A SPRING UNIT AND A DIVERTER SWITCH

Abstract

A spring unit includes a mechanical spring means having a spring direction and being located between a first spring support and a second spring support, which first and second spring supports are movable in relation to each other in the spring direction. The spring unit further includes a first actuation member facing the rear side of the first spring support and a second actuation member facing the rear side of the second spring support, which first and second actuating members are movable relative to each other and relative to the first and second spring supports in the spring direction.

Claims

1. A spring unit including mechanical spring means having a spring direction and being located between a first spring support and a second spring support, the first spring support having a front side abutting a first end of the spring means and a rear side opposite the front side, the second spring support having a front side abutting a second end of the spring means and a rear side opposite the front side, which first and second spring supports are movable in relation to each other in the spring direction, the spring unit further comprising a first actuation member facing the rear side of the first spring support and a second actuation member facing the rear side of the second spring support, which first and second actuating members are movable relative to each other and relative to the first and second spring supports in the spring direction, wherein the first actuation member is arranged to be able to apply a pushing force to the first spring support and includes first pulling means arranged to be able to apply a pulling force to the second spring support, and the second actuation member is arranged to be able to apply a pushing force to the second spring support and includes a second pulling means arranged to be able to apply a pulling force to the first spring support, such that a relative movement of the first and second actuation members towards each other results in compression of the spring means, and a relative movement of the first and second actuation members away from each other results in compression of the spring means.

2. A spring unit according to claim 1, wherein at least the first pulling means includes at least one rod extending in the spring direction and having a carrier means arranged to cooperate with the second spring support.

3. A spring unit according to claim 2, wherein the at least one rod extends through a respective through hole in the second spring support.

4. A spring unit according to claim 3, wherein each rod is provided with a radial extension extending radially outside said through hole in the second spring support, which extension forms said carrier means.

5. A spring unit according to claim 4, wherein the at least one rod is provided with a circumferential groove housing a ring device establishing said extension.

6. A spring unit according to claim 2, wherein the at least one rod extends through a respective through hole in the first spring support.

7. A spring unit according to claim 2, wherein also the second pulling means includes at least one rod extending in the spring direction and having a carrier means arranged to cooperate with the first spring support.

8. A spring unit according to claim 7, wherein the second pulling means includes features corresponding to those of the first pulling means specified in claim 3.

9. A spring unit according to claim 2, wherein the number of rods of each pulling means is two.

10. A spring unit according to claim 9, wherein the axes of the four rods are located in a respective corner of a rectangle, and wherein the rods of the first pulling means are diagonally located in the rectangle, and the rods of the second pulling means are diagonally located in the rectangle.

11. A spring unit according to claim 1, wherein the spring means consists of one single helical spring.

12. A spring unit according to claim 1, wherein the spring unit is adapted to actuate a contact of a diverter switch.

13. A diverter switch, comprising: a contact; and a spring unit that is adapted to actuate the contact; wherein the spring unit includes mechanical spring means having a spring direction and being located between a first spring support and a second spring support, the first spring support having a front side abutting a first end of the spring means and a rear side opposite the front side, the second spring support having a front side abutting a second end of the spring means and a rear side opposite the front side, which first and second spring supports are movable in relation to each other in the spring direction, the spring unit further comprising a first actuation member facing the rear side of the first spring support and a second actuation member facing the rear side of the second spring support, which first and second actuating members are movable relative to each other and relative to the first and second spring supports in the spring direction, wherein the first actuation member is arranged to be able to apply a pushing force to the first spring support and includes first pulling means arranged to be able to apply a pulling force to the second spring support, and the second actuation member is arranged to be able to apply a pushing force to the second spring support and includes a second pulling means arranged to be able to apply a pulling force to the first spring support, such that a relative movement of the first and second actuation members towards each other results in compression of the spring means, and a relative movement of the first and second actuation members away from each other results in compression of the spring means.

14. A tap changer including a diverter switch according to claim 13.

15. A transformer, comprising: a tap changer including a diverter switch; wherein the diverter switch comprises: a contact; and a spring unit that is adapted to actuate the contact; wherein the spring unit includes mechanical spring means having a spring direction and being located between a first spring support and a second spring support, the first spring support having a front side abutting a first end of the spring means and a rear side opposite the front side, the second spring support having a front side abutting a second end of the spring means and a rear side opposite the front side, which first and second spring supports are movable in relation to each other in the spring direction, the spring unit further comprising a first actuation member facing the rear side of the first spring support and a second actuation member facing the rear side of the second spring support, which first and second actuating members are movable relative to each other and relative to the first and second spring supports in the spring direction, wherein the first actuation member is arranged to be able to apply a pushing force to the first spring support and includes first pulling means arranged to be able to apply a pulling force to the second spring support, and the second actuation member is arranged to be able to apply a pushing force to the second spring support and includes a second pulling means arranged to be able to apply a pulling force to the first spring support, such that a relative movement of the first and second actuation members towards each other results in compression of the spring means, and a relative movement of the first and second actuation members away from each other results in compression of the spring means.

16. A spring unit according to claim 3, wherein the at least one rod extends through a respective through hole in the first spring support.

17. A spring unit according to claim 4, wherein the at least one rod extends through a respective through hole in the first spring support.

18. A spring unit according to claim 5, wherein the at least one rod extends through a respective through hole in the first spring support.

19. A spring unit according to claim 3, wherein the number of rods of each pulling means is two.

20. A spring unit according to claim 4, wherein the number of rods of each pulling means is two.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0040] FIG. 1 is schematic illustration of a tap changer of a kind for which the spring unit according to some embodiments is suitable.

[0041] FIG. 2 is a perspective view of a spring unit according to some embodiments in a neutral stage.

[0042] FIG. 3 is a split view of the spring unit in FIG. 2.

[0043] FIG. 4 is a schematic side view of the spring unit in FIG. 2 in a neutral stage.

[0044] FIG. 5 is a schematic side view of the spring unit of FIG. 2 in a compressed stage, where compression has been attained by pushing.

[0045] FIG. 6 is a schematic side view of the spring unit of FIG. 2 in a compressed stage, where compression has been attained by pulling.

DESCRIPTION OF EXAMPLE

[0046] In order to illustrate the context of some embodiments, FIG. 1 schematically illustrates a tap changer 100 of a kind for which the spring unit is intended. The tap changer 100 is connected to a regulating winding 105 of a transformer and has a set of different taps 110. The tap changer of FIG. 1 is of diverter switch type, and comprises a diverter switch 115 and a tap selector 120.

[0047] The tap selector 120 of FIG. 1 comprises two current collectors 125, two selector arms forming two movable contacts 130 and further comprises a set of fixed contacts 135, where each fixed contact 135 is arranged to be connected to one of the taps 110 of the regulating winding. The illustrated tap changer has fifteen different fixed contacts 135, and the regulating winding has fifteen taps. The tap changer of FIG. 1 is mechanically linear in the sense that the current collectors 125 are implemented as linear rods, and the fixed contacts are implemented in a linear fashion. The two current collectors 125 together form a current collector part.

[0048] The diverter switch 115 comprises two series connections of a main contact 140 and a transition contact 145, with transition resistor 150 connected in parallel with transition contact 145. It is common that the contacts are vacuum interrupters. Each of the series connectors are, at one end connected to a respective one of the two current collectors 125, and at the other end connected to an external contact 155 of the tap changer 100.

[0049] The movable contacts 130 are at one end in electrical contact with a respective one of the current collectors 125. A selector arm 130 can move along the current collector 125 to which it is connected, in order to reach different positions, at which the other end of the movable contact 130 is in electrical contact with one of the fixed contacts. The movable contacts 130 could for example be sliding contacts arranged to slide along the current collectors 125 and the different fixed contacts 135. The driving of the movable contacts 130 is arranged so that if one of the movable contacts 130 is in contact with a fixed contact 135, connected to a first tap, the other moveable contact 130 is in contact with a fixed contact 135, connected to a tap 110 which is adjacent to the first tap 110.

[0050] By switching the main contacts 140 and transition contacts 145 in a conventional manner, one or the other of the moveable contacts 130 will be in electrical contact with the external contact 155, and thus provide an electrical path through the tap changer 100. Similarly, the two current collectors 125 will take turns at being part of the electrical path of the tap changer 100. The electrical path through the tap changer 100 ends at the external contact 155 at one end, and at the fixed contact 135 that is currently connected at the other end. An example of a diverter switch is described in EP 0116748. The diverter switch 115 is an example only, and any suitable type of diverter switch can be used.

[0051] As mentioned above, the regulating winding 105 has a set of taps 110, which are shown to be connected to the fixed contacts 1355 of the tap changer 100 via cables 160. The other end of the regulating winding 105 is provided with an external contact 165. Depending on which tap 110 is currently connected to a fixed contact 135, the electrical path between the external contacts 155 and 165 will include a different number of the regulating winding turns.

[0052] When it is required to change from one tap to another, the vacuum interrupters of the contacts 140 and 145 and those on the other current collector are to be closed and opened, respectively in a certain sequence. This allows the selector arms with the movable contacts 130 to move to come into contact with the adjacent one of the fixed contacts 135. Closing and opening of the vacuum interrupters in the diverter switch 115 and movement of the movable contacts in the tap selector 170 has to be made in a certain time relation to each other. The actuation of the vacuum interrupters requires a rapid and strong actuation force, that normally is obtained by an energy accumulator having a spring that can be charged and rapidly discharged.

[0053] The spring according to some embodiments has the function to provide such energy accumulators for effectuating the actuation of the interrupters in the diverter switch.

[0054] FIGS. 2 and 3 in a perspective view and in a perspective split view, respectively, illustrate an example of a spring unit according to some embodiments. The spring unit has a helical compression spring 1. A first end 11 of the spring 1 abuts the front side 21 of a first spring support 2 at the left side of the figures. A second end 12 of the spring 1 correspondingly abuts the front side 31 of a second spring support 3.

[0055] Axially outside the first spring support 2 a first actuation member 4 is located, and defines a first actuation axis A1 of the diverter switch. Similarly a second actuation member 5 is located axially outside the second spring support 3 and defines a second actuation axis A2 of the diverter switch.

[0056] The first actuation member 4 has two rods 61, 62 rigidly connected to the actuation member 4 and extending in parallel to the axis of the spring 1. Each of the rods 61, 62 extend through holes 25, 26, respectively, in the first (the adjacent) spring support 2 and through holes 33, 34, respectively, in the second (the remote) spring support 3.

[0057] As can be seen in FIG. 3 each rod 61, 62 adjacent its end is provided with a circumferential groove 611, 621. In each groove a silted ring 612, 622, respectively, is mounted by having been snapped into the groove 611, 621. Each ring 612, 622 extends radially outside the related groove and has a larger outer diameter than the holes 25, 26, 33, 34

[0058] The diameter of the through holes 25, 26, 33, 34 corresponds to the diameter of the rods 61, 62, such that the rods 61, 62 with sufficient play can move axially through the holes 25, 26, 33, 34. Each ring 612, 622 extends radially outside the respective holes 25, 26, 33, 34.

[0059] The two rods 61, 62 together with their rings 612, 622 constitute pulling means, through which the second spring support 3 (on the right side of the figures) can be pulled in the leftward direction when the first actuation member (on the left side of the figures) is moving leftwards. The rings 612, 622 thereby act as a carrier when they abut the rear side 32 of the second spring support 3.

[0060] The second actuation member 5 (at the right side of the figures) correspondingly has two rods 71, 72 with grooves, rings and function that are equal to what have been described above for the rods 61, 62, but act in the opposite direction.

[0061] FIG. 4 in a schematic side view illustrates the spring unit in its neutral stage when the spring 1 neither is compressed nor expanded. FIGS. 5 and 6 illustrate the spring unit when loaded, in both cases by being compressed, but through two different modes of operation.

[0062] FIG. 5 illustrates compression of the spring when the two actuation axes A1, A2 move towards each other, normally in that one is moving towards the other which is stationary. When axis A2 moves from the neutral position in FIG. 3 in the leftward direction and axis A1 is stationary, the second actuation member 5, related to axis A2, pushes on the rear side 32 of the second spring support 3. The front side 31 of the second spring support abuts the second end 12 of the spring 1 and thus moves the second end 12 of the spring to the left. The first end 11 of the spring 1 abuts the front side 21 of the first spring support 2 and since the first spring support 2 with its rear side 22 contacts the stationary first actuation member 4, the spring 1 becomes compressed until it reaches the state illustrated in FIG. 5.

[0063] During this compression movement the rods 71 and 72 extending through the related holes in the second spring support 3 will move to the left and thereby move through the related holes 24, 23 in the first spring support 2 and project out on the left side of the first spring support 2 until it reaches the position in FIG. 5. The rods 71 and 72 are laterally located outside the first actuation member 4 (as visualized in the left end of FIG. 3), and therefore freely passes the first actuation member 4. As the second actuation member 5 together with the second spring support 3 moves to the left, the stationary rods 61, 62 of the first actuation member 4 will in a corresponding way pass through the holes in the second spring support 3 and laterally outside the second actuation member 5 to reach the position in FIG. 5. The spring unit is now loaded and prepared for the next switching manoeuvre. This mode of compression principally corresponds to conventional technique.

[0064] FIG. 6 illustrates compression of the spring when the two actuation axes A1, A2 move away from each other, in that the first axis A1 is stationary and the second axis A2 moves to the right from the position in FIG. 4. Thereby the rods 71 and 72 move to the right through the related holes in the second spring support 3, which in this position is locked against movement to the right. When the rods 71, 72 move to the right, their respective ring 712, 722 act on the rear side 22 of the first spring support 2 such that the first spring support is pulled in the rightward direction. The second spring support 3 is prevented to move rightwards by the rings 612, 622 on the rods 61, 62 attached to the stationary first actuation member 4. The spring 1 therefore becomes compressed between the two spring supports 2, 3 until it reaches the position of FIG. 6.

[0065] According to conventional technique the spring is loaded by expansion when the actuation axes move away from each other, which requires more space in the axial direction and renders the spring unit to be more bulky.