EP0053574A1 - Hydraulic control device for a high-tension electrical circuit breaker - Google Patents

Abstract

In a hydraulic control device (2) for an electrical switch (1), especially a high-tension circuit breaker, the drive consists of a differential piston (3) and a cylinder (4). The differential piston (3) is continuously loaded with the pressure of the pressure fluid on its side (9) with a small area and, on its side (13a) with a large area, can be acted on, optionally, via a valve device (6). In order to reduce the component of the switching time governed by the movement time of the interrupter unit until electrical isolation occurs, without reducing the weight of the switch pieces and the moving mass and without increasing the pressure of the hydraulic fluid, the differential piston (3) is designed as a two-position stepped-piston system. The first part (3a) of the stepped-piston system is a free-running piston moving in a limited fashion in the cylinder (4). This loads the second piston part (3b) on its side (9) with a small area and has an end face (10) which increases its effective piston area. <IMAGE>

Description

The invention relates to a hydraulic actuating device for an electrical switch, in particular high-voltage circuit breaker, with a drive consisting of a differential piston and a cylinder, the differential piston being continuously loaded with the pressure of the pressure fluid on its small-area side and on its large area via a Valve device is optionally acted upon.

Hydraulic actuators of this type have to move the moving contacts of the circuit breakers as quickly and without delay as possible depending on the control command to switch on and off. The switching time of a switching device is thus largely determined by the type of drive and its design. If you disregard the proportion of switching time determined by the arc time, the switching time is based on the start of the command, the solenoid time of the release, the valve time for the control valves, the switching rod and transmission time and the movement time of the interrupter units up to the electrical isolation.

This results in a mechanical switch-off time that reaches the order of 20 msec.

There are high-voltage supply networks in which the circuit breakers should not exceed a total switching time for two periods (so-called 2-cycle switches).

If the supply networks are operated at 60 Hz, this leaves a mechanical switch-off time of no more than 15 msec for a modern high-voltage circuit breaker.

Since some known high-voltage circuit breakers operate according to the blown-piston principle, in which the pressure required for the gas used to extinguish the arc is generated during the switch-off operation, namely by pre-compression, hydraulic actuating devices are known which operate at such a high pressure of, for example, 350 bar that they move the moving contact pieces, which weigh a few kilograms, from one end position to the other in the shortest possible movement time.

The invention is based on the object of reducing the proportion of switching time caused by the movement time of the interrupter unit up to the galvanic isolation, without reducing the weight of the switching pieces and the moving masses, and without increasing the pressure of the hydraulic fluid.

According to the invention, this is achieved in that the differential piston is designed as a two-part stepped piston system, the first part of which is a free-running piston which is limitedly movable in the cylinder and which loads the second piston part on its small-area side and has an end face which increases its effective piston area.

By applying the invention, an acceleration of the differential piston corresponding to the enlarged effective piston area initially results in the course of movement, preferably during the entire phase of pre-compression of the blowing piston system. The piston accelerated in this way is moved further after the limitation of the freewheel piston movement with a smaller effective piston area, so that there is a favorable energy balance in the entire movement sequence. In particular, there are smaller brakes forces when braking the accelerated piston system in the off position. In this way, the total time between the start of the command and the galvanic isolation of the contact system can be made less than 15 msec, with the solenoid and valve time remaining the same.

In a preferred embodiment of the invention, the freewheel piston is designed as an annular piston surrounding the piston rod of the second piston part at a distance. The free-running piston can be supported on the inner wall of the cylinder by means of two seals.

If the space between the seals of the freewheel piston is ventilated, the pressure of the oil expelled remains low during the switch-off process, while the switch-on force is reduced in the course of the switch-on process after the second piston part has hit the free-wheel piston in the sense of a desired damping effect.

In an advantageous embodiment of the hydraulic actuating device according to the invention, the freewheel piston encloses the second piston part in a pressure-tight manner via a seal. This results in a space-saving telescope arrangement.

Exemplary embodiments of a hydraulic actuating device according to the invention are described and the mode of operation is explained with the aid of the drawing.

In Fig. 1, a hydraulic actuating device for a high-voltage circuit breaker is shown schematically in a section, which is in the open position.

FIG. 2 shows a hydraulic drive, also shown schematically in section in the switch-off position.

FIG. 3 shows a further embodiment in the same position.

The hydraulic actuating device shown schematically in FIG. 1 is not shown further for one. set high-voltage circuit breaker 1 determines the z. B. can be designed as a blow piston switch with sulfur hexafluoride as an extinguishing agent. The switch 1 is actuated by a hydraulic actuation device 2, which has a drive consisting of a differential piston 3 and a cylinder 4. This drive can optionally be pressurized via a valve device 6. The pressure fluid is removed from a reservoir 7, in which a predetermined pressure, such as 350 bar, is maintained by means of a pump (not shown). The differential piston 3 is coupled to the movable contact piece of the switch 1 via a piston rod 8. As can be seen, the differential piston 3 is designed as a two-part stepped piston system, the first part 3 a of which is a free-running piston that is limitedly movable in the cylinder 4. This freewheel piston 3a loads the second piston 3b on its small-area side 9 at the beginning of the switch-off action. The freewheel piston 3a has an end face 10, which increases the effective piston area of the second piston part 3b.

The drive shown in the switch-off position is converted into the switch-on position by reversing valve 6 in the direction of arrow 11. As a result, the space 12 supplied with the pressure medium with the accumulator 7 comes into connection with the large-area side 13 of the second piston part 3b, as a result of which the piston and the piston rod 8 move in the direction of the arrow 13. In the course of the switch-on movement, the small-area Seita 9 strikes the freewheel piston 3a, which is thereby carried along in the direction of the arrow 13, resulting in a braking effect. This effect is due to a reduction in the effective An drive surface (area difference of the pistons). The freewheel piston also acts as a spool.

To switch off, the valve 6 reverses into the position shown in the direction of the arrow 11, so that the large-area side 13 of the piston part 3b is depressurized and the pressure present on the end face 10 and the small-area side 9 can take effect. In accordance with this large effective piston area, the piston rod 8 is moved in the opposite direction of the arrow 13 until the freewheel piston 3a assumes the position shown in FIG. 1. The resulting reduced effective piston area 9 results in a lower force for continuing the movement of the movable system with less mass. The freewheel piston 3a cooperates in FIGS. 1 and 2 with two seals 14a which delimit a ventilated space between them.

3, the freewheel piston 3a is only equipped with a seal 14a and a guide 14b.

In the exemplary embodiment shown, the piston part 3b is provided with a seal 14 which is supported against the inner wall of the cylinder 4.

In the exemplary embodiments shown in FIGS. 2 and 3, in which the same parts are provided with the same reference numerals, the pistons 3b are provided with seals 14 which run in a pressure-tight manner in the inner opening of the annular piston-like freewheel piston 3a. Compared to the exemplary embodiments shown in FIGS. 1 and 2, which show an annular freewheel piston with a stop shoulder 15, the exemplary embodiment according to FIG. 3 differs in that a hollow cylindrical, annular freewheel piston is arranged in the cylinder 4 without a special stop shoulder. It strikes a stop with its end face.

In all embodiments, it is possible to shorten the movement time of the interrupter unit to the galvanic isolation without increasing the hydraulic drive and without increasing the hydraulic pressure, while the magnet time, the valve time and the shift rod and transmission time can be maintained.

Claims (5)

1. Hydraulic actuating device for an electrical switch, in particular high-voltage circuit breaker, with a drive consisting of a differential piston and a cylinder, the differential piston being continuously loaded with the pressure of the pressure fluid on its small-area side and optionally actable on its large area via a valve device , characterized in that the differential piston (3) is designed as a two-part stepped piston system, the first part (3a) of which is a free-running piston which can be moved in a limited manner in the cylinder and which loads the second piston part (3b) on its small-area side (9) and one of its effective piston surfaces enlarging end face (10). - 2. Hydraulic actuating device according to claim 1, characterized in that the freewheel piston (3a) as a piston rod (8) of the second piston part (3b) is formed at a distance enclosing ring piston. 3. Hydraulic actuating device according to claim 1 or 2, characterized in that the freewheel piston (3a) is supported by means of two seals (14a, 14b) on the inner wall of the cylinder (4). 4. Hydraulic actuating device according to claim 3, characterized in that the space between the seals of the freewheel piston (3a) is ventilated. 5. Hydraulic actuating device according to one of claims 1 to 4, characterized. that the freewheel piston (3a) the two th piston part (3b) encloses a seal (14) pressure-tight.

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