NO149189B - STEP SELECTOR FOR STEP CONNECTORS IN STEP TRANSFORMERS - Google Patents

Description

Single- or multi-phase tap selector for tap-couplers in step-down transformers, where the fixed contacts of a phase divided into equal or odd numbers are arranged in a circular path in two planes and where in each plane there is a contact bridge that can be pivoted step by step from contact to contact as with one end constantly drags on an inner contact ring in its plane, both of the contact bridges belonging to odd-numbered contacts are rigidly connected to each other exactly like the contact bridges belonging to even-numbered contacts and where in any operating position an electrical connection is provided between an even-numbered and an odd-numbered contact and the on-load switch, respectively off the connection cables connected to the contact ring.

With known step selectors of this type, depending on the number of steps, there are more or fewer permanent contacts per plane in the circle arranged on a corresponding number of insulating rods. Depending on the number of contacts, i.e. insulating rods, the tap-coupler's circumference must be given a corresponding size. There are, however, cases where a very large number of steps is required, such as for tap-changers for furnace transformers, so that a step selector with a very large circumference must be arranged here. This, in turn, requires a lot of space and, on the other hand, it is not possible to build such a step selector out of e.g. standard parts, because both an operating mechanism with a very large number of steps and a special supporting construction of the selector are necessary. Attempts have been made to remedy this, e.g. have arranged two step selectors built from standard parts next to each other, which nevertheless require more space than a single selector with a correspondingly large circumference.

The purpose of the invention is therefore to provide a step selector of the type mentioned at the outset which can be built up from standard parts and whose space requirements are as small as possible.

This is achieved according to the invention by the fact that the two contact rings belonging to the odd number of contacts such that the two contact rings belonging to the even number of contacts are electrically conductively connected to each other and that two rigidly connected contact bridges belonging to the odd number of contacts exactly as the contact bridges belonging to the even number are offset in relation to each other that in each operating position only one of the two mutually offset, mutually connected contact bridges reaches a fixed contact, while the other reaches a position between two contacts.

The advantage provided by the present invention is based on the following: Additional switches are avoided. Only the selected and pre-selected contacts are mechanically loaded. That is, the contacts not required in their respective operating positions for the function of the step selector are not exposed to any mechanical stress whereby the normal operating force is sufficient and where no additional operating forces can occur.

It is fairly well known to influence the selector contact bridges of a tap selector offset in relation to each other by half a switching step, but this is done, however, to disengage the on-load tap-changer and to form the star point in the tap selector itself (CH-PS 4 93 964). This requires, in terms of influence, a further half switching step for the selector contact which does not carry current at the moment. This additional switching step must be carried out both immediately before and immediately after the load switching. To increase the number of step contacts, this method is therefore not suitable.

An embodiment of the invention will be explained in more detail below with reference to the drawings. Fig. 1 shows a side view of a single-phase step selector according to the invention. Fig. 2a and 2b show a schematic section through the step selector

on fig. 1 in two plans for the different number of contacts.

Fig. 3 schematically shows the step selector unfolded.

As can be seen from Figure 1, the step selector mainly consists of an operating mechanism with a step switch head 21, a load switch 22, an operating mechanism 23 and a step selector 24. These parts are arranged below each other in the usual way. The cylindrical step selector 24, on the other hand, mainly consists of five insulating rods 25 which are fixed in an upper and lower flange 26 and 27 respectively and which carry the fixed contacts 1 to 20, as well as one in the center of the cylinder. the arranged selector column 28 which carries the contact ring 29,

30. the voter column.

The fixed contacts 1 to 20 are divided into odd-numbered contacts and even-numbered contacts, where both the odd-numbered contacts and the even-numbered contacts are arranged in two planes.

Figures 2a and 2b show the two plans for the different number of contacts. This division can also be seen in figure 3, where in the first plane a^ an odd number of contacts 1, 5, 9, 13, 17 are arranged (figure 2a) and in the second plane a^ there are an odd number of contacts 3, 7, 11, 15, 19 (figure 2b) arranged. Likewise, an even number of contacts 2, 6, 10, 14, 18 are arranged in plane b^ and finally in plane b2 there are an even number of contacts 4, 8, 12, 16,

20 (see figure 3). Each plane has its own contact bridge 36 to 39, which constantly drags an associated contact ring 29 to 32, step by step from a fixed contact to the next one in its plane. This happens with the help of the operating rods 40, 41 which are swung around the selector column 38 with the help of the operating mechanism 23. The two contact bridges 36 and 37 in the plane a^ and a^ are mechanically rigidly connected to each other and are operated by the same

operating rod 40. The two contact bridges 36 and 37 are offset from each other in such a way that in each operating position only one of the two, for example the contact bridge 36, is always in contact with a fixed contact, for example 1 (figure 2a), while the other contact bridge, for example 37, occupies an intermediate position between the two fixed contacts, for example 3 and 19 (figure 2b). The same applies to the two contact bridges 38 and 39 in planes b^ and b2 for the even number of contacts (see Figure 3). This means that the individual connection steps in each plane correspond to half the distance 42 between two contacts in a plane. When, in figure 3, a connection step has been made, first the two contact bridges 36 and 37, which are rigidly connected to each other, are moved one connection step to the left, so that the contact bridge 37 comes into contact with the contact 3 and the contact bridge 36 occupies a free position between the two contacts 1 and 5. If earlier contacts 1 and 2 were respectively selected and preselected, then this now applies to contacts 2 and 3, because in this connection step no change occurs in the plans b^ and • Only at the next connection step are they likewise included each other rigidly connected contact bridges 38 and 39 moved a step to the left, so that the conact bridge leaves contact 2 and occupies a free intermediate position between contacts 2 and 6, while contact bridge 38 comes into contact with contact 4. Now contacts 3 and 4 are respectively selected and preselected. Important in this constructive design is of course that always two contact rings belonging to each other, for example 29 and 30, for the odd-number contacts are electrically conductively connected to each other, as are the two contact rings 31 and 32 belonging to each other for the even-number contacts. This happens in a simple way by connecting the connection lines 33 and 34 respectively leading to the on-load switch 22 to the two contact rings 29 and 30 and 31 and 32 respectively.

It is clear that the invention is in no way limited to the embodiment shown with five insulating rods. The number of insulating rods in the selector depends on the number of steps required and on the type program for the normal design of the step selector. Furthermore, it is also possible to arrange the individual planes a^ r a^, h^, fc>2 in another arbitrary order. Furthermore, the mutually offset contact bridges 36 and 37 and 38 and 39 belonging to each other with half the contact distance 42 can also be mutually offset by 1 1/2, 2 1/2 etc. contact distance.

Claims (1)

Single- or multi-phase tap selector for tap-changers in step transformers, where the - fixed contacts of a phase divided into even or odd numbers are arranged in a circular path in two planes and where in each plane there is a contact bridge that can be pivoted step by step from contact to contact, which with one end constantly drags on an inner contact ring in its plan, as both the contact bridges belonging to an odd number of contacts exactly like the contact bridges belonging to an even number are rigidly connected to each other and where in any operating position an electrical connection is provided between each an even number and an odd number of contacts and the on-load switch by means of connection lines connected to the contact ring, characterized in that the two contact rings (29, 30) belonging to the odd number contacts, as well as the two contact rings (31, 32) belonging to the even number contacts, are electrically conductively connected to each other , and that the two rigidly connected contact bridges belonging to the odd number of contacts "(36, 37) exactly like the contact bridges belonging to the same number (38, 39) are so offset in relation to each other that in each operating position only one of the two contacts each other offset interconnected contact bridges (e.g. 36 or 38) to contact a fixed contact (e.g. 1 or 2), while the other (e.g. 37 or 38) reaches a position between two contacts (e.g. 3 and 19 or 4 and 20).