WO2014048650A1 - On-load tap changer with preselector - Google Patents

Abstract

The invention discloses an on-load tap changer having a preselector (20) for controlling a control transformer (T) without interruption. The preselector (20) has a plurality of contact bars (21, 23, 25). One of the contact bars (25) is mounted in a pivotable manner in such a way that a start (10) of a tapped winding (2), by means of fixed contacts (22) of a contact bar (21), or the end (13) of the tapped winding (2), by means of fixed contacts (24) of a further contact bar (23), can be electrically conductively connected to the main winding (1) by means of sliding contacts (26) of the pivotable contact bar (25).

Description

 On-load tap-changer with selection

The invention relates to an on-load tap-changer with preselector for the uninterrupted control of a regulating transformer.

Selectors, also called inverters and coarse selectors, are generally used in on-load tap-changers to expand the control range of a control transformer. Turners make it possible to switch the control windings of a control transformer to or against a main winding. With the help of a coarse selector, it is possible to switch off or switch on a larger part of a main winding, a so-called coarse step, of a control transformer.

Both the step winding of a tapped transformer and the coarse step are briefly separated galvanically from the main winding during their switching by turning or coarse selector. They assume a potential which results from the voltages of the adjacent windings and the coupling capacitances to these windings or grounded parts. The resulting differential voltages are sometimes very significant; they claim the switching path of the opening preselector contacts and can lead to unacceptable Entiadungserscheinungen with the appropriate amount. Such discharge phenomena, also called arcs, cause gas formation in Isoiieröl. This is undesirable, especially as the system voltage increases, the amount of unwanted gases increases.

To eliminate these undesirable differential voltages, polarity switches are used, which hold the tap winding at a desired and defined potential by means of an ohmic resistor, which is switched on only during the switching phase of the inverter or coarse selector.

In FIG. 1, known from FIG. 2 of DE 10 2009 060 132 B3, a poling arrangement is explained. Shown is a main winding 1 and a tap winding 2 of a variable transformer T. At the tap winding 2, an on-load tap changer is connected, which has a selector 3. The selector 3 initially selects the new winding tapping of the tap winding 2, which is to be switched over, before switching over. The switching itself is done by a known diverter switch 4 of the on-load tap-changer, which will not be discussed in detail here. Furthermore, the tap changer on a turner 5, through which to increase the control range of At the beginning of 10 or the end 13 of the tap winding 2 can be switched to the end of the main winding 1. At the beginning 10 of the tap winding 2, a first polarity resistor 1 1 is provided, which is connected by means of a first polarity switch 12 with the load discharge. According to the invention, a second polarity resistor 14 is further provided at the end 13 of the step winding 2, which is in turn connected to the load discharge line 9 via a second polarity switch 15. The two polarity switches 12, 15 are only briefly turned on before the start of the operation of the preselector 5, so that only briefly the beginning 10 and the end 13 of the tap winding 2 are hinged to a defined potential. In addition, the main winding 1 has two physical contacts, namely the "0" contact and the "K" contact (commutation contact).

Structural designs of a polarity switch are, as known from DE 19 42 567 A, for example, arranged coaxially to the preselection and Feinwählerkontaktsystemen the tap changer below the tap selector or they are, as known from DE 28 15 736 C2, laterally attached to additional arms insulating bars in addition to the actual tap selector or the selection. In the first case, there are undesirably large overall lengths for the tap selector, in the second case also undesirable large horizontal expansions of the entire tap changer.

The zugschalteten ohmic resistors, also called Polungswiderstände are usually mounted below the selector on a cylinder. These require, depending on the power class of the on-load tap-changer, also installation space and have a significant effect on the manufacturing cost of an on-load tap-changer. Due to the applied unwanted differential voltage across the resistors, the oil of the on-load tap-changer and therefore also that of the transformer is additionally heated up. Since heating shortens the life of the transformers, this effect is also undesirable.

The object of the invention is therefore to provide an on-load tap-changer with preselector for uninterrupted control of control transformers, in which the preselector has a small space and yet the discharge phenomena of the opening preselector contacts, caused by the differential voltages, withstand.

This object is achieved by an on-load tap changer with preselector with the features of claim 1. The subclaims relate to particularly advantageous developments of the invention. The general inventive idea is to equip the preselector with a separate energy storage, which is driven by the motor drive of the on-load tap-changer, so as to be able to perform a quick changeover from the "+" position to the "-" position of the preselector contacts.

According to the invention, the energy accumulator is connected via a coupling element with a pivotally mounted contact rod. The actuation takes place via a fork attached to the coupling element with two fork rollers which correspond positively and non-positively to an armature driven by a motor drive. The anchor has two freewheels on the underside. Upon actuation of the armature, i. as it rotates, the energy accumulator is triggered when the rollers reach the freewheels. The further rotation of the fork is effected by a arranged between the freewheels of the armature anchor roller which engages in a arranged between the fork rollers fork contour. Upon further rotation of the fork of the energy storage is raised again. This course also leads to the fact that the sliding contacts of the pivoting contact rod are suddenly released from the fixed contacts, and are then pushed slowly onto the new fixed contacts to be connected. According to yet another embodiment of the invention, the switching "0" contact is combined with the so-called "K" contact (commutation contact) and designed as a movable contact rod.

According to yet another embodiment of the invention, the energy storage of the preselector is designed as a leg spring.

According to yet another embodiment of the invention, the armature is driven by a motor drive. In yet another embodiment of the invention, the anchor is at the top, i. arranged at the top of the on-load tap-changer.

According to one embodiment of the invention, the on-load tap-changer is designed as a load selector. The selection consists among other things of a first contact rod, a second contact rod and a third contact rod. At each of the contact bars three contacts are provided, each of which corresponds to a contact with a phase or a strand of the current. The first contact rod thus has three fixed contacts. At the second contact rod also three fixed contacts are arranged. The third contact rod is designed to be pivotable and trät three sliding contacts, which can be connected to the corresponding fixed contacts or separated from them.

The invention will be explained in more detail with reference to drawings. Show it:

Figure 1 shows an arrangement according to the prior art

 Figure 2 shows a preselector according to the invention

 Figure 3 is a plan view of the preselector according to the invention

 Figure 4 shows a preselector according to the invention with an anchor

 Figure 5 is a detail view of the anchor

For identical or equivalent elements of the invention, identical reference numerals are used. The illustrated embodiment represents only one way in which an inventive selection can be mapped.

FIG. 2 shows a preselector 20 according to the invention in the form of a reverser. This consists, inter alia, of a first contact rod 21, a second contact rod 23 and a third contact rod 25 on the first contact rod 21 are three fixed contacts 22, so each a fixed contact 22 per phase attached. On a first outer side 21A of the first contact rod 21, the fixed contacts 22 are conductively connected to the respective step winding 2. Fixed contacts 24 are likewise arranged on the second contact rod 23. Again, each phase is assigned a fixed contact 24. These fixed contacts 24 are connected on a second outer side 23 A, here outside on the contact rod 23, with the step windings 2. The fixed contacts 22 of the first contact rod 21 are conductively connected to the beginning 10 of the tap winding 2. In contrast, the fixed contacts 24 of the second contact rod 23 are connected to the end 13 of the tap winding 2. By this arrangement, it is possible to turn on the stage winding 2 to the parent winding 1 or against this, ie the voltage of the tap winding 2 becomes the voltage the parent winding 1 added or subtracted. For this reason, the first contact rod 21 with its fixed contacts 22 for the "+" - position and the second contact rod 23 with its fixed contacts 24 for the "-" - position. Furthermore, the preselector 20, the third contact rod 25 on which, corresponding to the fixed contacts 22 and 24, sliding contacts 26 are arranged. These sliding contacts 26 are connected to the respective parent windings 1. Likewise, these sliding contacts 26 make an electrically conductive connection either with the fixed contacts 22 of the "+" position or the fixed contacts 24 of the "-" position. The sliding contacts 26 are formed in two parts, so that when contacting each part of the respective fixed contact 22, 24 touches from above and below. It would also be conceivable to form the fixed contacts 22, 24 as sliding contacts and the sliding contacts 26 as fixed contacts. Due to the two-part design of the sliding contact 26, two contact points to the respective fixed contact 22, 24 can flow through the current.

The third contact rod 25, in particular the sliding contacts 26, combine the so-called "0" contact and "K" contact in one. Typically, the "0" contact has been translated by a separate contact rod located between the first and second contact bars 21, 23.

The switching from one position to the next and back again is realized such that the third contact rod 25 is pivotally mounted in two directions about a vertical axis A. The drive takes place via a force accumulator 27 which is intended only for the third contact rod 25. This is realized in FIG. 2 by a leg spring.

Both the first and second contact bars 21, 23 are fixedly attached to a frame 28. The pivotable contact rod 25 is movably connected to the frame 28 via the energy accumulator 27. The actuation of the force accumulator 27, so the leg spring, via a coupling element 29. This is mechanically connected by the frame 28 with the energy storage 27 while rotatably mounted in the frame 28.

FIG. 3 shows the preselector according to the invention from above. Here, the sliding contact 26 is in a middle position between the fixed contacts 22 and 24. As shown in Figures 4 and 5, the coupling element 29 via a fork 30 with a first and a second fork roller 31, 32, and arranged therebetween Fork contour 33, via an armature 34, on the underside of a first and a second freewheel 35, 36, and an armature roller 37 are actuated. The armature 34 is in the upper region, ie on the tap changer head, arranged and is driven by a motor drive, not shown here.

When the preselector 20 is in the "+" position, ie the sliding contacts 26 are galvanically connected to the fixed contacts 22, the energy accumulator 27 is in the drawn-up state, in which position the armature 34 is positively and non-positively interposed When the preselector 20 is actuated, the motor drive starts to rotate the armature 34. As soon as the two fork rollers 31, 32 reach the freewheels 35, 36, the force accumulator 27 is pulled up This pivotal movement in turn results in a pivotal movement of the third contact rod 25. The sliding contacts 26 are suddenly released from the fixed contacts 22 of the first contact rod 21. The fork 30 and indirectly attached thereto third contact rod 25 remain briefly in a middle position between the first Kontak tstab 21 and the second contact rod 23 are.

After further rotation of the armature 34, the armature roller 37 engages positively in the fork contour 33 and thereby pulls the energy storage 27 when turning the fork 30. During this rotation, the fork rollers 31, 32 leave the freewheels 35, 36 and take a non-positive and positive connection with the armature 34 a. The rotational movement of the armature 34 via the armature roller 37 and the fork contour 33 is terminated upon reaching the "-" position, i.e. after establishing an electrically conductive connection between the fixed contacts 23 and the sliding contacts 26.

When switching back to the "+" position, the armature 34 is rotated in the opposite direction, resulting in a rapid pivotal movement of the third contact rod 25 as soon as the fork rollers 31, 32 have reached the freewheels 35, 36 on the underside of the armature 34 As a result of the further rotation of the armature 34, the armature roller 37 engages in the fork contour 33, thereby pivoting the third contact rod 25 into the "+" position, thereby pulling on the energy store 27.

By a self-built-in for the selection 20 energy storage 27 Polungswiderstände and also polarity switch are no longer necessary. Characterized in that the sliding contacts 26 of the pivotable third contact rod 25 abruptly of the Fixed contacts 22, 24 are released, it comes to a very fast extinction of a possible arc. Since this switching is carried out only very slowly according to the prior art, the arc burns relatively long, resulting in a strong evolution of gas. In the solution according to the invention, the arc burns for a very short time and accordingly produces less gas.

The omission of the polarity resistors brings an enormous space saving with it. The entire on-load tap-changer is thereby shorter and thus more compact. The heat generated by the poling resistors is no longer available. As a result, the insulating oil of the transformer to be controlled is not additionally heated by this source. Since the transformer is then exposed to lower temperature fluctuations, this has a positive effect on the service life. Also, the additional costs caused by the polarity resistors omitted, so that the on-load tap-changer is cheaper overall.

Since the need for a polarity switch is eliminated, the entire mechanism of the preselector is simplified. The operation and control of the polarity switch was mostly done by Maltese gear which were not only complex and expensive to manufacture but also took up a lot of space. In addition, this actuating mechanism had to be connected to and matched with that of the preselector as well as the selector. Since the Polungsschaiter is no longer necessary, the selection can be realized by a simple operation by means of a fork 30, two arranged thereon fork rollers 31, 32 and a fork contour 33. This not only has a positive effect on the installation space, but also the production time, maintenance and error susceptibility.

By combining the contact rod for the "0" contacts with that for the "K" contacts in the form of the third contact rod 25, the preselection also becomes smaller. Thus, the entire on-load tap-changer becomes more compact and takes up less space in the transformer tank.

reference numeral

T control transformer

1 main winding

 2 step winding

 3 voters

 4 diverter switch

 5 turners

 9 load derivation

 10 start

 11 poling resistor

12 first polarity switch

13 end

 14 poling resistor

15 second polarity switch

20 selection

 21 first contact rod

 21A first outer side

22 fixed contacts

 23 second contact rod

23A second outer side

24 fixed contacts

 25 third contact rod

26 sliding contacts

 27 energy storage

 28 frame

 29 coupling element

30 fork

 31 first fork roller

 32 second fork roller

 33 fork contour

 34 anchors

 35 first freewheel

 36 second freewheel

 37 anchor roller

Claims

claims

1. On-load tap-changer with a preselector (20) for the uninterrupted control of a regulating transformer (T), characterized

in that the preselector (20) has a first contact rod (21) with fixed contacts (22) which are connected on a first outer side (21A) to a beginning (10) of a tap winding (2) of the regulating transformer (T),

and a second contact rod (23) having fixed contacts (24) connected on a second outer side (23A) to one end (13) of the tap winding (2) of the variable transformer (T),

and a third Kontaktstaab (25) with sliding contacts (26) which are connected to the main winding (1) of the control transformer (T), and

the third contact rod (25) is pivotably mounted in such a way that

that the beginning (10) of the tap winding (2) via the fixed contacts (22) of the first contact rod (21) or the end (13) of the tap winding (2) via the fixed contacts (24) of the second contact rod (23) with the main winding ( 1) via the sliding contacts (26) of the third contact rod (25) are electrically conductively connected.

2. on-load tap changer according to claim 1,

wherein the third contact rod (25) is mechanically coupled to a force accumulator (27), so that the sliding contacts (26) of the fixed contacts (22, 24) separable or with the fixed contacts (22, 24) are connectable.

3. on-load tap changer according to claim 1 and 2,

a coupling element (29) mechanically connecting the third contact rod (25) and the energy store (27),

the coupling element (29) having a fork (30) carrying first and second fork rollers (31, 32),

the fork (30) having a fork contour (33) arranged between the fork rollers (31, 32),

wherein the fork rollers (31, 32) correspond to a first and a second freewheel (35, 36) of an armature (34),

wherein the armature (34) has an anchor roller (37) and

the fork rollers (31, 32) and the first and the second freewheel (35, 36) and the armature roller (37) and the fork contour (33) co-operate positively and positively.

4. on-load tap-changer according to claim 3,

wherein the armature (34) actuates the third contact rod (25) and the energy store (27) such that as long as the two fork rollers (31, 32) have not reached the freewheels (35, 36) of the armature (34), the energy store ( 27) is in the wound state,

that upon reaching the freewheels (35, 36) the energy accumulator (27) is triggered abruptly and the sliding contacts (26) are separated from the fixed contacts (22) of the first contact rod (21),

that after further rotation of the armature (34) engages the armature roller (37) in the fork contour (33) and the two fork rollers (31, 32) leave the two freewheels (35, 36) and the fork (30) rotates until the sliding contacts (36) with the fixed contacts (24) of the second contact rod (23) are in contact and the energy storage device (27) is in the wound state.

5. on-load tap changer according to claims 1 to 4,

wherein the sliding contacts (26) of the third contact rod (25) are formed simultaneously as "0" contacts and "K" contacts.

6. on-load tap changer according to one of claims 1 to 4,

wherein the energy store (27) is a leg spring.

7. on-load tap changer according to claim 3,

wherein the armature (34) is driven by a motor.

8. on-load tap changer according to one of the preceding claims 3 to 7.

wherein the armature (34) is arranged at the top of the on-load tap changer.