KR100479652B1 - Hydraulic drive - Google Patents

Abstract

According to the invention, the actuating piston 13 is adapted to drive an actuating device, preferably a high voltage circuit breaker, via the piston rod 14 and to actuate the actuating piston cylinder device 13, 11, 12. Compression piston cylinder device (29,36) is provided with a hydraulic fluid for the stored energy is transferred to the compression piston cylinder device (29,36), the spring device is the actuating piston cylinder device (13, 12, 11) A hydraulic drive having a spring storage device (16, 17) around the same center, wherein the compression piston 36 is an annular piston, the annular piston is the actuating piston It surrounds the cylinder body 11 of the cylinder arrangement and is operated by the spring arrangement 16, 17 in an annular chamber 31, the hydraulic fluid being opposed to the spring arrangement 16, 17. In the portion of the annular chamber 31 located on the side of the annular piston 36.

Description

Hydraulic Drive {HYDRAULIC DRIVE}

The present invention relates to a hydraulic drive device described in the preamble of claim 1.

A drive of this kind is known from EP 0 158 054 B1. This drive device has an actuating piston with an integrally molded piston rod connected to a high voltage circuit breaker that turns the switch on and off. The actuating piston or actuating piston cylinder device is supplied with hydraulic fluid provided by a pressure tank comprising a compression piston and a compression cylinder (both surrounding the piston rod in the same center). In order to generate hydraulic fluid, the disk spring device acts on the compression piston, which also surrounds the actuating piston about the same center and connects to the outside of the cylinder body, on the other hand, almost at the center of the actuating piston cylinder arrangement. It is supported by a thrust piece connected to the compression piston via a connecting rod. The connecting rod passes through the cylinder body, which requires a large overall cost with regard to sealing.

It is an object of the present invention to provide a hydraulic drive of the first mentioned type, which is simpler than the conventional hydraulic drive.

The object of the invention is achieved according to the invention by the features of claim 1.

According to this claim, the compression piston is an annular piston which surrounds the actuating piston cylinder arrangement, is actuated by a spring arrangement and slides in an annular chamber, and the hydraulic fluid is an annular piston facing the spring arrangement. It is in the annular chamber part located on the side.

An advantageous improvement can be a compression piston cylinder device located between the spring device and the switch side end of the cylinder body. By switch side end here is meant the end from which the piston rod protruding actuating the switch or possibly another device. Such a device is a design that saves space as a result.

To form the compression piston cylinder device, it is formed inward by the outer surface of the cylinder body, outwardly by the inner surface of the outer cylinder, the spring device side is open, radially inwardly projecting foundation The annular chamber is provided in which the end side of the cylinder body close to the switch is closed. This foundation lies enclosed on or surrounds the outer surface of the cylinder body.

According to a further development of the invention, the fixed end of the spring device is fixed to the end of the cylinder body away from the switch, sealingly sliding the outer surface of the cylinder body and transmitting thrust to the spring piston of the spring device to the compression piston. A thrust piece is provided between the compression piston cylinder device and the other freely movable end of the spring device.

The relaxation movement of the spring device is directed towards the high voltage switch.

Advantageous further developments of the invention are described in the dependent claims.

The invention and advantageous further improvements and further advantages of the invention will be described and described in more detail with reference to the drawings in which exemplary embodiments of the invention are shown.

The hydraulic drive device 10 includes a cylinder body 11 including an operation cylinder chamber 12 in which the operation piston 13 slides. The piston rod 14 acting on the high voltage switch 15 is integrally molded to the actuating piston 13 shown on the upper side of the figure. High voltage here means a voltage range above 1 KV called the intermediate voltage range.

The cylinder body 11 has a cylindrical structure and is surrounded by a spring device 16 or 17. The spring device 16 with more disc springs than the spring device 17 is designed for higher pressure or other switching sequences.

A groove 18 is formed at the end of the cylinder body 11 spaced from the switch, and in the embodiment to the left of the center line a flange rim protruding radially inward of the L-shaped cross section into this groove. A divided force transmission element 19 with a 20 is inserted and the force transmission element 19 is surrounded by a holding cup 21, which holding cup 21 has an inner flange rim ( 22, wherein the flange rim protrudes radially inwardly, partially engages the force transmission element 19, and the outer flange rim 23 at the end of the holding cup away from the switch is a disk. It lies at one end of the outer flange rim of the spring device 16. This is the fixed end of the disk spring device. In the embodiment shown to the right of the center line MM, the force transmission element 19 is inserted into the groove 24, which groove 24 is of the cylinder body 11 spaced from the switch relative to the groove 18. Further away from the end. The force transmission element 19 is surrounded by a holding cup 25 of Z-shaped cross section, on which the radially outer flange rim 26 rests the fixed end of the spring arrangement 17.

The difference between the holding cup 21 and the holding cup 25 is only the fact that the axial length of the holding cup 21 is much longer than the axial length of the holding cup 25.

An end toward the switch 15 of the spring arrangement 16 and the spring arrangement 17 lies on the thrust element 27, which is fitted with a seal 28 and the cylinder body ( 11) surround the outside. On the other side of the thrust ring, as seen from the disc spring arrangement 16 or 17, an outer cylinder 29 is arranged at a distance from the cylinder body 11, the inner surface 30 of which is the cylinder body 11. The annular chamber 31 is formed together with the outer surface of the. The outer cylinder end transferred from the switch lies in the thrust element 27, and the end of the outer cylinder 29 adjacent to the switch forms the form of the base 32, such that the base is outside of the cylinder body 11. Lies directly on the surface.

A holding ring 33 protruding into the cylinder body 11 and the outer cylinder 29 is provided to secure the outer cylinder 29 with respect to the cylinder body 11. The annular cover 34 fixed to the switch-side cross section of the cylinder body 11 by a screw connection 35 acts as a connecting element for the channel or hole (no reference number), which channel or hole is the cylinder body 11. ), Through which the low pressure hydraulic fluid is delivered to the low pressure fluid collection chamber.

The annular compression piston 36, the operation of which is described in detail below, is located between the thrust portion 27 and the base 32 inside the annular chamber 31.

The piston rod 14 passes through, and the sealing bush 37 firmly fixed to the cylinder body 11 by the sealing lid 38 is an actuating cylinder 12 at the switch side end of the cylinder body 11. ) Is inserted. The piston rod 14 also passes through a hermetic lid 38.

Inside the cylinder body 11 and outside the working cylinder 12, there are provided holes 39 extending in the axial direction and holes 40 extending in the radial direction, which holes are connected to each other and / or are connected to the switching valve ( A device called a low pressure and pump unit (not shown), connected to the working cylinder 12 by means of a radially extending hole 42, and by means of an additional radial hole 43. 44). The low pressure chamber described above forms part of the low pressure and pump unit.

The specific method of operating the device 44 and connecting the respective holes 39 to 43 is not particularly important for the present invention. Through this hole, the hydraulic fluid is provided to the actuating piston 13 or the pressure is removed from the actuating piston 13 in an appropriate manner, see EP 0 158 054 B1 for this.

Importantly, by means of a pumping / low pressure storage device, the region of the annular chamber 31 facing the switch is driven by a switching valve such that the region is filled with hydraulic fluid, so that the annular piston 36 moves outward in the direction of the arrow P. Driven out of the side cylinder 29, in which the piston compresses the spring device 16 or 17 to store energy in the spring device 16 or 17, which acts as an energy storage device. In this process, the spring arrangement 16 or 17 is essentially compressed into a block such that the annular piston 36 comes out of the annular chamber 31, in which the switch side end of the annular piston 36 is connected to the annular chamber. It must not pass through the enclosed seal 45. The seal 46 located outside the region of the annular piston 36 adjacent to the switch must be at least inside the outer cylinder 29. Since the internal control means also provide hydraulic fluid to the up and down chambers of the actuating piston 13, the actuating piston 13 is up, so that the piston rod 14 moves out of the closure cap 38. Switch 15 is closed. This occurs because the chamber below the actuating piston 13 located opposite the piston rod 14 has a larger area than the chamber adjacent to the actuating piston 13.

If the switch is to be switched off, the pressure is removed from the chamber below the actuating piston 13, i.e. from the larger chamber, where the hydraulic fluid located here is supplied to the low pressure chamber in a manner that does not need to be described in more detail. Acting by a switching valve (not shown).

The transition between the actuating piston 13 and the piston rod 14 has a large diameter area 47, and a damping device 48 is assigned to the area 47. During the switch on operation, the area 47 is directed to the damping ring 48 and the switch on movement is relaxed. A pin-like extension 49 is provided on the side of the actuating piston 13 away from the piston rod that moves to the damping ring 50 and decelerates the end region of the switch-off movement during the switch-off operation. .

A particular advantage of the arrangement according to the invention is that the switch side of the annular chamber (referred to as the pressure chamber) is located directly adjacent to the pump / low pressure storage device and the actuating piston or actuating piston cylinder device, which must be overcome during switch on and off. Flow resistance is significantly reduced.

In the configuration according to the invention, all the components that transmit the force, namely the disk spring arrangement 16 or 17, the thrust ring 27, the annular compression piston 36, the support ring 33, and the cylinder body 11 Arranged coaxially with each other, each component surrounds the cylinder body 11. For this reason, the force intersects the longitudinal axis of the cylinder body and prevents the device from being overall compact in design. It is also important that the pressure chamber 31 in which the hydraulic fluid is located is arranged very close to the working cylinder chamber 12.

The sealing element 51 with a blind bore 52 fits into the working cylinder chamber 12 at the end of the cylinder body 11 spaced from the switch, through which the pin 49 is switched. Engaged in the off state, the sealing element 51 is securely fastened with the cover 53.

The present invention has been described with respect to a hydraulic drive device for a high voltage circuit breaker. Naturally, instead of such a high voltage circuit breaker, it is possible to drive all other devices necessary to carry out similar work on a high voltage circuit breaker.

1 shows two variants of a hydraulic drive, with a variant with a larger energy storage device shown on the left side of the center line, a variant with a smaller or weaker energy storage device. A diagram, shown to the right of the center line.

<Explanation of symbols for main parts of drawing>

10: hydraulic drive unit 11: cylinder body

12: working cylinder 13: working piston

14: piston rod 15: high voltage switch

16,17: spring device 18: groove

19: Force transmission element 20: Flange rim

25: holding cup 28: seal

31: annular chamber 32: base

36: piston 39 to 43: bore

Claims (6)

The actuating piston 13 has an actuating piston cylinder device for driving the high voltage circuit breaker through the piston rod 14; A compression piston cylinder device 29, 36 provided with hydraulic fluid for driving the actuating piston cylinder device 13, 11, 12; Stored energy is transferred to the compression piston cylinder device 29, 36, the spring device having a spring storage device 16, 17 which encloses the actuating piston cylinder device 13, 12, 11 in the same center. As a hydraulic drive, The compression piston 36 is an annular piston, and the annular piston surrounds the cylinder body 11 of the actuating piston cylinder device and is formed of an annular member, which is inward by the outer surface of the cylinder body 11. A surface is formed, and the inner surface of the outer cylinder 29 forms another surface continuous with the inner surface of the annular member, wherein the spring storage device 16, 17 of the two ends of the annular member is formed. The spring device () in an annular chamber (31) which is an annular member which is open and the end of the high voltage circuit breaker is closed by a base (32) which projects radially inwardly. 16,17, characterized in that the hydraulic fluid is present in the annular chamber portion located on the side of the annular piston 36 opposite the spring arrangement 16,17. Pneumatic drive. Hydraulic method according to claim 1, characterized in that the compression piston-cylinder device (36,29) is located between the spring device (16,17) and the high voltage switch (15) proximate to the cylinder body (11). drive. The fixed end of the spring device (16, 17) is fixed to the end of the cylinder body (11) away from the switch, and the closed cylinder body (3). A thrust piece 27 which slides on the outer surface of 11 and transmits the spring force of the spring device 16, 17 to the compression piston 36 is provided in the spring device 16, 17. Hydraulic drive device, characterized in that provided between the other end freely movable and the compression piston cylinder device (36,29). 3. The hydraulic drive according to claim 1, characterized in that the relaxation movement of the spring device (16, 17) is directed towards the high voltage switch (15). 4. A pump / low pressure storage device (44) is provided radially on one side of the cylinder body (11) in the region of the compression piston (36), and a switching valve (3). a changeover valve is provided on the opposite end side. 3. The cylinder according to any one of claims 1 to 2, wherein the cylinder body has a draw material in which the holes 39 to 43 for the actuating cylinder 12 and the hydraulic fluid line are machined (perforated). hydraulic drive device, characterized in that it is a drawn material or a forged material.

Images