DE1297733B - Drive device for electrical switches - Google Patents

Description

The invention relates to a drive device for electrical switches with a carrier for the movable ones Contacts, the one with two parallel running, mounted on the frame and around a common axis pivotable lever is coupled, which is arranged with a perpendicular to this axis to this Axis pivotable levers are coupled and can be actuated abruptly by a spring force storage device, when the switch is switched on or off by opposing rotary movements of a drive shaft can be tensioned and triggered at the end of these rotary movements.

Such a drive device for electrical switches is from the French patent 1 206 991 and from the magazine "Schakelingen", March 1961, page 24 ff.

In the known switching device that is required for the snap movement of the switching element Force supplied by a spiral leaf spring that is subjected to bending. For larger devices of this type, relatively strong and / or large springs are necessary to enable rapid actuation to supply the switching device required power, so that it is relatively expensive and large Constructions result. In addition, you always have to use it when using such helical springs expect that the spring material will sooner or later due to material fatigue at the clamping points breaks.

The French patent 1 013 272 already discloses a leaf spring for which torsion is stressed an electrical switch known.

Furthermore, from British patents 639 126 and 696 142 are arranged symmetrically in the center Known torsion springs for electrical switches.

A parallel arrangement of two used to snap a switch and against each other Movable plates are also shown in German patent specification 649 329.

German Patent 379 605 also discloses a pin-and-slot coupling between a drive shaft and a disc known, which is used to tension an energy store and to lock contacts an electrical switch is used.

The invention is based on the object of a drive device for an electrical switch with the features described above so that a simple structure, a simple series production and a small space requirement with high operational reliability results.

The invention is characterized in that the pivotable lever by a between them, in their common pivot axis arranged on torsion stressed leaf spring are connected and is attached to the leaf spring in the middle between the levers tensioning lever with its free

End into a recess of a transverse to this end and perpendicular to the longitudinal axis of the Leaf spring engages sliding clamping plate, which via a pin-and-slot coupling with the drive shaft is connected, and that a locking plate arranged parallel to this clamping plate at the end of the Rotary movement of the drive shaft is displaceable in each case against the action of a spring, which this Locking plate in the on position of the switch in front of the free end and in the off position of the Switch presses into a recess of a locking arm attached to the carrier.

The invention is explained below with reference to the drawings.

Fig. 1 is a perspective view of a drive device according to the invention;

F i g. Figure 2 is a plan view of a practical embodiment of the tensioning and locking mechanism according to FIG. 1 and

F i g. 3 is a cross-sectional view in the plane III-III the F i g. 2.

F i g. 1 shows the principle of a drive device according to the invention and is used exclusively for Explanation of the operation of the device, so that only the parts necessary for this purpose are shown schematically are shown.

The switching element of the device consists of a movable carrier 1 with a number of contact blades 2, which can be inserted into mating contacts 3. The carrier 1 is provided with two rigidly attached elements 4 movably guided in guide elements 5 which form part of the frame of the device. the Elements 4 are each articulated to the free end of a lever 6, which is rotatable in the frame the facility is stored. The ends of the levers 6 (of which the drawing shows only one) at the Bearings 7 are connected by a leaf spring 8, the can consist of one or more leaf springs.

The tensioning mechanism consists of a tensioning lever between the levers 6 on the spring assembly 8 is attached and a clamping plate 10, which is articulated with the free end of the clamping lever 9 is coupled and movably mounted within the framework of the device, which is shown schematically by the guide elements 11 is shown.

The locking mechanism consists of a locking plate 12, which, as also by the guide elements 11 is indicated, is mounted in the device so that it is with respect to the clamping plate 10 can slide parallel and with respect to a locking arm 13. The locking arm 13 is attached to the carrier 1 and provided with a recess 14 into which the edge of the locking plate 12 can snap. The lock plate 12 is also with the middle of a curved leaf spring

15 coupled with their free ends in bearings

16 rests within the framework of the device and presses the locking plate 12 in the direction of the locking arm 13.

The drive shaft 17 of the switching device carries a disk 18 with a projection at the lower end 19 and a cam-like part 20. The projection 19 slides in a slot 21 in the clamping plate 10, while the cam-like part 20 cooperates with two pins 22 on the edges of the Locking plate 12 are attached and extend over the clamping plate 10.

Fig. 1 shows the switching device in the switched on Position. In this position, the carrier 1 is blocked because the locking plate 12 is blocked by the spring 15 was moved over the free end of the locking arm 13. The clamping lever 9 takes the drawn drawn Position one and the springs of the torsion spring 8 are completely relaxed. The drive shaft

17 is rotated clockwise, the cam 20 rests on the left pin 22 of the locking plate 12.

To switch off the device, the drive shaft 17 must be rotated counterclockwise will. The clamping plate 10 is then dashed through the projection 19 on the disk 18 in the Drawn position moves. During the movement of the clamping plate 10, the locking plate 12 remains in its position

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opposite the end of the locking arm 13, so that the carrier 1 cannot move vertically and the leaf spring 8 is subjected to torsion. When the clamping plate 10 has almost reached the position shown in dashed lines, the cam 20 touches the right pin 22 on the locking plate 12 and this is moved against the action of the spring 15. At the moment in which the locking plate 12 comes out of reach of the locking arm 13, the device switches off under the effect of the torsional force which is present in the leaf spring 8 at that moment. This force is transmitted to the contact carrier 1 through the lever 6 and the elements 4. The leaf spring 8 is completely relaxed and when the drive shaft 17 is released, the locking plate 12 returns to its starting position under the effect of the force exerted by the leaf spring 15. However, the edge of the plate 12 now engages in the recess 14 of the locking arm 13, so that the carrier 1 is locked before it is switched on again. _a o

When the device is to be switched on, the drive shaft 17 is rotated clockwise. The clamping plate 10 moves from the position shown in dashed lines into the position shown in solid lines. The carrier 1 is prevented by the first _a5 engaging in the recess 14 of the lock arm 13 lock plate 12 to a vertical movement so that the spring arrangement is tensioned in the opposite direction. 8 When the cam 20 strikes the left pin 22 of the locking plate 12, this is pushed out of the recess 14 and the carrier 1 is released, so that the device switches on. The torsion spring 8 is then completely relaxed. When the drive shaft 17 is released, the locking plate 12 moves under the action of the spring 15 over the end of the locking arm 13 and thus again reaches the position shown.

F i g. 2 shows a top view of the tensioning and locking mechanism as it really looks in practice. Fig. 3 is a cross section along the plane III-III F i g. 2.

As can be seen from these two figures, the tensioning and locking mechanism is on a profile plate 25 mounted. The drive shaft 17 extends with 4s a part that extends under the disc 18, through the clamping plate 10, the locking plate 12 and the profile plate 25 and is in the indented part 28 the plate 25 stored. The clamping plate 10 is for this purpose with an elongated hole 26 and the locking plate 12 with a slot 27 provided, the F i g. 2 shows. An axial displacement of the drive shaft 17 is through the slot 26 of the plate 10 prevents.

The pins 22 on the locking plate 12 are guided in slots along the edges of the clamping plate are provided. The same slots 29 lead together with other slots 13 in the clamping plate and slots 31, 32 in the locking plate the two plates. The in F i g. 1 schematically shown guide members 11 consist in reality of screws 33 which are fastened in the plate 25 and through the slots 29, 30, 31, 32 in the plates. Between the heads of the screw 33 and the Clamping plate 10 and washers 34 are provided between the latter and the locking plate 12. Between the locking plate 12 and the plate 25 spacer elements 35 are provided which the Surrounding screw 33, as shown in FIG. 3 shows.

Claims (2)

Patent claims: 1. Drive device for electrical switches with a carrier for the moving contacts, the one with two parallel running, mounted on the frame and around a common axis pivotable lever is coupled, which is arranged with a perpendicular to this axis, Lever pivotable about this axis are coupled and by a spring force storage device Can be actuated suddenly, when the switch is turned on or off by opposite Rotary movements of a drive shaft can be tensioned and in each case at the end of these rotary movements is triggered, characterized in that the pivotable lever (6) by one between them, in their common Pivot axis arranged, torsionally stressed leaf spring (8) are connected and a tensioning lever (9) is attached to the leaf spring in the middle between the levers and is connected to the its free end in a recess arranged transversely to this end and perpendicular to The longitudinal axis of the leaf spring engages the displaceable clamping plate (10) via a pin-slot coupling (19, 20, 21) is connected to the drive shaft (17), and that one to this clamping plate locking plate (12) arranged in parallel at the end of the rotary movement of the drive shaft in each case can be displaced against the action of a spring (15), which this locking plate in the switched-on position of the switch in front of the free end and in the off position of the switch in a Presses recess (14) of a locking arm (13) attached to the carrier (1). 2. Apparatus according to claim 1, characterized in that the lever (6) by several stacked leaf springs (8) are connected and the clamping lever (9) perpendicular to the flat Side of the leaf springs is arranged. 1 sheet of drawings