KR20220004915A - Hydraulic Pressure Booster Cylinder) - Google Patents

Abstract

The present invention relates to a hydraulic pressure booster cylinder for maximizing the advantages and functions of pneumatic and hydraulic cylinders. A check valve (6) for selectively supplying pneumatic pressure is provided in a pneumatic portion (A) of the tip of a first cylinder hole (11). At low load, a low-pressure stroke is performed. In the low-pressure stroke, the pneumatic pressure is supplied to a pneumatic portion (C) so that as a second piston (3) is moved toward a bore (13), a third piston (5) is accordingly moved, and thus a piston rod (5a) is extended to the outside. At high load, a high-pressure stroke is performed. In the high-pressure stroke, the air in the pneumatic portion (C) is exhausted by the operation of the check valve (6) resulting from the movement of a slide piston (8), and pneumatic pressure is supplied to the pneumatic portion (A) so that as a first piston (2) is moved toward the bore (13), a trunk piston (2a) is moved toward the third piston (5) by passing through the bore (13) while maintaining an airtight state with the bore (13). Therefore, the hydraulic pressure booster cylinder is quickly operated with the low-pressure stroke at low load, and automatically switches to the high-pressure stroke at high load.

Description

Hydraulic Pressure Booster Cylinder}

The present invention relates to a hydraulic pressure boosting cylinder that maximizes the advantages and functions of a pneumatic cylinder and a hydraulic cylinder. .

As is well known, as the operation of the cylinder is necessary, it is necessary to operate at a low load at the first start of operation and work at high pressure with a small stroke for a high load. It gave me great strength.

The present invention has already been devised to facilitate the above-described operation, and the low load is operated quickly, and the high load is automatically switched to the high pressure stroke to produce the required output.

In order to achieve the above object, the present invention provides a first cylinder hole having a relatively large inner diameter, a first cylinder hole, and a second cylinder hole having a smaller or equal inner diameter, and a first cylinder hole, a second a second piston having a cylinder case in which a bore having an inner diameter smaller than that of the cylinder hole communicates with each other and a trunk piston selectively inserted into the bore, and is movably embedded in the first cylinder hole and through which the trunk piston passes; a spring disposed between the first piston and the second piston to elastically support the second piston; The third piston and the slide piston which are equipped with a piston rod protruding to the outside and are movably built in the second cylinder hole are arranged at both ends of the hydraulic pressure boosting cylinder and are respectively connected to the pneumatic line; In the hydraulic pressure boosting cylinder divided into a pneumatic part between the first and second pistons, a pneumatic part configured on the opposite side of the pneumatic part in the slide piston, and a hydraulic part having a hydraulic oil replenisher between the second and third pistons, the A check valve for selectively supplying pneumatic pressure to the pneumatic part of the second piston is provided, but in the general case of a low load, the pneumatic pressure supply to the pneumatic part is blocked by the check valve and the slide piston is in contact with the check valve. In , air pressure is supplied to the pneumatic part by the check valve, and as the first piston moves toward the bore, the trunk piston penetrates while maintaining an airtight state with the bore and performs a high-pressure stroke to move toward the third piston. is made of

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a longitudinal sectional view of a hydraulic pressure intensifying cylinder according to the present invention, showing an embodiment of the present invention. It consists of a number of parts built into the case.

The cylinder case (1) has a first cylinder hole (11) having a relatively large inner diameter, a second cylinder hole (12) having an inner diameter smaller than or equal to that of the first cylinder hole (11), and a first cylinder hole (11). ) and the second cylinder hole 12 positioned between the second cylinder hole 12 and a bore 13 having an inner diameter smaller than that of the second cylinder hole 12 communicates with each other, and the second cylinder hole 12 is equipped with a slide piston 8 The openings to the outside of the first cylinder hole 11 and the second cylinder hole 12 are sealed through the cylinder caps 15 and 22, respectively, and each of the cylinder caps 15 and 22 Pneumatic lines 1a, 1b, 1c, 1d, 1e, 1f, 1g are formed on It is composed of four check valves (6), the first piston (2) having a trunk piston (2a) selectively inserted into the bore (13) is movably embedded in the first cylinder hole (11), and the second piston (2) (3) is movably embedded in the first cylinder hole (11), the trunk piston (2a) is penetrated, and the spring (4) is disposed between the first piston (2) and the second piston (3). The second piston (3) is elastically supported, and the third piston (5) has a piston rod (5a) protruding to the outside and is movably embedded in the second cylinder hole (12), inside the second cylinder hole (12) The slide piston 8, the third piston 5, and the slide piston 8 that move according to the movement and penetrate the piston rod 5a are elastically supported by a spring 9.

In addition, the check valve 6 is installed in the cylinder cap 22 on the outside of the third cylinder hole 21, so that the pneumatic line 1g inside the check valve 6 is connected to the pneumatic line 1e on one side and The other side is connected to the pneumatic line (1c).

The pneumatic part (D) is communicated to the outside through the pneumatic line (1d) inside the piston rod (5a).

In addition, in the check valve 6, when the slide piston 8 is in close contact with the check valve 6 by the reaction force of the spring 9, the spring 10 is compressed, and the check valve 6 moves to Compressed air is to act on the pneumatic portion (A) through the pneumatic line (1g) and the pneumatic line (1e).

2 is a view showing an embodiment of the check valve 6 shown in FIG. 1. According to this, the check valve 6 according to the present invention is composed of a bore 23 and a spring 10 having a narrow inner diameter. It is composed of a check valve 6 and normally the check valve 6 is inserted into the bore 23 to block the compressed air of the pneumatic line 1c from going to the pneumatic line 1e, but the compressed air of the pneumatic line 1e It is made to serve to make it possible to go to the pneumatic line 1c.

In addition, the pneumatic line (1e) is in communication with the pneumatic line (1f) communicating with the pneumatic portion (A).

Therefore, when the slide piston 8 as shown in FIG. 2 does not push the check valve 6, the check valve 6 is inserted into the bore 23 due to the elasticity of the spring 10 so that the compressed air of the pneumatic line 1c It blocks movement to the pneumatic line 1e, and conversely, the spring 10 is contracted by the check valve 6 to allow the compressed air of the pneumatic line 1e to move to the pneumatic line 1c.

3 is a view showing the operating state during the low pressure stroke of the hydraulic pressure boosting cylinder according to the present invention, and the operating state during the low pressure stroke of the hydraulic pressure increasing cylinder will be described in detail.

The internal pressure of the pneumatic portion (C) increases through the compressed air supplied from the outside through the pneumatic line (1a) and the pneumatic lines (1b, 2c).

As such, when the internal pressure in the pneumatic part (C) increases, the second piston (3) moves toward the bore (13), so that the hydraulic medium stored in the hydraulic storage part (B1) is transferred to the hydraulic part (B) through the bore (13). It is moved so that the third piston 5 is extended to the outside.

Accordingly, the piston rod 5a of the third piston 5 is extended to the outside.

Figure 4 is a slide piston (8) to the check valve (6) by the elasticity of the spring (9) when the movement of the piston rod (5a) is stopped due to a high external load during the low pressure stroke of the hydraulic pressure boosting cylinder according to the present invention. shows moving.

5 shows that the slide piston 8 is pushing the check valve 6 by the elasticity of the spring 9. As shown in FIG.

At this time, the check valve 6 is separated from the bore 23 by the slide piston 8 as shown in FIG. 6 and the pneumatic line 1g and the pneumatic line 1c communicate with each other, and the air in the pneumatic part c is exhausted. .

Therefore, when the compressed air of the pneumatic line (1c) flows into the pneumatic part (A) through the pneumatic line (1g) and the pneumatic line (1f), the internal pressure of the pneumatic part (A) rises to move the first piston (2) and Since the trunk piston 2a connected to the first piston 2 moves toward the third piston 5 through the bore 13 while maintaining the airtight state with the bore 13, the trunk piston 2a moves toward the hydraulic part ( As it protrudes toward B), the pressure of the hydraulic part (B) increases and the third piston (5) is elongated.

Accordingly, the piston rod 5a of the third piston 5 is continuously extended to the outside.

At this time, the internal air of the pneumatic part (D) is discharged to the outside through the pneumatic line (1d).

7 shows a state in which the hydraulic pressure boosting cylinder according to the present invention is operated in the reverse direction, and a state in which the hydraulic pressure boosting cylinder is operated in the reverse direction will be described in detail with reference to this.

First, when compressed air is introduced into the pneumatic line 2b, the internal pressure of the pneumatic part E rises, and the slide piston 8 is moved to the third piston 5 to be in close contact with the slide piston 8 and the third When the piston (5) is integrated and presses the hydraulic part (B) to increase the internal pressure of the hydraulic part (B), the trunk piston (2a) moves toward the second piston (3), and the trunk piston (2a) moves toward the bore ( 13), the first piston 2 and the second piston 3 integrated with the trunk piston 2a are simultaneously moved toward the cylinder cap 15, and the trunk piston 2a is contracted.

As described above, according to the present invention, there is an effect of automatically generating a high output in a high load while being operated quickly in a low load state.

In addition, since the check valve can be built into the cylinder case, damage is prevented and the structure is simple.

Brief description of the drawing
1 is a longitudinal cross-sectional view of a hydraulic pressure boosting cylinder according to the present invention.
Figure 2: An enlarged view of the check valve used in the present invention.
3 is a view showing the operating state during the low pressure stroke of the hydraulic pressure boosting cylinder according to the present invention.
floor plan.
Figure 4: Moving image of the slide piston at high load of the hydraulic pressure-increasing cylinder according to the present invention
A drawing showing the state.
Figure 5: A view showing an operating state during high-pressure stroke according to the present invention.
Fig. 6 is an enlarged view of the check valve in the state of Fig. 5;
Figure 7: shows a state in which the hydraulic pressure boosting cylinder according to the present invention is operated in the reverse direction
one drawing.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a longitudinal sectional view of a hydraulic pressure intensifying cylinder according to the present invention, showing an embodiment of the present invention. It consists of a number of parts built into the case.

The cylinder case (1) has a first cylinder hole (11) having a relatively large inner diameter, a second cylinder hole (12) having an inner diameter smaller than or equal to that of the first cylinder hole (11), and a first cylinder hole (11). ) and the second cylinder hole 12 positioned between the second cylinder hole 12 and a bore 13 having an inner diameter smaller than that of the second cylinder hole 12 communicates with each other, and the second cylinder hole 12 is equipped with a slide piston 8 The openings to the outside of the first cylinder hole 11 and the second cylinder hole 12 are sealed through the cylinder caps 15 and 22, respectively, and each of the cylinder caps 15 and 22 Pneumatic lines 1a, 1b, 1c, 1d, 1e, 1f, 1g are formed on It is composed of four check valves (6), the first piston (2) having a trunk piston (2a) selectively inserted into the bore (13) is movably embedded in the first cylinder hole (11), and the second piston (2) (3) is movably embedded in the first cylinder hole (11), the trunk piston (2a) is penetrated, and the spring (4) is disposed between the first piston (2) and the second piston (3). The second piston (3) is elastically supported, and the third piston (5) has a piston rod (5a) protruding to the outside and is movably embedded in the second cylinder hole (12), and the second

The slide piston 8 and the third piston 5 and the slide piston 8 that move along the inside of the cylinder hole 12 and penetrate the piston rod 5a are elastically supported by a spring 9 .

In addition, the check valve 6 is installed in the cylinder cap 22 on the outside of the third cylinder hole 21, so that the pneumatic line 1g inside the check valve 6 is connected to the pneumatic line 1e on one side and The other side is connected to the pneumatic line (1c).

The pneumatic part (D) is communicated to the outside through the pneumatic line (1d) inside the piston rod (5a).

In addition, in the check valve 6, when the slide piston 8 is in close contact with the check valve 6 by the reaction force of the spring 9, the spring 10 is compressed, and the check valve 6 moves to Compressed air is to act on the pneumatic portion (A) through the pneumatic line (1g) and the pneumatic line (1e).

2 is a view showing an embodiment of the check valve 6 shown in FIG. 1. According to this, the check valve 6 according to the present invention is composed of a bore 23 and a spring 10 having a narrow inner diameter. It is composed of a check valve 6 and normally the check valve 6 is inserted into the bore 23 to block the compressed air of the pneumatic line 1c from going to the pneumatic line 1e, but the compressed air of the pneumatic line 1e It is made to serve to make it possible to go to the pneumatic line 1c.

In addition, the pneumatic line (1e) is in communication with the pneumatic line (1f) communicating with the pneumatic portion (A).

Therefore, when the slide piston 8 as shown in FIG. 2 does not push the check valve 6, the check valve 6 is inserted into the bore 23 due to the elasticity of the spring 10 so that the compressed air of the pneumatic line 1c It blocks movement to the pneumatic line 1e, and conversely, the spring 10 is contracted by the check valve 6 to allow the compressed air of the pneumatic line 1e to move to the pneumatic line 1c.

3 is a view showing the operating state during the low pressure stroke of the hydraulic pressure boosting cylinder according to the present invention, and the operating state during the low pressure stroke of the hydraulic pressure increasing cylinder will be described in detail.

The internal pressure of the pneumatic portion (C) increases through the compressed air supplied from the outside through the pneumatic line (1a) and the pneumatic lines (1b, 2c).

As such, when the internal pressure in the pneumatic part (C) increases, the second piston (3) moves toward the bore (13), so that the hydraulic medium stored in the hydraulic storage part (B1) is transferred to the hydraulic part (B) through the bore (13). It is moved so that the third piston 5 is extended to the outside.

Accordingly, the piston rod 5a of the third piston 5 is extended to the outside.

Figure 4 is a slide piston (8) to the check valve (6) by the elasticity of the spring (9) when the movement of the piston rod (5a) is stopped due to a high external load during the low pressure stroke of the hydraulic pressure boosting cylinder according to the present invention. shows moving.

5 shows that the slide piston 8 is pushing the check valve 6 by the elasticity of the spring 9. As shown in FIG.

At this time, the check valve 6 is separated from the bore 23 by the slide piston 8 as shown in FIG. 6 and the pneumatic line 1g and the pneumatic line 1c communicate with each other, and the air in the pneumatic part c is exhausted. .

Therefore, when the compressed air of the pneumatic line (1c) flows into the pneumatic part (A) through the pneumatic line (1g) and the pneumatic line (1f), the internal pressure of the pneumatic part (A) rises to move the first piston (2) and Since the trunk piston 2a connected to the first piston 2 moves toward the third piston 5 through the bore 13 while maintaining the airtight state with the bore 13, the trunk piston 2a moves toward the hydraulic part ( As it protrudes toward B), the pressure of the hydraulic part (B) increases and the third piston (5) is elongated.

Accordingly, the piston rod 5a of the third piston 5 is continuously extended to the outside.

At this time, the internal air of the pneumatic part (D) is discharged to the outside through the pneumatic line (1d).

7 shows a state in which the hydraulic pressure boosting cylinder according to the present invention is operated in the reverse direction, and a state in which the hydraulic pressure boosting cylinder is operated in the reverse direction will be described in detail with reference to this.

First, when compressed air is introduced into the pneumatic line 2b, the internal pressure of the pneumatic part E rises, and the slide piston 8 is moved to the third piston 5 to be in close contact with the slide piston 8 and the third When the piston (5) is integrated and presses the hydraulic part (B) to increase the internal pressure of the hydraulic part (B), the trunk piston (2a) moves toward the second piston (3), and the trunk piston (2a) moves toward the bore ( 13), the first piston 2 and the second piston 3 integrated with the trunk piston 2a are simultaneously moved toward the cylinder cap 15, and the trunk piston 2a is contracted.

(1)--Cylinder case (1a)(1b)(1c)(1d)(1e)(1f)(1g)--Pneumatic line
(1h)--Hydraulic oil replenishment port (11)--First cylinder hole
(12)--Second cylinder hole (13)(23)--Bore
(15)(22)--cylinder cap (2a)--trunk piston
(2)--First Piston (3)--Second Piston
(2b)(2c)--Pneumatic line (4)--Spring
(5)--third piston (5a)--piston rod
(6)--Check valve (7)--Sealing
(8)--Slide piston (B)--Hydraulic part
(B1)--Hydraulic oil storage part
(A)(C)(D)(E)--Pneumatic part (9)(10)--Spring

Claims (5)

The first cylinder hole 11 having a relatively large inner diameter, the second cylinder hole 12 having the same or smaller inner diameter than the first cylinder hole 11, and the first cylinder hole 11 and the second cylinder hole 12 ) located between the cylinder case 1 in which a bore 13 having an inner diameter smaller than that of the second cylinder hole 12 is communicated with each other and a trunk piston 2a selectively inserted into the bore 13, and the first cylinder hole a first piston (2) movably built in (11); The second piston (3) through which the trunk piston (2a) passes while being movably embedded in the first cylinder hole (11) is disposed between the first piston (2) and the second piston (3) and the second piston (3) Equipped with a spring 4 that elastically supports the It is built in to the piston rod (5a) and consists of a spring (9) that is elastically supported between the slide piston (8) and the third piston (5). 1b, 1c, 1e) respectively connected to the pneumatic parts (A, C), the pneumatic part (D) connected to the pneumatic line (1d) connected to the outside between the third piston (5) and the slide piston (8) and In the hydraulic pressure boosting cylinder partitioned by the pneumatic part (E) connected to the pneumatic line (2b) between the slide piston (8) and the cylinder cap (22), the third piston (5) and the spring (9) give elasticity In the structure in which the supported slide piston 8 and the check valve 6 elastically supported by the spring 10 communicate with each other according to the movement of the slide piston 8, when the hydraulic pressure boosting cylinder is expanded or contracted, the slide piston 8 ) compresses the spring 9 and is in close contact with the third piston 5, and when the piston rod 5a is extended, when the load is low, the compressed air flows through the pneumatic lines 1a and 1b to the pneumatic part C ) and as the second piston 3 is moved toward the bore 13, the third piston 5 and the slide piston 8 are moved accordingly to cause the piston rod 5a to extend to the outside. On the other hand, in the case of a high load, when the movement of the second piston 3 is stopped due to the resistance of the piston rod 5a, the slide piston 8 continues to operate due to the elasticity of the spring 9. ) to push the check valve 6, the compressed air of the pneumatic line 1c flows into the pneumatic part A through the pneumatic line 1e, and the air of the pneumatic part C is exhausted, and the first As the piston (2) moves, the trunk piston (2a) maintains an airtight state with the bore (13). A hydraulic pressure-increasing cylinder that independently performs a high-pressure stroke moving to the third piston rod (5) through the bore (13) while maintaining it. The check valve (6) according to claim 1, wherein the check valve (6) is installed on the cylinder cap (22) side, and the pneumatic line (1c) connected to the outside and the pneumatic lines (1f, 1e) connected to the pneumatic part (A) are connected to the check valve (6). ) connected to the pneumatic line (1g) and the compressed air of the pneumatic line (1c) is selectively supplied to the pneumatic part (A) by the check valve (6). 3. The elastic support according to claim 2, which is supported by a spring (9) and a third piston (5).
The slide piston 8 is provided, and in a state in which the slide piston 8 is in close contact with the third piston 5 by the compressed air of the pneumatic part E, the pneumatic part C is used with the compressed air of the pneumatic line 1a. ) is expanded, and the third piston 5 and the slide piston 8 extend outward in a close contact state due to the movement of the second piston 3, but when the piston rod 5a is blocked by a high external load and cannot be extended A hydraulic pressure increasing cylinder, characterized in that the slide piston (8) selectively opens the check valve (6) by the elasticity of the spring (9). 4. The method according to claim 3, wherein when the pneumatic lines (1c, 1e) of the check valve (6) have the slide piston (8) separated from the check valve (6), compressed air flows from the pneumatic line (1c) to the pneumatic line (1e). A hydraulic pressure boosting cylinder, characterized in that it is selectively arranged so as not to affect the flow from the pneumatic line (1e) to the pneumatic line (1c) when the check valve (6) blocks the flow and the internal pressure of the pneumatic line (1e) is high. The hydraulic pressure boosting cylinder according to claim 1, wherein an air passage (1d) configured to penetrate through the piston rod (5a) is formed so that the air of the pneumatic portion (D) passes to the outside.

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