DE2907715C3 - Drive device for high-voltage switches - Google Patents

Description

The invention relates to a drive device for a high-voltage switch according to the preamble of claim 1.

The development of new switches of the buffer type with SFb gas as an extinguishing agent requires drive devices with very high actuation force when switching off. At the same time, very short switch-off times are required.

A high-voltage switch is generally required to have a switch-off Guaranteed short response time, speed and breaking capacity even immediately after switching on can perform. This results in particularly high demands on the quality of the Drive device, since the switch-on mechanism switches off immediately after a switch-on must not hinder. For a switch with extremely high requirements in terms of the shortness of the Switch-off time also, the moving parts of the switch-off mechanism must have as low a mass as have possible.

ίο It is common for this to turn off quickly cause the disconnection force supplied by a spring, for example, to act directly on the arm lets who operate the switch. The arm is in the on position of the switch by a locking device locked. If the locking device receives a switch-off pulse, the arm is released and the Switch executes the switch-off movement. When the switch is turned on, it becomes an opposite Force applied to the switch arm, which overcomes the disconnection force, with disconnection energy is saved and the switch is turned on at the same time. When the switch is fully switched on, the Switch arm locked by the locking device, after which the switch arm quickly returned or to

r> page must be guided.

The invention is based on the object of providing a drive device of the type mentioned at the beginning develop in which the switch-off mechanism contains only a few simple and relatively light parts that

jo can move completely freely if they are switched off immediately after switching on target.

To achieve this object, a drive device according to the preamble of claim 1

j) proposed which according to the invention the in the characterizing Part of claim 1 has mentioned features.

Advantageous further developments of the invention are mentioned in the subclaims.

The invention is the desired required Freedom for the switch arm achieved in that the locking device is attached directly to the switch arm and this locking device is the only connection between the switch arm and the switch arm.

In order to get a large actuation force, a hydraulic or pneumatic one can expediently be used Actuating cylinder can be used. With conventional pneumatic or hydraulic However, actuation amplifiers tend to have a tendency to pulse time; H.

■ so the time from the received impulse to the full developed operating force, in addition, with increasing force requirement and with retained limited effect to increase on the trigger pulse. The delay is determined by filling times and position change times in

^r > 5 caused by an intermediate valve belonging to the system.

In order to avoid these disadvantages, a drive device according to the invention can be used as a locking device preferably a mechanical actuator

w) Use a motion amplifier from a series cascade-connected roller barriers. Such rolling locking devices can be used for very large forces and they are triggered by an electrical impulse. When the actuating cylinder to ·> Switching off is locked mechanically with such a locking device, so the cylinder can always be under Be put under pressure. This gives a drive device that, after a delay that affects the

Lockout response time limited, has a fully developed disengaging force.

A particularly simple drive device with a short response time is obtained according to a Further development of the invention in that a spring is used as a switch-off energy storage element which consists of several torsion bars that work in pairs and with one another with opposite directions of rotation.

Using the exemplary embodiments shown in the figures the invention is to be explained in more detail. It shows

1 shows a pneumatically operating drive device according to the invention in the switched-on position of the switch,

F i g. 2 the drive device according to FIG. 1 in the switch-off position, with the switch-on mechanism is still in the switch-on position,

3 shows the drive device according to FIG. 1 in the switch-off position, the switch-on mechanism is in the ready-to-switch position,

4 shows a drive device according to the invention with a spring drive in the normal operating position, d. H. the switch is switched on and the closing spring is tensioned.

The in the F i g. 1 to 3 shown pneumatic drive device includes an actuating cylinder 1 for switching off and an actuating cylinder 2 for switching on. Located in the switch-off actuating cylinder 1 a drive piston 3, which via a piston rod jo ge 4 and a switch arm 5 is connected to the drive shaft 6 of the switch. In the switch-on actuating cylinder 2 there is a drive piston 7, which is connected to a switch arm 9 via a piston rod 8 is connected, which is rotatable about the shaft 6. On the jj On arm 9, a locking device 10 is mounted, which consists of three cascaded roller locks.

The drive piston 3 in the switch-off actuating cylinder 1 delimits a cylinder space with its underside 11, which is in constant communication with a compressed air tank 13 via an inlet channel 12. Of the Switch arm 5 is thus constantly acted upon by a force in the switch-off direction.

The drive piston 7 in the switch-on actuation cylinder 2 delimits a cylinder space 14 with its underside, which is normally connected to the free atmosphere is in connection, but to turn on the switch via a valve device 15 to the Compressed air tank 13 can be connected.

The valve device 15 contains a valve disk 16 which can be displaced between two valve seats. Normally, the valve disk 16 rests against the left valve seat, under the action of a piston 18, which is located in the constantly pressurized cylinder space 17, and a spring ^r > 5 19. The cylinder space 14 of the on / off actuating cylinder 2 is included connected to the free atmosphere via the evacuation channel 20. In the left part of the valve device 15 there is a piston 21 which is used to actuate the valve disk 16 and which is controlled via a t> o on / off valve 22 and r ::: · evacuation valve 23.

When the switch is switched on (FIG. 1), the switch arm 5 is connected to the with the aid of the locking device 10 Start arm 9 coupled. The switch is driven by a tr> The fixed lock 24 acting on the switching arm is held in the switched-on position.

F i g. 1 shows the drive device in the normal operating position. The switch is on and stopped under the constant action of a disengaging force from the pressurized actuating cylinder 1. When an actuation pulse is given to the switch-off magnet 25, the locking device 10 is activated released and the pressurized gas drive piston 3 is pressed upwards and rotates the switch arm 5 and thus the drive shaft 6 of the switch into the position shown in FIG. 2 shown switch-off position of the switch.

The drive piston 3 carries a valve plate 26 which, during the switch-off movement, a throttle tube 27 runs through, with the supply of compressed air to the drive piston 3 during part of the piston stroke is interrupted. This ensures that the movable contact of the switch during the opening movement temporarily at a distance from the fixed contact that is favorable to extinguishing the arc is braked.

A cam 28 is arranged on the drive shaft 6, which during the switch-off movement releases the lock 24 for the switch-on arm 9 via a rod 29. Under the Effect of a return spring 30 in the switch-on actuating cylinder 2, the switch arm 9 is clockwise rotated, and with the aid of the locking device 10, the switch arm 9 is coupled to the switch arm 5. as shown in FIG. The drive piston 7 in the switch-on actuating cylinder 2 is located in FIG its lower limit.

During the disengaging movement of the shaker, the cam 28 also acts via the articulation system 29, 31, 32, 33 on the evacuation valve 23, so that the cylinder space 34 to the left of the piston 21 with a channel 35 is connected, which opens into the space on the right side of the left valve seat of the valve disk 16.

To turn on the switch from the in F i g. 3, an actuation pulse is applied given the switch-on magnet 36, whereby the valve member of the switch-on valve 22 to the right is pressed, and the cylinder space 34 to the left of the piston 21 via the channel 37 is pressurized. The piston 21 and thus the valve disk 16 are pressed to the right, and the cylinder chamber 14 in the The closing cylinder is pressurized. At the same time, the cylinder space 34 receives via the channel 35 Holding pressure, the on-off valve 22 being able to return to the closed position. The drive piston 7 in the switch-on actuating cylinder 2 is now pushed upwards and rotates the switch-on arm 9 and the associated switch arm 5 counterclockwise until the switch arm engages with the Lock 24 arrives, which has previously been retracted into its locking position by a spring 38. Over the pole 32 at the same time the valve element in the evacuation valve 23 is pressed to the right, the cylinder chamber 34 is evacuated to the left of the piston 21. By the piston 18, which is always acted upon by the compressed gas, and the spring 19, the valve disk 16 is pressed into its left limit position, and the cylinder chamber 14 in the The switch-on actuating cylinder is evacuated via the evacuation channel 20.

The spring drive device shown in Fig. 4 has an opening spring, which consists of two parallel Torsion bars 41, 42 are made of spring steel, which are firmly clamped in a cross member 43. The free ends of the rods are fixedly arranged on the shaft 6 via lever arms 44, 45 and rods 46, 47 Switch arm 5 connected in such a way that the rods mutually rotate in the opposite direction of rotation.

be rotated. On the shaft 6, an arm 48 is also fixedly arranged, which via a rod 49 to the movable contact 50 of the switch is coupled.

Two torsion bars 51, 52 arranged in parallel are also used to switch on the switch. which are firmly clamped in the cross member 43. The free ends of the rods are via lever arms 53, 54 and Rods 55, 56 are connected to an actuating arm 57 rotatably arranged on the shaft 6. at tensioned closing spring, the arm 57 of a stationary arranged locking device 58th of the Switching solenoid 36 can be released, held locked.

The switch arm 9, which is rotatably arranged on the shaft 6, is moved by the actuating arm in one direction of rotation 57 when the switch is switched on and in the opposite direction of rotation from the return spring 30 rotated.

4 shows the drive device; in normal Operating situation. The switch is switched on, and both the switch-off spring 41, 42 and the switch-on spring 51, 52 are curious. The switch arm 5 is in this case with the aid of the locking device arranged on the switch arm 10 coupled to the activation arm 9. The switch is operated by the lock 24 that controls the switch arm 9 locked, held in its on position.

When an actuation pulse is given to the switch-off magnet 25, the lock 10 is released.

and the opening spring 41 "42 rotates the movable one Contact of the switch quickly in the opening position c. The arranged on the shaft 6 cam 28 acts during the switch-off movement on the rod 29, which releases the lock 24 for the switch-on arm 9. Under the Effect of the return spring 30, the switch arm 9 is then rotated clockwise, and with the help of Locking device 10 couples the switch arm 9 to the switch arm 5.

ι «To switch on the switch, an actuation pulse is sent given to the switch-on magnet 36, which releases the locking device 58. The switching spring 51,52 rotates while the actuating arm 57 counterclockwise, and inter alia. the switch arm 9 and the switch arm 5

r> wiru the contact 50 led into the switch-on position. the Lock 24 comes into locking engagement at the same time as the sounding alarm 9. During the switch-on movement, the Switch-off spring 41, 42 tensioned. The switch can therefore be switched off immediately after it has been switched on will.

The invention is not restricted to the exemplary embodiments shown. For example, they need Switch-on and switch-off energy elements not to be pneumatic working cylinders or torsion springs, but ordinary coil springs or other types of energy-storing members can also be used will.

For this purpose 2 sheets of drawings

Claims (5)

Patent claims: 1. Drive device for high-voltage switches with one with the moving contact of the Switch permanently connected switch arm, which is used to turn the switch on and off, respectively opposite direction is rotatable and constantly from one of a switch-off energy storage element exerted force is applied in the switch-off direction, with a switch-on energy storage element, which exerts a closing force acting on the switch arm when the switch is switched on, which is greater than the switch-off force, with one to lock the switch arm in the switch-on position of the Switch serving locking device and with a to trigger this locking device provided switch-off pulse element, thereby characterized in that the locking device (10) is on one of the switch-on energy storage member (2, 51, 52) actuated single-shaft arm (9) is attached, which is opposite the switch arm (5) is arranged rotatably about the same pivot point and in the switched-on position of the switch of a stationary, releasable lock (24) is locked, and that the locking device (10) such is arranged that during the Eirschaltbewegung and when the switch is switched on, the inrush arm (9) and the switch arm (5) keeps coupled together. 2. Drive device according to claim 1, characterized in that the switch arm (5) with a fixedly connected to the movable contact of the switch drive shaft (6) on which the Closing arm (9) is rotatably mounted, is not rotatably connected. 3. Drive device according to claim 1 or 2, characterized in that the locking device (10) is a mechanical actuation amplifier, which consists of several cascade roller barriers consists. 4. Drive device according to one of the preceding claims 1 to 3, in which the switch-off energy storage element consists of a hydraulic or pneumatic actuating cylinder, characterized in that the actuating cylinder (1) is constantly pressurized. 5. Drive device according to claim 1, 2 or 3, wherein the switch-off energy storage element a Spring is characterized in that the spring consists of several torsion bars (41, 42) which work in pairs and with opposite directions of rotation.