JP4008544B2 - Fluid drive device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a fluid drive apparatus according to the premise of claim 1.
[0002]
[Prior art]
Such a driving device is known, for example, from EP 0 451 724 B1.
[0003]
In this drive device, the energy source is a disc spring device, and this spring force acts on a piston sliding in the pressure cylinder. A pressure medium chamber is provided on the opposite side of the disk spring. The drive piston for the switch is located beside the pressure cylinder. Therefore, this device requires a relatively large space.
[0004]
In the drive device disclosed in EP 0 158 054 B1, the spring device acts on the piston via a connecting rod. And since the drive piston rod is contained in this piston, a relatively small space is required. The pressure cylinder, drive piston rod, working cylinder and spring device are on one axis.
[0005]
[Problems to be solved by the invention]
The present invention is an apparatus described at the outset that improves the utilization of space.
[0006]
[Means for Solving the Problems]
This object is achieved by the features of claim 1.
[0007]
DETAILED DESCRIPTION OF THE INVENTION
In the present invention, the container device comprises at least two axial bores, in each of these bores has a pressure piston slidably, thrust ring on one end face of the pressure piston Abuts, and the pressure medium acts on the other end face.
[0008]
Preferably, there are three axial bores in which the pressure piston slides.
[0009]
In the first example, the container device has an annular container body concentrically surrounding the operating cylinder.
[0010]
For the purpose of fixing, the operation on the cylinder housing is formed a flange rim engages the recess on the container body, thus the container body is pressed against the flange rim by the energy storage spring.
[0011]
In this case, a pump is incorporated in the container body to pressurize the pressure medium.
[0012]
In another example of the present invention, the container device is composed of a plurality of containers corresponding to a plurality of bores. If there are three bores, three containers are provided, which are equally distributed around the working cylinder housing and fixed.
[0013]
The operating cylinder housing can be hexagonal, and the pressure medium components can be fixed to the hexagonal surface located between the containers.
[0014]
"Action / Effect"
With the configuration of the present invention, space can be effectively utilized.
[0015]
The spring acts on the pressure piston without going through the rod. Therefore, no seal is required in the area of the tie rod. Energy is supplied to the working piston over a short distance. The pressure piston is located substantially above the working piston.
[0016]
Furthermore, assembly and maintenance are easy. Because the container is modular, it can be easily replaced. The working cylinder housing is constructed from pultruded or forged material, and the individual containers of the pressure piston can also be constructed from aluminum semi-finished products.
[0017]
Further preferred configurations of the invention result from the subclaims.
[0018]
"Example"
The invention and further preferred configurations and improvements will be described in detail with reference to the drawings. Two embodiments are described therein.
[0019]
The fluid drive 10 has a cylinder 11 for an operating cylinder 12. An operating piston (also referred to as a drive piston) 13 is guided in the cylinder. A drive piston rod 14 is combined with the working piston 13 to actuate the high pressure breaker.
[0020]
Damping members 16 and 17 are located at the start and end points of operation of the drive or actuating piston 13. A region 18 enters the damping member 16 and a region 19 larger in diameter than the drive piston rod 14 enters the damping member 17 and dumps the working piston 13 at the start and end points of its movement.
[0021]
The cylinder 11 is combined with a large-diameter container body 20, and the body has three bores 21 (only one of which is visible). These three bores are equally distributed around the central axis MM of the fluid drive.
[0022]
Retaining ring 22, located at the free end of the operating cylinder housing 11 is fixed to the operating cylinder housing 11.
[0023]
The working cylinder housing 11 is surrounded by a thrust ring 23. The thrust ring 23 is guided so as to be movable on the outer surface of the operating cylinder housing 11.
[0024]
For example, an energy storage spring 24 is provided between the thrust ring 23 and the retaining ring 22 corresponding to the spring device of the fluid drive disclosed in EP 0 451 724 B1.
[0025]
A pressure piston 25 which is moved in the direction of arrow D by the energy storage spring 24 is incorporated in the bore 21. A pressure medium chamber 26 is provided on the opposite side of the thrust ring 23 of each pressure piston 25. A pressure medium is supplied into the pressure medium chamber 26 by a pump 27 driven by a motor 28 via a line 29, an operating cylinder 12, and lines 30 and 31. Thus, the pressure piston 25 is pushed in the direction opposite to the arrow D and biases the energy storage spring 24.
[0026]
Lines 29, 30 and 31 are made in the container 20. The line 30 is connected to the P port of the switching valve 32 having a switching slide 33. The switching slide 33 is driven by the solenoids A and E in the switch-off and switch-on directions, respectively.
[0027]
The pressure medium is supplied to the low-pressure tank 36 through the filter 35 via the line 34 connected to the T port of the switching valve 32. From here, the pressure medium is supplied to the working piston and the working cylinder 12 by the pump 27.
[0028]
The line 30 is connected to a line 38 connected to the P port of the switching valve 32. The Z port of the switching valve is connected via a line 39 to a chamber located on the large piston surface side of the cylinder 12.
[0029]
FIG. 1 shows that the switch is in a switch-off state.
[0030]
To switch on the switch 15, the pressure medium is sent to both sides of the working piston 13 via the pump 27 and line 39, the energy storage spring , with the switching valve 32 in place. In this case, since the area of the side to which the piston rod 14 of the working piston 13 is connected is smaller than the opposite side, the working piston 13 and the piston rod 14 are moved upward to close the switch 15.
[0031]
In order to turn off the switch 15, the low pressure tank 36 is connected between the lines 39 and 34 via the switching valve 32. Thus, the pressure on the side having the large piston area is reduced. As a result, the pressure medium having the smaller piston area places the working piston in the off position.
[0032]
The pressure medium is provided by a pump and an energy source. This energy source is formed by an energy storage spring 24 and three pressure pistons 25 in the bore 21. Then, the pressure medium in the pressure medium chamber 26 operates the working piston as described above.
[0033]
FIG. 2 is a cross-sectional view showing details of the fluid drive device without a spring.
[0034]
The operating cylinder housing 11 includes an operating cylinder 12 and an operation guided in the operating cylinder 12 and a drive piston 13.
[0035]
A retaining ring 22 is fixed on the working cylinder housing 11 by a threaded bush 40 having a step 41. The step portion 42 on the holding ring 22 is in contact with the step 41. A threaded bush 40 is screwed onto the outer thread 43 of the working cylinder housing 11.
[0036]
The working cylinder 12 is closed by a closing member 44 having a blind hole 45 that is part of the working cylinder housing 11. A plurality of lateral bores 46, 47 are opened in the closure member 44. In these bores 46, 47, lines corresponding to lines 39 and 29 (indicated by reference numerals 48 and 49 in this figure) parallel to the working cylinder 12 are opened.
[0037]
A container body or container 50 is arranged around the opposite end of the working cylinder housing 11. The container body 50 corresponds to a container housing 20 having a bore 21 in which the pressure piston 25 is incorporated, and the container body 20. There is a thrust ring 23 between the holding piece 22 and the container body 50, and an energy storage spring 24 (not shown in FIG. 2) between the holding piece 22 and the thrust ring 23.
[0038]
End of the working cylinder housing 11, there is a rim 51 at the top, the top of the figure, is engaged in the stepped portion 52 on Kontenabo di 50. When all the members are attached and assembled, the energy storage spring acts on the pressure piston 25 and the pressure medium via the thrust ring 23. Thus, the stepped portion of the housing abuts on the flange rim 51, and the container body 50 is held at a predetermined position.
[0039]
The pressure medium chamber 26 is connected to the bore 54 of the working cylinder housing 11 via the bore 53. These bore cores are aligned and extend radially with respect to the working cylinder housing 11 and open into the working cylinder 12. Line 48 is connected via a transverse bore 55 to a bore 56 that leads to the Z port of switching valve 32. The other bores leading to the P and T ports are not shown in FIG.
[0040]
A cover 57 in which the filter 35 (not shown) is accommodated is attached to the upper surface of the container body 50.
[0041]
On the piston rod side, the operating cylinder 12 is closed by another closing member 58. The piston rod protrudes outside through the closing member 58 and engages with the seal 59 in the cover 57.
[0042]
The fluid drive device 70 shown in FIG. 3 has an operation cylinder housing 71, and an operation cylinder 72 having an operation piston 73 therein is incorporated in the operation cylinder housing 71. The configuration and action of the working piston 73 correspond to that of the working piston 13.
[0043]
On the side away from the switch, ie at the bottom, the working cylinder housing 71 is closed by a bush 74 fixed by a cover 75.
[0044]
In the region of the bushing 74, i.e. at the end remote from the switch, the working cylinder housing 71 has a step 76. As a result, the reduced diameter portion 77 is formed. An external thread 78 is formed outside the reduced diameter portion 77, and a cylindrical collar 79 of the sleeve 80 is screwed onto the external thread 78.
[0045]
The sleeve 80 has two grooves 81 and 82 spaced apart from each other, and force transmission members 83 and 83a are engaged with these grooves, respectively. The force transmission members 83 and 83a cooperate with the thrust ring 84 and 84a. That is, the force transmission member 83 has a bead 85 protruding inward in the radial direction, and this engages with the slot and the groove 81. Moreover, it has the conical surface 86 and the force transmission member 84 acts on this.
[0046]
For assembly reasons, the force transmitting member 83 is divided, in particular, divided into two halved rings, forming one ring in the assembled state.
[0047]
The conical surfaces 87 and 86 are arranged such that a force transmission member 84 (also called a thrust ring) partially surrounds the force transmission member 83 concentrically.
[0048]
The thrust ring 84 surrounds the outer surface of the sleeve 80. The same effect is achieved using the members 83a, 84a.
[0049]
On the working cylinder housing, in particular the switch-side end region, the operation cylinder housing 71 has a region 88, a hexagon having six surfaces 89,90,91,92,93 and 94 on the outside ing. In FIG. 3, surface 92 is seen. Containers 95, 97 and 99 are secured to surfaces 90, 92 and 94 by screw connections 96, 98 and 100, respectively. The containers 95, 97 and 99 have the same configuration.
[0050]
Therefore, only the container 95 will be described with reference to FIG.
[0051]
The container 95 has a bottom 101 and a cylindrical wall 102 on the inside, and a rectangular cup on the outside (as seen in FIG. 4).
[0052]
A bore 103 in which the pressure piston 104 slides is formed inside the wall.
[0053]
The side of the container 95 away from the switch is sealed with a cover 105 and closed. The cover 105 has a bore 106, and a piston rod 107 integrally connected to the pressure piston 104 projects from the bore 106.
[0054]
The working cylinder housing 71 is surrounded by a thrust member 108 having a radial stop surface 109. A disk spring device is between the thrust ring 84 and the thrust member 108. The thrust member 108 is in contact with the piston rod 107. Therefore, when the pressure piston is pushed out of the container 95, the disc spring device is biased through the thrust member.
[0055]
The thrust member 108 may be a ring, or may be formed integrally with an arm that abuts against the piston rods 107 of all three containers around the annular portion.
[0056]
The three containers 95, 97 and 99 are arranged in a star shape on the area 88 of the working cylinder housing 71. Then, other parts for the pressure medium may be integrally provided on the three surfaces 91, 93 and 95 between these containers. For example, the switching valve 110 is fixed on the side surface 91, the travel detector 111 is fixed on the side surface 93, and the low-pressure tank / pump device 112 is fixed on the surface 89 (this is merely an example).
[0057]
The operating cylinder 72 is closed by a bush 115 on the switch side, and a piston rod 73a of the working piston 73 protrudes through the bush 115.
[0058]
Further, a closing cover 116 that functions as a low-pressure tank is provided.
[0059]
Similarly, longitudinal and lateral bores 117 and 118 functioning as pressure medium lines are provided in the working cylinder housing 71.
[0060]
Details of the thrust ring 84 and the force transmission member 83 are described in detail in DE 19637048 (Mp. NO 96/663).
[0061]
【The invention's effect】
In this way, the configuration of the fluid drive device is simplified. The individual pressure pistons are housed in replaceable containers, and the arrangement shown in FIGS. 3 and 4 is simple and modular, and is very easy to assemble and maintain.
[Brief description of the drawings]
FIG. 1 is an explanatory diagram of a fluid drive device.
FIG. 2 is a cross-sectional view of the fluid drive device shown in FIG.
FIG. 3 is a cross-sectional view of another example of the present invention.
4 is a plan view seen in the direction of arrow IV in FIG. 3. FIG.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 11 ... Working cylinder housing , 12 ... Working cylinder, 13 ... Working piston, 15 ... Switch, 20 ... Container body , 21 ... Axial bore, 22 ... Retaining ring, 23 ... Movable thrust ring , 24 ... Energy storage spring, 25 ... Pressure piston, 32 ... switching valve.

Claims (11)

In particular, a fluid drive for a high-pressure circuit breaker having an operating cylinder (12) in which an operating piston (13) moves and an energy storage comprising an energy storage spring (24) for pressurizing the pressure medium in the container device The energy storage spring (24) has one end supported by the operating cylinder housing (11) and the other end is moved by a movable thrust ring (23) surrounding the operating cylinder housing (11). In a fluid drive adapted to be
The container device surrounds the working cylinder housing (11) and has at least two axial bores (21) in which a pressure piston (25) can slide. It is provided to, on one end face of the pressure piston against the thrust ring (23) abuts, fluid drive device, characterized in that the pressure medium is adapted to act on the other end face. The fluid driving device according to claim 1, wherein the pressure piston (25) is provided in each of three bores. The container device, the fluid drive device according to claim 1 or 2, characterized in that it has an annular container body which surrounds the working cylinder (12) concentrically (20). The end of the working cylinder housing (11) is formed a flange rim (51) is engaged with the recess (52) on the container body (50), thus the container body (50) is the energy storage 4. The fluid drive device according to claim 1 , wherein the fluid drive device is pressed against the flange rim by a spring . 5. The fluid drive device according to claim 1 , wherein a pump (27) is incorporated in the container body (50) in order to pressurize the pressure medium . A switching valve (32) is fixed to the outside of the container body (50), and the pump is disposed on both sides of the bore (21), the switching valve (32) and the piston (13) of the working cylinder (12) on the working cylinder housing (11). The fluid drive device according to claim 6 , wherein the fluid drive device is connected via a bore provided in the container body (50) . Cover (57), according to any one of claims 1 to 6, characterized in that it is fixed on the substantially same surface of the container body and the free end of the operating cylinder housing (11) (50) Fluid drive device. The container device comprises a plurality of containers ( 95, 97, 99 ) corresponding to a plurality of bores (13), each of which has a bore and is equally distributed around the operating cylinder housing (71). The fluid drive device according to claim 1 , wherein the fluid drive device is fixed. 9. A fluid drive as claimed in claim 8, characterized in that the contact surface between the containers ( 95, 97, 99 ) is flat and extends axially on the working cylinder housing (71). Operation cylinder housing (71), the which forms a hexagon in the region of the container (95,97,99), parts for the pressure medium, for example the switching valve, the low-pressure tank or pump, working cylinder housing (71) The fluid drive device according to claim 8 or 9, wherein the fluid drive device is fixed to a hexagonal surface located between the containers ( 95, 97, 99 ). The fluid drive device according to any one of claims 1 to 10, wherein the energy storage spring (24) is constituted by a disc spring.

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