JP2002106502A - Fluid booster - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a compact fluid booster capable of supplying secondary pressured fluid of high pressure and furthermore, quickly actuating an actuator. SOLUTION: The fluid booster constitutes to establish an outside cylinder body 10 including three cylinder chambers 11, 12, 13 distinct in inner diameter, an inside cylinder body 20 having a cylinder chamber 24 therein and being inserted in the outside cylinder body 10 and two pistons 30 which comprise a flange part 31 and a rod part 32, of which the rod part 32 is inserted into the inside cylinder body 20 and the rod part 32 penetrates through the inside cylinder body 20, thereby being inserted into the cylinder chamber 11 of the outside cylinder body 10 as well as flow passage supplying primary pressured fluid to press them and a flow passage outflowing the boosted secondary pressured fluid.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a fluid pressure increasing device for introducing a primary pressurized fluid and outputting a secondary pressurized fluid which is increased in proportion to the pressure of the introduced primary pressurized fluid.

[0002]

2. Description of the Related Art In the field of machining using a machine tool, for example, a work is carried out after a pallet on which a work is placed and fixed is fixed on a table in a work area. In order to fix the pallet to the table, an actuator (clamp device) operated by a working fluid such as pressure oil is used.

In this machine tool, in order to obtain high machining accuracy, it is necessary to firmly fix a pallet on a table so as to sufficiently withstand a cutting resistance. Requires clamping force,
It is necessary to supply a sufficiently high working fluid to the clamping device. Therefore, conventionally, when the original pressure of the working fluid supply device is low, the working fluid (primary pressurized fluid) supplied from the pressurized fluid supply device is increased in pressure by the fluid pressure increase device, and the increased secondary pressure is used. Pressurized fluid was supplied to the clamp device.

Conventionally, as such a fluid pressure booster, for example, a cylinder body having a large-diameter cylinder chamber and a small-diameter cylinder chamber formed continuously in the axial direction, a small-diameter shaft portion and a large-diameter shaft portion, Has a stepped outer shape formed along the axial direction, a small-diameter shaft portion is inserted into the small-diameter cylinder chamber, and a large-diameter shaft portion is constituted by a piston inserted into the large-diameter cylinder chamber. Are known.

According to this fluid pressure increasing device, when a low-pressure primary pressurized fluid is supplied into the large-diameter cylinder chamber, the pressure presses the piston toward the small-diameter cylinder chamber, thereby causing the piston in the small-diameter cylinder chamber to move. The secondary pressurized fluid is increased in pressure according to the ratio of the actual sectional area of the small-diameter cylinder chamber to the actual sectional area of the large-diameter cylinder chamber, and the increased secondary pressurized fluid is discharged from the small-diameter cylinder chamber. Then, the secondary pressurized fluid discharged from the small-diameter cylinder chamber under the increased pressure is supplied to the clamp device.

[0006]

By the way, as described above, the above-described fluid pressure intensifier is designed to increase the secondary pressurized fluid in accordance with the ratio of the actual cross-sectional area of the small-diameter cylinder chamber to the actual cross-sectional area of the large-diameter cylinder chamber. Therefore, in order to further increase the pressure of the secondary pressurized fluid, it is necessary to make the inner diameter of the small-diameter cylinder chamber smaller.

However, when the inside diameter of the small-diameter cylinder chamber is reduced, the capacity per unit length in the axial direction is reduced.
In order to supply the next pressurized fluid, it is necessary to increase the length of the small-diameter cylinder chamber in the axial direction to increase the stroke of the piston, which causes a problem that the size of the device increases. Was. In addition, the smaller the inner diameter of the small diameter cylinder, the smaller the supply amount of the secondary pressurized fluid per unit time, the longer the operation time of the clamp device, and in the case of the above machine tool, In addition, there is a problem that the mounting time of the pallet becomes long, and efficient processing cannot be performed.

The present invention has been made in view of the above circumstances, and can supply a high-pressure secondary pressurized fluid.
Moreover, an object of the present invention is to provide a compact fluid pressure intensifier capable of operating an actuator quickly.

[0009]

Means for Solving the Problems and Effects Thereof The invention described in claim 1 of the present invention for solving the above problems has the following features.
A fluid pressure intensifier that introduces a secondary pressurized fluid and outputs a secondary pressurized fluid whose pressure is increased in proportion to the pressure of the introduced primary pressurized fluid, and is formed continuously along the axial direction. An outer cylinder body having at least three cylinder chambers having different inner diameters of a small-diameter cylinder chamber, a medium-diameter cylinder chamber, and a large-diameter cylinder chamber, and at least a small-diameter shaft portion and a large-diameter shaft portion are formed along the axial direction. A small-diameter shaft portion is inserted into the medium-diameter cylinder chamber of the outer cylinder body, and a large-diameter shaft portion is inserted into the large-diameter cylinder chamber. An inserted inner cylinder body, comprising a flange portion and a rod portion having a smaller diameter than the flange portion, the flange portion is inserted into a cylinder chamber of the inner cylinder body, and the rod portion penetrates the inner cylinder body. Small diameter cylinder of the outer cylinder body And a piston inserted into the outer cylinder body, and a primary space is separately provided for a space on both sides of a large-diameter shaft portion of the inner cylinder body in a large-diameter cylinder chamber provided in the outer cylinder body. A flow path for supplying a pressurized fluid, and a flow path for separately flowing in and out of the secondary pressurized fluid in the medium-diameter cylinder chamber and the small-diameter cylinder chamber are formed in the outer cylinder body, respectively, while the inner cylinder body is formed in the outer cylinder body. A flow path for supplying a primary pressurized fluid to each of the spaces on both sides of the flange portion of the piston in the provided cylinder chamber is separately formed in the outer cylinder body and the inner cylinder body, respectively. The present invention relates to a fluid pressure intensifier.

[0010] According to this fluid pressure increasing device, the flow path provided in the outer cylinder body is used to define the inner space of the large-diameter cylinder chamber formed on both sides of the large-diameter shaft portion of the inner cylinder body. A primary pressurized fluid is supplied to a space opposite to the small-diameter shaft portion, and is formed on both sides of a flange portion of the piston from a flow path provided in the outer cylinder body and the inner cylinder body. When the primary pressurized fluid is supplied to the space on the opposite side of the piston rod portion from the space inside the inner cylinder body cylinder chamber, the inner cylinder body is moved by the primary pressurized fluid supplied to the large-diameter cylinder chamber. The secondary pressurized fluid in the medium-diameter cylinder chamber is increased in pressure by this pressing action to move toward the small-diameter shaft, and the piston is pressed by the primary pressurized fluid supplied to the cylinder chamber of the inner cylinder body. So Go is pressed against the rod side, the secondary pressurized fluid of the small-diameter cylinder chamber is boosted by this pressing action.

The secondary pressurized fluid in the medium diameter cylinder chamber is
The pressure is increased in accordance with the ratio between the actual cross-sectional area of the medium-diameter cylinder chamber and the actual cross-sectional area of the large-diameter cylinder chamber, and the secondary pressurized fluid in the small-diameter cylinder chamber is reduced by the actual cross-sectional area of the small-diameter cylinder chamber. The pressure is increased according to the ratio with the actual cross-sectional area of the cylinder chamber of the inner cylinder body. Therefore, the ratio of the actual cross-sectional area of the medium-diameter cylinder chamber to the actual cross-sectional area of the large-diameter cylinder chamber, and the ratio of the actual cross-sectional area of the small-diameter cylinder chamber to the actual cross-sectional area of the cylinder chamber of the inner cylinder body are appropriately set. Accordingly, the pressure of the secondary pressurized fluid in the small-diameter cylinder chamber can be made higher than the pressure of the secondary pressurized fluid in the medium-diameter cylinder chamber.

The secondary pressurized fluid in the small-diameter cylinder chamber and the secondary pressurized fluid in the medium-diameter cylinder chamber, which have been pressurized in this manner, are respectively discharged to the outside from flow paths provided in the outer cylinder body. Needless to say, the actual sectional area of the medium diameter cylinder chamber is larger than the actual sectional area of the small diameter cylinder chamber. For this reason, the capacity per unit length in the axial direction of each cylinder chamber is larger in the medium-diameter cylinder chamber than in the small-diameter cylinder chamber. Therefore, the flow rate of the secondary pressurized fluid discharged from the medium-diameter cylinder chamber is Is larger than the flow rate of the secondary pressurized fluid discharged from the small-diameter cylinder chamber.

[0013] The secondary pressurized fluid discharged from the fluid pressure intensifier is simultaneously supplied to a predetermined actuator.
Among the secondary pressurized fluids, mainly driven by the secondary pressurized fluid discharged from the medium-diameter cylinder chamber at a low pressure but at a large flow rate, the secondary pressurized fluid is driven at a high pressure while discharged from the small-diameter cylinder chamber. The low flow rate of the secondary pressurized fluid provides the final required output.

As described above, according to the fluid pressure intensifier of the present invention, the small-pressure, high-pressure secondary pressurized fluid is discharged from the small-diameter cylinder chamber, and the low-pressure, multi-flow secondary pressurized fluid is discharged to the medium-diameter. Since the two secondary pressurized fluids are supplied from the cylinder chamber, for example, when these two secondary pressurized fluids are supplied to the above-described clamp device, they are quickly driven by the low-pressure, multi-flow rate secondary pressurized fluid. High pressure and small flow rate
A predetermined clamping force can be obtained by the next pressurized fluid. Therefore, unlike the conventional example described above, there is no problem that the operation time of the clamp device is lengthened, and furthermore, efficient machining cannot be performed.

Further, since the two secondary pressurized fluids are discharged by a combined operation of the inner cylinder body and the piston, the movement strokes required to obtain a predetermined amount of the secondary pressurized fluid are reduced. The fluid pressure intensifier can be made extremely short, and the size of the entire fluid pressure intensifier can be made compact.

The passage for supplying the primary pressurized fluid into the space on the side of the small-diameter shaft portion in the cylinder chamber provided in the inner cylinder body is provided as in the second aspect of the invention. A flow path formed in the cylinder body, one of which is open at an end surface forming a step portion between the large-diameter shaft portion and the small-diameter shaft portion of the inner cylinder body, and inside a cylinder chamber provided in the inner cylinder body. This may be constituted by a flow path whose other end is opened at the end face on the side of the small diameter shaft portion.

When the primary pressurized fluid is supplied to the space on the side of the small-diameter shaft portion in the large-diameter cylinder chamber and the space on the side of the small-diameter shaft portion in the inner cylinder body cylinder chamber, both the inner cylinder body and the piston are moved together. The secondary pressurized fluid that has moved toward the large-diameter shaft portion in the axial direction and discharged again flows into the medium-diameter cylinder chamber and the small-diameter cylinder chamber, respectively. As described above, when the secondary pressurized fluid is re-introduced into the medium-diameter cylinder chamber and the small-diameter cylinder chamber, respectively, the inner cylinder body and the piston are both moved toward the large-diameter shaft portion in the axial direction. The small-diameter shaft in the large-diameter cylinder chamber is formed by communicating the space on the small-diameter shaft portion side in the large-diameter cylinder chamber with the space on the small-diameter shaft portion side in the inner cylinder body cylinder chamber by a flow path formed in the body. It is possible to supply the primary pressurized fluid supplied to the space on the part side to the space on the small diameter shaft part side in the inner cylinder body cylinder chamber through the flow path. In this manner, the supply path of the primary pressurized fluid can be simplified.

According to a third aspect of the present invention, there is provided a fluid pressure intensifier which introduces a primary pressurized fluid and outputs a secondary pressurized fluid which is increased in proportion to the pressure of the introduced primary pressurized fluid. The apparatus comprises five cylinder chambers of first, second, third, fourth, and fifth cylinder chambers formed continuously along an axial direction, and among the five cylinder chambers, An outer cylinder body in which the inner diameter of the central third cylinder chamber is formed to be the largest diameter, and the inner diameter of the cylinder chamber is gradually reduced toward both sides along the axial direction; A stepped outer shape formed by a first small-diameter shaft portion and a second small-diameter shaft portion on both sides in the axial direction thereof, and having a sixth cylinder chamber therein, wherein the large-diameter shaft portion is The first small-diameter shaft portion is fitted into the third cylinder chamber of the outer cylinder body, and
An inner cylinder body fitted into the cylinder chamber, the second small-diameter shaft part fitted into the fourth cylinder chamber; a flange portion; and a rod portion having a smaller diameter than the flange portion, wherein the flange portion is the inner cylinder body. A first piston whose rod portion penetrates through the inner cylinder body and is inserted into the first cylinder chamber of the outer cylinder body; and a flange having a smaller diameter than the flange portion and the flange portion. A rod portion, wherein the flange portion is inserted into the sixth cylinder chamber of the inner cylinder body, and the rod portion penetrates the inner cylinder body and is inserted into the fifth cylinder chamber of the outer cylinder body. A first pressurized fluid in a third cylinder chamber provided in the outer cylinder body and separately in a space on both sides of a large-diameter shaft portion of the inner cylinder body. A flow path for supplying and a flow path for separately flowing in and out of the secondary pressurized fluid in the first, second, fourth and fifth cylinder chambers are respectively formed in the outer cylinder body, while the inner cylinder body is formed. The space between the first piston and the second piston, the space on the rod portion side of the first piston, and the space on the rod portion side of the second piston in the sixth cylinder chamber provided in The present invention relates to a fluid pressure booster, wherein flow paths for supplying a next pressurized fluid are formed in an outer cylinder and an inner cylinder, respectively.

According to this fluid pressure increasing device, the flow path provided in the outer cylinder body can be used to form a space inside the third cylinder chamber formed on both sides of the large-diameter shaft portion of the inner cylinder body. A first pressurized fluid is supplied to a space on the side of the second small-diameter shaft portion, and the first piston provided in a sixth cylinder chamber of the inner cylinder body from a flow path provided in the outer cylinder body and the inner cylinder body. The primary pressurized fluid is supplied to the space between the first and second pistons, and the second pressurized fluid is supplied to the second cylinder from the flow passages provided in the outer cylinder body and the inner cylinder body.
When the primary pressurized fluid is supplied to the space on the second piston rod portion side of the space in the sixth cylinder chamber formed on both sides of the flange portion of the piston with the flange portion interposed therebetween, the primary pressure fluid supplied to the third cylinder chamber is provided. The inner cylinder body is pressed by the pressurized fluid toward the first small-diameter shaft portion and moves, and the pressurizing action increases the pressure of the secondary pressurized fluid in the second cylinder chamber.
The first piston is pressed against the rod portion by the primary pressurized fluid supplied to the cylinder chamber and moves, and the pressurizing action increases the pressure of the secondary pressurized fluid in the first cylinder chamber, while increasing the inner cylinder. Due to the movement of the body, the secondary pressurized fluid flows into the fourth cylinder chamber, and the second piston is moved by the primary pressurized fluid supplied to the space on the second piston rod side in the sixth cylinder chamber. The second pressurized fluid flows into the fifth cylinder chamber by this movement.

The secondary pressurized fluid in the second cylinder chamber is
The pressure is increased in accordance with the ratio of the actual cross-sectional area of the second cylinder chamber to the actual cross-sectional area of the third cylinder chamber, and the secondary pressurized fluid in the first cylinder chamber is disconnected from the actual first cylinder chamber. The pressure is increased according to the ratio between the area and the actual sectional area of the sixth cylinder chamber of the inner cylinder body. Accordingly, by appropriately setting the ratio between the actual cross-sectional area of the second cylinder chamber and the actual cross-sectional area of the third cylinder chamber, and the ratio between the actual cross-sectional area of the first cylinder chamber and the actual cross-sectional area of the sixth cylinder chamber. The pressure of the secondary pressurized fluid in the first cylinder chamber can be made higher than the pressure of the secondary pressurized fluid in the second cylinder chamber.

The secondary pressurized fluid in the first cylinder chamber and the second cylinder chamber thus increased in pressure is discharged to the outside from flow paths provided in the outer cylinder body.
Since the actual sectional area of the second cylinder chamber is larger than the actual sectional area of the first cylinder chamber, the capacity per unit length in the axial direction of each cylinder chamber is larger in the second cylinder chamber than in the first cylinder chamber. Therefore, the flow rate of the secondary pressurized fluid discharged from the second cylinder chamber is larger than the flow rate of the secondary pressurized fluid discharged from the first cylinder chamber.

Conversely, the primary pressurized fluid is supplied to the space on the first small-diameter portion side of both spaces in the third cylinder chamber, and formed on both sides of the flange portion of the first piston. When the primary pressurized fluid is supplied to the space on the first piston rod portion side of the space in the sixth cylinder chamber, the inner cylinder body is moved to the second small diameter by the primary pressurized fluid supplied to the third cylinder chamber. The second pressurized fluid in the fourth cylinder chamber is increased in pressure by this pressing action, and is moved by the primary pressurized fluid supplied to the sixth cylinder chamber. The second pressurized fluid in the fifth cylinder chamber is increased in pressure by this pressing action, and the secondary pressurized fluid flows into the second cylinder chamber by the movement of the inner cylinder body, 1 supplied to the sixth cylinder chamber The pressurized fluid, the first piston is moved by being pressed by the second piston side, the secondary pressurized fluid flows into the first cylinder chamber by the movement.

The pressure of the secondary pressurized fluid in the fourth cylinder chamber is increased according to the ratio of the actual cross-sectional area of the fourth cylinder chamber to the actual cross-sectional area of the third cylinder chamber. The secondary pressurized fluid is applied to the actual sectional area of the fifth cylinder chamber and the sixth pressurized fluid.
The pressure is increased according to the ratio to the actual cross-sectional area of the cylinder chamber.
By appropriately setting the ratio between the actual cross-sectional area of the cylinder chamber and the actual cross-sectional area of the third cylinder chamber, and the ratio of the actual cross-sectional area of the fifth cylinder chamber to the actual cross-sectional area of the sixth cylinder chamber, the fifth cylinder The secondary pressurized fluid in the chamber can be at a higher pressure than the secondary pressurized fluid in the fourth cylinder chamber.

The secondary pressurized fluid in the fourth cylinder chamber and the fifth cylinder chamber thus increased in pressure is discharged to the outside from the flow paths provided in the outer cylinder body, respectively.
Since the actual sectional area of the fourth cylinder chamber is larger than the actual sectional area of the fifth cylinder chamber, 2
The flow rate of the next pressurized fluid is 2 which is discharged from the fifth cylinder chamber.
It is larger than the flow rate of the secondary pressurized fluid.

The secondary pressurized fluid discharged from the first cylinder chamber and the second cylinder chamber and the secondary pressurized fluid discharged from the fourth cylinder chamber and the fifth cylinder chamber are supplied to different actuators respectively. A low-pressure, high-pressure secondary pressurized fluid is discharged from the first cylinder chamber and the fifth cylinder chamber, and a low-pressure, multi-flow secondary fluid is discharged from the second cylinder chamber and the fourth cylinder chamber. Since the pressurized fluid is discharged, the same operations and effects as those of the first aspect are achieved.

According to a fourth aspect of the present invention, one of the inner cylinder bodies has an opening at an end surface forming a step between the large-diameter shaft portion and the first small-diameter shaft portion, and is provided on the inner cylinder body. A first inner flow path, the other of which is open at the end surface of the sixth cylinder chamber on the side of the first small-diameter shaft portion, is formed in the inner cylinder body, and is supplied into the third cylinder chamber on the first small-diameter shaft portion side. The primary pressurized fluid is configured to be supplied to the sixth cylinder chamber on the same first small-diameter shaft portion side of the inner cylinder body via the first inner flow path, One end is open at the end face forming the step between the large diameter shaft part and the second small diameter shaft part, and the other is open at the end face on the side of the second small diameter shaft part in the sixth cylinder chamber provided in the inner cylinder body. Forming a second inner flow passage in the inner cylinder body;
The first cylinder supplied to the third cylinder chamber on the side of the small-diameter shaft portion.
The invention according to claim 3, wherein the next pressurized fluid is supplied to the sixth cylinder chamber on the same second small diameter shaft portion side of the inner cylinder body via the second inner flow path. Similarly, a flow path for supplying a primary pressurized fluid to a space on the first piston rod side in the sixth cylinder chamber, and
The flow path for supplying the primary pressurized fluid to the space on the second piston rod side in the sixth cylinder chamber can be simplified.

Both the primary pressurized fluid and the secondary pressurized fluid may be gas or liquid.

[0028]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, specific embodiments of the present invention will be described with reference to the accompanying drawings. FIG. 1 is a sectional view showing a fluid pressure booster according to the present embodiment.

As shown in FIG. 1, the fluid pressure intensifier 1 of this embodiment
Is for introducing a primary pressurized fluid and outputting a secondary pressurized fluid whose pressure is increased in proportion to the pressure of the introduced primary pressurized fluid. The outer cylinder body 10 and the inner cylinder body 20 When,
The first and second pistons 30 and 40 are provided.

The outer cylinder body 10 has first, second, third, fourth and fifth parts formed continuously along the axial direction.
It has five cylinder chambers 11, 12, 13, 14, and 15, of which the inner diameter of the central third cylinder chamber 13 is formed to be the largest, and on both sides along the axial direction. The inner diameter of the cylinder chamber is formed so as to gradually decrease as it goes.

The inner cylinder body 20 includes a central large-diameter shaft portion 21, first small-diameter shaft portions 22 on both axial sides thereof,
It has a stepped outer shape formed from the small-diameter shaft portion 23 and has a sixth cylinder chamber 24 therein, and the large-diameter shaft portion 21 is connected to the third cylinder chamber 13 of the outer cylinder body 10.
The first small-diameter shaft portion 22 is fitted into the second cylinder chamber 12, and the second small-diameter shaft portion 23 is fitted into the fourth cylinder chamber 14. The inside of the sixth cylinder chamber 24 has an opening 2.
5 are divided into two rooms 24 ′ and 24 ″.

The first piston 30 has a flange 31
And a rod portion 32 having a diameter smaller than that of the flange portion 31. The flange portion 31 is inserted into the sixth cylinder chamber 24 ′ of the inner cylinder body 20, and the rod portion 32 penetrates the inner cylinder body 20 and It is fitted into the first cylinder chamber 11 of the cylinder body 10.

Similarly, the second piston 40 has a flange portion 41 and a rod portion 42 having a smaller diameter than the flange portion 41.
The flange portion 41 is inserted into the sixth cylinder chamber 24 ″ of the inner cylinder body 20, and the rod portion 42 penetrates the inner cylinder body 20 and is inserted into the fifth cylinder chamber 15 of the outer cylinder body 10. Have been.

The outer cylinder body 10 has a port 1
6, 17, 18 are formed, and these ports 16,
17 and 18 are connected to a pressurizing pump. Further, the outer cylinder body 10 has first and second ports which separately communicate the ports 16 and 17 and the spaces (pressurized fluid chambers) 13a and 13b on both sides of the large-diameter shaft portion 21 of the inner cylinder body 20 respectively.
Second outer flow paths 10a and 10b are formed.

One end of the inner cylinder body 20 has an opening at an end surface forming a step between the large-diameter shaft portion 21 and the first small-diameter shaft portion 22 of the inner cylinder body 20, and is provided on the inner cylinder body 20. First small diameter shaft portion 22 in sixth cylinder chamber 24 '
A first inner flow path 20 a having the other opening is formed on the end face on the side of the first piston 30 in the port 16 and the sixth cylinder chamber 24 ′ provided in the inner cylinder body 20. (A pressurized fluid chamber) 24a is connected to the first outer channel 10a, the pressurized fluid chamber 13a, and the first inner channel 20a.
Is communicated through.

One end of the inner cylinder body 20 has an opening at an end surface of the inner cylinder body 20 which forms a step between the large-diameter shaft portion 21 and the second small-diameter shaft portion 23, and is provided on the inner cylinder body 20. The second small diameter shaft portion 23 in the sixth cylinder chamber 24 "
A second inner flow path 20b having the other open side is formed in the end surface on the side, and the port 17 and the rod portion 42 side of the second piston 40 in the sixth cylinder chamber 24 ″ provided in the inner cylinder body 20 are formed. (A pressurized fluid chamber) 24b and the second outer flow path 10b, the pressurized fluid chamber 13b and the second inner flow path 20b.
Is communicated through.

One of the inner cylinder body 20 has an opening on the outer peripheral surface of the large-diameter shaft portion 21 of the inner cylinder body 20, and the first piston 30 in the sixth cylinder chamber 24 provided in the inner cylinder body 20. A third inner flow path 20c having the other opening is formed on the inner peripheral surface between the first piston 40 and the second piston 40.
On the other hand, the outer cylinder body 10 includes the third inner flow path 20.
A third outer flow path 10 c communicating between the first piston 30 and the second piston 40 in the sixth cylinder chamber 24 provided in the inner cylinder body 20 is formed. (Pressurized fluid chamber) 24c communicates with each other through the third outer channel 10c and the third inner channel 20c.

The outer cylinder body 10 has a port 1
9a, 19b, 19c, and 19d are formed in the ports 19a, 19b, 19c, and 19d, respectively, in the first, second, fourth, and fifth cylinder chambers 11, 12, and 1, respectively.
The fourth, fifth, sixth, and seventh outer flow paths 10d, 10e, 10f, and 10g communicating with the fourth and fifth communication paths are connected.

The ports 19a and 19b and the port 19
c and 19d are connected to the same or different actuators.

Next, the fluid pressure intensifier 1 having the above configuration
The operation of will be described. Note that the fluid pressure intensifier 1 is initially in the state shown in FIG.

First, when a primary pressurized fluid is supplied from a pressurized fluid supply device (not shown) such as a pressurized pump to the ports 17 and 18 and the port 16 is allowed to flow out, the pressurized fluid chamber 13b, The primary pressurized fluid flows into 24b and 24c, and the inner cylinder body 20, the second piston 40, and the first piston 30 move leftward in the drawing.

Thus, the first cylinder chamber 11 and the second cylinder chamber 11
The secondary pressurized fluid in the cylinder chamber 12 is increased in pressure,
The secondary pressurized fluid in the first cylinder chamber 11 is
0d, is supplied to an actuator (not shown) through a port 19a, and at the same time, the secondary pressurized fluid in the second cylinder chamber 12 is supplied to the same actuator (not shown) through a first outer passage 10b and a port 19b. ), And the actuator (not shown) is driven by these secondary pressurized fluids.

The pressure of the secondary pressurized fluid in the second cylinder chamber 12 is increased according to the ratio of the actual sectional area of the second cylinder chamber 12 to the actual sectional area of the third cylinder chamber 13. The pressure of the secondary pressurized fluid in the first cylinder chamber 11 is increased according to the ratio of the actual sectional area of the first cylinder chamber 11 to the actual sectional area of the sixth cylinder chamber 24 ′ of the inner cylinder body 20. You. Therefore, the ratio of the actual sectional area of the second cylinder chamber 12 to the actual sectional area of the third cylinder chamber 13 and the ratio of the first cylinder chamber 11
By appropriately setting the ratio between the actual cross-sectional area of the first cylinder chamber and the actual cross-sectional area of the sixth cylinder chamber 24 ′, specifically, the cross-sectional area of the first cylinder chamber 11 is S ₁₁ , and the cross-sectional area of the second cylinder chamber 12 is Is S ₁₂ , the sectional area of the third cylinder chamber 13 is S ₁₃ ,
'The cross-sectional area of S _24' the cylinder chamber 24 when the,
_{(S 24 '/ S 11)} > ((S 13 -S 12) / (S
₁₂ -S ₁₁ )), the first cylinder chamber 1
The pressure of the secondary pressurized fluid in 1 can be higher than the pressure of the secondary pressurized fluid in the second cylinder chamber 12.

Since the actual cross-sectional area of the second cylinder chamber 12 is larger than the actual cross-sectional area of the first cylinder chamber 11, the capacity per unit length of each of the cylinder chambers 11, 12 in the axial direction is equal to the second cylinder chamber. The chamber 12 is the first cylinder chamber 11
Therefore, the flow rate of the secondary pressurized fluid discharged from the second cylinder chamber 12 is larger than the flow rate of the secondary pressurized fluid discharged from the first cylinder chamber 11.

Therefore, the actuator (not shown) mainly includes the secondary pressurized fluid supplied simultaneously,
While being driven quickly by the low-pressure, multi-flow secondary pressurized fluid discharged from the second cylinder chamber 12, the high-pressure, small-flow secondary pressurized fluid discharged from the first cylinder chamber 11 causes the final drive. The output which is required is given.

On the other hand, when the inner cylinder body 20 moves to the left in the figure, the fourth cylinder is moved from an actuator (not shown).
The secondary pressurized fluid flows into the cylinder chamber 14, and the second
The secondary pressurized fluid flows into the fifth cylinder chamber 15 from the same actuator (not shown) by the movement of the piston 40 to the left in the figure.

Next, conversely, when the primary pressurized fluid is supplied to the port 16 and the port 17 is allowed to flow out, the primary pressurized fluid flows into the pressurized fluid chambers 13a and 24a, and The body 20, the first piston 30, and the second piston 40 move rightward in the figure.

As a result, the fourth cylinder chamber 14 and the fifth
The secondary pressurized fluid in the cylinder chamber 15 is increased in pressure,
The secondary pressurized fluid in the fifth cylinder chamber 15 is supplied to the seventh outer channel 1
0g, is supplied to an actuator (not shown) through a port 19c, and at the same time, the secondary pressurized fluid in the fourth cylinder chamber 14 is supplied to the same actuator (not shown) through a sixth outer flow path 10f and a port 19d. ), And the actuator (not shown) is driven by these secondary pressurized fluids.

The pressure of the secondary pressurized fluid in the fourth cylinder chamber 14 is increased according to the ratio of the actual sectional area of the fourth cylinder chamber 14 to the actual sectional area of the third cylinder chamber 13. The pressure of the secondary pressurized fluid in the fifth cylinder chamber 15 is increased according to the ratio of the actual cross-sectional area of the fifth cylinder chamber 15 to the actual cross-sectional area of the sixth cylinder chamber 24 ″ of the inner cylinder body 20. Therefore, the ratio of the actual sectional area of the fourth cylinder chamber 14 to the actual sectional area of the third cylinder chamber 13 and the fifth cylinder chamber 15
Specifically, by appropriately setting the ratio between the actual cross-sectional area of the fifth cylinder chamber 24 ″ and the actual cross-sectional area of the sixth cylinder chamber 24 ″, the cross-sectional area of the fifth cylinder chamber 15 is set to S ₁₅ and the cross-sectional area of the fourth cylinder chamber 14 is set. Is S ₁₄ , the sectional area of the third cylinder chamber 13 is S ₁₃ ,
When the cross-sectional area of the cylinder chamber 24 ″ is S _{24 ″} ,
_{(S 24 "/ S 15)} > ((S 13 -S 14) / (S
₁₄ -S ₁₅ )), the fifth cylinder chamber 1
The pressure of the secondary pressurized fluid in 5 can be made higher than the pressure of the secondary pressurized fluid in the fourth cylinder chamber 14.

Since the actual cross-sectional area of the fourth cylinder chamber 14 is larger than the actual cross-sectional area of the fifth cylinder chamber 15, the capacity per unit length of each of the cylinder chambers 14, 15 in the axial direction is equal to the fourth cylinder chamber. The chamber 14 is larger than the fifth cylinder chamber 15. Therefore, the flow rate of the secondary pressurized fluid discharged from the fourth cylinder chamber 14 is equal to the flow rate of the secondary pressurized fluid discharged from the fifth cylinder chamber 15. More than that.

Therefore, the actuator (not shown) mainly includes the secondary pressurized fluid supplied simultaneously,
While being driven quickly by the low-pressure, multi-flow secondary pressurized fluid discharged from the fourth cylinder chamber 14, the high-pressure, small-flow secondary pressurized fluid discharged from the fifth cylinder chamber 15 causes the final drive. The output which is required is given.

On the other hand, when the inner cylinder body 20 moves rightward in the figure, the second cylinder body 20 moves from the actuator (not shown) to the second side.
The secondary pressurized fluid flows into the cylinder chamber 12, and
The secondary pressurized fluid flows into the first cylinder chamber 11 from the actuator (not shown) by the rightward movement of the piston 30 in the figure.

As described above, according to the fluid pressure increasing device 1 of the present embodiment, the small flow rate, high pressure secondary pressurized fluid discharged from the first cylinder chamber 11 and the low pressure discharged from the second cylinder chamber 12, A multi-flow secondary pressurized fluid can be simultaneously supplied to an actuator (not shown), and similarly, a small flow, high-pressure secondary pressurized fluid discharged from the fifth cylinder chamber 15 and the fourth pressurized fluid.
Since the low-pressure, multi-flow rate secondary pressurized fluid discharged from the cylinder chamber 14 can be simultaneously supplied to the actuator (not shown), the low-pressure, multi-flow rate secondary pressurized fluid is used by the actuator (not shown). Can be quickly driven, and a predetermined output (clamping force or the like) can be given to the actuator (not shown) by the secondary pressurized fluid having a high pressure and a small flow rate. Therefore, unlike the conventional example described above, there is no problem that the operation time of the clamp device is lengthened, and furthermore, efficient machining cannot be performed.

Further, the inner cylinder body 20 and the first and second
Since the secondary pressurized fluid is discharged by the combined operation of the pistons 30 and 40, the moving stroke required for obtaining a predetermined amount of the secondary pressurized fluid can be extremely short. In addition, the size of the entire fluid intensifier 1 can be made compact.

As described above, one embodiment of the present invention has been described in detail, but it is needless to say that a specific embodiment of the present invention is not limited to this. For example, in the above-described embodiment, a small flow rate, high pressure secondary pressurized fluid is discharged from the first cylinder chamber 11 and the fifth cylinder chamber 15, and the second cylinder chamber 12 and the fourth cylinder chamber 14 are discharged.
, A low-pressure, multi-flow rate secondary pressurized fluid is discharged from the second, fourth, and fifth cylinder chambers 14, 15, the second small-diameter shaft portion 23, and the second piston. 40 is omitted, so that a small-pressure, high-pressure secondary pressurized fluid is discharged only from the first cylinder chamber 11 and a low-pressure, multi-flow secondary pressurized fluid is discharged only from the second cylinder chamber 12. May be configured.

In the above example, the first, second and third inner flow paths 20a, 20b and 20c are provided and the ports 16, 17 and
18 and the pressurized fluid chambers 24a, 24b, 24c are individually communicated with each other, but are not limited thereto.
Channels communicating with the pressurized fluid chambers 24a, 24b, 24c can be provided at appropriate positions in the outer cylinder body 10 and the inner cylinder body 20.

Both the primary pressurized fluid and the secondary pressurized fluid may be gas or liquid.

[Brief description of the drawings]

FIG. 1 is a cross-sectional view illustrating a fluid pressure booster according to an embodiment of the present invention.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Fluid pressure booster 10 Outer cylinder body 10a 1st outer flow path 10b 2nd outer flow path 10c 3rd outer flow path 10d 4th outer flow path 10e 5th outer flow path 10f 6th outer flow path 10g 7th outer flow Road 11 First cylinder chamber 12 Second cylinder chamber 13 Third cylinder chamber 14 Fourth cylinder chamber 15 Fifth cylinder chamber 20 Inner cylinder body 20a First inner flow path 20b Second inner flow path 20e Third inner flow path 21 Large Radial shaft part 22 First small diameter shaft part 23 Second small diameter shaft part 24 Sixth cylinder chamber 30 First piston 31, 41 Flange part 32, 42 Rod part 40 Second piston

Claims (4)

[Claims] 1. A fluid pressure intensifier for introducing a primary pressurized fluid and outputting a secondary pressurized fluid that is increased in proportion to the pressure of the introduced primary pressurized fluid. An outer cylinder body having at least three cylinder chambers having different inner diameters of a small-diameter cylinder chamber, a medium-diameter cylinder chamber, and a large-diameter cylinder chamber formed at least continuously, and at least a small-diameter shaft portion and a large-diameter shaft portion. It has a stepped outer shape formed along the direction, and has a cylinder chamber inside, a small-diameter shaft part is inserted into a medium-diameter cylinder chamber of the outer cylinder body, and the large-diameter shaft part is An inner cylinder body fitted into the large-diameter cylinder chamber, a flange portion and a rod portion having a smaller diameter than the flange portion, wherein the flange portion is fitted into the cylinder chamber of the inner cylinder body, and the rod portion is inserted into the inner cylinder body. The outer cylinder through the cylinder body And a piston fitted in a small-diameter cylinder chamber of the body, and a large-diameter cylinder chamber provided in the outer cylinder body.
A flow path for separately supplying a primary pressurized fluid to each of the spaces on both sides of the large-diameter shaft portion of the inner cylinder body, and a separate secondary pressurized fluid for the medium-diameter cylinder chamber and the small-diameter cylinder chamber. The first pressurized fluid is formed separately in both sides of the cylinder chamber provided in the inner cylinder body, on both sides of the flange portion of the piston, while the flow passages flowing into and out of the outer cylinder body are respectively formed in the outer cylinder body. The fluid pressure intensifier is characterized in that flow paths for supplying pressure are formed in an outer cylinder body and an inner cylinder body, respectively. 2. An inner surface of the inner cylinder body, one end of which forms a step between the large-diameter shaft portion and the small-diameter shaft portion, has an opening, and the end surface of the inner cylinder body on the side of the small-diameter shaft portion in the cylinder chamber provided in the inner cylinder body. Forming a flow path with the other opening in the inner cylinder body,
The 1 supplied to the large-diameter cylinder chamber on the small-diameter shaft portion side.
The fluid pressure booster according to claim 1, wherein the next pressurized fluid is supplied to the cylinder chamber on the same small diameter shaft portion side of the inner cylinder body via the flow path. 3. A fluid pressure intensifier for introducing a primary pressurized fluid and outputting a secondary pressurized fluid that is increased in proportion to the pressure of the introduced primary pressurized fluid. First, second, third,
It has five cylinder chambers, a fourth cylinder chamber and a fifth cylinder chamber. Of the five cylinder chambers, the inner diameter of the central third cylinder chamber is formed to be the largest, and goes to both sides along the axial direction. The outer cylinder body formed so that the inner diameter of the cylinder chamber becomes smaller in order according to the following, a large diameter shaft portion at the center, and a first small diameter shaft portion and a second small diameter shaft portion on both sides in the axial direction. And a sixth cylinder chamber provided therein. A large-diameter shaft portion is inserted into the third cylinder chamber of the outer cylinder body, and a first small-diameter shaft portion is inserted into the second cylinder chamber. An inner cylinder body fitted and inserted with the second small-diameter shaft portion fitted into the fourth cylinder chamber; a flange portion and a rod portion having a smaller diameter than the flange portion; The rod is inserted into the cylinder chamber, A first piston inserted through the damper body into the first cylinder chamber of the outer cylinder body; and a flange portion and a rod portion having a smaller diameter than the flange portion. Sixth
A second piston inserted into the cylinder chamber, the rod portion penetrating through the inner cylinder body and inserted into the fifth cylinder chamber of the outer cylinder body, and the second piston is provided on the outer cylinder body. In the third cylinder chamber
A flow path for separately supplying a primary pressurized fluid to a space on both sides of the large-diameter shaft portion of the inner cylinder body, and a secondary processing chamber in the first, second, fourth, and fifth cylinder chambers While the flow path which flows in and out of a pressurized fluid separately is formed in each of the outer cylinder bodies, a sixth cylinder chamber provided in the inner cylinder body is provided.
A flow path for separately supplying a primary pressurized fluid between the first piston and the second piston, a space on the rod portion side of the first piston, and a space on the rod portion side of the second piston. A fluid pressure booster formed on an outer cylinder and an inner cylinder, respectively. 4. A first small diameter inside a sixth cylinder chamber provided in the inner cylinder body, one of which is open at an end surface forming a step portion between the large diameter shaft portion and the first small diameter shaft portion of the inner cylinder body. A first inner flow path, the other of which is open at the end face on the shaft portion side, is formed in the inner cylinder body, and the primary pressurized fluid supplied into the third cylinder chamber on the first small diameter shaft portion side is the first pressurized fluid. A large diameter shaft portion and a second small diameter shaft portion of the inner cylinder body are configured to be supplied into the sixth cylinder chamber on the same first small diameter shaft portion side of the inner cylinder body via one inner flow passage. A second inner flow path, one of which is open at the end face forming the stepped portion of the inner cylinder body and the other of which is open at the end face on the side of the second small-diameter shaft in the sixth cylinder chamber provided in the inner cylinder body. And the one supplied to the third cylinder chamber on the side of the second small diameter shaft portion. 4. The structure according to claim 3, wherein the pressurized fluid is supplied to the sixth cylinder chamber on the side of the second small-diameter shaft portion of the inner cylinder body via the second inner flow path. Fluid intensifier.