EP2421014A1 - Stepping switch - Google Patents

Abstract

The switch has a center switch and/or drive shaft (3) actuatable by a motor drive. The drive shaft directly acts on a contact actuating unit and/or an energy accumulator. The drive shaft drives the contact actuating unit after activation. The motor device includes a directly driven stepper motor (5) i.e. torque motor, which is arranged above the step switch and directly connected with the drive shaft. The stepper motor includes preselectable fixed rotational angles per switching. The stepper motor directly drives the switch.

Description

The innovation relates to a tap changer for uninterrupted switching between winding taps of a tapped transformer.

Tap changers have been on the market for many years based on two different operating principles.

So-called reactor switches, which are particularly common in North America, have a switching reactance, which allows a slow, continuous switching.

On the other hand, so-called resistance rapid-action switches, also called Jansen switches according to their inventor, perform a rapid changeover between the winding taps, in the short term switching resistors leading the circulating current during load switching.

The latter type of tap changers in turn can be divided in the load selector on the one hand, in which the winding selection and load switching is performed simultaneously, and tap changer with separate selector and separate diverter switch. In this case, the voter first makes a power-less preselection of the winding tapping to which it is to be switched; Subsequently, the diverter switch then performs the actual fast switching.

Typical load selectors are the Applicant's OILTAP® V and VACUTAP® VV types.

Typical tap-changers with separate selector and diverter switch are the Applicant's OILTAP® M and VACUTAP® VM types.

All tap changers, regardless of their operating principle, are usually operated by a motor drive. The motor drive usually includes a three-phase asynchronous, which is turned on by means of a controller and switched off again after reaching the respective desired voltage level. The motor drive further comprises a load gear and corresponding control and display means. The rotational movement of the drive motor is transmitted via a shaft guide and an angle gear on the respective tap changer. An early design of such a motor drive is from the DE-OS 24 10 641 known; There are numerous other versions of such motor drives from different manufacturers. Such motor drives are complex devices with a variety of mechanical and electrical components and correspondingly expensive. Usually, they are mounted laterally on the outside of the transformer tank and take up considerable space there. Finally, in any case, a drive train is required, which transmits the rotational movement from the motor drive to the tap changer, which is to be operated.

The transmitted rotary motion of the motor drive is usually used to lift an energy accumulator, after its triggering a fast switching movement is generated. Such energy storage are known in various embodiments; an early design is in the DE-OS 19 56 369 described. The same basic principle is common to all these energy accumulators: there is a continuous lift of an elevator part, during which the elevator springs are tensioned, followed by the sudden release of an output part, in which the energy storage springs relax again.

The object of the innovation is to specify an easy-to-operate and simply constructed tap-changer. In particular, it is an object of the innovation to omit the previously necessary motor drive completely.

This task is solved by the innovation. Protection claim 1 relates to a renewal tap changer according to the invention; the dependent claims relate to advantageous developments of the innovation.

The innovation is based on the general idea to drive the tap changer directly by a stepper motor "on site" make. This eliminates both the actual motor drive and the previously required drive train to the tap changer.

In a tap changer of the load selector type, the stepper motor can directly control its switch column with any division, for. B. with a rotation angle of 30 degrees, which in many cases corresponds to the distance between the contacts of adjacent winding taps that can be connected. A speed of the stepping motor is particularly advantageous such that this rotational movement of 30 degrees is completed in about 60 ms. Modern, commercially available stepper motors do this.

In a tap changer with separate selector and diverter switch the stepper motor usually performs a rotation angle of 180 degrees, during which the described energy storage is mounted. After its release takes place, as described, the actual load switching.

In an advantageous development of the innovation can be omitted in the last-mentioned tap-changer type and the energy storage. The stepper motor itself generates the required rapid rotational movement and thus actuates the diverter switch directly.

The innovation will be explained in more detail below with reference to three schematic representations.

Figur 1

einen Stufenschalter des Lastwählertyps in schematischer Darstellung von oben

Figur 2

einen solchen Stufenschalter in konkreterer Darstellung der tatsächlichen Bauelemente

Figur 3

einen Kraftspeicher eines Stufenschalters mit getrenntem Wähler und getrenntem Lastumschalter.

Show it:

FIG. 1

a tap changer of the load selector type in a schematic representation from above

FIG. 2

Such a tap changer in a more concrete representation of the actual components

FIG. 3

a power storage of a tap changer with separate selector and separate diverter switch.

The in FIG. 1 Tap changer shown has an insulating cylinder 1, on the circumference fixed contacts 2 are arranged in a known manner. For reasons of clarity, only one of these contacts has been provided with reference numerals; The numerals in brackets denote the respective tap, here is the number of taps 12. Inside the insulating cylinder 1 is a central switching or drive shaft 3, which carries a movable contact carrier 4, which contacts one of the fixed contacts 2. According to the innovation, the actuation, ie rotational movement of the central drive shaft 3 is effected by a stepping motor 5, which is indicated here only by dashed-dotted lines, and which may have an arbitrary degree of division. In the example shown here, the stepper motor 5, and thus the drive shaft 3, performs a rotation angle a of 30 degrees with each changeover from one winding tap to an adjacent winding tap.

In FIG. 2 this tap-changer is shown with its concrete possible embodiment. Again, the insulating cylinder 1 is shown again, at the periphery of the fixed contacts 2 are located. Arranged around the central pivot point 3 here is a switching shaft 6, which in turn carries the contact carrier 4 already explained. This switching shaft 6 is according to the innovation driven directly by a stepper motor, not shown here. Also shown here, around the switching shaft 6 around, a partial cylinder 7, which carries the at least one switching resistor 8. On the contact carrier 4, two forks 9, 10 are arranged, which carry at their free end rollers 11, 11 a, the respective fixed contact 2, depending on the position of the switching shaft 6, contact. Slip rings 12, 13 for discharging the load as well as the respective power terminals 14, 15, 16, each for one phase, are still shown here. Also in this illustration, the corresponding angle of rotation a is indicated, ie the angle, the renewal of the stepping motor and thus perform the switching shaft 6 at a changeover.

FIG. 3 shows a power storage of another tap-changer type, are separated in the selector and actual diverter switch. In this case, usually at the beginning of switching an initially powerless preselection of the selector, at the same time the energy storage is mounted. After covering a rotation angle of 180 degrees then the known power storage is triggered and the actual load switching completed quickly. Here again, only schematically, a stepping motor 5 is shown, which acts on a drive shaft 21, which leads to the force accumulator 17. The drive shaft 21 actuates an eccentric 20, which in turn biases an elevator carriage 18. The known power storage springs are omitted here. The tension of the elevator carriage 18 through the eccentric 20 is effected by pressing against a lateral block 18a. Such a block is available for both directions, but here only one is provided with a reference numeral. After maximum tension, ie deflection of the elevator carriage 18, the output member 19 is triggered and performs a rapid movement, which is converted into a rotational movement of the output shaft 22, which operates a known diverter switch 23 quickly. In this embodiment, the stepping motor 5 performs a rotational movement of 180 degrees. While at the in the Figures 1 and 2 embodiment shown, the rotational movement of the stepping motor and the angle a in both directions is possible, the device shown in the embodiment 3, an actuation by the angle b = 180 degrees always in the same direction.

In a further development of the innovation, it is also possible in this type of tap changer to omit the energy storage completely and to actuate the diverter switch directly by a fast-moving stepper motor; this is z. B. possible by a torque motor.

Claims (5)

Tap changer for uninterrupted switching between winding taps of a tapped transformer,
comprising a drive shaft operable by a motor drive,
wherein the drive shaft acts directly on contact actuation means and / or a force accumulator, which in turn drives contact actuation means upon actuation,
characterized,
in that the motor drive actuating the drive shaft (3, 6) consists of a directly driving stepping motor (5)
and that the stepping motor (5) is arranged above the tap changer and connected directly to the drive shaft (3, 6). Tap changer according to claim 1
characterized,
that the stepping motor comprises a pre-selectable number of segments in, ie a pre-selectable fixed angle of rotation (a, b) by switching. Tap changer according to claim 1 or 2,
characterized,
that the stepping motor is a torque motor. Tap changer according to one of claims 1 to 3,
characterized,
that the tap changer is a load selector. Tap changer according to Claims 1 to 3,
characterized,
that the tap changer has a separate selector and separate diverter switch.

Images