DE2250260A1 - STORAGE DRIVE FOR LOAD CHANGEOVER AND FOR LOAD SELECTOR - Google Patents

Description

Energy storage drive for diverter switches and load selectors

The invention relates to an energy storage drive for diverter switches and load selectors in step transformers the moving contact pieces by means of a swiveling shaft be moved by leaps and bounds from one stationary to another stationary contact piece, the jumping movement takes place by means of a latchable energy storage device, which is operated by means of a Geneva wheel that specifies the switching direction or can be tensioned by means of a Geneva crank.

In such energy storage drives there is usually an energy storage device ¹ which can be opened directly by the motor or manual drive and which, when unlatched, acts on a Geneva washer or a crank, which then moves the contact pieces step by step. This structure is complex and is not optimally adapted to the sequence of movements over time. The one-sided attack of the energy store requires a lot of space, results in greater friction losses in the kinematics and leads to a drive that is difficult to understand and makes it difficult to replace individual parts.

The invention is based on the object of simplifying the energy storage drive, which is talking about it, in its entirety To design the structure in a clear and space-saving manner, with optimal adaptation to the requirements Switching sequence. According to the invention, this object is achieved in that the aforementioned in the energy storage drive Kind of two coaxially mounted double-armed clamping levers are provided, between the ends of which two are on the one hand opposing springs are clamped and on the other hand, a winding and a jump crank with ^ e two crank ends engage, the winding crank with the Geneva washer

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and the jump crank with which the switching pieces actuate Shaft are coupled.

It is particularly useful here if the jump crank is provided with a radially displaceable locking slide, which can be latched into a locking ring around the jump crank for each switching position and by means of the winding crank can be released.

The gate parts achieved with the invention exist in particular In the following: The springs arranged on both sides of the axis result in a very compact and yet clearly arranged Construction that allows easy assembly and easy replacement of the energy storage springs without dismantling the drive enables. The two-sided engagement of the crank ends means that friction losses in the bearing are practically avoided. Through this, that the Geneva washer is located in front of the energy storage device, seen from the power drive, this can be done during the actual switching operation, that is, when the pivotable contact pieces are actuated, they act on the shortest possible path, and the Geneva washer can also be held in the rest positions by means of the energy storage springs without special locking.

An embodiment of the invention - for one Load selector - is shown in the drawing and is described in more detail below. Bs show: 1 shows a cross section of the new energy storage drive, FIG. 2 shows another rotated by 90 ° with respect to FIG

Cross section and
3 - 5 in a schematic representation three different positions of the force storage drive during a switching operation.

As can be seen from Fig.1 and 2, the new energy storage drive constructed as follows: A load-bearing housing plate 1 and an associated housing cover 2 are used to accommodate and the axial mounting of the moving parts of the drive, and a flange 3 on the housing cover 2 serves as a bearing for the drive shaft 4. The drive shaft 4 is connected to the Geneva crank 5

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connected, which cooperates with the Geneva 6 disk. the Geneva washer 6 is with its shaft 7 in the housing cover 2 stored and over the shaft 7 with a winding crank 8 rigidly connected. Below the winding crank 8 is the jump crank 9 mounted in the housing plate 1, which is rigidly connected to the drive shaft 10. There are two between the winding crank 8 and the jump crank 9 double-armed clamping levers 11 and 12, which are arranged crosswise and are also mounted on the shaft 7. In each case between two ends of these clamping levers 111 and 121 or 112 and 122 (see Fig. 3-5) two opposing compression springs 13i 14 are clamped. Furthermore, both the crank handle 8 as well as the jump crank 9 with two crank ends each 81, 82 or 91 »92 between the clamping levers 11 and 12. Next a locking ring 15 is provided between the housing plate 1 and the housing cover 2, with a plurality of Recesses 151 »where the number of recesses corresponds to the number of switch positions is provided. The ratchet is arranged around the jump crank 9, and the latter is provided with a locking slide 16 which is radially displaceable is and in each switching position in one of the recesses 151 clicks into place. For this purpose, the locking slide is acted upon by a compression spring 17 which is supported on the jump crank 9. The locking slide can be pushed back via a driver surface 18 and two release levers 19 and 20.

The mode of operation of the new energy storage drive is as follows:

Starting from the rest position shown in FIG Execution of a switching operation, the drive shaft 4 by means of a power drive, not shown, in the direction of the arrow rotated by 360 °. Here, the Maltese roller 21 comes in a recess of the. Geneva disk 6 and moves it one step further. This movement is carried over on the winding crank 8 rigidly connected to the Geneva washer, which thereby with its two crank ends 81,82 the clamping lever 11 takes with it. On the other hand, since the tension lever 12

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over the jump crank 9; which by means of the locking collar 15 seated locking slide 16 is held, remains in its position, tension here the compression springs 13 and 14. In During the last phase of the sequence of movements of the Geneva disk or the winding crank 8, the winding crank 8 then runs with it its crank end 81 against the release lever 19 · This pushes the locking slide 16 back via the driver surface 18, see above that the jump crank loses its hold. By means of the two crank ends 91, 92, which are attached to the spring-loaded clamping lever 12 are present, the jump crank is now also moved further. This movement, which occurs suddenly, is transferred to the output shaft 10 and serves to drive the pivotable contact pieces, which is not shown in detail. the Rotational movement of the jump crank causes the release lever 19 to again move away from the crank end 81 of the winding crank removed. As a result, the compression spring 17 can lead the locking slide radially outwards again, so that it, as shown in FIG can be seen, engages in the next recess 151 of the locking ring. The Maltese crank 5 is still running in its starting position back; and the switching operation is complete. Of course, it is easily possible for the Geneva crank 5 also provide a smaller angle of rotation than 360 ° per circuit. If, for example, the Geneva crank Executed with two arms, the mentioned angle of rotation is halved.

In the event that the new energy storage drive for diverter switches, that is to be used for only two switching positions, the Geneva washer shown in the exemplary embodiment 6 can be converted into a Maltese crank with two Maltese incisions. Here are the two Maltese incisions then assigned to the two switching positions; and the Geneva crank 5 would alternately by means of a back and forth pivoting movement run into these two incisions. Likewise, the locking ring 15 would be simplified by this only to be provided with two recesses 151 corresponding to the two switching positions.

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Claims (3)

Claims M J Energy storage drive for diverter switch and load selector in Step transformers, in which moving contact pieces by means of a swiveling shaft of a stationary one be moved abruptly to another fixed contact, the jump movement by means of a latchable KraftSpeichers takes place, which by means of a die Switching direction prescribing Geneva wheel or can be tensioned by means of a Geneva crank, marked by two coaxially mounted double-armed clamping levers (11, 12) between their ends (111, 12t or 112, 122) on the one hand two opposing springs (13 »14) are clamped and on the other hand a winding and a Jump crank (8, 9) with two crank ends each (81, 82, 91,92) intervene, the winding crank (8) with the Geneva washer (6) and the jump crank (9) with the switching pieces actuating shaft (10) are coupled. 2. Energy storage drive according to claim 1, characterized in that that the jump crank (9) with a radially displaceable Lock slide (16) is provided for each switching position can be latched into a locking ring (15) lying around the jump crank and can be disengaged by means of the winding crank (8) is. 3. Energy storage drive according to claim 1 or 2, characterized by means of a rigid connection between the Geneva washer (6) 'and the winding crank (S). 409817/0539