WO1996019004A1

WO1996019004A1 - Spring-loaded drive for an electrical power switch

Info

Publication number: WO1996019004A1
Application number: PCT/DE1995/001803
Authority: WO
Inventors: Gunnar Lutzke; Joaquin-Conrado Bohrdt; Klaus Schuler; Christian Klocke
Original assignee: Siemens Aktiengesellschaft
Priority date: 1994-12-16
Filing date: 1995-12-08
Publication date: 1996-06-20
Also published as: DE4446664C1

Abstract

The proposed spring loaded drive for an electrical power switch is provided with: at least one spring which acts on a drive shaft (1) to effect switching; a rotating damping lever in the form of a cam plate (2) fixed to the drive shaft (1); and an actuating element (5) of a damping member (3). The damping member (3) is located in the path of the damping lever (2) which can move past the damping member (3) after being braked by it. It is proposed that the actuating element (5) of the damping member (3) in the form of a roller should form a rigid stop for the recoil movement of the damping lever (2) once the latter has moved past it. This arrangement prevents the spring and the moved drive components from recoiling after the switching action.

Description

description

Spring-loaded actuator for an electrical circuit breaker

The invention relates to a spring-loaded drive for an electrical circuit breaker with at least one spring which drives a drive shaft in the switching case and with a circumferential damping lever attached to the drive shaft, in particular in the form of a cam disc, and with one arranged in the movement path of the damping lever Actuating element of a damping element, on which the damping lever can be moved past after being braked by the damping element.

Such a spring-loaded drive is known for example from DE-OS 22 15 535.

In the known spring-loaded drive, a damping lever firmly connected to a drive shaft strikes an actuating element arranged in its path of movement in the form of a roller and thus actuates a toggle lever mechanism with the interposition of a damping member. After actuation, the damping lever can move past the actuating element.

With such a construction, especially if the spring accumulator consists of a helical spring, the problem may arise that the helical spring is deformed in opposite directions to the position in which it normally is after the switching masses have been moved by the accelerated masses

Stores energy. After the switching operation, this causes the spring and the parts directly connected to it to swing back. Such a swinging back movement should, however, be prevented in order to prevent damage to the drive by the swinging back components. The present invention is therefore based on the object of designing a spring-loaded drive of the type mentioned in such a way that, on the one hand, the damping member dampens the dynamic energy of the drive as well as possible after completion of the actual stopping movement, and that it is not caused by the overshoot of a spring and a subsequent swinging back of drive parts collide with other drive parts.

The object is achieved in that the actuating element of the damping member, after the damping lever has moved past it, forms a fixed stop for its return movement.

In the course of the switching movement, the drive shaft is first driven by the spring and thereby a mechanism connected to the drive shaft for actuating switching contacts is driven.

After completion of this switching operation, the drive shaft releases the excess kinetic energy by means of the damping lever to the damping element and until the damping lever can be moved past the actuating element of the damping element.

If the damping lever then moves back due to the action of the spring after an harmonic oscillation, the actuating element of the damping member forms a fixed stop and thus blocks a backward movement of the damping lever.

This prevents the swinging back damping lever or other components firmly connected to the drive shaft from colliding with other moving or stationary parts of the drive, for example when directly connected of the switching process, an opposite switching process of the circuit breaker is carried out.

The invention can advantageously be designed in that the actuating element of the damping member is designed as a rotatably mounted roller and the damping lever is designed as a cam with a cam.

In the course of the switching movement, the cam disc rotates with the drive shaft until the cam strikes the roller and actuates the damping member by means of the roller. As a result, the cam disc is braked. After the roller has been pushed back, the cam disc can be moved past it particularly easily because of the rotatability of the roller. The roller then moves back to its original position and the cam is blocked by the roller in its swinging-back movement.

It can advantageously be provided that the cam has two flanks of different designs.

It is thereby achieved that the cam disc interacts with the roller during the actuation of the damping member in such a way that the roller is moved and that the damping lever is used in a swinging-back movement with the aid of its different design

Flank exerts pressure on the roller in a direction in which it cannot be moved.

A further advantageous embodiment of the invention provides that the damping lever actuates a control mechanism in the course of its orbital movement after passing the top dead center of the spring, which stops a tensioning motor.

It is therefore not necessary to provide a separate control device for switching off the tensioning motor. The shutdown of the

The tensioning motor is only activated by the damping lever let go when the top dead center of the spring and thus the spring is fully tensioned.

It can also be advantageously provided that the damping member has a hydraulic shock absorber.

The damping liquid of this shock absorber advantageously consists of an environmentally friendly substance, for example a liquid of water hazard class 0.

In the following, the invention is shown on the basis of an exemplary embodiment in a drawing and then described.

It shows

1 shows schematically a drive shaft in cross section with a cam and an damping member in a position at the end of the damping movement, FIG. 2 shows the arrangement from FIG. 1 after the damping and after the swinging back movement of the cam,

3 shows the arrangement from FIG. 1 during a subsequent tensioning process shortly before the cam actuates the control mechanism which stops the tensioning motor.

FIG. 1 shows in cross section a drive shaft 1 with which a cam disk 2, which forms a damping lever 1, is firmly connected.

The drive shaft 1 is connected by means of a crank, not shown, to a coil spring, also not shown, which serves as an energy store of the spring-loaded drive.

During a switching operation, the drive mechanism is first unlatched, so that under the influence of the spring, not shown, the drive shaft 1 is rotated and this Passes movement to a breaker unit, not shown.

After completion of the switching movement, i.e. H. After the switching contacts have been separated or conductively connected to one another, the drive shaft 1 and the cam disk 2 and other parts accelerated during the switching process have considerable dynamic energy, which is to be largely implemented in the attenuator 3. After completion of the switching movement, the cam 4 of the cam disc 2 meets the roller 5, which acts as an actuating element of the damping member 3. The roller 5 is rotatably mounted on a tappet 6 which drives a piston 7 in a hydraulic cylinder 8. The attenuator 3 is a shock absorber working with hydraulic fluid.

An environmentally compatible liquid, for example of water hazard class 0, is advantageously provided as the hydraulic fluid.

After the movement of the cam disc 2 and thus the rotation of the drive shaft 1 is braked, the cam 4 can run past the roller 5. This is facilitated by the rotatable mounting of the roller 5.

If the cam rotates further after moving past the roller 5 and the spring (not shown) is deformed beyond its bottom dead center, this leads to the spring returning both the cam and the drive shaft 1 after the movement has stopped moves, creating a swing back movement.

In the meantime, however, a plunger 6 with the roller 5 has been pushed back into its initial position by a return spring 13 within the damping member 3, so that the cam plate 2, also due to the asymmetrical design the cam 4 is blocked by the roller 5 with a very steep formation of the flank 9. The roller 5 lies against a guide 10 which guides the damping member 3 and the movement of the roller 5 and the plunger 6 during the damping movement. This ensures that the roller does not move sideways and the cam disc cannot turn counterclockwise and that, for example, other levers or cranks attached to the drive shaft 1 cannot collide with other parts of the drive, not shown.

When the spring-loaded drive is tensioned, the drive shaft 1 is rotated further in the same direction of rotation in which it is moved during the switching movement, by means of a motor (not shown) and a tension crank. The spring, not shown, is stretched until its top dead center is reached. Then the drive shaft moves so much under the influence of the spring in the same direction of rotation that the drive falls into a pawl, not shown. At this time, the tensioning motor should be mechanically decoupled from the drive shaft on the one hand and electrically switched off on the other hand.

For this purpose, a control mechanism 11 is provided which has a lever which can be actuated by the cam 4 of the cam plate 2 after passing through the top dead center of the spring. This control mechanism also has a control lever which actuates the control device 12 of the tensioning motor.

Claims

claims

1. Spring-loaded drive for an electrical circuit breaker with at least one spring which drives a drive shaft (1) in the switching case and with a circumferential damping lever (2) attached to the drive shaft (1), in particular in the form of a cam and with one in the path of movement of the damping lever (2) arranged actuating element (5) of a damping element (3), past which the damping lever (2) can be moved after it has been braked by the damping element (3), characterized in that the actuating element (5) of the damping member (3), after the damping lever (2) has moved past it, forms a fixed stop for its return movement.

2. Spring-loaded actuator according to claim 1, so that the actuating element (5) of the damping member (3) is designed as a rotatably mounted roller and the damping lever (2) as a cam disc with a cam (4).

3. Spring-loaded actuator according to claim 2, d a d u r c h g e k e n n z e i c h n e t that the cam has two differently shaped edges.

4. Spring-loaded actuator according to claim 1 or 3, so that the damping lever (2) actuates a control mechanism (11, 12) in the course of its orbital movement after passing the top dead center of the spring, which stops a tensioning motor.

5. spring-loaded actuator according to claim 1 or one of the following, characterized in that the damping member (3) has a hydraulic shock absorber.