EP1197977A2 - Load switch for a tap changer - Google Patents

Abstract

The device has 2 permanent main contact pairs (3,4) per switched phase with a single movable main contact (5) with 2 end positions and a central switch shaft for operating the movable main contact. Each of the 2 permanent main contact pairs consists of a first main contact (3.1,4.1) and a second main contact (3.2,4.2) electrically isolated from it. One of the first main contacts is connected to one side of the switch, the other to the other side.

Description

The invention relates to a diverter switch for a tap changer with electrical for each phase de-energized permanent main contacts.

It is known prior art, on diverter switches of tap changers two Provide permanent main contacts, which in the steady state the continuous current of each switched Guide side A or B of the diverter switch and thus the actual switching contacts of this Relieve the diverter switch. At the beginning of each switch, i. H. every actuation of the diverter switch, is the first to open the permanent main contact, which previously carried the continuous current, the current is transferred to the Switch contacts of the diverter switch commutated; after completion of the entire load switching the other permanent main contact then closes and takes over the continuous current again. Such known circuit with two main contacts is z. B. in Figure 1 of WO 95/24724 shown.

A constructive version of a generic diverter switch with one for each phase Permanent power contact that switches electrically without power is known from WO 97/23888. That one The diverter switch described has two fixed main contact pairs for each phase to be switched which can be connected by means of a movable permanent main contact. To operate them a cam is arranged on the selector shaft of the diverter switch, which for each switching phase has a separate control curve. There is a role in each of these control curves a, which acts on one of the movable permanent main contacts by means of mechanical coupling elements, so that this, depending on the contour of this control curve, can be pivoted about a central longitudinal axis is.

However, this known diverter switch has the disadvantage that the actuation of the movable Permanent main contact is structurally complex. There are a number of mechanical links, such as one Swing arm and various levers, required to move on the moving To transfer permanent main contact. In addition, the known arrangement requires a high level of power, to ensure that the permanent moving main contact with the corresponding corresponding fixed Bring permanent main contact pair in connection.

The object of the invention is to provide a diverter switch of the type mentioned above, which is simple is constructed, needs few transmission links and also only requires a small amount of power required for wiring.

This object is achieved by a diverter switch with the features of the first claim solved. The subclaims relate to particularly advantageous developments of the invention.

The invention will be explained in more detail below by way of example with reference to a figure. This FIG. 1 shows a diverter switch according to the invention in a schematic, perspective illustration, where for the sake of clarity a number of components and switching means that are not absolutely necessary to explain the invention.

The supporting element of the entire arrangement is a lower base plate 1, which is the movable Main contacts and the means to operate them and carries. The single ones Switching elements and actuating parts of the diverter switch are omitted here. On the base plate 1 are numerous recesses, openings and. a. recognize that for other components of the Diverter switch serve and are not explained here. On the circumference of the base plate 1, each around Attached 120 degrees to this, there are the movable permanent main contacts 5 for each a phase as an independent assembly. The permanent fixed main contacts 3, 4 are with these interacting, on the inner wall of an oil container, not shown, that the entire Diverter switch encloses, fastened. There are three permanent main contact carriers for each phase 2.1, 2.2, 2.3 are provided, which are explained in more detail below. For the sake of clarity only one such complete permanent main contact with its actuating means for one Phase shown, which will be explained in detail below. There is a fixed one on the left Permanent main contact pair 3, consisting of fixed permanent main contacts 3.1 arranged below, the are electrically connected to one side A of the diverter switch, and arranged above permanent permanent main contacts 3.2, which lead to the joint transfer of the diverter switch, arranged. It can be seen that each of the permanent fixed main contacts 3.1 and 3.2 from one There are a large number of individual contact blades 3.1.1 and 3.2.1. Each of the contact blades 3.1.1, 3.2.1 is spring-articulated by means of contact springs 3.1.2 or 3.2.2. On the right is a second fixed permanent main contact pair 4. This consists entirely of analog arranged below fixed Permanent main contacts 4.1, which are electrically connected to the other side B of the diverter switch stand, and fixed permanent main contacts 4.2 arranged above that for common Lead load transfer. Here, too, each of the permanent fixed main contacts 4.1 or 4.2 is from one A large number of individual contact lamellae 4.1.1 and 4.2.1, which in turn are completely analogous Contact springs 4.1.2 and 4.2.2 are individually spring articulated. The permanent permanent main contacts 3.2, 4.2 are arranged on the first electrically conductive contact carrier 2.1 and form the common one Load transfer. The fixed permanent main contacts 3.1 are on the second permanent main contact contact carrier 2.2 and the permanent permanent main contacts 4.1 are, electrically isolated, on the third Permanent main contact contact carrier 2.3 arranged.

Furthermore, a common movable permanent contact 5, this is electrically conductive, intended. It has a run-up surface 5.1 in the upper area on its left side, which corresponds to the fixed permanent main contacts 3.2 corresponds, and on the right side a contact surface 5.2, which corresponds to the permanent permanent main contacts 4.2. In its lower area it points to the on the left side there is a contact surface 5.3, which corresponds to the permanent permanent main contacts 3.1, as well as on the right side analogue another contact surface 5.4, which in turn with the fixed permanent main contacts 4.1 corresponds. The movable permanent main contact 5 does not have one Bearing 6 shown in detail, such that it is in the longitudinal axis of the diverter switch around a central position is pivotable around. The bearing 6 is held in an upper base plate, not shown. The pivoting path of the permanent main contact 5 is indicated in the figure by two double arrows.

The contour of the two run-up surfaces 5.1, 5.2 is dimensioned such that they are spherical Swiveling the movable permanent main contact 5 around its bearing 6 constantly with the fixed Permanent main contacts 3.2 and 4.2, which, as explained above, both with the electrical load transfer of the diverter switch are connected. They therefore run constantly on these fixed ones Permanent main contacts 3.2 and 4.2 from; this takes the form of sliding.

In contrast to this, the two contact surfaces 5.3 and 5.4 respectively arranged below are such dimensioned in their contours that they only when pivoting the moving permanent main contact 5 in one of its two end positions in contact with the corresponding fixed Step contacts 3.1 and 4.1, which, as also already explained, with one of the two Diverter switch sides A or B are connected, come into contact. In the middle position of the moving permanent main contact 5, however, have no contact surfaces 5.3 and 5.4 electrical contact.

The actuation of the movable main contact 5 is carried out by an actuation tab 7 has a guide 7.1 in the form of an elongated hole and is articulated by fastening means 7.2. In the guide 7.1 runs an actuating pin 8.2 of a deflection crank 8, which in turn by one Pivot 8.1 is stored. At its free end, this deflection crank 8 has a contour that consists of Roller interventions 8.3 and a blocking contour 8.4 in between. Furthermore, one Drive disc (9) of the diverter switch can be seen, which does not have a central opening 9.1 for the shown, drive shaft of the diverter switch, which in turn from the triggered - not shown-energy storage is operated. For the transmission of their rotary movement there is a toothing 9.2 provided on the drive pulley 9. On this drive pulley 9 there is one for each phase Actuating roller 9.3 is provided. Between the actuating rollers 9.3 offset by 120 degrees the drive pulley 9 has a continuous blocking contour 9.4 on its end face. One each the actuating rollers 9.3 shown corresponds to one of the roller interventions 8.3 of the deflection crank 8. When the diverter switch is actuated, the drive disk 9 rotates in each case by a specific one Angle of rotation - alternately in one of the two directions of rotation with each actuation. In doing so, the corresponding actuating roller 9.3 in the corresponding roller engagement 8.3 of the deflection crank 8 on. Their actuating pin 8.2 in turn pivots in the guide 7.1 with this Actuating tab 7 connected main contact 5 about its vertical pivot point, d. H. his Bearing 6. As a result, the previously fixed permanent main contact 3.1 or 4.1 connected contact surface 5.3 or 5.4 disengaged; the permanent main contact pair 3 or 4 is interrupted. At the end of the entire load switchover, there is the moving permanent main contact 5 pivoted by its maximum possible angle by moving in the direction of movement the next following actuating roller 9.3 has engaged in the roller engagement 8.3. In the meantime, during which the switch contacts, resistance switch contacts and other switching elements of the The diverter switch is connected in a certain actuation sequence, the moving one remains Permanent main contact 5 in its middle position. This is ensured by the fact that in this Middle position, the locking contour 8.4 of the deflection crank 8 with the locking contour 9.4 of the drive pulley 9 corresponds, so that the entire deflection crank 8 remains positively fixed in the middle position. First shortly before the load switchover is completed, this blocking contour 9.4 is interrupted and the described engagement of the next actuating roller 9.3 and subsequently the Further pivoting of the movable permanent main contact 5 is possible.

Finally, two contact points 10 and 11 are shown in the figure, by means of which the electrical Connection to sides A and B of the diverter switch can be established, as well as a further contact 12, at which the connection to the common load transfer starts.

It can thus be seen that in the diverter switch according to the invention, the one - only movable Permanent main contact 5 of each phase in its upper part constantly on the fixed Permanent main contacts 3.2, 4.2 slides, so they never leave. Wired only in its lower area he alternately in each of his two end positions one of the permanent permanent contacts 3.1 or 4.1. Only small forces are to be applied; essentially these are just frictional forces.

The invention has two, functional for actuating the movable permanent main contact 5 successively operating crank drives. First of all, actuate the actuating rollers 9.3 centrically around the control shaft mounted drive pulley 9 around a separate pivot point 8.1 mounted deflection crank 8, whose, arranged outside the fulcrum 8.1, Actuating pin 8.2 in turn actuates the movable main contact 5, which in a third Pivot point, namely the vertical bearing 6, is pivotable. This arrangement is also space-saving, especially since the cams and protruding parts required by the state of the art Lever transfers are no longer required.

Claims (7)

Diverter switch for a tap changer, two permanent main contact pairs being provided for each phase to be switched, which can be bridged by a single, movable, electrically conductive permanent main contact that can be pivoted into two different end positions, with one of the two permanent main contact pairs in each phase being switched stationary state is bridged and carries the continuous current in such a way that at the start of a load switchover, the one main main contact pair that previously carried the continuous current opens and at the end of each load switchover the other open main contact pair is bridged and takes over the continuous current
and in the interior of the diverter switch there is arranged a central switching shaft through which the movable permanent main contact can be actuated,
characterized in that each of the two permanent main contact pairs (3, 4) each consists of a first permanent main contact (3.1, 4.1) and a second second permanent main contact (3.2, 4.2), which is electrically insulated therefrom,
that one of the first permanent main contacts (3.1) is electrically connected to one side (A) and the other of the first permanent main contacts (4.1) to the second side (B) of the diverter switch,
that the two second permanent main contacts (3.2, 4.2) are electrically connected to a common load derivation of the diverter switch,
that the movable permanent main contact (5) is designed such that it is constantly electrically connected to the two second permanent main contacts (3.2, 4.2) and slides on them
and that , in each of its two end positions, it is alternatively electrically connected to one of the first two permanent main contacts (3.1 or 4.1). Diverter switch according to claim 1,
characterized in that a drive pulley (9) is arranged on the selector shaft and has actuating rollers (9.3),
that the movable permanent main contact (5) has a guide (7.1) in which a deflection crank (8) which is mounted separately around a pivot point (8.1) is positively guided, which in turn corresponds to the actuating rollers (9.3) and can be pivoted by them, such that that the movable permanent main contact (5) can thus be pivoted into one of its two end positions, depending on the direction of rotation of the selector shaft. Diverter switch according to claim 2,
characterized in that the deflecting lever (8) has roller interventions (8.3) on its side corresponding to the actuating rollers (9.3) and between them a locking contour (8.4), the latter with a further front locking contour in the middle position of the movable permanent main contact (5) (9.4) interacts positively on the drive pulley (9). Diverter switch according to one of the preceding claims,
characterized in that each of the fixed permanent main contacts (3.1, 3.2; 4.1, 4.2) consists of a large number of individual contact blades (3.1.1, 3.2.1; 4.1.1, 4.2.1),
and that each of the contact blades (3.1.1, 3.2.1; 4.1.1, 4.2.1) is articulated by means of at least one contact spring (3.1.2, 3.2.2; 4.1.2, 4.2.2). Diverter switch according to one of the preceding claims,
characterized in that the only movable permanent main contact (5) of each phase has at least one contact surface (5.1, 5.2) in its upper area, which corresponds to the second fixed permanent main contacts (3.2, 4.2),
and that it also has two contact surfaces (5.3, 5.4), each of which optionally corresponds to one of the fixed first permanent main contacts (3.1, 4.1) in one of its two end positions. Diverter switch according to one of the preceding claims,
characterized in that the movable permanent main contact (5) of each phase is arranged on the circumference of a base plate (1) of the diverter switch,
and that the two fixed permanent main contact pairs (3, 4) of each phase are arranged on permanent main contact contact carriers (2.1, 2.2, 2.3) on the inner wall of an isolating cylinder surrounding the diverter switch, corresponding to the movable permanent main contact (5). Diverter switch according to claim 6,
characterized in that in a three-phase version, three separate, identical arrangements, each consisting of two fixed permanent main contact pairs (3, 4) and a movable permanent main contact (5), are each offset by at least approximately 120 degrees.

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