EP1891652A1

EP1891652A1 - Energy accumulator

Info

Publication number: EP1891652A1
Application number: EP06753458A
Authority: EP
Inventors: Silke Wrede; Klaus Hoepfl
Original assignee: Maschinenfabrik Reinhausen GmbH; Maschinenfabrik Reinhausen Gebrueder Scheubeck GmbH and Co KG
Current assignee: Maschinenfabrik Reinhausen GmbH; Scheubeck GmbH and Co
Priority date: 2005-06-15
Filing date: 2006-04-29
Publication date: 2008-02-27
Anticipated expiration: 2026-04-29
Also published as: CN101019197A; EP1891652B1; ES2361337T3; CN101019197B; DE102005027524B3; KR101213057B1; US20080093207A1; DE502006008913D1; HK1115226A1; BRPI0605903A; BRPI0605903B1; JP2008544504A; US7518075B2; WO2006133766A1; RU2380782C2; JP4774437B2; UA91368C2; ATE498896T1; RU2008101543A; KR20080016522A

Abstract

The accumulator has longitudinally movable lift and leaping carriages (3, 16) fixed in connection with a drive shaft, where the carriages are guided through three parallel guide rods extending in the direction of motion of the carriages. Two of the three rods are surrounded by a power accumulator spring, and each of the carriages has three linear bearings, where each of the bearings surrounds the other rod. A cam follower (29) is arranged to coincide with an actuator such that the leaping carriage is pushed into a new final position by rotation of an eccentric plate.

Description

power storage

The invention relates to a power storage for an on-load tap-changer.

On-load tap-changers are used for uninterrupted switching between different winding taps of a tapped transformer under load. Since this changeover usually takes place abruptly, on-load tap-changers generally have a force store.

Such a power storage is known from DE-PS 19 56 369 and DE-PS 28 06 282 already known. It is mounted at the beginning of each actuation of the on-load tap-changer by its drive shaft, d. H. curious; excited. The known power storage essentially consists of an elevator carriage and a jump carriage, between which power storage springs are arranged as energy storage.

In the known power storage two guide rods are provided on which elevator carriage and jump carriage are mounted independently longitudinally movable. At the same time, the guide rods form the guide for the force-storing springs, such that in each case one force-storing spring in each case encloses a guide rod.

The elevator carriage is moved linearly relative to the skid carriage by means of an eccentric connected to the drive shaft, thereby tensioning the energy storage springs therebetween. If the elevator carriage has reached its new end position, the locking of the jump carriage is released. This follows now abruptly, as standing under the force of the tensioned power storage springs, the previous linear movement of the elevator carriage also linearly. This sudden movement of the jump carriage is converted into a rotational movement of an output shaft. This in turn serves to actuate the on-load tap-changer, i. H. to switch between the previous to a new winding tap under load.

In the known power storage both elevator carriage and jumping carriage on an open 4-point storage: they are on - seen in the direction of movement - upper and lower end respectively mounted on the two parallel guide rods and are guided by these.

The well-known power storage places high demands on the parallelism of the guide rods and the accuracy of the moving parts as a whole, since jamming or even a stiffness of elevator or jump sled must be avoided. A stiffness of the elevator carriage would cause unacceptably large actuation forces; a stiffness of the jump carriage could cause this does not reach its final position and thus the switching of the on-load tap changer can not be properly completed, since the energy storage does not latch in its new end position. The object of the invention is to provide a force accumulator of the type mentioned, which has a simple structure and a particularly high reliability.

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

The inventive arrangement of three parallel guide rods and the invention also embraced 3-point storage of both elevator carriage and jump carriage optimum guidance of these components is ensured without mechanical overdetermination. This results in a particularly high reliability even when occurring shear forces, z. B. in conjunction with pressing devices, in comparison to the prior art.

The invention will be explained in more detail by way of example with reference to drawings. Show it:

Fig. 1 shows a force storage device according to the invention in a lateral view

Fig. 2 this energy storage in perspective view

Fig. 3 this energy storage in a further perspective view of the other

Page, d. H. horizontally rotated by 180 grand

Fig. 4 is a schematic representation of the principle of the three parallel

Guide rods and the entangled 3-point storage of elevator corn also jump carriage.

Figures 1 to 3 show a force storage device according to the invention in different representations, not all items described in more detail below recognizable in each representation and thus not all reference numerals are entered. In addition, in FIG. 2, the force-storing springs and the force-storing carrier have been omitted for better illustration.

As is known from the prior art, an eccentric disc 2 which is connected to a drive shaft 1 is also provided in the force accumulator described here, which actuates an elevator carriage 3 by acting on the driver blocks 4 and 5 arranged at the top and bottom in the direction of movement of the elevator carriage 2. According to the invention, the force accumulator has three parallel extending, along the direction of movement of the elevator carriage 3 extending guide rods 6, 7 and 8, two of which, in the example shown, these are the guide rods 6 and 7, of power storage springs 12, 13 are enclosed. The third guide rod 8, also referred to as a carrier rod, however, is not enclosed by a force storage spring. The elevator carriage 3 has at its one end two linear bearings 9 and 10. The linear bearing 9 encloses the guide rod 6, the linear bearing 10 encloses the guide rod 8. At its other end, the elevator carriage 3 has only a single linear bearing 11, which encloses the guide rod 7. With these three linear bearings in the described arrangement of the elevator slide 3 is stably stored and guided defined in its movement.

It has already been explained that the energy storage springs 12 and 13 each extend around one of the two guide rods 6 and 7, respectively. They are fixed in the direction of movement above or below in each case a displaceable spring bar 14 and 15 with one of their ends and are supported there. The function of the spring bars 14, 15 will be explained later in more detail.

Below the elevator carriage 3, in the same direction as this longitudinally movable, a jumping carriage 16 is guided. This jumping carriage 16 has, on the side at which the elevator slide 3 has two linear bearings 9, 10, only a single linear bearing 18, which surrounds the guide rod 7. On the other side, where the elevator carriage 3 has only a single linear bearing 1 1, it has, however, two separate such linear bearings 19, 20. Here, the linear bearing 19 encloses the guide rod 6 and the linear bearing 20, the guide rod 8. This is also the jump slide 16 stably stored and also guided defined in its movement. In Figure 4, this looped 3-point storage of elevator carriage 3 and jump carriage 16 is shown schematically. It can be seen that it is a virtually mirror-image arrangement of the individual bearings of the two moving components.

The described three guide rods 6, 7, 8 are attached at its two ends to a force storage carrier 17, to which the other stationary components of the force accumulator according to the invention are attached.

The sequence of movements in an elevator of the force accumulator according to the invention is as follows: The drive shaft 1 begins to rotate, with it the eccentric disc 2, which slides on the corresponding driver block 4, 5 and thus shifts the elevator carriage 3 in the longitudinal direction. As a result, the force storage springs 12, 13 are tensioned. Has the elevator carriage 3 reaches its new end position, these power storage springs 12, 13 are biased maximum. Until this time, the jump slide 16 is still locked by laterally up and down in the direction of movement latch lever 21, 22 so that it can not follow the direction of movement of the elevator slide 3. In the new end position of the elevator carriage 3, however, by a suitable actuator, which is not shown in the drawings, depending on the direction of movement, an upper or lower roller 23, 24 on the upper and lower latch lever 21, 22 pressed inwards. As a result, the respective latch lever 21 or 22 is released against the force of a pawl spring 25 from the lock and the jump carriage 16 now follows, due to the force of the tensioned power storage springs 12 and 13, the movement of the elevator carriage 3 abruptly. Once it has reached its new end position, a locking takes place again, ie the latch levers 21, 22 latch the jump carriage 16 in the new position again. At the next actuation of the energy storage takes place the described Movement of elevator carriage 3 and jump carriage 16 in the other direction. The direction of movement of the individual components is indicated in the figures by arrows; The energy storage has a left and a right end position, between which alternately changed at each switching.

A suitable actuator for the rollers 23 and 24 may, for. B. a vertical, laterally arranged on the elevator carriage 3, be downwardly extending actuating sheet whose presentation has been omitted here for reasons of clarity, since it would have hidden many important other components. Such an actuating plate may be fastened to a screw connection 33 indicated in FIG.

Further above, the spring bars 14 and 15 have already been briefly described, which are arranged displaceably on the guide rods 6 and 7 and respectively form upper and lower abutment for the power storage springs 12 and 13. Spring webs 14, 15 on the one hand and elevator slide 3 and jump carriage 16 on the other hand are designed such that the spring bars 14, 15 abut both upper and lower limits of the elevator carriage 3 and the jump carriage 16 in the direction of movement and taken by these two components in both directions of movement can be. By this construction, the already described tensioning of the power storage springs 12, 13 when mounting the elevator carriage 3 and the subsequent sudden relaxation in the release of the jump carriage 16 in both directions of movement is technically realized.

The jump-like linear movement of the jump carriage 16 is by known technical means, for. Example, a gear associated with a longitudinal toothing, as known from WO 02/31847, or by a sliding block and a crank, as known from DE-PS 19 56 369, converted into a rotational movement of an output member 26. In the example shown here, one or two rollers 31 are provided for this purpose, which are fastened to the jump carriage 16 and are guided in a groove 32 of the output element 26. This output element 26 is connected to an output shaft, not shown here, in connection, which ultimately jumped the on-load tap changer, d. H. initiates the sudden changeover between two winding taps under load. The rollers 31 are fastened by means of a carrier 34 on the jump carriage 16.

According to a particularly advantageous embodiment of the invention, an additional pressing device is arranged in the force storage device according to the invention. Such Nachdrückeinrichtung should ensure that even under difficult operating conditions, for example, at low temperatures and very tough the energy storage enclosing oil with certainty the new end position is reached and the energy storage latched in this new position again. It consists of in the direction of movement at the top and bottom of the jump carriage 16 arranged drivers 27 and 28, with a roller pin 29 on the Eccentric disc 2 correspond. The roller pin 29 is arranged such that it shortly before the end of the movement of the jump carriage 16, ie shortly before reaching its new end position, depending on the position of the jump carriage 16 coincides with either the driver 27 or the driver 28 and thus by the still rotating Eccentric disc 2 additionally pushes the jump carriage 16 in the new end position - hence the name Nachdrückeinrichtung.

Claims

claims

1. Power storage for an on-load tap changer, wherein a longitudinally movable, standing with a drive shaft in connection elevator carriage and also longitudinally movable, standing with an output shaft in connection jump carriage are provided, wherein elevator carriage and jump carriage are guided by extending in the direction of their movement parallel guide rods, wherein between Elevator carriage and jumping carriage power storage springs are provided, wherein the elevator carriage at each circuit of the on-load tap-changer by the rotating

Drive shaft in alternatively one of two opposite directions is linearly movable, such that the power storage springs are tensioned and wherein just before reaching the new end position of the elevator slide locked until then

Jump carriage is triggered, such that it follows the movement of the elevator carriage jump, characterized in that exactly three parallel guide rods (6, 7, 8) are provided, of which two adjacent

Guide rods (6, 7) are each enclosed by a force storage spring (12, 13), that the elevator Schi itten (3) has three linear bearings (9, 10, 11) and each of these linear bearings (9, 10,

11) in each case encloses another guide rod (6 or 7 or 8) and that the jump carriage (16) has three further linear bearings (18, 19, 20) and each of these further linear bearings (18, 19, 20) in each case in turn a different guide rod (16). 6 or 7 or 8).

2. Power accumulator according to claim 1, characterized in that both the elevator carriage (3) and the jump carriage (16) each have two linear bearings (9, 10 and 19, 20) on one side, approximately perpendicular to the direction of movement, are arranged and that respectively another linear bearing (1 1 or 18) is arranged on the other side.

3. Power accumulator according to claim 1 or 2, characterized in that the force storage springs (12, 13) on both sides in a respective spring bar (14, 15) are supported, that each spring bar (14, 15) independently of the other on the guide rods (6, 7 , 8) is displaceable and that the spring webs (14, 15) on the one hand and elevator carriage (3) and jump carriage (16) on the other hand are formed such that the spring webs (14, 15) at boundaries of the elevator carriage (3) and the jump carriage ( 16) strike and are displaced by these two components in both directions of movement.

4. energy accumulator according to one of claims 1 to 3, characterized in that in addition to the jump carriage (16) driver (27, 28) are provided which with a

Roll pin (29) on the eccentric disc (2) correspond and that the roller pin (29) is arranged such that it is close to the end of the movement of the

Jump carriage (16) before reaching its new end position coincides with one of the drivers (27, 28), such that by the rotating eccentric disc (2) in addition to the

Jump carriage (16) can be pressed into the new end position.