EP0151740B1 - Load changer for tapped transformers - Google Patents

Abstract

1. Selector switch for tapped transformers for switching over from one tapping to the next, having fixed contacts (1) arranged on a circle and connected to the tappings, and having switching contacts (3, 4, 5) for three branch circuits on a common contact carrier, which switching contacts can be rotated at the same time on the circle and are represented by rollers, whereby : all the switching contacts (3, 4, 5) carry in their resting position the potential in each case of the same step contact (1), when the contact carrier is rotated, the switching contacts (3, 4, 5) loaded with spring force (12, 14) are moved, with regard to the contact carrier, essentially only in the radial direction, and the movements of the switching contacts (3, 4, 5) with regard to the contact carrier are controlled by the fixed step contacts (1) representing at the same time cams, characterised in that : the contact carrier has guide rails (6) aligned radially to the circle of the step contacts (1), for at least two contact slides (9, 13), a first contact slide (13) carries a main switching contact (3), and another contact slide (9) carries two resistance contacts (4, 5) flanking on both sides the main switching contact (3) in the direction of rotation, movements, occurring in operation, of the contact slides (9, 13) in opposite directions on the guide rails (6) are limited in both directions by limit stops (15, 16) on the contacts slides (15, 16) themselves, so that, when the limit stops (9, 13) lie next to each other, in each case all the spring forces (12, 14) assigned to the switching contacts (3, 4, 5) load the one switching contact (3, 4, 5) which is just carrying current, and the guide rails (6) and the contact slides (9, 13) engage with one another, guiding each other.

Description

The invention relates to load selectors for step transformers for switching from one tap to the next with fixed step contacts arranged on a circle, connected to the taps, and with switching contacts of three current branches on a common contact carrier, which are simultaneously pivotable on the circle and represented by rollers.

For such load selectors, it is known from European patent application 0 029 467, from which the preamble of the present claim 1 is based, that all switch contacts in their rest position each have the potential of the same step contact, that when the contact carrier is pivoted, the middle switch contact in a guide rail opposite the contact carrier is moved essentially only in the radial direction and that when the contact carrier is pivoted, the two outer switching contacts are pivoted relative to the contact carrier on levers mounted on the contact carrier, the movements of the switching contacts relative to the contact carrier being controlled by the fixed step contacts which simultaneously represent cams.

From DE-PS 29 14 928 an arrangement is already known for load selectors, in which the movable contact, also represented by rollers, are mounted at the break point of angular levers. In this arrangement too, the fixed contacts serve as a cam track for controlling the movement of the contact rollers transversely to their switching movement. Each of the angled levers carrying the contact rollers is mounted with the end of one leg on the pivotable contact carrier and carries a coil spring on the other leg in order to generate the required contact force between the contact rollers and the fixed contacts respectively brushed by them.

Normally, in load selectors, the respective outer switch contacts are in series with a contact resistance. This results in the so-called "flag switching", which is particularly favorable with regard to the switching power that is controlled at the individual contacts. In the rest position of the known load selector, the operating current of the transformer flows from a fixed contact via the main switch contact located in the middle, while the two outer switch contacts represent resistance contacts and are de-energized in the rest position of the load selector. To ensure an uninterrupted switchover, at least one of the movable switch contacts must be in contact with a fixed contact in each intermediate position during the adjustment process. This means that in an intermediate position one resistance contact must run onto the current-carrying fixed contact earlier than the main switching contact runs from this fixed contact. Correspondingly, the second resistance contact must already touch the following fixed contact before the current-carrying resistance contact of the previously carrying fixed contact has expired.

In order to meet these conditions, the width of the fixed contacts must be greater than half the distance from contact rollers that represent resistance contacts, and the distance of these contact rollers must be greater than the distance between two adjacent, fixed contacts.

A disadvantage of the first-mentioned contact arrangement is the relatively bulky structure, which additionally complicates use when very high operating voltages occur. The contact arrangement with contact rollers mounted on angle levers is unsatisfactory in that it requires different cam tracks for controlling the individual contacts assigned to the same contact carrier. This results in a relatively large manufacturing effort, which is further increased by the need to take into account the possible manufacturing tolerances that occur.

The invention is based on the object of creating a contact arrangement for load selectors which has a compact structure and enables a largely smooth-surface design for the contact carrier and the fixed contacts and at the same time allows greater manufacturing tolerances.

This object is achieved according to the invention for a load selector of the type described in the introduction in that the contact carrier has guide rails aligned radially in the circle of the stepped contacts for at least two contact carriages, in that a first contact carriage carries a main switching contact and another contact carriage carries two resistance contacts flanking the main switching contact in the pivoting direction on both sides, that operationally occurring, opposing movements of the contact carriage on the guide rails are limited by stops on the contact carriage itself in both directions, so that when the stops abut each other, the spring contacts assigned to the switching contacts load the current-carrying switching contact, and that the guide rails and the contact carriage mutually interlocking leaders.

In expedient developments of the invention it is provided that the contact slide carrying the main switching contact is arranged between two guide rails and that a box-like contact slide comprising this arrangement serves as a common carrier for the two resistance contacts. In this case, pins protruding transversely to the swivel direction and to the direction of the spring forces from the contact slide carrying the main switch contact engage in elongated holes in the box-like contact slide and, together with the ends of the elongated holes, represent the stops for limiting the slide movements in the radial direction.

Advantageous embodiments of the invention consist in the fact that each of the contact slits is constantly radially outwards by spring force is pressed that an end stop for the box-like contact carriage is provided on at least one guide rail, which secures this contact carriage during assembly before sliding off the guide rails.

Another advantageous embodiment of the invention is that the contact carriages are supported among one another and on the guide rails via roller bearings.

The features according to the invention enable a very advantageous, simple structure for a load selector because, in the rest position and in the first part of the switching process, the main switching contact and the switching carriage assigned to it are supported on the fixed contact and because as long as neither of the two resistance contact rollers touches one of the fixed contacts, the switching slide of the resistance contacts is supported radially on the switching slide of the main switching contacts. However, as soon as the contact roller of the main switching contact has run from the fixed contact, the switching slide of the main switching contact is supported radially on the switching slide of the resistance contacts, so that both switching slides are then supported radially via the resistance contact roller just touching a fixed contact. During the entire switching process, the two switching carriages are supported in their radial position, in each case by the contact rollers resting on fixed contacts at the respective moment. This results in two major advantages of this system in that both manufacturing tolerances and contact burn-up caused by the arcs during switching are compensated for by the radially self-adjusting system.

• Fig. 1 ist ein Längsschnitt durch den Kontaktträger eines erfindungsgemäßen Lastwählers.
• Fig. 2 bis 4 sind Seitenansichten des Kontaktträgers in aufeinanderfolgenden Schaltstellungen.

An embodiment of the invention is explained in more detail with reference to a drawing.

• Fig. 1 is a longitudinal section through the contact carrier of a load selector according to the invention.
• 2 to 4 are side views of the contact carrier in successive switching positions.

Corresponding parts are provided with the same reference symbols in all figures.

Fixed step contacts 1 are arranged in a circle in a manner not shown, known, wherein they are carried by insulating rods or an insulating cylinder forming a cylindrical cage. The fixed step contacts 1 are galvanically connected to taps of a fine step winding.

In the idle state, a main switch contact is located on each of the step contacts 1, which in turn is galvanically connected to a load line. The main switch contact 3 is formed by a roller rotatably mounted on an axis 10 and, together with a contact slide 13 between guide rails 6, can be displaced in the radial direction until the roller contacts the step contact 1 by means of a spring 14. The guide rails 6 are parts of a frame 11, which in turn is supported by an insulating tube 2 mounted centrally to the cage. The insulating tube 2 is rotated in a manner not shown via a step-by-step manual transmission.

The frame 11 with the guide rails 6 and the contact slide 13 are surrounded by a box-shaped contact slide 9. The contact slide 9 carries on it axles 10 the main switch contact 3 flanking resistance contacts 4 and 5 in the direction of the switching movement. The resistance contacts 4 and 5 are also designed as rollers. Each of the resistance contacts 4 and 5 usually forms a series connection with a series resistor, which in turn is parallel to the main switching contact 3, so that it leads the load current between one or briefly two step contacts 1 and the load line, not shown, in certain switching positions.

The box-like contact slide 9 is pushed by compression springs 12 in the direction of the fixed step contacts 1. To limit this movement, pins 16 protruding transversely to the switching direction from the contact slide 13, which engage in elongated holes 15 in the contact slide 9. As a result, in the rest position shown in FIG. 2, the switching slide 9 is supported radially and the contact force exerted by the compression spring 14 on the main switching contact 3 is increased by adding the forces generated by the compression springs 12.

To prevent the sliding of the contact carriages 9 and 13 from the guide rails 6 of the frame 11 before the installation of the contact arrangement in the cage formed by the insulating rods, which carries the fixed step contacts 1, 6 end stops 17 are provided at the end of at least one of the guide rails, which the radial Limit displacement of the contact carriage 9 and thereby also indirectly hold the contact carriage 13 via the pins 16 projecting into the elongated holes 15.

When switching, e.g. by pivoting the insulating tube 2, initially only the main switching contact 3 rolls to the side on the usually spherically shaped contact surface of the fixed step contact 1. However, before the main switch contact 3 runs from the current-carrying fixed step contact 1, this is e.g. reached by the resistance contact 4, which runs onto the fixed step contact 1 and thereby displaces the contact carriage 9 against the force of the compression springs 12 in the direction of the axis of rotation of the insulating tube 2 and at the same time cancels the stop between the pins 16 and elongated holes 15. In this switching position shown in Fig. 3, the load current still flows through the main switch contact 3, because this still short-circuits the series connection from the resistance contact 4 with a transition resistor.

Only after the main switching contact 3 has completely rolled off from the current-carrying fixed step contact 1 is the load current taken over by the resistance contact 4. The contact slide is supported in this switch position 13 with its pin 16 at the outer end of the elongated holes 15, so that the force of the compression spring 14 now contributes to increasing the contact force for the resistance contact 4. Before the resistance contact 4 carrying the load current rolls off the fixed step contact 1, the resistance contact 5 meets the next fixed step contact 1, which has to take over the load current after the step switching has been completed. For the very short time in which both resistance contacts 4 and 5 are present at fixed step contacts 1 at the same time, an equalizing current limited by the switching resistors flows between the resistance contacts 4 and 5.

In the further course of the switchover, during which the resistance contact 5 runs onto the newly selected fixed step contact 1, the connection between the resistance contact 4 and the fixed step contact 1 which has been conducting until then is broken. Only after this interruption has occurred, the main switch contact 3 reaches the fixed step contact 1, on which the resistance contact 5 is located. As a result, the series connection on the resistance contact 5 and the associated transition resistor, not shown, is short-circuited and the laser current commutates again to the main switching contact 3.

After completion of the step reclamation there are again both resistance contacts 4 and 5 next to the fixed step contact 1, which then carries the current, so that they, together with the contact slide 9, are pushed radially outwards by the compression springs 12 to such an extent that the pins 16 at the inner ends of the elongated holes 15 and the spring forces of the compression springs 12 contribute to increasing the contact force for the main switching contact 3.

With very large load currents or with very wide, fixed step contacts 1, it could be expedient to divide the contact slide 13 and to arrange two main switching contacts 3 one behind the other in the circumferential direction. A further forced distribution of the load current over a plurality of contact slides acting in parallel could be achieved by subdividing the contact slides 13 parallel to the swivel plane.

To facilitate the relative movements between the contact carriages 9 and 13 and the guide rails 6, regardless of the number of contact carriages, it is advantageous to provide rolling bearings on some or all of the slideways. On the one hand, this reduces the mechanical closure and, on the other hand, increases the lifespan and operational reliability.

By suitable arrangement of the elongated holes 15 and the pin 16, the placement and lifting of the contact rollers can be controlled so that the contact roller of the main switching contact 3 always lifts and touches on the outer edges of the fixed step contact 1, while the rollers of the resistance contact 4 and 5 each about Lift off or put on halfway between the outer edge and the center of the fixed contacts. As a result, the erosion caused by the arc on the surface of the fixed contacts can be distributed over a larger total area of this surface than if, for example, all three contact rollers each run up and down on the outer edges of the fixed contacts.

Claims (7)

1. Selector switch for tapped transformers for switching over from one tapping to the next, having fixed contacts (1) arranged on a circle and connected to the tappings, and having switching contacts (3, 4, 5) for three branch circuits on a common contact carrier, which switching contacts can be rotated at the same time on the circle and are represented by rollers, whereby:

all the switching contacts (3, 4, 5) carry in their resting position the potential in each case of the same step contact (1),

when the contact carrier is rotated, the switching contacts (3, 4, 5) loaded with spring force (12, 14) are moved, with regard to the contact carrier, essentially only in the radial direction, and

the movements of the switching contacts (3, 4, 5) with regard to the contact carrier are controlled by the fixed step contacts (1) representing at the same time cams, characterised in that:

the contact carrier has guide rails (6) aligned radially to the circle of the step contacts (1), for at least two contact slides (9, 13),

a first contact slide (13) carries a main switching contact (3), and another contact slide (9) carries two resistance contacts (4, 5) flanking on both sides the main switching contact (3) in the direction of rotation,

movements, occurring in operation, of the contact slides (9, 13) in opposite directions on the guide rails (6) are limited in both directions by limit stops (15, 16) on the contacts slides (15, 16) themselves, so that, when the limit stops (9, 13) lie next to each other, in each case all the spring forces (12, 14) assigned to the switching contacts (3, 4, 5) load the one switching contact (3, 4, 5) which is just carrying current, and the guide rails (6) and the contact slides (9, 13) engage with one another, guiding each other.

2. Selector switch according to claim 1, characterised in that the contact slide (13) carrying the main switching contact (3) is arranged between two guide rails (6), and that a box-like contact slide (9) embracing this arrangement serves as a common carrierforthetwo resistance contacts (4, 5).

3. Selector switch according to claim 2, characterised in that pegs (16) projecting, in each case crosswise to the direction of rotation and to the direction of spring forces, from the contact slide (13) carrying the main switching contact (3), engage in elongated holes (15) in the box-like contact slide (9), the said pegs (16) and the ends of the elongated holes (15) representing the limit stops for limiting the movements in both directions of the slide on the guide rails (6).

4. Selector switch according to one of claims 1 to 3, characterised in that each of the contact slides (9, 13) is constantly pressed radially outwards by spring force (12, 14).

5. Selector switch according to one of claims 2 to 4, characterised in that, on at least one guide rail (6) of a mounting (11), an end limit stop (17) is provided for the box-like contact slide (9) which safeguards this contact slide (9) from sliding off the guide rails (6) during assembly.

6. Selector switch according to one of claims 1 to 5, characterised in that the contact slides (9, 13) are supported by each other and on the guide rails (6) by way of rolling bearings.

7. Selector switch according to one of claims 1 to 6, characterised in that, because of the arrangement of the elongated holes (15) and the pegs (16), the setting down and lifting off of the rollers of the switching contacts (3, 4, 5) is controlled so that the main switching contact roller comes to rest on the outer edge of the respective step contact (1), rolls along the periphery of the circle on the contact surface of this step contact (1) and lifts off on the other outer edge of the said step contact, and so that the resistance contact rollers lift off and set down in the respective region of the contact surface between the corresponding outer edge and the centre of the step contact (1).

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