JPH10184611A - Fluid driving system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a fluid driving system having a simpler constitution as compared with a conventional fluid driving system. SOLUTION: A pressure piston 36 is an annular piston which encircles a cylinder body 11 of an operating piston cylinder mechanism, and can be driven by spring mechanisms 16 and 17 in an annular chamber 31. In this case, a pressure medium is situated in the annular chamber 31 of the annular piston 36 positioned on the opposite side of the spring mechanisms 16 and 17.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to a fluid driving device according to the preamble of claim 1.

[0002]

2. Description of the Related Art A driving device of this kind is disclosed in EP 0 158
054 B1.

[0003] This driving device has an operating piston integrally provided with a piston rod connected to a high-voltage circuit breaker.

The working piston or working cylinder mechanism includes:
The pressure medium is supplied from a pressurized tank with a pressure piston and a pressure cylinder provided concentrically around the piston rod.

A disk spring mechanism acts on the pressure piston to generate a pressure medium. This pressure piston is likewise provided concentrically around the working piston and is supported substantially at the center of the working piston-cylinder mechanism, on the one hand outside the cylinder body and on the other hand via a connecting rod to the pressure piston Supported by the thrust piece. The connecting rod penetrates the cylinder body. This requires a high overall height for the sealing.

[0006]

SUMMARY OF THE INVENTION It is an object of the present invention to provide a fluid driving device having a simpler structure than the conventional fluid driving device.

[0007]

SUMMARY OF THE INVENTION The object of the present invention is defined in claim 1.
This is achieved by the configuration described in the characterizing portion.

According to the first aspect, the pressure piston includes:
An annular piston surrounding the working piston-cylinder mechanism,
It is also driven by a spring mechanism in the annular chamber, in which case the pressure medium is in the annular chamber of the annular piston located on the opposite side of the spring mechanism.

In a preferred configuration, the pressure piston cylinder mechanism is located between the spring mechanism and a switch located at the end of the cylinder body. Here, the switch-side end means that a piston rod extending from this end drives the switch. This configuration results in
It is a configuration that can save space.

In forming the pressure piston cylinder mechanism, the annular chamber is formed inside the outer surface of the cylinder body and outside the inner surface of the outer cylinder. Preferably it is closed by a base projecting radially towards the end of the cylinder body. The base is in contact with the outer surface of the cylinder body, that is, the base is sealed and sealed.

In a further preferred refinement, the fixed end of the spring mechanism is fixed to the end of the cylinder body remote from the drive, remote from the switch, in which case the movable end of the spring mechanism and the pressure piston cylinder mechanism A thrust piece provided therebetween is sealed on the outer surface of the cylinder body and slides to transmit the spring force of the spring mechanism to the pressure piston.

The relaxing movement of the spring mechanism is directed to the high pressure switch.

[0013] Further refinements of the invention are disclosed in the subclaims.

Further improvements and advantages of the present invention are described in detail with reference to the accompanying drawings, in which embodiments of the invention are also described.

[0015]

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a perspective view of a fluid driving device according to a first embodiment of the present invention;

One variant of a strong energy storage is shown to the left of the center line, and a small, weak energy storage is shown to the right of the center line.

The fluid drive device 10 has a cylinder body 11, in which a working cylinder 12 is provided, in which a working piston 13 slides.

Piston rod 1 cooperating with high pressure switch
4 is integrated into the working piston 13 upward in the figure. Here, high pressure means 1 kV or more with respect to medium pressure.

The cylinder body 11 is cylindrical and has a spring mechanism 1
It is surrounded by 6 and 17. The spring mechanism 16 is composed of more disk springs than the spring mechanism 17 and is for a high pressure level.

A groove 18 is formed at an end of the cylinder body 11 on the side remote from the switch. A split force transmitting member 19 having a flange rim 20 projecting radially inward with an L-shaped cross section is inserted into the groove 18 in the example on the left side of the center line. The force transmitting member 19 is surrounded by a coercive cup 21. This coercive cup 21
An outer flange rim 22 protruding radially inward and partially engaging the force transmitting member 19 and having at its end remote from the switch an outer flange rim 23 supporting one end of a disk spring mechanism have. This is the stationary end of the disk spring mechanism.

In the example on the right side of the center line MM, the force transmitting member 19 is inserted in the groove 24. This groove is groove 2
The distance from the end of the cylinder body 11 distant from the switch is greater than that of 0. The force transmission member 19 has a cross section Z
It is surrounded by a coercive cup 25 of the shape. A spring mechanism 1 is attached to the radially outer flange rim 26 of the coercive cup 25.
7 are supported.

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

The end faces of both the spring mechanism 16 and the spring mechanism 17 facing the switch 15 are in contact with the thrust member 27. The thrust member 27 surrounds the outside of the cylinder body 11 with a seal 28 interposed.

The disk spring 1 of the thrust member 27
On the opposite side as viewed from 6, 17 the cylinder body 11
An outer cylinder 29 is provided at a distance from the outer cylinder 29. The inner surface 30 of the outer cylinder 29 forms an annular chamber 31 together with the outer surface of the cylinder body 11.

The end of the outer cylinder 29 remote from the switch contacts the thrust member 27, and the end of the outer cylinder 29 near the switch forms a base 32. The base 32 is in direct contact with the outer surface of the cylinder body 11.

A holding ring 33 that protrudes into both the cylinder body 11 and the outer cylinder 29 is provided for fixing the outer cylinder 29 to the cylinder body 11.

At the end of the cylinder body 11 on the switch side,
An annular cover 34 fixed by a screw connection 35 functions as a member for connecting the channel and the bore (not numbered). These bores are in the cylinder body 11
Running in the chamber and sends the low pressure medium to the low pressure medium chamber.

An annular pressure piston 36 (the details of which will be described later) is provided in the annular chamber 31 between the thrust piece 27 and the base 32.

A seal bush 37 through which the piston rod 14 passes is attached to the cylinder body 11 by a closing cup 38.
It is fixed by. The seal bush 37 is housed in the operation cylinder 12 located at the switch side end of the cylinder body 11. And the piston rod 14
Also penetrates the closing cup 38.

Inside the cylinder body 11 and outside the working cylinder 12, a bore 39 extending in the axial direction and a bore 40 extending in the radial direction are provided. These bores are connected to each other and / or to a connection 41 to a switching valve (not shown). It is connected to the working cylinder 12 through a bore 42 extending in the radial direction. A device 43 as a low-pressure pump unit is provided with a bore 43 extending in the radial direction.
Connected through. The aforementioned low-pressure medium chamber is a part of the low-pressure pump unit.

The operation of the device 44 and the individual bores 39-43
Is not an important part of the present invention. Via these bores, the pressure medium is supplied to the working piston 13 and
Conversely, it is removed from the working piston 13. For example, EP
See 0 158 054 B1.

The important points are as follows.

By means of the pump / low-pressure reservoir device, the area of the annular chamber 31 facing the switch is filled with a pressure medium driven by the switching valve, so that the annular piston 36 is pushed out of the outer cylinder 29 in the direction of the arrow P. In this process, the spring devices 16 and 17 are compressed, and energy is stored in the spring devices 16 and 17 functioning as energy storage devices. In this process, the spring devices 16 and 17 are compressed, and the annular piston 36 is pushed out of the annular chamber 31.

However, the switch-side end of the annular piston 36 does not cross the seal provided in the annular chamber. At least the outer seal 46 must remain inside the outer cylinder 29 in the area of the annular piston 36 near the switch.

The internal control means feeds the pressure medium into the upper and lower chambers of the working piston 13 so that the working piston 13 is pushed upwards, so that the piston rod 14 comes out of the cover 38 and closes the switch 15.

This is for the following reason. Working piston 1
3, the area of the chamber opposite the piston rod 14 is
This is because the working piston 13 is larger than the area of the chamber in which the piston rod is attached.

To turn off the switch 15, the pressure is removed from the chamber below the working piston 13, that is, the chamber having a large piston surface. In this case, the pressure medium is sent to the low-pressure chamber by the operation of the switching valve (not shown).

There is a large diameter area 47 between the working piston 13 and the piston rod 14. A damping device 48 is mounted in the area 47.

If the area 47 enters the damping ring 48 during the switch-on operation, the switch-on operation is dumped.

During the switch-off operation, when the pin-like extension 49 enters the damping ring 50 provided on the side of the working piston 13 remote from the piston rod, the end portion of the switch-off operation is decelerated. You.

It should also be noted that a seal member 51 having a blind hole 52 is mounted in the working cylinder chamber 12 at the end of the cylinder body 11 remote from the switch. And in this blind hole, with the switch off,
Pin 49 is inserted. The seal member 51 is held by the cover 53.

The present invention has been described with reference to a fluid drive for a high voltage circuit breaker.

Of course, instead of such a high voltage circuit breaker, it is also possible to drive another device which performs the same work as the high voltage circuit breaker.

[0044]

A particular advantage of the present invention resides in the switch section, the working piston, and the working piston cylinder mechanism associated with the pressure chamber of the annular chamber provided immediately adjacent to the pump / low pressure reservoir device. This greatly reduces the fluid resistance to be overcome during switch on / off.

In the structure of the present invention, all the members for transmitting the force, that is, the disk spring mechanisms 16 and 17, the thrust ring 2
7, the annular pressure piston 36, the retaining ring 33 and the cylinder body 11 are arranged concentrically with each other, and individual members are provided surrounding the cylinder body 11.

According to this configuration, a force perpendicular to the long axis of the cylinder body is avoided, and the configuration is compact.

The pressure chamber 31 in which the pressure medium is located
It is also important that is provided very close to the working cylinder chamber 12.

[Brief description of the drawings]

FIG. 1 shows two variants of the configuration of a fluid drive device in one drawing. One variation of strong energy storage is shown to the left of the centerline, and a small, weak energy storage is shown to the right of the centerline.

[Explanation of symbols]

11: Cylinder body, 12: Working cylinder, 13: Working piston, 14: Piston rod, 16, 17: Spring mechanism, 29, 36 ... Pressure piston, 31: Annular chamber, 36 ...
Annular piston

Claims (7)

[Claims] An operating piston-cylinder mechanism in which an operating piston (13) is connected via a piston rod (14).
A working piston cylinder mechanism for actuating the drive mechanism, preferably a high pressure circuit breaker, and a pressure piston cylinder mechanism (29, 36) by which the working piston cylinder mechanism (13, 11, 12) is actuated. A spring energy storage mechanism (16, 17) having a pressure piston cylinder mechanism to which the medium is supplied, the stored energy of which is transmitted to the pressure piston cylinder mechanism (29, 36), wherein the spring mechanism is an operating piston In a fluid drive having a spring energy storage mechanism concentrically surrounding the cylinder mechanism (13, 11, 12);
The pressure piston (36) is an annular piston surrounding the cylinder body (11) of the working piston cylinder mechanism, and is driven by a spring mechanism (16, 17) in an annular chamber (31). Fluid drive, characterized in that in this case the pressure medium is in an annular chamber of an annular piston (36) located opposite the spring mechanism (16, 17). 2. The pressure piston cylinder mechanism (29,
36) The spring mechanism (16, 17) is located between the drive mechanism and a switch, preferably located at the end of the cylinder body (11). Fluid drive. 3. The pressure piston cylinder mechanism (29,
The annular chamber (31) of 36) is formed inside the outer surface of the cylinder body (11) and outside of the inner surface of the outer cylinder (29). Is a base (3) protruding in the radial direction toward the switch located at the end of the cylinder body (11).
3. Fluid drive according to claim 2, characterized in that the base is closed by (2) and that the base (32) is in sealing contact with the outer surface of the cylinder body (11). 4. A fixed end of the spring mechanism (16, 17) is fixed to an end of the cylinder body (11) away from the drive device, preferably to an end of the cylinder body (11) away from the switch.
In this case, a thrust piece (27) provided between the movable end of the spring mechanism (16, 17) and the pressure piston cylinder mechanism (29, 36) is sealed on the outer surface of the cylinder body (11) and slides. Fluid drive according to any one of the preceding claims, characterized in that the spring force of the spring mechanism (16, 17) is transmitted to the pressure piston (36). 5. Fluid according to claim 1, wherein the relaxation movement of the spring mechanism (16, 17) is directed to a drive, preferably to a high-pressure switch (15). Drive. 6. A pump / low pressure reservoir device (44) comprising:
Fluid drive according to any one of the preceding claims, characterized in that it is provided radially in the region of the pressure piston (36) of the cylinder body (11) and a switching valve is provided at the opposite end. apparatus. 7. The cylinder body is a drawn or forged product,
The fluid drive device according to any one of the preceding claims, wherein a working cylinder (12) and a bore (39-43) as a pressure medium line are machined therein.