WO1999060588A1

WO1999060588A1 - Selector switch

Info

Publication number: WO1999060588A1
Application number: PCT/EP1999/002020
Authority: WO
Inventors: Wolfgang Albrecht; Dieter Dohnal
Original assignee: Maschinenfabrik Reinhausen Gmbh
Priority date: 1998-05-14
Filing date: 1999-03-25
Publication date: 1999-11-25
Also published as: DE19821775C1; DE59901305D1; CN1275241A; HUP0100062A2; JP2002516481A; JP3612278B2; AU3417899A; BG104589A; CN1134035C; CZ20004212A3; PL344005A1; UA70325C2; HUP0100062A3; BG63835B1; EP1078380A1; ATE216801T1; CZ298858B6; KR100420630B1; CA2311781A1; HK1033613A1

Abstract

The invention relates to a selector switch for tapped transformers to enable continuous tap switching with respect to a tapped winding, whereby fixed stepped contacts are arranged inside a cylinder made of insulating material on a horizontal plane for each phase. A rotating actuating shaft is located inside the insulating cylinder. The actuating shaft has a moveable hinged contact carrier for each phase that is to be switched and vacuum switching cells are respectively and vertically arranged on said contact carrier.

Description

Load selector

The invention relates to a load selector for step transformers according to the preamble of the first claim.

Such load selectors are already known from DE 38 33 126 C2.

Load selectors on transformers serve to tap the control windings of these

Switching transformers under load and thus specifically compensating for voltage changes.

Load voters can be because of the waiver of the otherwise usual separation of voters and

Manufacture and use of diverter switches with less effort.

During the switching process, arcing occurs in various contacts in the load selector.

To avoid this, the above DE 38 33 126 C2 proposes a load selector in which in each phase to be switched there are two movable mechanical switching contacts which can be pivoted simultaneously with one another on a common contact carrier, and in each case one vacuum switching cell, likewise arranged on the contact carrier, is provided in series with each of the two moving mechanical switching contacts .

The fixed ones that can be connected by the swiveling mechanical switch contacts

Step contacts of the load selector are on a concentric circle in the wall of one

Insulated plastic cylinder arranged.

The vacuum switching cells are arranged horizontally on the contact carrier and are controlled or actuated by a cam track arranged on a further concentric circle, which is arranged axially between the circle of the fixed step contacts and an additional slip ring.

This known load selector has several disadvantages.

On the one hand, the horizontal arrangement of the vacuum switching cells on the common contact carrier results in an undesirably large diameter of the

Isolierstoffzylinders and thus the load selector.

Vacuum switch cells have certain ones depending on their switching capacity

Minimum dimensions, in particular also a considerable longitudinal expansion. The actuating plungers also protrude from the vacuum switchgear cell in the longitudinal direction. It is therefore obvious that the common contact carrier one by the dimensions of the

Vacuum switch cell and the actuating means must have dictated radial expansion, which determines the overall diameter of the load selector.

Apart from these general dimensional problems, a particular disadvantage with the horizontal installation of the vacuum switching cells according to the prior art is that When the load selector is filled with oil, air remains on the upper folds of the vacuum cell bellows, which is not completely displaced by the oil filling. This leads to the fact that

Actuation of the vacuum switch cell an unequal load of the corresponding

Vacuum cell bellows occurs, whereby there is a risk that it tears.

Such remaining air in the area of the vacuum cell bellows can be arranged horizontally; Exclude reliably only by filling the load selector under vacuum; such vacuum filling is on site, e.g. after performed

Revisions, not possible or only with unreasonably high effort.

It should also be borne in mind that load selectors generally have a large axial overall

Longitudinal expansion, i.e. have a considerable overall height. The fixed step contacts of the individual phases to be switched are arranged in a circle one above the other, the means for

Actuation of the rotatable selector shaft inside the load selector, which is the contact carrier each

Carries phase in the head of the load selector as well as the means for mounting this selector shaft in

Bottom of the load selector also need space, so that, as explained, the

Load selector has a significant longitudinal expansion. This has the consequence that the mentioned

Switch shaft inside is also quite long.

Switching shafts of this type are usually made from GRP or other insulating material, although metallic switching shafts have also been proposed.

The contact carriers are in the known load selector by means of fastening screws on the

Shift shaft attached.

DE 44 14 941 Cl describes a further fixed attachment of a contact carrier to the selector shaft by means of a clamping flange.

Due to tolerances, different thermal expansion of oil tank and switch column,

Bends etc. can cause problems with the known load selector

The interaction of the components arranged on the individual contact carriers - in particular the vacuum switching cells - come with the circularly arranged actuating means, especially also because the actuating plungers of vacuum switching cells usually only have a relatively small linear actuation path.

The object of the invention is to eliminate these disadvantages and to provide a generic load selector which allows a space-saving arrangement of the vacuum switching cells and their safe and reliable actuation under all operating conditions.

This object is achieved by a load selector with the features of the first claim.

The subclaims relate to particularly advantageous developments of the invention. With the load selector according to the invention, the vacuum switching cells are standing on the

Contact carrier arranged The contact carriers have sliding contacts. they are through

Rolls in a lead are precisely guided by cams in this lead

Vacuum switching tubes controlled.

Knife sliding contacts, which are mounted in the contact carrier, conduct the current over the

Abieitring off.

Additional knife sliding contacts on the contact carrier enable the power supply.

According to a further feature of the invention, the contact carriers are each movable on the

Shift shaft arranged.

The particular advantage of the load selector according to the invention is in addition to the smaller ones

Dimensions then that all forces for the actuation of the vacuum switch cells as well as the contact forces on the Ableitrmg and the fixed contacts on the stable oil vessel are axially supported. This causes a radial load on the switch column, especially its

Deflection, and this results in a change in the timing of the

Vacuum switch cells and a reduction in contact forces avoided.

Through the rotatably or axially displaceably mounted contact carrier, which is axially through the

Is carried out, the switching sequence is guaranteed even in the event of height shifts due to tolerances and different thermal expansion of the oil tank and switch column.

The invention will be explained in more detail below with reference to drawings

The figures show:

1 shows a first embodiment of a load selector according to the invention in a partial lateral sectional view; FIG. 2 shows a part of the contact carrier of this load selector in a sectional view from above; FIG. 3 shows a second embodiment of a load selector according to the invention in a partial lateral sectional view; FIG Circuit Fig. 5 shows a modified such circuit

Fig. 6 shows a typical switching sequence of a load selector according to the invention.

The load selector shown in Figure 1 shows an embodiment of the invention with a rotatably mounted on a selector shaft 2 contact carrier 3 and standing on this arranged vacuum switch cells 27, 28 for constructive construction in detail The load selector consists of an insulating cylinder 1. A switching shaft 2, preferably made of insulating material, is arranged centrally and extending longitudinally through the insulating cylinder 1. The control shaft 2 is rotatable in a known manner; this is usually the case with Maltese drives, which are not shown. The bearing of the selector shaft 2 on the bottom of the insulating material cylinder 1 is also not shown.

The control shaft 2 carries in each level of the fixed step contacts 16 to be actuated, which will be explained in more detail below, a contact carrier 3 which is rotatably mounted in a bearing block 4 on the control shaft 2. The bearing block 4 is fastened to the selector shaft 2 with screws 4.1, 4.2.

The contact carrier 3 consists of a bearing part 5, a support housing 6 and the contact housing 7. The individual components of the contact carrier 3 are connected to one another by screws 8, 9. The contact housing 7 in turn in the exemplary embodiment shown consists of an upper contact housing part 10 and a lower contact housing part 11; both parts are in turn connected by further screws 12. The contact housing 7 can equally well be formed in one piece. The bearing part 5 has a bearing point 13, in which a bolt 14 is guided, which establishes the connection to the bearing block 4 and thus allows the rotary movement. The bolt 14 is secured in position by a cross pin 15.

Overall, the entire contact carrier 3 can thus be pivoted as a complete assembly around the bolt 14 and thus relative to the fixed selector shaft 2. In the wall of the insulating cylinder 1 - for each phase to be switched in a separate plane - fixed step contacts 16 are arranged, which are electrically connected to the taps of the control winding of the step transformer that is to be connected. The fixed step contacts 16 can be connected by corresponding contacts 17, 18. These contacts 17, 18 are arranged on the contact carrier in the horizontal direction next to one another such that when the switching shaft 2 and thus the contact carrier 3 are pivoted, one of the contacts 17, 18 reaches the adjacent new fixed step contact 16 before the other of these contacts reaches the previous fixed contact Step contact leaves. One contact 17 acts as a switching contact, the other contact 18 acts as an auxiliary contact.

In Figure 2, the arrangement of the two contacts 17, 18 from above next to each other on the contact carrier 3 and the interaction with the respective fixed step contact 16 is shown. In the embodiment shown in FIG. 2, the contact 17 acting as a switching contact is designed twice for reasons of the highest possible current carrying capacity, ie consisting of two parts 17.a and 17.b which are electrically connected to one another. Each of the contacts 17, 18 consists of an upper contact part 17.1, 18.1 and a lower contact part 17.2, 18.2. In the special embodiment of the switching contact shown in FIG. 2, the contact 17 there consists of a total of four parts, namely two upper contact parts 17.1a and 17.1b and two lower contact parts 17.2a and 17.2b. This double design of the contact 17, which acts as a switching contact, is useful for various designs, but is not necessary for the invention. Both the upper contact parts 17.1, 18.1 and the lower contact parts 17.2, 18.2 of each of the two contacts 17, 18 are each rotatably mounted on the contact housing 7 about separate pivot points 19, 20, 21, 22. They are pressed towards one another by springs 23, 24, 25, 26, in the direction of the fixed step contact 16 located between them in the connected state.

In other words: the respective upper contact part 17.1, 18.1 and the corresponding other contact part 17.2, 18.2 press with a defined contact force from both sides onto the respectively connected fixed step contact 16. Through the described storage about these separate pivot points 19, 20, 21, 22 running onto the fixed step contacts 16 is possible. In FIGS. 1 and 2, only the contact parts, fulcrums and springs lying in the front and top in the viewing direction can be seen.

Furthermore, two vacuum switch cells 27, 28 are fastened on each contact carrier 3, each by means of upper and lower fastening clamps 29, 30, 31, 32, such that the bellows 33, 34 and the actuating plungers 35, 36 of the vacuum switch cells 27, 28 extend upwards. Of the components just described, only the one lying in front in the viewing direction can be seen in FIG. 1. Two levers 37, 38, which each have a roller pin 41, 42 with a control roller 39, 40, are used to actuate the actuating plungers 35, 36 of the vacuum switching cells 27, 28. At their respective other free ends they act on the actuating plungers 35, 36 already described. Both levers 37, 38 are rotatably mounted about pivot points 43, 44; it is also possible to provide a common pivot point. The control rollers 39, 40 of both levers 37, 38 in turn correspond to a control ring 45, which has an upper control contour 46 and a lower control contour 47. The control ring 45 extends radially on the inner wall of the insulating material cylinder 1. From FIG. 1 it can be seen that the first control roller 39 corresponds to the lower control contour 47, i.e. runs on it and in exactly the same way the second control roller 40 runs on the upper control cam 46. The two control cams 46, 47 are thus used to actuate the vacuum switch contacts 27, 28 by pivoting the associated lever 37, 38 about its pivot point 43, 44 and thus the corresponding actuating plunger 35, 36 when the corresponding control roller 39, 40 runs onto a cam the vacuum switch cell 27, 28 actuated.

Furthermore, on the inside of the insulating material cylinder 1 there is a diverter contact ring 48 which has a connecting element 49 leading to the outside and is used for load dissipation. In a particularly simple manner, the control ring 45 and the diverter contact ring 48 can be combined to form a single component made of conductive material, as is shown in FIG. 1. The discharge contact ring 48 in turn corresponds to a mechanical one Diverter contact 50, which is arranged on the contact carrier 3 and, in a manner similar to the contacts 17, 18 already described above, in turn consists of an upper diverter contact part 50.1 and a lower contact part 50.2. Both of these diverting contact parts 50.1, 50.2 are rotatably supported analogously separately about further pivot points 53, 54 and are pressed against one another by further springs 51, 52 such that they grip around the diverting contact ring 48 with a defined contact pressure.

Finally, the contact carrier 3 also has two rollers 55, 56 which roll on both sides on the diverter contact ring 48 and thus guide the entire contact carrier 3. The arrangement described makes it possible to compensate for tolerances of any kind and, in particular, also to compensate for bending of the long control shaft. The contact carrier 3, which can be pivoted about the control shaft 2, is in any case guided in a defined manner by the diverter contact ring 48, so that despite the tolerances described, the control rollers 39, 40 are actuated precisely and the vacuum switching cells 27, 28 are thus actuated - despite their only small actuation paths is.

FIG. 3 shows a further embodiment of a load selector according to the invention. In this case, in contrast to the example explained so far, the contact carrier 103 is not rotatable, but rather is arranged to be longitudinally displaceable.

Within an insulating material cylinder 101 there is, in turn, arranged centrally, a switching shaft 102 which carries a longitudinally displaceable contact carrier 103. The longitudinal displaceability is realized by means of a guide 104. In this case, too, two vacuum switching cells, of which only the front vacuum switching cell 105 is shown, are arranged upright. In each level there are again fixed step contacts 106 in a circle in the wall of the insulating material cylinder 101, these in turn are connected by a switching contact and an auxiliary contact, of which only an upper contact part 107.1 and an associated lower contact part 107.2 are shown in the figure. In a similar manner, there is again a conductor contact ring 108 inside the insulating material cylinder 101, which is enclosed by a conductor contact, which in turn consists of an upper conductor contact part 109.1 and a lower conductor contact part 109.2. In this case, the entire contact carrier is guided by a roller 110 which runs in the contour of the diverter contact ring 108. The vacuum switchgear cells are in turn controlled by two levers 115, 116, which each have control rollers 113, 114 at their free ends, which in turn run on a lower control contour 11 1 or an upper control contour 112 and in this way the actuating plungers of the vacuum switchgear cells, of which only actuate the actuating plunger 117 of the vacuum switching cell 105 in the direction of view. FIG. 4 schematically shows the circuit which is implemented by the load selector according to the invention. The electrical connections between the contacts 17, 18 to the vacuum switching cells 27, 28 and from there in turn to the diverter contact 50 and thus to the diverter contact ring 48 are not shown in FIG. 1, which corresponds to this illustration.

FIG. 5 shows a circuit in which, as shown in FIG. 2, the switching contact 17 consists of two contact parts 17a, 17b arranged next to one another. The electrical connections are also only indicated in FIG. 2 corresponding to this illustration. It can be seen that the principle of operation does not differ, i.e. the same switching sequence can be achieved both by the circuit according to FIG. 4 and by the circuit according to FIG.

Such a switching sequence that can be achieved by way of example is shown in FIG. 6.

A load selector with different switching steps is shown. Such a load selector with different switching steps is known in principle from EP 0 160 125. The center distance between the fixed step contact lying on the main winding and the two fixed step contacts adjacent to it is greater than the center distance between the other fixed step contacts. This enables the load selector to be used on transformers with higher nominal voltages; this means that a higher withstand voltage can be achieved. In this document, suitable fixed step contacts, which are designed differently, are also already disclosed for such a load selector.

Regardless, it is particularly advantageous not to bend the fixed step contacts 16, as is customary in the prior art, i.e. parallel to the curvature of the insulating cylinder 1, but straight, as shown in Figure 2. While according to the prior art, the upper and lower contact parts 17.1, 18.1; 17.2, 18.2 run continuously on the same path of the fixed step contacts 16, the straight design ensures that other points of the surface of the fixed step contact 16 are constantly covered, which reduces their wear.

Claims

Claims:

1. Load selector for step transformers for uninterrupted switching between taps of a control winding of a step transformer, the load selector having an insulating cylinder as a housing, with fixed step contacts that are electrically connected to the taps in

Inside of the insulating cylinder are arranged in a circular manner for each phase of a horizontal plane, a rotatable switching shaft being in the center of the insulating cylinder, which also has a rotatable step contacts for each horizontal plane of fixed step contacts

Has contact carrier, wherein each of the contact carrier has at least two mechanical contacts, each of which can be contacted with the fixed step contacts of the respective horizontal plane, at least one of the contacts on each contact carrier directly with a first

Vacuum switch cell and at least one other of the contacts on each contact carrier via an intermediate switching resistor with a second

Vacuum switch cell is electrically connected, and being the other side of the two vacuum switch cells on each

The contact carrier is electrically connected to a load conductor, characterized in that all contact carriers (3) are articulated independently of one another on the selector shaft (2) and that the two vacuum switch cells (27, 28) each stand on the respective one

Contact carriers (3) are arranged such that their actuating plungers (35, 36) extend essentially in the axial direction.

2. Load selector according to claim 1, characterized in that each of the contact carriers (3) is pivoted about a pivot point on the selector shaft (2).

3. Load selector according to claim 1, characterized in that each of the contact carriers (103) is articulated axially longitudinally displaceably on the selector shaft (102).

4. Load selector according to one of claims 1 or 2, characterized in that each of the contacts (17, 18) consists of at least one upper contact part (17.1, 18.1) and at least one lower contact part (17.2, 18.2) and wherein each contact part (17.1 , 18.1; 17.2, 18.2) is pressed against the force of at least one spring (23, 24, 25, 26) against one another in such a way that when a fixed step contact (16) is peeled, it is mechanically enclosed on both sides and electrically contacted.

5. Load selector according to one of claims 1 to 4, characterized in that the fixed step contacts (16) inside the isothermal cylinder (1) have a horizontal extent which is not adapted to the inner contour of the isothermal cylinder (1), but in particular runs straight .

6. Load selector according to one of claims 1, 2, 4 or 5, characterized in that a control ring (45) is arranged on the inner wall of the isothermal cylinder (1) for each phase to be switched and thus for each horizontal plane fixed step contacts (16) which has an upper control contour (46) and a lower control contour (47) that on each contact carrier (3) for each of the two vacuum switching cells (27, 28) has a lever (37, 38) mounted about a pivot point (43, 44) ) is arranged and that each lever (37, 38) with one of its two free ends on one

Actuating plunger (35, 36) of a vacuum switching cell (27, 28) acts and with its respective other free end runs on one of the control contours (46, 47) in such a way that, depending on the spatial shape of the respective control contour (46, 47) respective

Vacuum switch cell (27, 28) can be actuated.

7. Load selector according to one of claims 1, 2, 4 to 6, characterized in that each load derivative consists of a concentric discharge contact ring (48) arranged on the inner wall of the isothermal cylinder (1) and having an outwardly guided connecting element (49) and which can be contacted by means of a discharge contact (50) which is arranged on the respective contact carrier (3) and which is electrically connected to the respective vacuum switching cells (27, 28) on this contact carrier (3).

8. Load selector according to one of claims 1, 2, 4 to 7, characterized in that that each of the contact carriers (3) has two further rollers (55, 56) which roll on both sides on the corresponding diverter contact ring (48) such that the respective contact carrier (3) is positively guided.

9. Load selector according to one of claims 1, 2, 4 to 8, characterized in that the control ring (45) and discharge contact ring (48) of each phase are combined into a single component.