EP1138052A2

EP1138052A2 - Energy accumulator for a step switch

Info

Publication number: EP1138052A2
Application number: EP99948751A
Authority: EP
Inventors: Dieter Dohnal; Klaus Hoepfl; Silke Wrede
Original assignee: Maschinenfabrik Reinhausen GmbH; Maschinenfabrik Reinhausen Gebrueder Scheubeck GmbH and Co KG
Current assignee: Maschinenfabrik Reinhausen GmbH; Scheubeck GmbH and Co
Priority date: 1998-12-03
Filing date: 1999-09-14
Publication date: 2001-10-04
Anticipated expiration: 2019-09-14
Also published as: CN1123021C; BG63837B1; KR20010080659A; WO2000033339A2; AU6190799A; ES2178476T3; CN1308765A; ATE219603T1; BG104833A; HK1038826A1; EP1138052B1; KR100603555B1; DE19855860C1; WO2000033339A3; DE59901826D1

Abstract

The invention relates to an energy accumulator for a step switch, comprising a slide which can be pulled upwards and a latchable switch slide that follows the movement of the pull-up slide in an elastic manner upon release. The pull-up slide and switch slide are can be respectively displaced in the longitudinal direction of a guide rod. The pull-up slide and the switch slide have a respective guide roller on one side and have a guide contour on the opposite side, whereby the guide roller of the pull-up slide is guided in the guide contour of the switch slide and vice versa.

Description

Lift mechanism for a tap changer

The invention relates to an energy accumulator for a tap changer. Such energy stores are known from DE-PS 19 56 369.

Step switches are used for uninterrupted switching between different winding taps of a step transformer and thus for voltage regulation. The actual load switching must be done as quickly as possible, therefore tap changers or their diverter switches are usually provided with an energy accumulator. The energy accumulator is pulled up by a continuously and slowly rotating drive shaft, tensioned and, after its subsequent triggering, suddenly releases kinetic energy.

A generic energy accumulator is known from DE-PS 19 56 369. This has a pull-up slide and a latchable tension slide; springs formed as compression springs are arranged between these two slides. The mounting slide and the tensioning slide are provided with flanges and lie on their inner sides so that the compression springs can be tensioned between a flange of the mounting slide and a flange of the tensioning slide. Mounting slides and tensioning slides are slidably mounted on parallel guide rods. The mounting slide is actuated by an eccentric on the drive shaft, i. H. moved relative to the tension slide in its direction. As a result, the compression springs located between them are tensioned. When the winding carriage has reached its end position, i. H. the springs are maximally tensioned, the latching of the tensioning carriage is released and the carriage moves quickly. This rapid longitudinal movement is carried out via a roller pin, which is guided in a groove of the tensioning carriage, in a likewise rapid rotary movement of a switching crank, i. H. a switching shaft, which in turn actuates the diverter switch.

From DE-PS 28 06 282 a very similar further energy accumulator is known, which is also equipped with additional means for safe switching even in the cold.

Finally, from DE-PS 39 19 596 an energy accumulator is known, in which the eccentric on the drive shaft and the compression springs for energy storage lie essentially in the same horizontal plane in order to avoid an asymmetrical attack on forces.

However, all of these known energy stores have a number of disadvantages. First of all, they are relatively complicated and consist of numerous individual components. In particular, the longitudinal guidance of the longitudinally displaceable mounting slides and clamping slides by means of parallel guide rods places high and highest accuracy requirements, and this both the parallelism and the dimensional accuracy of the guide rod itself and the mounting of the two slides on these guide rods. Furthermore, in the known energy stores there is a double conversion of the direction of movement: a rotary movement of the drive shaft is converted into a longitudinal movement of the energy store, the longitudinal movement of which, in turn, is converted back into a rotary movement of the selector shaft for actuating the step switch. This is complicated and also unsuitable and superfluous for step switches or their diverter switches which can be moved in any case in a linear manner. It should also be noted that the known energy stores are designed for operation in the switching oil of the tap changer. To do this, you have to know that the known tap changers are usually oil-filled, the switching oil inside both acting as an insulating medium and having a lubricating function with regard to the moving mechanical components. In recent times, however, tap changers have become known which work with air or gas as the insulating medium and for which lubrication is therefore not possible in this way. The required high-precision longitudinal guides and bearings described in the prior art are unsuitable for such applications.

The object of the invention is to provide an energy accumulator of the type mentioned at the outset, which is of simple construction, consists of as few and simple components as possible and also works safely and reliably under air or gas.

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

A particularly advantageous feature of the energy accumulator according to the invention is primarily the significantly simplified mechanical structure of the entire assembly. The centerpiece of this energy accumulator are only three flat components, namely a base plate, the mounting slide and a switching slide, which corresponds to the clamping slide of the prior art, all of which can be designed particularly advantageously as simple sheet metal parts. The necessary stops against which the springs are supported are easily molded directly onto the corresponding components as bent-over sheet metal tongues or tabs. Another advantage of the energy accumulator according to the invention is that both pull-up and tensioning slides are only guided on one side on fixed guide rods and are each supported and guided against each other. Tolerance compensation is thus possible in a simple manner. In addition, the entire arrangement places no special requirements on lubrication. Finally, in a very uncomplicated manner, the longitudinal movement of the tensioning carriage is tapped directly as a movement for actuating the diverter switch or step switch in this energy accumulator by means of a switching coupling.

The invention will be explained in more detail below by means of drawings. Show it:

Fig. 1 shows an energy accumulator according to the invention in a perspective view

2 a base plate of this energy accumulator alone, namely a) from above and b) from below FIG. 3 a pull-up slide of this energy accumulator alone, again a) from above and b) from below FIG. 4 a switching slide of this energy accumulator alone, also a) from above and b) from below

Before the structure of the energy accumulator according to the invention is described in detail, it should also be pointed out that in FIG. 1, which shows the complete arrangement, not all details are provided with reference numerals in order not to impair the clarity and clarity of the illustration. However, all of the reference symbols mentioned below can be found in FIGS. 2 to 4, ie. H. the corresponding partial representations.

The energy accumulator according to the invention consists of three main assemblies, namely a base plate 1, a mounting slide 7 and a switching slide 14. The switching slide 14 corresponds to the component referred to in the prior art as a clamping slide.

The base plate 1 is made of thin material, for example sheet steel. On two opposite sides, angled plates 1.1 and 1.2 or 1.5 and 1.6 are formed in pairs. The associated tabs 1.1 and 1.2 each have a receiving bore 1.3, 1.4; Likewise, the associated tabs 1.5, 1.6 each have a receiving bore 1.7, 1.8. These receiving bores are used to receive a respective guide rod 5, 6, such that the two guide rods 5, 6 extend parallel to one another, but at different heights, lengthwise through the entire base plate 1. The longitudinal direction of the individual components in the sense of this description is shown in the figures by a double arrow. At the ends, the guide rods 5, 6 are each closed by detents 5.1, 5.2 or 6.1, 6.2. The function of these guide rods 5, 6 will be discussed in more detail later. On a pair of molded tabs 1.5, 1.6, a bearing shoulder 1.9 or 1.10 is formed, which in turn is angled. This bearing approach 1.9, 1.10 each has a bearing point 1.11, 1.12, in each of which a ratchet lever 3 or 4 is pivotally mounted. Each of the two ratchet levers 3, 4 has at its other free end a roller pin 3.1, 4.1, on each of which an actuating roller 3.2, 4.2 is arranged. The function of the actuating rollers 3.2, 4.2 will be explained in more detail later. Between the respective latch lever 3, 4 and the base plate 1, a spring 3.3, 4.3 is arranged, which is supported against a spring seat 1.13, 1.14 of the base plate 1 and is thereby guided. Each of the two ratchet levers 3 and 4 has one as the actuating track 3.4 or 4.4 formed special area to which trigger rollers 7.13 and 7.14, which will be explained in more detail later, can act and thus deflect the respective latch lever 3, 4 from its rest position. With only indicated screws 1.15, the entire base plate can be fastened to other components of the tap changer, to which the energy accumulator belongs constructively. A drive shaft stub 2 leads from the underside through the base plate 1 to the top thereof. There is a drive crank 2.1 with an eccentrically acting drive roller 2.2 located on the drive shaft stump 2. This assembly is firmly connected to the base plate by a screwed bearing 2.3.

A mounting slide 7 is arranged above the base plate 1 and is designed to be longitudinally displaceable and is to be explained in more detail below. On one of its side faces, viewed in the direction of movement, the mounting slide 7 has an integrally formed and upwardly angled tab 7.1 on which a guide roller 7.2 is fastened by means of a fastening screw 7.3. On the opposite side, a guide tab 7.4 is formed, which extends over the entire length and has a guide contour 7.5, which extends in the longitudinal direction, i. H. extends in the direction of movement. As already explained above, this direction is represented by a double arrow. Fastening tabs 7.6, 7.7 are also arranged opposite one another on the end faces of the mounting slide 7, and one tab is also formed on the opposite side as a stop 7.8, 7.9. Furthermore, a further stop 7.10, 7.17 is integrally formed on each fastening tab 7.6, 7.7. In other words: there are two stops on each end: 7.8 and 7.10 on one side and 7.9 and 7.17 on the other side. Spring supports 1 1, 12 are inserted into the mounting slides on both end faces, each of which is supported outwardly against the stops 7.8 and 7.10 just described on one side and 7.9 and 7.17 on the other side. The stop 7.17 is only indicated in the drawing in FIG. 3; it is designed in the same way as the stop 7.10 and molded onto the fastening tab 7.7. There are compression springs 13 between the spring supports 11, 12. One of them is guided through a spring guide rod 10, the spring guide rod 10 is fastened at both ends to the fastening tabs 7.6 and 7.7. On the underside of the mounting slide 7 there are further, downwardly directed tabs 7.11, 7.12, on each of which a release roller 7.13, 7.14 is arranged by means of fastening screws 7.15, 7.16, the function of which is explained in more detail below. On one side, the entire mounting slide 7 is guided by two longitudinal guides 8, 9, which are each screwed by means of fastening screws 8.1, 9.1, on the one guide rod 5 so as to be longitudinally displaceable. On the side facing away from this guide rod 5 is the already explained guide plate 7.4 with the guide contour 7.5. On the underside, the mounting slide 7 has a transverse guide 7.18, in which the drive roller 2.2 of the drive crank 2.1 is guided in the assembled state.

Another component arranged above it now engages in the guide contour 7.5: the switching slide 14. This switching slide 14 in turn has a tab 14.1 on one of its sides which is angled downwards and carries a guide roller 14.2 which is screwed on by means of a fastening screw 14.3. This guide roller 14.2 runs in the already explained guide contour 7.5 of the mounting slide. This tab 14.1 also has lateral locking lugs 14.4, 14.5. Fastening tabs 14.6 and 14.7 are again provided on both end faces, between which a further spring guide rod 17 is fastened. On the side of the switching carriage 14 on which the tab 14.1 is located, further longitudinal guides 15 and 16 are fastened by means of fastening screws 15.1 and 16.1, respectively, by means of which the switching carriage 14 is also guided in a longitudinally displaceable manner on the second guide rod 6. All longitudinal guides 15, 16 are designed as linear bearings known per se. On the other hand, analogously to the mounting slide 7, it again has a guide tab 14.8 which extends over the entire width and has a guide contour 14.9. The guide roller 7.2 of the mounting slide 7, which has already been described above, runs in this guide contour 14.9. Stops 14.10, 14.12 and 14.11, 14.13 on the other side are also provided here on the two end faces. Finally, there are pairs of angles 14.14 ... 14.17 on the upper side, between which a U-beam 18 is arranged. The connection between the switching slide 14 and the U-beam 18 via the angles 14.14 ... 14.17 just described is made by means of damping means 20 ... 23. A coupling member 19 is articulated to a bearing point 18.1 on the U-beam 18 and transmits the abrupt movement of the triggered switching carriage to the respective switching means of the diverter switch or the tap changer, which are not shown here.

It follows from the explanations that mounting slide 7 and switching slide 14, with their open sides facing each other, are built into one another. Both the mounting slide 7 and the switching slide 14 are longitudinally guided on their outer side on a guide rod 5 or 6, respectively. Otherwise, the two carriages are supported against each other. This is done in that each of the two carriages has a guide contour 7.5 or 14.9 in which a guide roller 14.2 or 7.2 of the other carriage runs. Specifically, the mounting slide 7 has a guide roller 7.2 which runs in the guide contour 14.9 of the switching slide 14, and the switching slide 14 has a guide roller 14.2 which runs in the guide contour 7.5 of the mounting slide 7. This mechanism fixes mounting slide 7 and switching slide 14 in their relative position to one another and, moreover, can be moved individually and independently of one another.

The operation of this energy accumulator is as follows: At the beginning of each actuation of the step switch, the drive shaft coming from the motor drive, which is connected to the drive shaft stump 2, rotates through an angle of 180 degrees. As a result, the drive roller 2.2 also rotates by this angle. The drive roller 2.2 runs in the transverse guide 7.18 of the mounting slide 7 and thus shifts it by a certain amount in the longitudinal direction. As a result, the compression springs 13 are tensioned. The tensioning takes place in that the stops on the rear side of the mounting slide 7, as seen in the direction of movement, i.e. the stops 7.8 and 7.10 on one side or the stops 7.9 and 7.17 on the other side, take the corresponding rear spring support 11 or 12 with them, while at the same time the stops remaining in their rest position 14.10 and 14.12 or 14.11 and 14.13 of the switching slide 14 fix the respective front spring bracket 11 or 12. The mounting slide 7 is thus moved in the longitudinal direction, while the switching slide 14 remains in its previous position. The switching carriage 14 remains in its previous position because it is locked by the actuating rollers 3.2 and 4.2 of the latch levers 3 and 4 described, which are supported against the corresponding locking projection 14.4, 14.5. If the slide 7 reaches the end position after its longitudinal movement, one of the two release rollers 7.13 or 7.14 - depending on the direction of movement - runs against the corresponding actuating track 3.4 or 4.4 of the corresponding latch lever 3 or 4 and presses it against the force of the respective spring 3.3 or 4.3 downward. As a result, the respective actuating roller 3.2 or 4.2 disengages from the respective locking attachment 14.4 or 14.5. The locking of the switching slide 14 is thus released, and the switching slide 14 abruptly follows the movement of the mounting slide 7, the compression springs 13 relax and the actuating rollers 3.2 or 4.2 come back into engagement with the respective locking attachment 14.4 in the new end position of the switching slide 14 or 14.5 - the locking is restored. The next time the tap changer is operated, the same process takes place in the opposite direction. The pull-up carriage 7 is therefore always moved alternately to the left or right and the switching carriage 14 follows, after its locking, which initially holds it in place, is then followed by this movement. This abrupt longitudinal movement of the switching carriage 14 is then transmitted through the coupling member 19 directly to the switching means to be actuated linearly.

Overall, there are a number of advantages in the energy accumulator according to the invention compared to the prior art. On the one hand, as already explained above, there are practically only three essential components that can be easily produced from sheet metal: the base plate 1, the mounting slide 7 and the switching slide 14. All the necessary means for receiving guide rollers for receiving the Guide contours and for the stops against which the spring supports 11, 12 are supported on both sides are easily realized by bent, ie angled, sheet metal tabs. Another advantage is that despite relatively low accuracy requirements for the components described, there is an ideal tolerance compensation. As described, both mounting carriages 7 and switching carriages 14 are longitudinally guided only on one of the two guide rods 5, 6, for the rest they are supported against one another and practically guide themselves. Finally, due to the nested arrangement of mounting carriages 7 and switching carriages 14 a compact design possible. It should also be noted that the energy accumulator according to the invention is particularly well suited for use in air or other gaseous insulating media, since the guides described each have one Guide roller 7.2 or 14.2 in a guide contour 14.9 or 7.5 do not have any special requirements, for example, on lubrication.

Claims

claims

1. Energy store for a tap changer, wherein a pull-up slide that can be actuated by a drive shaft along a path and a latchable switch slide are provided, between which at least one compression spring is arranged, two parallel guide rods being provided, on which pull-up slides and

Switching carriages are guided so that they can move independently of one another, the longitudinal movement of the mounting carriage relative to the switching carriage making it possible to tension the at least one compression spring, in such a way that after triggering of the switching carriage which has been latched up to that point, this jumps abruptly to the movement of the mounting carriage, characterized in that the mounting carriage (7) only in a guide rod (5) and the switching slide (14) is guided only in the other guide rod (6) that the mounting slide (7) has a first guide roller (7.2) on one side and a first one extending in the direction of movement on the opposite side

Guide contour (7.5) has that the switching carriage (14) also on one side a second guide roller (14.2) and on the opposite side a second extending in the direction of movement

Has guide contour (14.9) and that the first guide roller (7.2) with the second guide contour (14.9) and the second guide roller (14.2) correspond with the first guide contour (7.5) and are guided in a form-fitting manner.

2. Lift mechanism according to claim 1, characterized in that the two guide rods (5, 6) are attached to a separate base plate (1).

3. Energy accumulator according to claim 2, characterized in that the base plate (1) has angled pairs of tabs (1.1, 1.2; 1.5, 1.6), each receiving one of the guide rods (5, 6).

4. Energy accumulator according to claim 2 or 3, characterized in that on the base plate (1) two latch levers (3, 4) are provided, each around a bearing (1.11, 1.12) against the force of a spring (3.3, 3.4) can be deflected from the rest position, that the switching slide (14) can be latched by the pawl levers (3, 4) and that one of the ratchet levers (3, 4) can be deflected by a trigger roller (7.13, 7.14) arranged on the mounting slide (7), in such a way that the latching of the switching carriage (14) can be lifted when the actuated mounting carriage (7) has reached its new end position.

5. Lift mechanism according to claim 4, characterized in that the respective release roller (7.13, 7.14) runs in each case in an actuating path (3.4, 4.4) of the corresponding ratchet lever (3, 4).

6. Energy accumulator according to claim 4 or 5, characterized in that the latching of the switching carriage (14) takes place in such a way that a side tab (14.1) is formed thereon, which has two locking lugs (14.4, 14.5) into which, depending on Position, an actuating roller (3.2, 4.2) engages one of the two latch levers (3, 4).

7. Energy storage device according to one of the preceding claims, characterized in that stops (7.8, 7.10; 7.9, 7.17) are arranged in pairs on each end face on the mounting slide (7) and corresponding stops (14.10, 14.12; 14.1) on the switching slide (14) are also arranged in pairs 1, 14.13) are arranged, between which spring supports (11, 12) are fixed, against which the at least one compression spring (13) is supported.

8. Energy accumulator according to claim 7, characterized in that mounting slide (7) and switching slide (14) are each designed as one-piece sheet metal parts and both the stops (7.8, 7.10; 7.9, 7.17) of the mounting slide (7) and the stops (14.10 , 14.12; 14.11, 14.13) of the switching carriage (14) are designed as angled tabs.

9. Energy storage device according to one of the preceding claims, characterized in that a coupling member (19) is articulated on the switching slide (14), such that the abrupt longitudinal movement of the switching slide (14) can be transmitted directly to the tap changer to be actuated.

10. energy store according to claim 9, characterized in that the coupling member (19) is connected to the switching slide (14) via at least one damping means (20, 21, 22, 23) acting in the direction of movement.