EP0577864B1 - Change-over device - Google Patents

Description

The invention relates to a switching arrangement for load-free switching between two fixed contacts when changing the direction of rotation of a drive shaft, in particular for tap changers on tap transformers.

Such a switching arrangement according to the preamble of the first claim is known especially for diverter switches of tap changers from FR-A-2 232 132 and DE-C-25 20 670. In this arrangement, changeover contacts are arranged in series with the two switch contacts, one of the switch contacts being connectable directly to the load derivation, such that the two switch contacts function as main switch contact and as resistance switch contact when the switching direction is reversed. This has the advantage that the contact erosion progresses evenly with both switching contacts, regardless of whether the corresponding step transformer to be switched often with the full load current, which leads to severe erosion of the main switch contact, or with no load, with a very low load current with a correspondingly low erosion this contact is claimed.

The changeover contacts are designed as a single-pole changeover switch, the movable changeover contact connected to the load derivative, depending on the switching direction, is in contact with one of its two fixed mating contacts, one mating contact each being directly connected to one switching contact.

In this changeover arrangement, the movable changeover contact and the movable switch contacts are actuated together by a force accumulator, which acts directly on the changeover contact after tripping. The changeover contact takes the switch contacts with it by means of a mechanical stop; when the direction of rotation is reversed, the changeover contact is first moved from one fixed mating contact to the other before the switching contacts described are carried along.

However, this known switchover arrangement has the disadvantage that the switchover contact as well as the actual switch contacts are moved by the energy storage drive, which means that part of the energy in the energy store must already be used to actuate the switchover contact and thus not for safe actuation of the two actual switch contacts more is available. In addition, the total switching time extends from one stage to the other, for which the energy accumulator must be designed, by the switching time of the changeover contact, which is added to the switching time of the two switching contacts.

The object of the present invention is to change the actuation of a single-pole changeover contact so that it can be driven directly by a drive shaft, i.e. that the switch is actuated without the interposition of an energy accumulator, in the case of several circuits in the same direction, i.e. Repeatedly turning the selector shaft in the same direction, but the switch remains in its position.

This object is achieved by the features of the first claim. The subclaims contain advantageous developments of the invention.

The advantage of the invention is, in particular, that the de-energized changeover contact, which is actuated directly by the drive shaft, does not require any complicated mechanics between the energy accumulator and the changeover contact for its actuation and for coordination with the actuation of the switch contacts.

In addition, there are no specific requirements for the energy store; it is irrelevant, for example, whether it can be tensioned or released in both directions.

The rollers connected to the drive shaft ensure simple and safe actuation of the changeover contact; The elastic design of the actuating part, on which the rollers act, permits greater installation tolerances and prevents jamming or pushing.

Fig. 1

eine erste Ausführungsform einer erfindungsgemäßen Umschaltanordnung von oben gesehen

Fig. 2

einen Schnitt A-A durch das Gehäuse dieser Umschaltanordnung

Fig. 3

einen Schnitt B-B durch die Laufrollen dieser Umschaltanordnung

Fig. 4

eine zweite Ausführungsform einer erfindungsgemäßen Umschaltanordnung von oben gesehen

Fig. 5

dieselbe in seitlicher Schnittdarstellung.

The invention will be explained in more detail below by way of example.
Show it:

Fig. 1

a first embodiment of a switching arrangement according to the invention seen from above

Fig. 2

a section AA through the housing of this switching arrangement

Fig. 3

a section BB through the rollers of this switching arrangement

Fig. 4

a second embodiment of a switching arrangement according to the invention seen from above

Fig. 5

the same in a side sectional view.

In a first embodiment of the invention, the switching arrangement consists of an actuating part and an actual switching part.

A roller bearing 2, which is firmly connected to the drive shaft 1 and carries one or more rollers 3, acts as an actuating part. The number of rollers 3 depends, among other things, on the angle by which the drive roller 1 rotates in each switching step.

Preferably, as shown in the drawing, two rollers 3 are each offset by 180 ° at the free ends of the roller carrier, expediently a spacer sleeve 31 is provided in each case within the actual rollers 3 in order to increase the rotatability of the rollers in a manner known per se to guarantee. The switchover part consists of an electrically conductive rocker switch 4, which is rotatably mounted at a point 41 and has contact surfaces 42, 43 at both free ends, preferably symmetrically, each of which strikes a fixed contact 61, 62 in an end position of the rocker switch 4 and one Establish an electrically conductive connection with it.

Furthermore, the rocker switch 4 is provided with a latching contour 44, the surface of which is at a certain distance from the pivot point 41.

Also part of the switching part is a locking member 5, which can be pivoted about a pivot point 51 in the same horizontal plane as the rocker switch 4 and has a spring-loaded locking contour 54 at its free, pivotable end, which engages in the locking contour 44 of the rocker switch 4, so that the rocker switch 4 and locking member 5 are movable together in opposite directions of rotation. For this purpose, both the locking contour 44 and the locking counter contour 54 are expediently designed as corresponding inner and outer radii.

The locking member 5 itself consists of a spring pin 52 and a concentric spring washer 53 which carries the locking counter contour 54 and is pressed against the locking contour 44 by means of a compression spring 55 arranged around the spring pin 52.

On the side opposite the latching contour 44, the rocker switch 4 is firmly connected to an actuating part 7. The Actuating part 7 is elastic in itself, for example made of spring steel, and dimensioned so that the rollers 3 strike this actuating part 7 and thus actuate the rocker switch.

The position shown in Fig. 1 has been reached after a rotation of the drive shaft 1 counterclockwise. The right roller 3 has run onto the actuating part 7 and has rotated it together with the rocker switch 4 into the position shown.

The fixed contacts 61, 62 each receive the electrical potential in isolation from one another by means of contact strips 63, 64, and the changeover contact is derived by means of a further contact strip 56 on the spring pin 52.

In the position shown in FIG. 1, the right fixed contact 61 is thus connected to the load derivation.

The locking member 5 ensures a safe and complete switching of the rocker switch 4 up to the stop on the respective other fixed contact 61, 62.

If the next switching step takes place in the same direction, i.e. if the selector shaft turns again counterclockwise, the roller 3 moves over the elastic actuating part without causing a shift change. When the control shaft rotates clockwise, the actuating part 7 is pivoted and thus the rocker switch 4 is brought into the opposite end position; then the left fixed contact 62 is connected to the load derivative, which leads through the spring pin 52.

The rocker switch 4 with the actuating part 7, the complete locking member 5 and the fixed contacts 61, 62 are expedient arranged in a housing 8, which consists of two symmetrical housing halves 81, 82 with corresponding recesses for fixing the fixed contacts 61, 62 and the rocker switch 4 and the locking member 5.

In an advantageous further development of the invention, it is possible to keep the space requirement particularly small by arranging the drive shaft as closely as possible parallel to the inner wall of a vessel, for example a tap changer vessel. The required swivel range can be obtained in that each time the drive shaft rotates 180 °, one of the rollers runs onto the inner wall of the vessel, whereby the entire roller bolt is displaced from its central position and the opposite roller comes into the area of the elastic actuating part.
Such an embodiment of the invention is shown in FIGS. 4 and 5.
A drive shaft 11 is penetrated by horizontal bores in which roller bolts 12 are slidably guided; each roller pin 12 is guided by guide bushes 14, 15 which are inserted on both sides in the bore or in the bores and have an outer collar which prevents them from sliding inwards.
At both ends of the roller pin 12 rollers 13 are rotatably arranged in a conventional manner.
Instead of the illustrated fastening of the rollers 13 between two parallel roller bolts 12, it is also possible to provide only one such roller bolt.
An abutment 110, 111 is located in the middle of each roller bolt 12, within the hollow drive shaft 11.
Springs 16, 17, 18, 19 are supported between the abutment 110, 111 and the inner sides of the guide bushes 14, 15, so that each roller pin 12 can be displaced linearly on both sides, however, is always withdrawn symmetrically to the longitudinal axis of the drive shaft 11 by spring force in its stable central position.
When it rotates, one of the rollers 13 runs on the inner wall of the insulating cylinder and causes the displacement described, as a result of which the other roller 13 comes into engagement with the actuating part (not shown here).

Appropriately, at least the surface of the rollers 3, 13 consists of Teflon®; this enables very low wear onto an insulating cylinder made of, for example, GRP

According to a further preferred embodiment of the invention, the guide bushes 14, 15 are held in the respective bore of the drive shaft 11 by fixing plates 112, 113; the curvature of the fixing plates 112, 113 is adapted to that of the drive shaft 11. The fixing plates 112, 113 in turn can be fixed on the drive shaft in a simple manner and without special fastening means by the radial wrapping of the entire drive shaft 11 in the corresponding area.

Claims (6)

1. Switch-over arrangement for switching over between two fixed contacts (61, 62) on changing of the rotational direction of a drive shaft (1, 11), particularly in tap selectors for tapped transformers, consisting of a switch part and a roller part, wherein the switch part comprises an electrically conductive switching rocker (4), which is provided at each of its two free ends with a respective contact surface (42, 43) and is rotatably mounted between two fixed contacts (61, 62), wherein the switching rocker (4) comprises an actuating part which projects into the region of the roller part in such a manner that or each first relative movement of switching rocker (4) and roller part the switching rocker is pivoted in dependence on direction into the opposite end setting, wherein the switching rocker (4) furthermore is connected with a spring-loaded detent element (5) which is rotatable about a separate fulcrum (51) and which engages at the switching rocker (4) at a determined spacing from the fulcrum (41) thereof and allows merely two stable settings of the switching rocker (4), in which each time one of its contact surfaces (42, 43) stands in electrically conductive connection with a fixed contact (61, 62), and wherein the load output of the switch-over arrangement takes place directly from the switching rocker (4) or the detent element (5) then similiarly electrically conductive, characterised thereby that the actuating part (7) is constructed to be resilient, that the roller part is connected directly with the drive shaft (1, 11) and has at least one pivotable roller (3, 13), which actuates the switching rocker (4) in the manner that the at least one roller (3, 13) is rotatably arranged at at least one end of a roller pin (2, 12), and that the roller pin (2, 12) penetrates the drive shaft (11) perpendicularly to the longitudinal axis thereof so that the at least one roller (3, 13) describes a concentric circular path on rotation of the drive shaft (11).
2. Switch-over arrangement according to claim 1, characterised thereby that the roller pin (2, 12) has rollers (3, 13) at both free ends and is displaceable out of its middle position against a spring force in both directions in its longitudinal axis in the drive shaft (11) and that on rotation of the drive shaft (11) one of the rollers (3, 13) runs on a wall, preferably the inner side of a cylinder of insulating material of the tap selector, and therewith the respective other roller (13, 3) is pivoted out of its concentric circular path into the region of the actuating part.
3. Switch-over arrangement according to claim 2, characterised thereby that the roller pin or roller pins (12) is or are linearly guided by guide bushes (14, 15) at both ends, wherein the guide bushes (14, 15) have an outer collar which projects outwardly beyond the corresponding bore through the drive shaft (11).
4. Switch-over arrangement according to claim 3, characterised thereby that the guide bushes (14, 15) are outwardly retained by fixing means (112, 113), the curvature of which is matched to the external contour of the drive shaft (11).
5. Switch-over arrangement according to claim 4, characterised thereby that the fixing means (112, 113) and therewith the respective guide bushes (14, 15) are retained on the drive shaft (11) by radial winding with a winding band (114).
6. Switch-over arrangement according to claims 2 to 5, characterised thereby that a counterbearing (110, 111) is disposed within the drive shaft (11) in the middle of each roller pin (12) and helical springs (16, 17, 18, 19), which surround the roller pins (12), are supported each time between counterbearing (110, 111) and inner edge of the corresponding guide bush (14, 15).

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