the at least two auxiliary current branches between the respective winding tap and the respective additional vacuum switching tube.

2. The on-load tap changer according to claim 1, wherein the additional contacts are mechanical contacts in oil.

3. The on-load tap changer according to claim 1, wherein the additional contacts are changeover contacts.

4. The on-load tap changer according to claim 1, wherein the additional contacts are constructed as further vacuum switching tubes.

5. The on-load tap changer according to claim 1, wherein the further contacts are constructed as a semiconductor switching arrangement or as semiconductor switching arrangements.