CZ20014330A3 - Snap-action mechanism for electrical switchgear - Google Patents

Abstract

The invention relates to a snap-action mechanism for electrical switchgear with a drive shaft and an actuation disk which is non-rotatably linked with said drive shaft and actuates a moving spring. The snap-action mechanism further comprises a transfer element (8) that is rotatably received by the drive shaft and that is hinged at the moving spring and acts upon the switch shaft via a connecting rod (9). According to the invention, the snap-action mechanism is designed in such a manner that the switch-off force required for overcoming the adhesive forces for switching off the switchgear is reliably produced and transmitted. To this end, a pressure spring (18) is arranged between the transmission element (8) and the connecting rod (9) and is mounted on one of these elements of the snap-action mechanism. Said pressure spring interacts with the respective other element of the snap-action mechanism once the dead center position (T) has been overcome.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The invention relates to a stepping mechanism for electric switches with a drive shaft and a fixed control disk for a drive spring arranged substantially transversely to the drive shaft, with a transfer member mounted rotatably on the drive shaft and in operative connection with the switching shaft of the switch, the energy of the drive spring being abruptly released when the drive shaft is actuated via the dead-end position and acting on the switch shaft via the transfer member and the connecting rod.

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Electrical switches, in particular power quick switches, require a generally indirectly acting actuator to ensure that the switching takes place independently of the operator, at the same and sufficient speed. These indirect drives include step drives, by means of which a step switch is performed via a charged energy storage device.

A stepping mechanism for stepping on an electric switch with a spring-loaded energy storage device (drive spring), which in connection with the drive shaft is tensioned and acts upon the switch shaft after the dead center position has been exceeded, is known from DE 23 50 761 C3. The stepping drive has, in a non-rotatable manner with the drive shaft, an actuating and tensioning disk for the drive spring arranged in a plane given transversely to the drive shaft and a transfer member mounted rotatably on the drive shaft and on the drive shaft side articulated to the drive spring . This transfer member is again connected to the switch shaft via a connecting rod. When actuating the drive shaft by servicing the power and voltage of the shaft to exceed its person and associated therewith as well as changing the position of the dead-end driving position, its spring force is released stepwise, i.e. at high speed, acting through the transfer member and coupling switch shaft switch shaft. The actuating and tensioning disk cooperates with an articulation pin connecting the drive spring to the transfer member and has a circular sector cut-out to create a movement path limited in its length and a driving flank for it and thus also for the transfer member and the drive spring.

When the machine switch is switched off and also when switched on via the drive shaft control, the control disk also rotates as the articulation pin is carried and continues to reach the dead point of the forced movement while receiving energy to the drive spring. After the dead point has been exceeded, the drive spring is released in step with the release of spring energy and independent of operator action, so that depending on the design of the switch, the same switching energy as well as switching speed and opening and closing of the switch contacts operator influences.

The disadvantage of this drive is that failure to operate the drive shaft in the cut-off direction can cause the drive spring to reach a stable position through and beyond the dead point, but without separating the contacts, since switching power from the drive spring is not available , necessary for the separation of contacts, especially at high short-circuit power with correspondingly high contact forces or for switches which have not been adequately maintained for a long time. Although the achieved position is stable, the stepping drive is not in its defined end position for the trip being performed. In the inattention of the operator, ie. keeping this position, the switch · · · · remains closed.

SUMMARY OF THE INVENTION The object of the invention is to provide a stepping mechanism for electrical switches according to the generic part of claim 1, so that when the switch is switched off, the required breaking force is exceeded and transmitted reliably to overcome the contact force.

SUMMARY OF THE INVENTION

This object is achieved by a stepping drive for electric switches with a drive shaft and a fixed control disk for the drive spring arranged substantially transversely to the drive shaft, with a transfer member mounted rotatably on the drive shaft and articulated to the drive spring. it is operatively connected to the switch shafts, the energy of the drive spring being suddenly released when the drive shaft is actuated via the dead-end position and acting on the switch shaft by means of the transfer member and the connecting rod. there is provided a compression spring which is arranged on one of the two jump drive members and which, after exceeding the dead-end position, enters into operative connection with just another jump drive member.

Preferred embodiments are found in the subclaims.

The invention is characterized in that in a step drive between a transmission member and a connecting rod having a drive shaft substantially with a drive disk for the drive spring fixed thereon, and a transmission member mounted on the drive shaft rotatably and articulated to the drive spring, A pressure spring is provided on one of the two step drive members, which acts on the switch shaft via a connecting rod and, when the tripping movement exceeds the dead-end position of the drive spring, enters an operative connection with just another step drive member.

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This compression spring is placed in the event of a tripping failure of the stepping drive, that is, when the drive spring moves in the tripping direction outward through the dead point to a rest position without separating the switching contacts on just another stepping member, compresses when receiving energy and rotates the transfer member and the drive spring when the energy is dispensed back, so that the rest position is not stable and thus it is apparent that the separation of the contacts and the disconnection has not taken place. If the drive shaft is then moved by hand again in the cut-off direction or even further, the spring is fully compressed and in the course of the transmission it transmits the forces exerted by the hand until the increased contact forces are overcome and contact separation has taken place. When the contact forces are overcome, the compression spring is released, causing an increase in the separation speed of the contacts. The arrangement of the compression spring ensures that the drive shaft is clearly rotated, and the position of the control device and the operator shows whether or not the switch contacts have been separated. The simple design of the stepper drive remains preserved.

Preferably, the compression spring is disposed on the transfer member and, for engagement with the tie rod, is held on the spring guide rod directed towards it. In this case, the connecting rod can be articulated on the drive shaft side via an articulation pin on the drive lever mounted rotatably on the drive shaft. This drive lever then serves as a support for the compression spring.

The actuating disk has a preferred and known method of recess in the form of a circular ring to create a travel path and away from the driving flank for the hinge pin connecting the drive spring to the transmission member.

Also, the transmission member has such a recess for a hinged member hingedly connecting the tie rods to the drive lever. This can • • · ·

movement of the transmitting to the connecting rod.

simply implement the drive member due to the released energy of the spring,

BRIEF DESCRIPTION OF THE DRAWINGS

The invention is further explained by way of example. The figures show schematically in part: FIG. 1: the stepper in the closed position and FIG. 2: the stepper in the tripping position.

DETAILED DESCRIPTION OF THE INVENTION

The stepping drive for the switch shown in FIG. 1 has a drive shaft 6 and a control disk 2 connected thereto with a recess 3, in the form of a ring with two drive flanges 4 for a hinge pin X arranged on a drive spring 7 arranged perpendicular to the drive shaft X. on a spring guide rod 6 and on a transmission member 8 mounted in a rotatably movable manner on a drive shaft X which, via a connecting rod 9, is in operative connection with a switch shaft (not shown). On its side facing the drive shaft X, the drive spring 7 is supported on a support 10 which has a recess 11 for the spring guide rod 6. The transfer member 6, constructed as a double lever, is also provided with a recess 12 in the form of a circular ring to create a travel path and from the flank 13 to the hinge pin XX through which the connecting rod 9 is articulated. A spring holder 16 for the spring guide 17 on which the compression spring 18 is arranged is mounted on the transmission member 6. The holder 16 is designed in such a way that the spring guide 17 is arranged tangentially to the recess 12 and allowed to engage with the spring. drive lever 15

When the control disc 2 and thus the drive shaft X is rotated counterclockwise to the cut-off direction, it is carried away.

In this case, the drive springs 7 are tensioned when the position is changed, whereby the spring guide rod 6 is moved by the recess 11 and the transfer member is rotated together. When the dead-end position J is exceeded, the drive spring jumps, the transmission member 8 being carried by the side 11, hitting the hinge pin 14 and, via this and through the hinged connecting rod 13, causes the switch contacts to become disconnected and thereby trip.

However, if, in this switching process, the rupture or separation force required to separate the switching contacts is greater than the force that can be propagated by the release spring upon release of the switching energy, the pressure spring transfer member 8 reaches the drive lever 15 and compresses; as a result, the transfer member 8 pushes the drive spring Z back. In this case, the operator touches the drive shaft X once more so that the compression spring 18 is fully compressed and is fully pushed on the drive lever 15, and the operator's support triggers the shutdown process, releasing the drive spring when the required trigger force is exceeded. Z and compression spring 18a serve for a high switching speed. FIG. 2 shows the position of the step drive in which the compression spring 18 as a whole lies on the drive lever 15.

Claims (5)

Stepper drive for electric switches with a drive shaft (1) and a fixed control disk for a drive spring (7) connected substantially transversely to the drive shaft (1), with a transmission member (8) mounted rotatably on the drive shaft (1). 1) and articulated to a drive spring (7) which is operatively connected to the switch shaft via a connecting rod (9), the drive spring energy (7) being actuated via the dead point position (T) when actuating the drive shaft (1) it externally releases itself and acts on the switch shaft (1) by means of a transfer member (8) and a connecting rod (9), characterized in that a compression spring (18) is arranged between the transfer member (8) and the connecting rod (9), which is arranged on one of the two step drive members and which, after exceeding the dead-end position (T), enters into active communication with just another step drive member. Jump drive according to claim 1, characterized in that the compression spring (18) is held on a spring guide rod (17) arranged on the transfer member (8). Stepping drive according to claim 1 or 2, characterized in that a drive lever (15) is pivotably mounted on the drive shaft (1), articulated by means of a hinge pin (5) to the connecting rod (9) with which the drive lever is a compression spring (18) engages. The stepping drive according to claim 1, characterized in that the control disk (2) has a recess (3) in the form of a circular ring to form a movement path and from the driving flank (4) for the hinge pin (5) connecting the drive a spring (7) and a transfer member (8). Jump drive according to claim 1 or 3 · φ φ · · · · · φ φ φ φ φ · · φ φ φ φ φ φ φ φ Characterized in that the transfer member (8) has a recess (12) in the form of an annular ring to form a travel path and away from the driving flank (13) for the hinge pin (14) which is in operative connection a rod (9) with a transfer member (8).