JPH0440013Y2 - - Google Patents

Description

[Detailed Description of the Invention] [Industrial Field of Application] The present invention relates to a double-acting cylinder device, and more particularly to a double-acting cylinder device with an improved rod cover structure.

[Conventional technology]

Generally, double-acting cylinder devices are widely used as actuators. The following types of double-acting cylinder devices have been proposed. The double-acting cylinder device consists of a rod cover that forms the outer end wall of one end of the cylinder chamber and through which the piston rod passes, and a first space and a second space of the cylinder chamber that are partitioned by the piston.
The double-acting cylinder device has a space, and the rod cover is formed with a pair of supply/discharge ports communicating with the first space and the second space, respectively. . (Utility Model No. 61-4061).

[Problem that the invention attempts to solve]

However, in the double-acting cylinder device having the above structure, only a pair of supply/discharge ports are provided, so the direction of the fluid flow path pipe connected to the supply/discharge ports is limited. There was a problem. For example, if there is a blocker in the direction in which the fluid flow path pipe is taken out, use becomes difficult or impossible.

The present invention was developed in view of the above-mentioned problems, and its purpose is to provide a double-acting cylinder device that allows fluid flow pipes to be taken out from a plurality of different directions at will. .

[Means for solving problems]

In order to achieve the above object, the present invention provides a double-acting cylinder device having a first space and a second space of a cylinder chamber partitioned by a rod cover and a piston, wherein the rod cover has a plurality of cylinders having different orientations. A first outer circumferential wall surface of these outer circumferential wall surfaces is provided with a first supply/discharge port and a second supply/discharge port communicating with the first space and the second space of the cylinder chamber, respectively. At the same time, a third supply/discharge port and a fourth supply/discharge port are provided on the second outer circumferential wall surface of the outer circumferential wall surface, respectively communicating with the first space and the second space of the cylinder chamber.
An object of the present invention is to provide a double-acting cylinder device provided with a supply/discharge port.

[Effect]

According to the above-mentioned means, the first supply/discharge port and the second supply/discharge port formed on the first outer circumferential wall surface of the rod cover are set as one set, or the third supply/discharge port formed on the second outer circumferential wall surface is set as one set.
Since the supply/discharge port and the fourth supply/discharge port can be piped as a set, for example, if it is difficult to pipe the fluid flow path pipe on the first outer peripheral wall side of the former, the second outer peripheral wall of the latter Piping can be done using the third supply/discharge port and the fourth supply/discharge port on the wall surface. Conversely, if piping of the fluid flow pipe on the second outer peripheral wall side is difficult,
Piping can be performed using the first supply/discharge port and the second supply/discharge port on the first outer peripheral wall surface.

〔Example〕

Fig. 1 is a sectional view of a double-acting cylinder device according to an embodiment of the present invention, Fig. 2 is a sectional view taken along the - line in Fig. 1, Fig. 3 is a sectional view taken along the - line in Fig. 1, and Fig. 4 is a sectional view taken along the - line in Fig. The figure is a sectional view showing the state of piping.

The double-acting cylinder device of this embodiment has a double cylinder tube structure, and an inner cylinder tube 2 is provided inside an outer cylinder tube 1. A piston 3 is provided within the inner cylinder tube 2 so as to be slidable in the axial direction of the inner cylinder tube 2. The inner diameter of the outer cylinder tube 1 is larger than the outer diameter of the inner cylinder tube 2, and a cylindrical first flow path 4 for supplying and discharging fluid is formed between the two.

Furthermore, the inner ends of a head cover 5 and a rod cover 6 are fitted to both ends of the inner cylinder tube 2. The cylinder chamber 7 has one outer end wall formed by a rod cover 6 and the other end outer end wall formed by a head cover 5.

Similar to the inner cylinder tube 2, a head cover 5 and a rod cover 6 are fitted to both ends of the outer cylinder tube 1. Specifically, the fitted portions are caulked so that the fitted portions are fixed and the inside of the outer cylinder tube 1 is kept airtight.

Further, an O-ring 8 is provided at a portion where the inner cylinder tube 2 is fitted into the rod cover 6, and a cylinder chamber 7 constituted by the inner cylinder tube 2, the piston 3, and the rod cover 6 is provided.
The airtightness of the first space 7a is maintained. Furthermore, the airtightness of the first space 7a of the cylinder chamber 7 is as follows.
It is also held by a piston packing 9a fitted on the outer periphery of the piston 3 and a rod packing 11 provided on the rod cover 6 at the portion through which the piston rod 10 passes.

A through hole 2a is formed at the end of the inner cylinder tube 2 on the head cover 5 side. This through hole 2a is connected to the head cover 5 in the cylinder chamber 7.
The side second space 7b and the cylindrical first flow path 4 are communicated with each other. A piston packing 9a is fitted in the piston 3 in line with the piston packing 9a to prevent fluid such as compressed air in the second space 7b from leaking to the first space 7a.

A second flow passage 61 extending in the axial direction of the rod cover 6 and a flow passage communicating between the second flow passage 61 and the first flow passage 4 are provided on the inner end side of the rod cover 6 through which the piston rod 10 passes. 62 are provided. The end of the second flow passage 61 of the rod cover 6 on the first space 7a side is connected to the sealing member 61.
Since it is closed by a, it does not communicate with the first space 7a. However, the second flow passage 61 communicates with the second space 7b of the cylinder chamber 7 via the flow passage 62, the first flow passage 4, and the through hole 2a.

Furthermore, a third flow passage 63 is provided on the inner end side of the rod cover 6, extending in the axial direction of the rod cover 6 and communicating with the inside of the first space 7a.

Further, a fourth flow passage 64 is formed in the rod cover 6 so as to extend perpendicularly from the second flow passage 61, and a fifth flow passage 65 is formed in the rod cover 6 so as to extend perpendicularly from the third flow passage 63. There is.
Further, as shown in FIG. 2, the fourth flow passage 64 to the sixth flow passage 66 and the fifth flow passage 65 to the seventh flow passage 67 are formed in the rod cover 6 so as to extend in the same direction of the outer peripheral wall. There is.

Here, as shown in FIG. 2, the rod cover 6 has a plurality of outer circumferential wall surfaces 68 having different directions. That is, the portion having the plurality of outer circumferential wall surfaces 68 is formed into a quadrangular prism shape in this embodiment.

The first outer peripheral wall surface 68 among the plurality of outer peripheral wall surfaces 68
A is formed with a first supply/discharge port 69 and a second supply/discharge port 70 for supplying and discharging compressed fluid. These first supply/discharge port 69 and second supply/discharge port 70 have a female threaded portion S and an O-ring groove O, and the female threaded portion S of the former is provided with a seal shown in FIGS. 2 and 4. Stopper T
It can be closed by screwing on the O-ring groove O, and the O-ring can be fitted into the O-ring groove O. Further, the first supply/discharge port 69 is connected to the cylinder chamber 7 through the seventh flow passage 67, the fifth flow passage 65, and the third flow passage 63.
It communicates with the first space 7a of. On the other hand, the second supply/discharge port 70 is connected to the sixth flow path 66 and the fourth flow path 6.
4, second flow path 61, flow path 62, first flow path 4,
The second space 7 of the cylinder chamber 7 via the through hole 2a
It communicates with b.

Next, a second outer circumferential wall surface 68b, which is one of the plurality of outer circumferential wall surfaces 68 in the rod cover 6 and is orthogonally adjacent to the first outer circumferential wall surface 68a, has a third supply/discharge port 71 and a fourth supply/discharge port. 72 is formed. The third supply/discharge port 71 and the fourth supply/discharge port 72 each have a female thread portion S and an O-ring groove O similarly to the first supply/discharge port 69 and the second supply/discharge port 70. Also,
The third supply/discharge port 71 is the fifth flow path 65 and the third flow path 6
It communicates with the first space 7a of the cylinder chamber 7 through the order of No. 3. In contrast to the third supply/discharge port 71, the fourth supply/discharge port 72 is connected to the cylinder chamber 7 through the fourth flow passage 64, the second flow passage 61, the flow passage 62, the first flow passage 4, and the through hole 2a. It communicates with the second space 7b.

In this way, the first outer peripheral wall surface 6 of the rod cover 6
A first supply/discharge port 69 communicating with the first space 7a of the cylinder chamber 7 and a second supply/discharge port 70 communicating with the second space 7b are formed in the rod cover 8a. 2. The cylinder chamber 7 is provided on the outer peripheral wall surface 68b.
Since a third supply/discharge port 71 communicating with the first space 7a and a fourth supply/discharge port 72 communicating with the second space 7b are formed, for example, the first outer peripheral wall surface 68a side of the former If piping of the fluid flow path pipe is difficult, piping can be performed using the third supply/discharge port 71 and fourth supply/discharge port 72 of the latter second outer circumferential wall surface 68b as a set. On the contrary, if it is difficult to pipe the fluid flow path on the second outer peripheral wall surface 68b side, the first supply/discharge port 69 of the first outer peripheral wall surface 68a
and the second supply/discharge port 70 can be used as a set for piping. Furthermore, in special cases, piping that uses the first supply/discharge port 69 on the first outer circumferential wall surface 68a and the fourth supply/discharge port 72 on the second outer circumferential wall surface 68b as a set, or the second supply/discharge port 70 and the third supply/discharge port 72 may be used as a set. Piping using the supply/discharge port 71 as a set is also possible.

In the case of each of the above-mentioned piping, the unused supply/discharge ports are closed by screwing the sealing plug T onto the female threaded portion S as shown in FIGS. 2 and 4.

Here, stepped portions 3 are provided on both end surfaces of the piston 3.
a and 3b are provided respectively, and the piston 3
The structure is such that when the piston 6 comes into contact with the inner end surface of the head cover 5 or the rod cover 6, the end surface of the piston 6 is prevented from coming into close contact with the inner end surface and becoming difficult to separate.

Further, a male threaded portion 10a is formed at the outer end of the piston rod 10 provided on the piston 6, and is configured to be connected to an external load (not shown) or the like.

Furthermore, two cylinder mounting holes 73 are formed through the outer end of the rod cover 6 in the transverse direction thereof. This cylinder mounting hole 73
The structure is such that the double-acting cylinder device can be easily attached to a predetermined mechanical device (not shown) by inserting a mounting bolt (not shown) into the double-acting cylinder device. Further, as shown in FIG. 3, the inner diameter of both opening ends of this cylinder mounting hole 73 is formed to be larger than the inner diameter of the middle part thereof, so that when the bolt is inserted, the head of the bolt is inserted into the rod cover 6. The structure is such that the head does not protrude from above the outer circumferential surface of the rod cover 6, and even when the mounting bolt is inserted from either of the opening sides of the cylinder mounting hole 73, its head does not protrude from above the outer circumferential surface of the rod cover 6. There is.

Next, the operation of this embodiment will be explained.

First, the case where piping for supplying and discharging compressed fluid is provided to the double-acting cylinder device will be described. An example of this piping is shown in FIG. 4. The example of the piping shown in FIG. 4 is the third supply and discharge port 7 of the second outer peripheral wall surface 68b.
1 and a fourth supply/discharge port 72. These third supply and discharge ports 71 and fourth supply and discharge ports 72
is connected to the supply/discharge path _B1 of the mounting base B.
Wetting of the compressed fluid from these connection points is appropriately prevented by the O-rings R fitted in the O-ring grooves O of the third supply/discharge port 71 and the fourth supply/discharge port 72.

On the other hand, the first supply/discharge port 69 and the second supply/discharge port 70 are closed by a sealing plug T and a gasket G screwed onto the female threaded portion S thereof.

Further, the double-acting cylinder device itself is attached to the mounting base B by a fixing member such as a mounting bolt (not shown) inserted into the cylinder mounting hole 73 of the rod cover 6.

In the example of the piping shown in FIG. 4 and in the state shown in FIG. 1, the piston 3 moves to the right in FIG. 1, and the piston rod 10 is in the retracted position. By causing compressed air to flow into the fourth supply/exhaust port 72 communicating with the second space 7b, the piston 3 is moved to the left in FIG. Accordingly, the piston rod 10 is projected to the outside of the double-acting cylinder device, thereby performing a predetermined work against an external load (not shown).

On the other hand, when compressed air flows into the third supply/discharge port 71 communicating with the first space 7a of the cylinder chamber 7, the piston 3 is moved to the right in FIG. Accordingly, the piston rod 10 is drawn into the double-acting cylinder device.

In this way, the third supply/discharge port 71 and the fourth supply/discharge port 72
By flowing compressed air into either one of the two piston rods, the piston rod 10 is caused to perform a predetermined reciprocating motion, thereby driving an external load (not shown) connected to the piston rod 10.

According to this embodiment, the following effects can be obtained.

(1) The portion of the rod cover 6 having a plurality of planar outer circumferential surfaces 68 in different directions is formed into a prismatic shape, and the cylinder device can be mounted in a predetermined manner using the prismatic portion of the rod cover 6. By doing this, you can achieve a stable and firm installation.

(2) The first outer peripheral wall surface 68a where the first supply/discharge port 69 and the second supply/discharge port 70 are formed, and the third supply/discharge port 7
For example, in the case of a rectangular rod cover 6, the cylinder device can be rotated 90 degrees in either direction if it is formed so that the second outer circumferential wall surface 68b on which the first and fourth supply/discharge ports 72 are formed are orthogonally adjacent to each other. Just by rotating it, you can run the piping in any desired direction among the four directions.

(3) By drilling the cylinder mounting hole 73 in the rod cover 6, the cylinder device can be easily mounted using the rod cover 6, and there is no need to use a special cylinder mounting bracket.

(4) O-ring grooves are provided in the first supply/discharge port 69, the second supply/discharge port 70, the third supply/discharge port 71, and the fourth supply/discharge port 72, respectively.
By providing an O-ring R around the O-ring groove O and fitting an O-ring R into the O-ring groove O, airtightness, that is, leak prevention performance, can be achieved at the connection points between each of these supply/discharge ports and the predetermined fluid piping connected to them. can be increased.

[Effect of idea]

According to the present invention, the cylinder chamber has a rod cover which is an outer end wall on one end side of the cylinder chamber and through which the piston rod passes, and a first space and a second space of the cylinder chamber which are partitioned by the piston. In the double-acting cylinder device, the rod cover has a plurality of planar outer peripheral wall surfaces in different directions,
Further, a first supply/discharge port communicating with the first space and a second supply/discharge port communicating with the second space are formed on a first outer circumferential wall surface of the outer circumferential wall surfaces thereof, and a second supply/discharge port communicating with the second space is formed. A double-acting cylinder structure in which a third supply/discharge port communicating with the first space and a fourth supply/discharge port communicating with the second space are formed on the second outer circumferential wall surface of the outer circumferential wall surface. By doing so, the following unique effects can be obtained.

(1) A first supply/discharge port and a second supply/discharge port formed on the first outer circumferential wall surface of the rod cover are set as a pair, or a second supply/discharge port formed on the second outer circumferential wall surface facing in a different direction from the first outer circumferential wall surface. Since the 3rd supply/discharge port and the 4th supply/discharge port can be piped as a set, the pipes can be taken out in two directions: the first outer peripheral wall side and the second wall side.
The direction can be arbitrarily selected. Therefore, piping can be installed even when there is a shield on either the first outer peripheral wall side or the second outer peripheral wall side, so the degree of freedom in piping can be greatly increased.

(2) According to (1) above, it can be said that it is extremely suitable not only for normal use but also for use in a manifold of a double-acting cylinder.

(3) The first outer wall surface where the first supply/discharge port and the second supply/discharge port are formed and the second outer circumferential wall surface where the third supply/discharge port and the fourth supply/discharge port are formed are planes. Moreover, since the double-acting cylinder device is directly mounted on the rod cover itself, the cylinder device can be placed in a stable state on the mounting base, for example, when piping is carried out with the first outer peripheral wall surface or the second outer peripheral wall surface in contact with the mounting base. It can be securely installed and held.

[Brief explanation of the drawing]

Fig. 1 is a sectional view of a double-acting cylinder device according to an embodiment of the present invention, Fig. 2 is a sectional view taken along the - line in Fig. 1, Fig. 3 is a sectional view taken along the - line in Fig. 1, and Fig. 4 is a sectional view taken along the - line in Fig. The figure is a sectional view showing the state of piping. DESCRIPTION OF SYMBOLS 1... Outer cylinder tube, 2... Inner cylinder tube, 2a... Through hole, 3... Piston, 3a, 3b... Step portion, 4... First flow path,
5... Head cover, 6... Rod cover, 7...
...Cylinder chamber, 7a...First space, 7b...Second
Space, 8b...O ring, 9a, 9b...Piston packing, 10...Piston rod, 10a
... Male thread part, 11 ... Rod packing, 61
...Second flow path, 61a...Seal member, 62...
...Flow path, 63...Third flow path, 64...Fourth flow path, 65...Fifth flow path, 66...Sixth flow path,
67...Seventh flow path, 68...Outer peripheral wall surface, 68a
...First outer peripheral wall surface, 68b... Second outer peripheral wall surface, 6
9...First supply/discharge port, 70...Second supply/discharge port, 71...
...Third supply/discharge port, 72...Fourth supply/discharge port, 73...Cylinder mounting hole, B...Mounting base, B ₁ ...Support/discharge path, O...O-ring groove, R...O-ring , S...
...Female thread part, T...Sealing plug.

Claims (1)

[Claims for Utility Model Registration] (1) A rod cover that forms the outer end wall of one end of the cylinder chamber and through which the piston rod passes, and the first space and second space of the cylinder chamber that are partitioned by the piston. The rod cover has a plurality of planar outer circumferential wall surfaces having different directions, and a first outer circumferential wall surface of these outer circumferential wall surfaces includes the first space. A first supply/discharge port communicating with the first space and a second supply/discharge port communicating with the second space are formed on the second outer peripheral wall surface of the outer peripheral wall surface. A double-acting cylinder device characterized in that a third supply/discharge port communicating with the second space and a fourth supply/discharge port communicating with the second space are formed. (2) The double-acting cylinder according to claim 1, wherein the rod cover has a prismatic portion having a plurality of planar outer circumferential walls facing different directions. Device. (3) The double-acting cylinder device according to claim 1 or 2, wherein the first outer circumferential wall surface and the second outer circumferential wall surface are orthogonally adjacent to each other. (4) The double-acting cylinder device according to claim 1 or 2, wherein the rod cover is provided with a cylinder mounting hole. (5) 1st supply/discharge port, 2nd supply/discharge port, 3rd supply/discharge port, and 4th supply/discharge port
The double-acting cylinder device according to claim 1 or 2, wherein the supply/discharge port is formed so as to be closable. (6) 1st supply/discharge port, 2nd supply/discharge port, 3rd supply/discharge port, and 4th supply/discharge port
The double-acting cylinder device according to claim 1 or 2, wherein each of the supply and discharge ports is provided with an O-ring groove.