JP2018155402A - Cylinder device, press device, work clamp device, cylinder device operation method, clamping method of work, and pressing method of work - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a cylinder device with large stroke, using an air hydraulic cylinder.SOLUTION: A pneumatic chamber 20 is composed of a first pneumatic chamber 21 for pressurizing a first piston 11, and a second pneumatic chamber 22 for pressurizing a second piston 12. The first pneumatic chamber 21 and the second pneumatic chamber 22 are communicated with each other. A hydraulic pressure generating portion 55 incorporates a hydraulic chamber 30, and further the hydraulic chamber 30 is composed of a first hydraulic chamber 31 pressurized by the first pneumatic chamber 21 through the first piston 11, and a second hydraulic chamber 32 pressurized by the second pneumatic chamber 22 through the second piston 12. The hydraulic pressure generating portion 55 can move in a cylinder 2 in a thrust direction, and the second hydraulic chamber 32 has a function for elastically deforming a thin portion 15 in a radial direction by a hydraulic pressure, and fixing the moving hydraulic pressure generating portion 55 in the cylinder 2. The first hydraulic chamber 31 outputs the hydraulic pressure of the first hydraulic chamber 31 increased by fixation to an output rod 7.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a cylinder device, a pressing device, a workpiece clamping device, a cylinder device operating method, a workpiece clamping method, and a workpiece pressing method, for example, to a device using a fluid pressure cylinder.

Fluid pressure cylinders using fluids such as air (gas) and oil (liquid) are used in a wide range of industries.
These fluid pressure cylinders can be the driving force for various mechanical operations such as driving of a press and an actuator, for example, by generating a thrust in a piston in the cylinder with a fluid pressure.

By the way, the hydraulic cylinder is characterized in that a large thrust can be obtained even with a small size by a large pressure applied by the hydraulic pressure, but there is a problem that a large-scale facility such as a hydraulic pressure supply device is necessary.
For this reason, Patent Document 1 proposes a fluid pressure cylinder that can be reduced in size at low cost by eliminating the complicated hydraulic system by generating hydraulic pressure with air pressure by an air hydro cylinder that combines an air cylinder and a hydraulic cylinder. doing.

However, the technique of Patent Document 1 has a problem in that the stroke is short because the amount of movement of the piston of the air cylinder is made to correspond to the sectional area of the hydraulic cylinder.
For example, when an actuator is mounted on the output side of an air-hydro cylinder, it is necessary to move the actuator together with the air-hydro cylinder in order to ensure a stroke.

Japanese Patent No. 4895342

  An object of this invention is to provide the cylinder apparatus with a large stroke using an air hydro cylinder.

In order to achieve the above object, the present invention provides a cylinder, a pneumatic chamber formed on one end side in the cylinder, a hydraulic chamber that moves in the cylinder to the other end side by the pressure of the pneumatic chamber, A fixing means for generating a radial force from a thrust force applied to the hydraulic chamber by the pneumatic chamber, and fixing the hydraulic chamber in the cylinder by the radial force; and the pneumatic chamber A hydraulic amplifying means provided on the other end side for amplifying the hydraulic pressure generated in the fixed hydraulic chamber by the pneumatic chamber; and the outside of the one end side of the cylinder through the hydraulic amplifying means and the pneumatic chamber And an output rod that outputs the amplified hydraulic pressure at the one end side.
In the invention according to claim 2, the hydraulic chamber has a force in the other end side direction that the pneumatic chamber gives to the hydraulic chamber and a force in the one end side direction that the output rod gives to the hydraulic chamber. The cylinder device according to claim 1, wherein hydraulic pressure is generated by receiving the cylinder device.
According to a third aspect of the present invention, the hydraulic chamber includes a first hydraulic chamber provided with the output rod, and a second hydraulic chamber provided with the fixing means. The radial pressure is generated by the hydraulic pressure of the second hydraulic chamber to fix the second hydraulic chamber and the first hydraulic chamber, and the hydraulic amplifying means amplifies the hydraulic pressure generated in the first hydraulic chamber. Then, the cylinder device according to claim 1, wherein the cylinder device is output to the output rod.
According to a fourth aspect of the present invention, the fixing means presses the side wall of the second hydraulic chamber elastically deformed by the radial force against the inner wall of the cylinder, whereby the second hydraulic chamber and the first hydraulic pressure are pressed. The cylinder device according to claim 3, wherein the chamber is fixed.
According to a fifth aspect of the present invention, the fixing means generates a radial force by pressing a taper member moving in the thrust direction against the clamper with the hydraulic pressure generated in the second hydraulic chamber. The cylinder device according to claim 3, wherein the second hydraulic chamber and the first hydraulic chamber are fixed by pressing the clamper against an inner wall of the cylinder.
According to a sixth aspect of the present invention, the first hydraulic chamber is provided with an output piston that presses the output rod in the output direction. A cylinder device is provided.
In the invention according to claim 7, the output piston of the first hydraulic chamber does not move even when the hydraulic pressure generated by being amplified in the first hydraulic chamber works on the output rod and outputs thrust, The cylinder device according to claim 6, wherein only the output is transmitted to the output rod.
In the invention according to claim 8, the pneumatic chamber includes a first pneumatic chamber including a first piston that pressurizes the first hydraulic chamber, and a second piston that pressurizes the second hydraulic chamber. A second air pressure chamber; and a communication hole that communicates the first air pressure chamber and the second air pressure chamber. The first air pressure chamber includes a first intake / exhaust port and the second air chamber. The cylinder device according to any one of claims 3 to 7, wherein the cylinder device is formed on the one end side of the pressure chamber.
According to a ninth aspect of the present invention, the first piston is configured such that the other end to which the first hydraulic chamber is movable until the output rod comes into contact with the object to be pressed by the pressure of the first pneumatic chamber. The cylinder device according to claim 8, wherein the second pneumatic chamber, the first hydraulic chamber, and the second hydraulic chamber are moved to the other end side until reaching a side end portion. I will provide a.
According to a tenth aspect of the present invention, the amount of movement of the second piston when the second piston of the second hydraulic chamber generates an amplified hydraulic pressure in the second hydraulic chamber is allocated to the second piston. The cylinder device according to claim 9, wherein the cylinder device is within a range of an elastic deformation amount of a seal member of the second hydraulic chamber provided.
The invention according to claim 11 is characterized in that the first pneumatic chamber has a first intake / exhaust port, and has a communication hole communicating the first pneumatic chamber and the second pneumatic chamber. A cylinder device according to claim 9 or 10 is provided.
In a twelfth aspect of the present invention, the first hydraulic chamber is formed on the other end side of the second hydraulic chamber, and the first piston includes the second pneumatic chamber and the second hydraulic chamber. The cylinder device according to claim 9, 10, or 11, wherein the cylinder device is formed up to the first hydraulic chamber.
In a thirteenth aspect of the present invention, a third pneumatic chamber is provided on the other end side in the cylinder, has a second intake / exhaust port, and presses the hydraulic chamber toward the one end side. A cylinder device according to claim 11 or claim 12 is provided.
The invention according to claim 14 comprises rotation angle changing means for changing the rotation angle around the center axis of the output rod when the output rod is moved. A cylinder device according to any one of the claims is provided.
In the invention according to claim 15, the rotation angle changing means is formed on the output rod, a protruding member formed on one side of the sliding surface facing the output rod, and the other side. The cylinder device according to claim 14, wherein the rotation angle of the output rod is changed by a sliding mechanism that engages with the projecting member and a groove formed in a moving direction of the output rod. I will provide a.
According to a sixteenth aspect of the present invention, the cylinder device according to the eleventh aspect, a workpiece setting means for setting a workpiece at a predetermined position with respect to the cylinder device, and the cylinder device is driven to be attached to the output rod. There is provided a press device comprising press means for pressing the set work with the tool and a detaching means for detaching the pressed work from the predetermined position.
The invention according to claim 17 is the cylinder device according to claim 13, work placing means for placing a work at a predetermined position with respect to the cylinder device, and driving the cylinder device to attach it to the output rod. There is provided a workpiece clamping device comprising: means for pressing and clamping the placed workpiece with a tool that has been removed; and detaching means for detaching the clamped workpiece from the predetermined position.
According to an eighteenth aspect of the invention, there is provided a cylinder device operating method for operating the cylinder device according to the thirteenth aspect, wherein the third air pressure chamber is pressurized from the second intake / exhaust port and the first air exhaust port is used for the first air exhaust. A first step of reducing the pressure chamber and the second pneumatic chamber to move the first hydraulic chamber and the second hydraulic chamber to one end side and setting them to an initial state; and The first and second pneumatic chambers are moved to the other end side by pressurizing the pressure chamber and the second pneumatic chamber and depressurizing the third pneumatic chamber from the second intake / exhaust port. Then, the output rod is brought into contact with the object to be pressed, or the second hydraulic pressure chamber is made to reach the end on the other end side where the first hydraulic chamber can move, and further from the first intake / exhaust port. Pressure to operate the fixing means to fix the first hydraulic chamber and the second hydraulic chamber to the cylinder. And a fourth step of operating the hydraulic pressure amplifying means by further pressurizing from the first intake / exhaust port and pressing the output rod against the pressing object; and the third pneumatic chamber from the second intake / exhaust port And a first step of depressurizing the first intake / exhaust port to move the first hydraulic chamber and the second hydraulic chamber to the one end side to return to the initial state. A cylinder device operating method is provided.
According to a nineteenth aspect of the present invention, there is provided a method of operating the cylinder device according to the thirteenth aspect to clamp the workpiece in a predetermined position, the first step of setting the workpiece in a predetermined position, and driving the cylinder device. The first pneumatic chamber until the tool mounted on the output rod comes into contact with the workpiece and stops, or until the first hydraulic chamber reaches the movable end of the other end and stops. A second step of moving by pneumatic pressure, a second step of moving by pneumatic pressure, a third step of fixing the first hydraulic chamber and the second hydraulic chamber by the fixing means, and the hydraulic amplifying means A fourth step in which the hydraulic pressure in the first hydraulic chamber is amplified, and a fifth step in which the tool attached to the output rod presses the workpiece with the hydraulic pressure and clamps it in place by the hydraulic pressure amplified in the fourth step. It provides a way of clamping the workpiece and having Tsu and up, the.
According to a twentieth aspect of the invention, there is provided a method of pressing the workpiece by operating the pressing device according to the sixteenth aspect, wherein the cylinder device is driven to return the position of the output rod to an initial state. A step, a second step of placing the workpiece at a predetermined position, and driving the cylinder device until the tool attached to the output rod comes into contact with the workpiece and stops, or the first hydraulic chamber is movable. A third step of moving the first pneumatic chamber by the pressure of the first pneumatic chamber until reaching the end of the other end side and stopping; and a fourth step of fixing the first hydraulic chamber and the second hydraulic chamber by the fixing means. A fifth step in which the oil pressure in the first hydraulic chamber is amplified by the oil pressure amplifying means, and a tool attached to the output rod presses the workpiece with the oil pressure by the oil pressure amplified in the fifth step. , A sixth step of pressing the workpiece, a seventh step of driving the cylinder device to disengage the tool mounted on the output rod together with the output rod from the workpiece by air pressure, and a workpiece that has been pressed And an eighth step of releasing from the position of the workpiece.
In a twenty-first aspect of the present invention, the pneumatic chamber includes a first pneumatic chamber that includes a first piston that pressurizes the first hydraulic chamber, and a second piston that pressurizes the second hydraulic chamber. A second pneumatic chamber, the second pneumatic chamber is disposed on the one end side of the second hydraulic chamber, and the first pneumatic chamber is on the other end side of the second hydraulic chamber. A first intake / exhaust port that pressurizes the second pneumatic chamber, and a third intake / exhaust that pressurizes the first pneumatic chamber through the second pneumatic chamber and the second hydraulic chamber. A cylinder device according to any one of claims 3 to 7 is provided.
In a twenty-second aspect of the present invention, the output rod penetrates to the outside of the one end side of the second pneumatic chamber, the second hydraulic chamber, and the cylinder, and the third intake / exhaust port includes the output rod. The cylinder device according to claim 21, wherein the first pneumatic chamber is pressurized from a portion of the output rod through a part of the output rod.
In the invention according to claim 23, the output rod penetrates from the outside of the one end side to the outside of the other end side in the entire length of the cylinder, and the third intake / exhaust port is the other end of the output rod. The cylinder device according to claim 21, wherein the first pneumatic chamber is pressurized from a side through a part of the output rod.
According to a twenty-fourth aspect of the present invention, an input-side housing having the second hydraulic chamber and an output-side housing having the first pneumatic chamber and the first hydraulic chamber 31 are provided. The cylinder device according to claim 21, 22 or 23, wherein the cylinder device is fixed to the one end side of the side housing.
In a twenty-fifth aspect of the invention, the second piston is disposed between the input-side housing and the second pneumatic chamber, and moves to the other end side by the pressure from the second pneumatic chamber. The cylinder device according to claim 24, further comprising a rod portion that pressurizes the second hydraulic chamber by the movement.
According to a twenty-sixth aspect of the invention, there is provided a cylinder device operating method for operating the cylinder device of the twenty-fifth aspect, wherein the second piston and the second piston are pressurized by pressurizing the second pneumatic chamber from the first intake / exhaust port. The movement of the input housing and the output housing is stopped by moving the input housing and the output housing to the other end, and bringing the output rod into contact with the object to be pressed. A movement stop step, and further pressurizing the second pneumatic chamber from the first intake / exhaust port, and moving the second piston to the other end side, so that the second hydraulic chamber is moved by the rod portion. A fixing step for fixing the input side housing and the output side housing to the cylinder by pressurizing and operating the fixing means; and after the fixing, the first pneumatic chamber is opened from the third intake / exhaust port. It operates the hydraulic amplification means by applying, to provide a cylinder apparatus operation method characterized by having a thrust generation step of generating a thrust by the amplified pressure from the tip of the output rod.

  According to the present invention, the stroke can be ensured and the thrust can be ensured by moving the hydraulic chamber in the cylinder by the pneumatic chamber.

It is a figure for demonstrating the cylinder apparatus of 1st Embodiment. It is a figure for demonstrating press work. It is a figure for demonstrating the cylinder apparatus of 2nd Embodiment. It is a figure for demonstrating the cylinder apparatus of 3rd Embodiment. It is a figure for demonstrating the cylinder apparatus of 4th Embodiment. It is a figure for demonstrating the cylinder apparatus of 5th Embodiment. It is component drawing of 5th Embodiment. It is explanatory drawing showing the operation state of 5th Embodiment. It is a figure for demonstrating the cylinder apparatus of 6th Embodiment. It is a figure for demonstrating the cylinder apparatus of 7th Embodiment.

(Outline of the first embodiment)
The conventional air-hydro cylinder has a feature that the air cylinder portion has a large stroke but a small thrust, and the hydraulic cylinder portion has a feature that the stroke is small but the thrust is large.
there. In the cylinder device 1 (FIG. 1) of the present embodiment, the function of moving the hydraulic system consisting of the hydraulic chamber 30 in the thrust direction within the cylinder 2 to the pneumatic system consisting of the pneumatic chamber 20, and the hydraulic chamber 30 after the movement By providing the function of generating hydraulic pressure by applying pressure, the necessary stroke is secured and the necessary thrust is generated.

More specifically, the pneumatic chamber 20 includes a first pneumatic chamber 21 that pressurizes the first piston 11 and a second pneumatic chamber 22 that pressurizes the second piston 12.
The first pneumatic chamber 21 and the second pneumatic chamber 22 communicate with each other through a through hole formed inside the retaining bolt 17.

On the other hand, the hydraulic pressure generator 55 has a built-in hydraulic chamber 30, and the hydraulic chamber 30 further includes a first hydraulic chamber 31 pressurized by the first pneumatic chamber 21 via the first piston 11, and a first hydraulic chamber 31. The second hydraulic chamber 32 is pressurized by the second pneumatic chamber 22 via the two pistons 12.
The hydraulic pressure generating section 55 can move in the thrust direction in the cylinder 2, and the second hydraulic chamber 32 elastically deforms the thin-walled section 15 in the radial direction by hydraulic pressure, and moves the moving hydraulic pressure generating section 55 to the cylinder 2. It has the function of fixing inside.
The first hydraulic chamber 31 outputs to the output rod 7 the hydraulic pressure of the first hydraulic chamber 31 that has been increased by fixation.

The operation of the cylinder device 1 is as follows.
First, the first intake / exhaust port 5 is opened and air is injected from the second intake / exhaust port 6, and the hydraulic pressure generating unit 55 is moved toward the first intake / exhaust port 5 to be set in the initial state.
Next, the second intake / exhaust port 6 is opened and air is injected from the first intake / exhaust port 5.
As a result, the first pneumatic chamber 21 is pressurized, the first piston 11 is pushed, and the hydraulic pressure generator 55 moves to the second intake / exhaust port 6 side. Thereby, a sufficient stroke of the output rod 7 is obtained.

When the output rod 7 comes into contact with the workpiece 100 via a tool such as a claw 76, the movement of the hydraulic pressure generating portion 55 is stopped. The second hydraulic chamber 32 inside the hydraulic pressure generating unit 55 is configured such that the lid 34 is configured as an inner wall on the output side, and the internal oil is sandwiched between the second piston 12 of the second pneumatic chamber 22. ing.
The seal members used for the first piston 11 and the second piston 12 are made of different materials, and the seal member of the second piston 12 has a lower sliding resistance, starts operating earlier, and completes earlier. It is like that. The difference in sliding resistance between the seal members of the first piston 11 and the second piston 12 is based on a difference in frictional resistance due to a difference in material, but may be based on a difference in shape and tightening allowance.
When the movement of the hydraulic pressure generator 55 stops and the movement of the lid 34, which is an internal partition wall, stops, the internal pressure rises because the pressure is pressed by the second piston 12 from the input side. Similarly, the first hydraulic chamber 31 inside the hydraulic pressure generating unit 55 is sandwiched between the output rod 7 and the first piston 11 of the first pneumatic chamber 21, and when the output side is stopped moving by the output rod 7. Since it is pressed by the first piston 11 from the input side, the internal pressure rises.
At this time, since the second piston 12 having a small sliding resistance moves faster, the thin wall portion 15 is elastically deformed first by the hydraulic pressure of the second hydraulic chamber 32 and comes into contact with the inner peripheral surface of the cylinder 2 due to friction. The hydraulic pressure generator 55 is fixed to the cylinder 2.

When the hydraulic pressure generating unit 55 is fixed, the first piston 11 and the second piston 12 further pressurize the first hydraulic chamber 31 and the second hydraulic chamber 32 by the air supplied from the first intake / exhaust port 5.
As a result, the hydraulic pressure increased in the second hydraulic chamber 32 further presses the thin wall portion 15 against the inner peripheral surface of the cylinder 2, and the fixation is further secured. When the hydraulic pressure generating portion 55 is fixed to the cylinder 2, the thrust force for moving the third piston 13 forward by the hydraulic pressure in the first hydraulic chamber 31 increases, so that the further increased oil pressure in the first hydraulic chamber 31 is increased by the third piston. 13 and output to the output rod 7, and a large thrust by hydraulic pressure is applied to the workpiece 100.
As described above, the cylinder device 1 can have both a long stroke by the air cylinder device and a large hydraulic pressure by the hydraulic cylinder.

(Details of the first embodiment)
FIG. 1A shows a cross-sectional view in the thrust direction (the direction of the center line) of the cylinder device 1 according to the first embodiment, and FIG. 1B shows a component diagram.
In FIG. 1A, the O-ring is omitted in order to avoid complication of the drawing. The omitted O-ring is disposed between members constituting a space for sealing a fluid such as air or oil, and is installed to seal the space and prevent leakage of the fluid. FIG. The O-ring is also shown in the part diagram.

  The cylinder device 1 is configured by closing both open ends of the cylinder 2 with lids 3 and 4, and a hydraulic pressure generating unit 55 that moves in the thrust direction by the first piston 11 of the first pneumatic chamber 21 is provided inside. It is stored (built-in).

The hydraulic pressure generator 55 is an assembly having a hydraulic pressure generating function including the second pneumatic chamber 22, the second hydraulic chamber 32, the first hydraulic chamber 31, and the like housed in the piston housing 14 as a casing. It is.
The hydraulic pressure generating unit 55 moves to the output side (the second intake / exhaust port 6 side) due to the pressure in the first pneumatic chamber 21. The second hydraulic chamber 32 fixes the hydraulic pressure generating portion 55 moved by the hydraulic pressure in the cylinder 2, and the first hydraulic chamber 31 is fixed to propel the hydraulic pressure increased inside in one direction of the output rod 7. Output as force.

  The output rod 7 extends through the second hydraulic chamber 32, the second pneumatic chamber 22, and the first pneumatic chamber 21 to the outside of the lid 3 on the input side (the first intake / exhaust port 5 side). In other words, the cylinder 2 extends to the outside on one end side. Further, the output rod 7 presses the workpiece 100 against the workpiece installation table 101 on one end side of the cylinder 2 by pulling the claw 76 installed at the tip toward the cylinder device 1 side.

  As described above, the cylinder device 1 includes the hydraulic chamber that moves in the cylinder to the other end side (output side) with the pressure of the pneumatic chamber, and the hydraulic chamber has a first hydraulic pressure in which the output rod 7 is provided. The chamber 31 and the second hydraulic chamber 32 provided with fixing means are configured.

The material of the parts constituting the cylinder device 1 is a metal such as aluminum, stainless steel, or iron.
As an example, the cylinder device 1 has an outer diameter of about 20 mm and a stroke length of about 50 mm, but may be larger or smaller. The above is the outline of the configuration of the cylinder device 1.

Hereinafter, one end side where the first intake / exhaust port 5 is formed is referred to as an input side because it is a side to which pressurizing air is input, and the other end side where the second intake / exhaust port 6 is formed is output with hydraulic pressure. Since this is the side to be processed, it will be called the output side. For this reason, the output rod 7 is formed on the input side.
Further, the state shown in FIG. 1A in which the components in the cylinder 2 are located on the most input side will be referred to as an initial state.

The cylinder 2 is a cylindrical member whose both end faces are open, and constitutes a casing of the cylinder device 1.
The input side end of the cylinder 2 is closed by a lid 3 made of a columnar member.
A recess 43 for inserting the cylinder 2 is formed on the output side of the lid 3. A male screw formed on the outer periphery of the input side end of the cylinder 2 and a female screw formed on the inner peripheral surface of the recess 43 By fitting, the cylinder 2 and the lid 3 are screwed and joined.
Further, a through-hole for inserting the output rod 7 and extending to the outside of the lid 3 is formed on the center line of the lid 3.

A first piston 11 that slides in the thrust direction along the inner wall of the cylinder 2 is provided at the end portion on the input side in the cylinder 2.
The input-side end surface of the first piston 11 and the bottom surface of the concave portion 43 face each other, and a convex portion 44 having a groove is formed on the bottom surface of the concave portion 43.

Since the movement range of the first piston 11 to the input side is restricted by the convex portion 44, even when the first piston 11 is closest to the input side, the concave portion 43, the end surface of the first piston 11, and the cylinder 2 A space surrounded by the inner wall is formed.
An intake / exhaust passage communicating with the space from the first intake / exhaust port 5 is formed on the side surface of the lid 3, whereby a first pressure that can be increased or decreased by intake or exhaust from the first intake / exhaust port 5. A pneumatic chamber 21 is formed in the space.
The groove is formed in the convex portion 44 so that when air is supplied from the first intake / exhaust port 5, the air quickly spreads over the entire end surface of the first piston 11.

The output side end face of the first piston 11 penetrates a retaining nut 18, a second pneumatic chamber 22, a second piston 12, an overhang portion 57, a second hydraulic chamber 32, and a lid 34, which will be described later, along the center line. Thus, the rod portion 50 reaching the first hydraulic chamber 31 is formed in the thrust direction.
The rod portion 50 is formed in a cylindrical shape, and a through hole is formed through the first piston 11 along the center line so as to be slidably inserted through the output rod 7.

Thus, the first hydraulic chamber 31 is formed on the other end side (output side) of the second hydraulic chamber 32, and the first piston 11 penetrates the second pneumatic chamber 22 and the second hydraulic chamber 32. The first hydraulic chamber 31 is formed.
The first piston 11 has a function of moving the hydraulic pressure generating unit 55 to the output side in the cylinder 2 and a function of pressurizing the first hydraulic chamber 31 and outputting the hydraulic pressure to the output rod 7.

A hydraulic pressure generator 55 is disposed on the output side of the first piston 11.
The hydraulic pressure generator 55 uses the piston housing 14 having a substantially cylindrical shape as a casing, and drives the second pneumatic chamber 22, the second hydraulic chamber 32, and the first hydraulic chamber 31 formed in the casing. The hydraulic pressure generating assembly generates the hydraulic pressure.

The piston housing 14 is a substantially cylindrical member having an internal shape that forms the second pneumatic chamber 22, the second hydraulic chamber 32, and the first hydraulic chamber 31 from the input side.
A thin portion 15 that slides with a predetermined clearance from the inner peripheral surface of the cylinder 2 is formed in the outer cylinder portion at the center of the piston housing 14. The outer diameter is smaller than that.

A retaining nut 18 that closes the opening of the piston housing 14 is fitted to an end of the piston housing 14 on the input side, and a female screw formed on the piston housing 14 and a male screw formed on the retaining nut 18 are fitted. It is fixed by screwing together.
A coil spring 19 is provided between the first piston 11 and the retaining nut 18 to urge the first piston 11 away from the first piston 11 and the retaining nut 18.
The coil spring 19 is installed in a recess formed at a corresponding position on the output side end surface of the first piston 11 and the input side end surface of the retaining nut 18.

The first piston 11 is formed with a through hole for inserting the retaining bolt 17, and the retaining nut 18 is provided with a screw hole for fixing the retaining bolt 17. ing.
The through hole of the retaining nut 18 is counterbored on the input side, and a collar 16 that is a cylindrical member is inserted from the through hole of the first piston 11 to the counterbored portion.

A retaining bolt 17 is inserted into the collar 16, and the distal end of the retaining bolt 17 is fitted and fixed to a female screw formed on the retaining nut 18.
Further, the input side of the through hole of the first piston 11 is counterbored, and the head of the retaining bolt 17 is in contact with the counterbored portion, thereby preventing the first piston 11 from coming off.

Although not shown, an O-ring is provided between the outer peripheral surface of the collar 16 and the inner peripheral surface of the through hole of the first piston 11, and the first piston 11 slides in the thrust direction with respect to the collar 16. Can do.
As described above, the first piston 11 is biased in the direction away from the retaining nut 18 by the coil spring 19, and the retaining piston 17 prevents the first piston 11 from being separated from the retaining nut 18 by a predetermined distance or more. Maximum separation is regulated.

This maximum separation amount is formed between the output side end face of the first piston 11 and the input side end face of the retaining nut 18 to form a gap 51 for ensuring a stroke in which the first piston 11 is pushed into the retaining nut 18 side. Is set to an amount.
With the above configuration, in the initial state, the first piston 11 and the retaining nut 18 are separated by an amount regulated by the retaining bolt 17 by the coil spring 19, but pressure is applied to the first pneumatic chamber 21, When the hydraulic pressure generating section 55 is fixed by the second hydraulic chamber or when the hydraulic pressure generating section 55 comes into contact with the lid 4 and cannot move, the first piston 11 can approach the retaining nut 18.
At this time, air in the gap 51 is discharged from a through hole 40 described later to the third pneumatic chamber 41 via a space between the outer periphery of the piston housing 14 and the inner periphery of the cylinder 2.

A recess is formed on the output side of the retaining nut 18, and the second empty space is formed by the end surface of the second piston 12 disposed on the output side of the retaining nut 18 in the piston housing 14 and the space formed by the recess. A pressure chamber 22 is formed.
Further, a through-hole through which the rod portion 50 is slidably inserted is formed on the center line of the retaining nut 18.
A through hole is formed in the retaining bolt 17 along the center line, and the first pneumatic chamber 21 and the second pneumatic chamber 22 communicate with each other through the through hole.

Thus, the cylinder device 1 includes a pneumatic chamber (pneumatic chamber 20) formed on one end side (input side) in the cylinder. The pneumatic chamber 20 adds the first hydraulic chamber 31 to the pneumatic chamber. The first pneumatic chamber 21 includes a first piston 11 that pressurizes, and the second pneumatic chamber 22 includes a second piston 12 that pressurizes a second hydraulic chamber 32.
The first pneumatic chamber 21 is provided on one end side of the second pneumatic chamber 22 and has a first intake / exhaust port 5.
Further, the first piston 11 has a communication hole that communicates the first pneumatic chamber 21 and the second pneumatic chamber 22.

On the output side of the second piston 12, a projecting portion 57 is formed that projects from the inner peripheral surface of the cylinder 2 in the direction of the center line in order to form the second hydraulic chamber 32.
Between the output side end surface of the second piston 12 and the input side end surface of the overhanging portion 57, a coil spring 33 that urges the second piston 12 in a direction away from the overhanging portion 57 is installed. The rod portion 50 of the first piston 11, the rod portion 58 of the second piston 12, and the output rod 7 are inserted through the center.

With the above configuration, in the initial state, the input side end surface of the second piston 12 abuts on the tip of the edge of the recess of the retaining nut 18, and the output side end surface of the second piston 12 and the input side end surface of the overhang portion 57. A gap 52 for ensuring a stroke in which the second piston 12 is pushed toward the overhanging portion 57 is provided between the two.
Further, in the portion where the gap 52 of the piston housing 14 is formed, the air in the gap 52 is released to the space between the piston housing 14 and the cylinder 2 when the second piston 12 moves toward the protruding portion 57. For this purpose, a through hole 40 is formed.

A through hole reaching the second hydraulic chamber 32 is provided on the center line of the overhang portion 57, and the rod portion 58 of the second piston 12 is slidably inserted.
Further, the rod portion 58 is formed with a through hole penetrating the second piston 12 on the center line, and the rod portion 50 of the first piston 11 is slidably inserted through the through hole.
Thus, the rod portion 58 is formed in a cylindrical shape, and an end portion that penetrates the protruding portion 57 and is exposed to the second hydraulic chamber 32 functions as a piston that pressurizes the oil in the second hydraulic chamber 32.

Here, the air pressure in the first pneumatic chamber 21 and the second pneumatic chamber 22 is P1, and the sectional area of the second piston 12 in the second pneumatic chamber 22 (the portion that receives pressure from the air is projected in the thrust direction. S1 is the area (the same applies hereinafter), S2 is the cross-sectional area of the rod portion 58 in the second hydraulic chamber 32, and F1 is the force by which the coil spring 33 biases the second piston 12, the hydraulic pressure P2 in the second hydraulic chamber 32 is P2 = (P1 · S1-F1) / S2. Therefore, if (P 1 · S 1 -F 1) / S 2> P 1, the pressure in the second pneumatic chamber 22 is amplified and transmitted to the second hydraulic chamber 32.
The hydraulic pressure generating unit 55 is configured to satisfy this condition, and the second hydraulic chamber 32 firmly fixes the hydraulic pressure generating unit 55 with the increased hydraulic pressure.

The second hydraulic chamber 32 is configured by a space in which the input side is partitioned by the overhang portion 57, the outer peripheral portion is partitioned by the thin portion 15 of the piston housing 14, and the output side is partitioned by the lid 34. Is filled.
The second hydraulic chamber 32 is pressurized according to the above formula because the rod portion 58 is inserted into the second hydraulic chamber 32 when the second piston 12 is pressed toward the overhanging portion 57 by the thrust force. Is done. In particular, when the output rod 7 contacts the workpiece 100 (more specifically, when the claw 76 attached to the tip of the output rod 7 contacts the workpiece 100), the pressure is rapidly applied.

The second hydraulic chamber 32 is pressurized according to the above formula because the rod portion 58 is inserted into the second hydraulic chamber 32 when the second piston 12 is pressed toward the overhanging portion 57 by the thrust force. Is done. At this time, the pressurized pressure uniformly presses the surrounding inner wall. The cross-sectional area in the thrust direction of the inner wall of the second hydraulic chamber 32 is smaller on the input side by the end area of the rod portion 58 than on the output side when comparing the input side and the output side. For this reason, the force with which the oil inside the second hydraulic chamber 32 presses the inner wall is larger on the output side having a larger cross-sectional area, so that the force that moves toward the output side acts on the second hydraulic chamber 32.
At this time, since air is simultaneously supplied to the pneumatic chamber 21 and the pneumatic chamber 22, the second piston 12 and the first piston 11 start to operate simultaneously. Therefore, oil pressure starts to be generated in the first hydraulic chamber 31 at the same time. The oil pressure generated in the first hydraulic chamber 31 presses the output side end face of the lid 34, and thus a force to move to the input side is generated in the hydraulic pressure generator 55.
In the relationship between the opposing forces to be moved to the output side and the input side, when the force to move to the output side by the second hydraulic chamber 32 is larger, the hydraulic pressure generating unit 55 includes the second hydraulic chamber. A force acts in the direction of pressing the output rod 7 by 32, but since the output rod 7 cannot move, the hydraulic pressure generator 55 also stops on the spot.
The hydraulic pressure increased in the second hydraulic chamber 32 cannot move in the thrust direction as the output rod 7 stops, pressure is applied to the thin portion 15 having low rigidity, and the radial direction indicated by the arrow line (from the center line) The outer peripheral surface of the thin portion 15 is pressed against the inner peripheral surface of the cylinder 2. Thereby, a frictional force is generated between the thin wall portion 15 and the cylinder 2, and the hydraulic pressure generating portion 55 is fixed in the thrust direction in the cylinder 2.
On the other hand, when the force to move to the input side by the first hydraulic chamber 31 is larger, the second piston 12 has a lower sliding resistance by the seal member than the first piston 11 and operates faster. The operation of the second piston 12 is completed before the first piston 11 moves through the gap 51 (before the first piston 11 abuts against the retaining nut 18), and pressure acts on the thin portion 15 having low rigidity, The outer peripheral surface is pressed against the inner peripheral surface of the cylinder 2, and the hydraulic pressure generating unit 55 is fixed in the thrust direction within the cylinder 2.

As described above, the cylinder device 1 includes a fixing unit that generates a radial force from the thrust force applied to the hydraulic chamber by the pneumatic chamber, and fixes the hydraulic chamber in the cylinder 2 by the radial force. Yes.
The hydraulic chamber generates hydraulic pressure by receiving the force in the other end side (output side) given to the hydraulic chamber by the pneumatic chamber and the force in the one end direction (input side) given by the output rod to the hydraulic chamber. Yes.
More specifically, the fixing means (thin wall portion 15) generates a radial force by the hydraulic pressure of the second hydraulic chamber 32, and the side wall of the second hydraulic chamber 32 elastically deformed by the radial force is applied to the cylinder 2. The second hydraulic chamber 32 and the first hydraulic chamber 31 are fixed by pressing against the inner wall.

The lid 34 has a male screw formed on the outer peripheral surface thereof, and is fixed by being screwed into a female screw formed at the output side end of the piston housing 14.
A through hole is formed at the center of the lid 34, and the tip portion of the rod portion 50 of the first piston 11 is inserted into the through hole.

A third piston 13 having an output rod 7 formed on the input side along the center line is disposed on the output side of the lid 34, and the output side end surface of the lid 34, the end surface of the tip portion of the rod portion 50, A first hydraulic chamber 31 partitioned by a space is formed on the input side end surface of the three piston 13, the input side end surface of an oil filler plug 38 described later, and the inner peripheral surface of the piston housing 14.
As described above, the first hydraulic chamber 31 includes the output piston (third piston 13) that presses the output rod 7 in the output direction.

  The third piston 13 is formed with an oil supply passage that communicates the output-side end face and the input-side end face and reaches the first hydraulic chamber 31. After that, an oil filler plug 38 for sealing this is fixed by a screw mechanism.

The output rod 7 passes through the first hydraulic chamber 31 and further passes through the inside of the rod portion 50 and the through hole of the lid 3 to thereby provide the second hydraulic chamber 32, the second pneumatic chamber 22, and the first pneumatic chamber. 21 extends to the outside of the lid 3.
A claw 76 is formed at the tip of the output rod 7 so as to project in a direction perpendicular to the axial direction of the output rod 7.
When the output rod 7 moves in the output direction, the claw 76 is drawn (drawn) toward the lid 3, and the output side end face of the claw 76 presses the workpiece 100 installed on the workpiece installation table 101 to the output side. .

With this configuration, when the first piston 11 approaches the piston housing 14, the rod portion 50 is inserted into the first hydraulic chamber 31, the oil in the first hydraulic chamber 31 is pressurized, and the output rod 7 is pressurized. Moves to the output side under hydraulic pressure.
Here, the pressure of the air in the first pneumatic chamber 21 and the second pneumatic chamber 22 is P1, the sectional area of the first piston 11 in the first pneumatic chamber 21 is S3, the hydraulic pressure of the first hydraulic chamber 31 is P3, The sectional area of the first piston 11 in the first hydraulic chamber 31 is S4.
In this case, P3 = S3 · P1 / S4, and if S3> S4, the pressure in the first pneumatic chamber 21 is amplified and transmitted to the first hydraulic chamber 31.

  Further, when the sectional area of the third piston 13 in the first hydraulic chamber 31 is S5, the force F with which the output rod 7 presses the workpiece 100 is F = P1, S3, S5 / S4.

The hydraulic system (hydraulic chamber 30) of the cylinder device 1 outputs the force F 3 necessary for machining the workpiece 100 by amplifying the pressure of the first pneumatic chamber 21 in the first hydraulic chamber 31 by the rod portion 50 of the piston 11. It is set so as to be exerted by the rod 7 (so that the thrust increases).
Thus, the cylinder device 1 includes a hydraulic amplifying means (piston 11, rod portion 50) for amplifying the hydraulic pressure generated by the pneumatic chamber 20 in the first hydraulic chamber 31, and a cylinder penetrating the hydraulic amplifying means and the pneumatic chamber. 2 is provided with an output rod 7 that extends to the outside of one end side (input side) of 2 and outputs the amplified hydraulic pressure at one end side. The hydraulic pressure amplifying means supplies the hydraulic pressure generated in the first hydraulic chamber 31. Amplified and output to the output rod 7.

A screw groove is formed at the open end of the output side of the piston housing 14, and a retaining nut 37 having a through hole through which the output rod 7 is inserted at the center is screwed.
A gap 54 is formed between the output side end surface of the third piston 13 and the input side end surface of the retaining nut 37 to secure a stroke for the third piston 13 to move in the output direction. A through hole 53 through which air in the gap 54 is inserted when the third piston 13 is moved is formed in the end face of 37.
A spring (not shown) may be disposed in the gap 54 between the output side end face of the third piston 13 and the retaining nut 37. This spring functions as an auxiliary to press the third piston 13 to the input side.

The lid 4 is a cylindrical member, and has a recess for inserting the cylinder 2 on the input side.
A female screw is formed on the inner peripheral surface of the concave portion, and both of them are screwed by fitting with a male screw formed on the corresponding outer peripheral surface of the cylinder 2.
Similar to the convex portion 44 of the lid 3, a convex portion having a groove is formed on the bottom surface of the concave portion.

Further, an intake / exhaust passage communicating from the second intake / exhaust port 6 to the inside of the cylinder 2 is provided on the side surface of the lid 4. A third pneumatic chamber 41 is formed.
The third pneumatic chamber 41 opens the first intake / exhaust port 5 and supplies air from the second intake / exhaust port 6, thereby moving the hydraulic pressure generating unit 55 to the input side and setting the cylinder device 1 in the initial state. Used to return to
Thus, the cylinder device 1 includes the third pneumatic chamber 41 that is provided on the other end side in the cylinder, has the second intake / exhaust port 6, and presses the hydraulic chamber (hydraulic chamber 30) toward the one end side. ing.

The cylinder device 1 configured as described above operates as follows.
First, air is supplied from the second intake / exhaust port 6 while the first intake / exhaust port 5 is opened to depressurize the pneumatic chamber 20 (the first pneumatic chamber 21 and the second pneumatic chamber 22). The pressure chamber 20 and the hydraulic chamber 30 (the first hydraulic chamber 31 and the second hydraulic chamber 32) are set to the initial state.
Next, air is supplied from the first intake / exhaust port 5 while the second intake / exhaust port 6 is opened to decompress the third pneumatic chamber 41.

Then, the air pressure in the first pneumatic chamber 21 and the second pneumatic chamber 22 rises, and the first piston 11 presses against the hydraulic pressure generating portion 55, so that the claw 76 of the output rod 7 comes into hydraulic pressure until it contacts the workpiece 100. The generator 55 slides to the output side and moves.
As described above, the first piston 11 has the second pneumatic chamber 22, the first hydraulic chamber 31, and the first until the output rod 7 contacts the object to be pressed (workpiece 100) with the pressure of the first pneumatic chamber 21. 2 The hydraulic chamber 32 is moved to the other end side (output side).

When the hydraulic pressure generating portion 55 moves and the claw 76 of the output rod 7 contacts the workpiece 100, the first piston 11 presses the first hydraulic chamber 31 and the second piston 12 presses the second hydraulic chamber 32. The oil in the first hydraulic chamber 31 and the second hydraulic chamber 32 is pressurized and the hydraulic pressure increases.
At this time, the hydraulic pressure generating portion 55 has a sectional area of the inner wall in the thrust direction of the second hydraulic chamber 32. Since the sectional area on the output side is larger than the sectional area on the input side by the end area portion of the rod portion 58, A pressing force is generated in the direction of the output rod 7.
At this time, the oil pressure generated in the first hydraulic chamber 31 presses the output side end face of the lid 34, so that a force to move to the input side is generated in the hydraulic pressure generating unit 55.
In the relationship between the contradictory forces to be moved to the output side and the input side, when the force to move to the output side by the second hydraulic chamber 32 is larger, the claw 76 of the output rod 7 is applied to the workpiece. Since the contact is stopped, the hydraulic pressure generator 55 also stops moving.
As a result, since the oil inside the second hydraulic chamber 32 cannot move in the thrust direction, the internal pressure further increases, and the thin wall portion 15 is pressed in the radial direction to be elastically deformed and brought into contact with the inner peripheral surface of the cylinder 2. As a result, the hydraulic pressure generator 55 is fixed in the cylinder 2.
On the other hand, when the force moved to the input side by the first hydraulic chamber 31 is larger, the second piston 12 has a lower sliding resistance than the first piston 11 and operates faster, so the first piston 11 Before the movement of the gap 51, the operation of the second piston 12 is completed, pressure is applied to the thin portion 15 having low rigidity, the outer peripheral surface is pressed against the inner peripheral surface of the cylinder 2, and the hydraulic pressure generating portion 55 Is fixed in the thrust direction in the cylinder 2.

Since air is further supplied to the pneumatic chamber 20 in a state where the hydraulic pressure generating unit 55 is fixed, the hydraulic pressure in the first hydraulic chamber 31 and the second hydraulic chamber 32 further increases. Thereby, the thin part 15 presses the cylinder 2 further, and the gripping force by the pressing force of the thin part 15 increases. As the gripping force by the thin wall portion 15 increases, the hydraulic pressure generating portion 55 is firmly held in the thrust direction (the hydraulic pressure generating portion 55 is fixed to the cylinder 2 by the thin wall portion 15), and the thrust in which the oil pressure in the first hydraulic chamber 31 is generated. It will not move even if it receives direction force. Then, the hydraulic pressure in the first hydraulic chamber 31 is applied to the output rod 7 and presses the workpiece 100 with the hydraulic pressure via the claw 76.
At this time, the workpiece 100 is only pressed and fixed in place after the claw 76 abuts against the workpiece 100. If there is no movement or deformation due to the oil pressure applied from the output rod 7, the third piston 13 does not move in the thrust direction in the first hydraulic chamber 31, so that the oil in the first hydraulic chamber 31 is taken out with the movement of the O-ring (see FIG. 1B) of the third piston 13. There is no.
Further, since the internal oil is sealed and the volume of the second hydraulic chamber 32 is constant, when the thin portion 15 swells in the radial direction, the volume in the thrust direction decreases and the volume increases in the radial direction. Therefore, the second piston 12 can move forward by the shortened amount. The amount of deformation in the radial direction of the thin wall portion 15 is very small. Therefore, the amount of change in the thrust direction is small, and the amount of movement of the second piston 12 is small and hardly moves. For this reason, the O-ring (see FIG. 1B) of the second piston 12 is hardly moved and the oil in the second hydraulic chamber 32 is hardly taken out to the outside. In the present embodiment, the amount of movement of the second piston 12 is set so as to be within an elastic deformation range of a seal member such as an O-ring (the seal member of the second hydraulic chamber 32 disposed on the second piston 12). In this embodiment, since the O-ring does not move at all, the internal oil is not taken out to the outside.
When the pressing process on the workpiece 100 is completed, the first intake / exhaust port 5 is opened, and the first pneumatic chamber 21 and the second pneumatic chamber 22 are decompressed.

As a result, the hydraulic pressure in the first hydraulic chamber 31 and the second hydraulic chamber 32 decreases.
In the second hydraulic chamber 32, the elastic deformation of the thin wall portion 15 is returned by the restoring force, and the fixing of the hydraulic pressure generating portion 55 is released. Further, the second piston 12 returns to the initial position by the biasing force of the coil spring 33.
Next, an example in which the workpiece 100 is pressed and clamped using the cylinder device 1 will be described.
It is assumed that a clamping member that is optimal for pressing and clamping the workpiece 100 is assembled to the tip of the output rod 7 in the cylinder device 1.
And the cylinder apparatus 1 presses the workpiece | work 100, and performs the clamp operation | movement to the member clamped in the following order.
(1) First, by opening the first intake / exhaust port 5 and supplying air to the second intake / exhaust port 6, the cylinder device 1 is brought into an initial state, whereby the clamp member is moved backward to set the workpiece 100 to a predetermined state. Install in the position. At this time, the workpiece 100 is installed so as not to move even if pressed.
(2) Then, the second intake / exhaust port 6 is opened and air is supplied from the first intake / exhaust port 5. Then, the output rod 7 moves forward in the output direction by air driving, and the clamping member attached to the tip of the output rod 7 contacts the workpiece 100.
(3) When the clamp member comes into contact, the pressure in the pneumatic chamber 20 increases, and the hydraulic pressure generating portion 55 is fixed to the cylinder 2. Thrust due to oil pressure is generated in the output rod 7. Thereby, since the workpiece | work 100 is pressed with a strong force, the workpiece | work 100 is strongly pressed and clamped to the member clamped.
(4) When releasing the workpiece 100 from the member to be clamped, the first intake / exhaust port 5 is opened, air is supplied from the second intake / exhaust port 6, the piston rod 7 is retracted by air drive, and then the workpiece 100 is removed from the predetermined position.
Thereafter, the above cycle is repeated while exchanging the workpiece 100.

Here, the generation of the oil pressure at the cylinder end, that is, the case where the oil pressure is generated in a state where the oil pressure generating portion 55 is in contact with the cylinder end (lid 4) on the output side will be described. This operation example is an example in which a hydraulic propulsion force can be generated even when the output rod 7 does not contact the workpiece 100.
The operation will be described below.
When the hydraulic pressure generating unit 55 moves forward and contacts the cylinder end (lid 4), the second piston presses the second hydraulic chamber 32 by the second pneumatic chamber 22, and at the same time, the first piston by the first pneumatic chamber 21. Presses the first hydraulic chamber 31. Since the hydraulic pressure generating unit 55 cannot advance, the oil in the second hydraulic chamber 32 is constricted and pressurized by the lid 34 and the second piston 12. Then, the thin portion 15 is elastically deformed, and the inner wall of the cylinder 2 is fixed. At this time, since the sliding resistance of the second piston 12 is smaller than that of the first piston 11, the second piston 12 operates faster, and the operation of the second piston 12 is completed before the first piston 11 moves through the gap 51.
When the hydraulic pressure generating portion 55 is fixed to the cylinder 2, the thrust force in the thrust direction is increased and the rigidity is increased. Force is generated.
As a result, it is possible to apply a hydraulic driving force to the output rod 7 even when the output rod 7 is not in contact with the workpiece.

FIG. 2A is a diagram for explaining an example in which press working is performed using the cylinder device 1.
A press device (not shown) fixes the cylinder device 1 with the output direction downward (that is, with the output rod 7 facing upward).
On the output side of the claw 76 attached to the output rod 7 as a tool, an installation base 73, a component 72, and a pin 71 are installed in this order from the bottom. The installation table 73 functions as a workpiece installation means.
The component 72 is formed with a through hole into which the pin 71 is inserted by an interference fit, and the pin 71 is temporarily inserted into the through hole in advance.
The cylinder device 1 press-fits the pins 71 that are temporarily inserted in the order of the numbers shown in parentheses.

(1) First, by opening the first intake / exhaust port 5 and supplying air to the second intake / exhaust port 6, the cylinder device 1 is brought into an initial state, whereby the claw 76 is moved back upward, A component 72 in which a pin 71 is temporarily inserted on 73 is installed at a predetermined position.
(2) Next, the second intake / exhaust port 6 is opened and air is supplied from the first intake / exhaust port 5.
Then, the output rod 7 moves forward in the output direction (downward) by driving with air, and the end surface of the claw 76 comes into contact with the tip of the pin 71.

(3) When the claw 76 and the pin 71 come into contact with each other, the pressure in the pneumatic chamber 20 is increased, the hydraulic pressure generating unit 55 is fixed to the cylinder 2, and the output rod 7 is driven by hydraulic pressure. Thereby, the claw 76 is pressed to the pin 71 with a strong force, and the pin 71 is press-fitted into the hole of the component 72. As described above, the pressing apparatus includes a pressing unit.
(4) When the press-fitting is completed, the first intake / exhaust port 5 is opened, air is supplied from the second intake / exhaust port 6, the claws 76 are pulled up by air driving, and then the component 72 is detached from the predetermined position. As described above, the pressing device includes the detaching means.

(Modification of the first embodiment)
In the cylinder device 1, the output rod 7, the rod portion 50, and the rod portion 58 are formed coaxially. Thus, the output rod 7 has a degree of freedom to rotate around the central axis.
In this modification, in order to restrict this degree of freedom and prevent the output rod 7 from rotating around the central axis, the output rod 7, the rod portion 50, and the rod portion 58 are eccentric from the center line of the cylinder 2. (The center line of the output rod 7, the rod part 50, and the rod part 58 is formed so as not to coincide with the center line of the cylinder 2).

That is, the rod part 50, the rod part 58, and the output rod 7 are formed from the first piston 11, the second piston 12, and the third piston 13 from positions offset from the centers of these pistons, such as eccentric pins.
In accordance with this, the through holes of the lid 3, the retaining nut 18, the overhanging portion 57, and the lid 34 are also eccentric.

Thereby, the output rod 7 can perform a piston motion while keeping the angle of the claw 76 constant.
Further, as a method of regulating the rotation angle around the central axis of the output rod 7, a cam mechanism described later can be used.

(Second Embodiment)
In the cylinder device 1a of the present embodiment, by using the cam mechanism, the rotation angle around the central axis of the output rod 7 is changed corresponding to the movement of the output rod 7 in the thrust direction.
Below, description is simplified or abbreviate | omitted about the same location as 1st Embodiment, and a different point is demonstrated.

FIG. 3A shows a sectional view of the cylinder device 1a in the thrust direction, and FIG. 3B shows a component diagram.
A blind hole 81 is formed in the third piston 13 from the output side end surface to the middle of the output rod 7 along the center line.
The reason why the blind hole 81 is not a through-hole but is closed at one end side is to prevent the leakage of the air in the third pneumatic chamber 41 from the hole.

A fixing hole for the cam shaft rod 82 is formed in the recess on the input end side of the lid 4 along the center line. The cam shaft rod 82 is fixed to the input side of the fixing hole by, for example, a screw mechanism. Yes.
Thus, the cam shaft rod 82 extends from the input side end of the lid 4 toward the output rod 7 along the center line of the cylinder 2.

  The outer diameter of the camshaft rod 82 is smaller than the inner diameter of the through hole 53 of the retaining nut 37 and the blind hole 81 of the output rod 7, and the camshaft rod 82 has a through hole 53 of the retaining nut 37. It penetrates and is inserted into the blind hole 81 of the output rod 7.

Since the camshaft rod 82 is fixed to the lid 4 and the hydraulic pressure generating portion 55 moves in the thrust direction, the inner peripheral surface of the blind hole 81 is moved along the camshaft rod 82 as the hydraulic pressure generating portion 55 moves. Slide on the outer peripheral surface.
The length of the blind hole 81 is set to such a length that the bottom surface of the blind hole 81 does not contact the tip of the cam shaft rod 82 even when the hydraulic pressure generating portion 55 moves to the most output side.

A guide groove 83 is formed on the side surface of the cam shaft rod 82 in the longitudinal direction. The cam shaft rod 82 is fixed so that the guide groove 83 faces a cam pin 80 described below.
The third piston 13 is formed with a through hole reaching the blind hole 81 from the side surface in the first hydraulic chamber 31. A cam pin 80 is inserted into the through-hole, and is fixed by, for example, a screw mechanism. ).
A predetermined clearance (gap) is set between the end surface of the tip of the cam pin 80 and the bottom surface of the guide groove 83, so that when sliding, the outer peripheral side surface of the cam pin 80 and the guide groove The side surfaces of 83 are in contact with each other.

In the case of a straight line as shown in FIG. 3, the guide groove 83 serves as a guide for linear driving of the claw 76. Further, the guide groove 83 may be formed in a spiral shape in a region corresponding to the turning range so that the claw 76 can be driven to turn in the middle.
That is, the guide groove 83 is formed with a spiral groove so as to connect the circumferential phase positions corresponding to the start and end positions of the rotation of the output rod 7 and the claw 76, and further output from the output side end of the spiral groove. A linear groove extending in the axial direction toward the side (in the direction of the lid 4) is formed. The linear groove portion is formed so that the claw 76 is linearly moved by pneumatic driving in the axial direction so that the workpiece 100 and the claw 76 come into contact with each other during the linear operation, and then the workpiece 100 is drawn (pushed). ing.

When the hydraulic pressure generating portion 55 moves in the thrust direction, the cam pin 80 and the guide groove 83 are engaged, so that the hydraulic pressure generating portion 55 rotates around the central axis following the guide groove 83. As a result, the output rod 7 also rotates following the guide groove 83.
The lengths of the cam shaft rod 82 and the guide groove 83 are set to the length that the cam pin 80 is engaged with the guide groove 83 even when the hydraulic pressure generating portion 55 moves to the most input side.

The state shown in the figure is an initial state, and represents a state where the cam pin 80 is located on the most input side of the cam shaft rod 82.
The position of the cam pin 80 when the hydraulic pressure generating part 55 moves to the most output side is the position of the cam pin 80a indicated by the wavy line in the figure.
The guide groove 83 between the two positions defines how the output rod 7 rotates.

In the portion where the guide groove 83 is formed linearly along the axis of the cam shaft rod 82, the output rod 7 moves while keeping the angle constant, and in the portion where the guide groove 83 is twisted in a spiral shape. The output rod 7 rotates along the twist.
Therefore, if the shape of the guide groove 83 is appropriately set, the claw 76 attached to the tip end of the output rod 7 is synchronized with the movement of the output rod 7 by the cam mechanism by the cam pin 80 and the guide groove 83. Can be rotated to an angle.

  For example, when the claw 76 is moved to the input side and the workpiece 100 is set on the workpiece setting table 101, the claw 76 is rotated at an angle that does not interfere with the setting operation of the workpiece 100, and after setting the workpiece 100, The shape of the guide groove 83 can define the operation of abutting the workpiece 100 and pressing it while rotating the workpiece 100 toward the workpiece 100 side.

  Thus, the cam mechanism functions as a rotation angle changing means that changes the rotation angle around the center axis of the output rod when the output rod moves, and the rotation angle changing means includes the output rod, Of the sliding surfaces facing the output rod, the projection member (cam pin 80) formed on one side and the projection member (cam pin 80) formed on the other side are engaged and the output rod moves. The rotation angle of the output rod is changed by a sliding mechanism with a groove portion (guide groove 83) formed in the direction.

(Third embodiment)
In the cylinder device 1a of the second embodiment, since the cam pin 80 is inserted from the first hydraulic chamber 31, there is an advantage that the structure can be reduced in size.
Therefore, in the cylinder device 1b of the third embodiment, the cam pin 80 is installed at a position where it can be easily replaced.

FIG. 4 shows a sectional view of the cylinder device 1b in the thrust direction.
In the cylinder device 1 b, a convex portion 84 is formed on the output side of the retaining nut 37, and the cam pin 80 is fixed to a through hole formed on the side surface of the convex portion 84.
A cam pin 80a indicated by a broken line indicates a position when the cam pin 80 is moved to the most output side. Other configurations are the same as those of the cylinder device 1a.

  Thus, in the cylinder device 1b, since the cam pin 80 is exposed to the outside of the hydraulic pressure generator 55, the overall length of the cylinder device 1b is longer than that of the cylinder device 1a, but the cam pin 80 can be easily replaced.

(Fourth embodiment)
The cylinder device 1 c according to the present embodiment fixes the hydraulic pressure generating unit 55 to the cylinder 2 by the clamper 90.
5A shows a cross-sectional view in the thrust direction around the clamper 90 of the cylinder device 1c, and FIG. 5D shows a part diagram around the clamper 90. FIG.
In this figure, the entire vicinity of the second pneumatic chamber 22 and the second hydraulic chamber 32 is shown without being shown in all drawings.
The input-side end surface of the second hydraulic chamber 32 includes an end surface of a columnar member 95 fixed to the piston housing 14 and an end surface of an annular member 91 disposed around the columnar member 95.
The annular member 91 has an inner peripheral surface in contact with the outer peripheral surface of the columnar member 95 and an outer peripheral surface in contact with the inner peripheral surface of the piston housing 14. These contacting surfaces are sealed by O-rings, and the annular member 91 can move in the thrust direction while maintaining airtightness.
On the input side of the cylindrical member 95, a female screw is formed, and a member corresponding to the retaining nut 18 in the first embodiment is assembled. A male screw is formed on the input side outer periphery of a member corresponding to the retaining nut 18, and a nut 97 is screwed and fixed.

A coil spring 96 is installed between the output side end face of the nut 97 and the annular member 91, and the annular member 91 secures a space constituting the second hydraulic chamber 32 (not shown, In order to ensure space, a restricting means for restricting the movement of the annular member 91 to the output side is provided), and the coil member 96 is biased to the output side.
For this reason, the annular member 91 moves to the input side when the hydraulic pressure in the second hydraulic chamber 32 increases, and moves back to the output side when the hydraulic pressure decreases.

As shown in FIG. 5B, a tapered portion 92 whose outer diameter decreases toward the input side (the left side in the drawing) is formed at the input side end of the annular member 91.
A clamper 90 is disposed in a space formed between the tapered portion 92 of the annular member 91 and the output side end surface of the nut 97.
The clamper 90 is an annular member formed with a tapered portion 93 whose inner diameter decreases toward the input side, and the angle of the tapered portion 93 is equal to the angle of the tapered portion 92.

As shown in FIG. 5C, the clamper 90 is divided into four so as to spread in the radial direction indicated by the arrow.
The outer peripheral surface of the clamper 90 is formed in parallel with the inner peripheral surface of the cylinder 2, and in the initial state, a predetermined clearance is formed between the outer peripheral surface of the clamper 90 and the inner peripheral surface of the cylinder 2, and there is friction between them. Power is not generated.

Further, a groove is formed in the circumferential direction on the outer peripheral surface of the clamper 90, and an O-ring 94 is installed in the groove.
In general, the O-ring is installed to maintain airtightness, but the O-ring 94 is installed to pull back the clamper 90 that spreads in the radial direction.
Therefore, the height of the groove formed on the outer peripheral surface of the clamper 90 is set to be larger than the diameter of the O-ring 94 so that the O-ring 94 does not contact the inner peripheral surface of the cylinder 2.
In the present embodiment, the O-ring 94 is used. However, if the member expands in the radial direction and the inner diameter becomes larger, any other member may be used as long as the member is intended to shrink back to the original inner diameter. it can. For example, a string-like annular elastic member having elasticity may be used. Moreover, you may use what made the annular | circular shape by connecting the both ends of a coil spring.

In the cylinder device 1b configured as described above, since the pressure in the second hydraulic chamber 32 is low in the initial state, the annular member 91 is urged to the output side by the coil spring 96, whereby the nut 97 A sufficient clearance is secured between the output side end face and the tapered portion 92 of the annular member 91.
Therefore, the clamper 90 is bundled in the central axis direction by the contraction force of the O-ring 94, a clearance is generated between the clamper 90 and the inner peripheral surface of the cylinder 2, and the hydraulic pressure generator 55 can move in the thrust direction. it can.

On the other hand, when the pressure in the second hydraulic chamber 32 increases, the clamper 90 is pushed and moved in the input direction by the hydraulic pressure.
Then, the clamper 90 is sandwiched between the output side end face of the nut 97 and the taper portion 92 of the annular member 91, and receives the force in the thrust direction from both ends as shown by the arrow lines in FIG. .
More specifically, when the second pneumatic piston 12 moves forward, the pressure in the second hydraulic chamber 32 increases, and the increase in pressure passes through the communication path 32a and the hydraulic chamber 32b (second chamber) in the end surface space of the annular member 91. To the hydraulic chamber).
When the force to move in the thrust direction generated by the pressure of the second hydraulic chamber 32 becomes larger than the force by which the O-ring 94 attempts to contract the clamper 90, the annular member 91 has a larger clamper 90. Move to the input side while expanding. At this time, the oil in the second hydraulic chamber 32 pushed away by the second piston 12 flows into the end space through the communication passage 32a, so that the annular member 91 moves in the thrust direction.

This thrust force is converted into a radial force as shown by the arrow in FIG. 5 (b) by the contact between the tapered portion 92 of the annular member 91 and the tapered portion 93 of the clamper 90. As a result, the clamper 90 is pushed out in the radial direction.
As a result, the outer peripheral surface of the clamper 90 and the inner peripheral surface of the cylinder 2 come into contact with each other to generate a frictional force, and the hydraulic pressure generating unit 55 is fixed in the cylinder 2.
The fixing method by the clamper 90 used in the fourth embodiment can also be used in the first embodiment, the second embodiment, and the third embodiment.

  In this example, a radial force is generated by pressing a taper member (annular member 91) moving in the thrust direction against the clamper 90 with the hydraulic pressure generated in the second hydraulic chamber 32, and the clamper 90 is moved by the force. The second hydraulic chamber 32 and the first hydraulic chamber 31 are fixed by pressing against the inner wall of the cylinder.

According to each embodiment described above, the following effects can be obtained.
(1) By skillfully combining an air piston and a hydraulic piston and incorporating an air hydro mechanism, it can be operated as an air piston until it abuts against the workpiece 100, and can be operated as a hydraulic cylinder after it abuts against the workpiece 100. It is possible to realize both the long stroke movement by the air piston and the large thrust characteristic of the hydraulic piston only by air supply that does not require individual incidental equipment such as a hydraulic pump or hydraulic piping that requires labor for construction. .
(2) After a necessary stroke is earned by the air piston, the thrust force in the thrust direction is converted into a radial force by elastic deformation of the thin wall portion 15 or pushing out of the clamper 90 to fix the hydraulic piston in the cylinder 2 Can do.
(3) Since the hydraulic piston can be fixed by increasing the force in the radial direction by hydraulic pressure, it can be firmly fixed.
(4) A large force can be generated by generating hydraulic pressure in a hydraulic cylinder fixed in the cylinder 2.
(5) Since most of the required strokes are covered with air pistons and the minimum required strokes are performed with hydraulic pistons, the amount of strokes of the hydraulic pistons can be reduced, so that wear due to oil leakage is minimized. Can do.
In particular, in the case of a usage method in which the output rod 7 is brought into contact with the workpiece 100 and then only the oil pressure is applied to the workpiece without the movement of the output rod 7, the amount of movement of each hydraulic piston in each hydraulic chamber is determined by each seal. Since it is only within the range of elastic deformation of the member, it is possible to prevent leakage of oil in each hydraulic chamber.
(6) The direction in which the thrust to the output rod 7 increases is not the direction of moving away from the position of the cylinder 1 and the second housing 62 fixed inside (the direction of pushing outward), but the direction of approaching (direction of pulling inward) Therefore, the force necessary for machining the workpiece 100 can be reliably transmitted.
(7) Since the cam mechanism for turning the output rod 7 around the central axis is provided, the claw 76 can be arranged in a phase different from that of the workpiece 100 before the second housing 62 is fixed in the radial direction.

Next, fifth to seventh embodiments will be described.
In the fifth to seventh embodiments, the piston housing 60 is moved to a predetermined position by air drive and then fixed to the cylinder 20 and fixed (clamping), and then the output rod 7 is moved by the air hydro mechanism. The hydraulic pressure output operation for generating the hydraulic pressure amplified at the tip can be performed separately.

(Fifth embodiment)
Hereinafter, a fifth embodiment will be described.
In the fifth embodiment, in the fixing operation, the operation of the rod portion 58 and the second piston 12 generates the hydraulic pressure in the radial direction in the second hydraulic chamber 32, thereby expanding the thin portion 15 and moving the piston housing 60. Is fixed to the cylinder 2.
On the other hand, in the hydraulic pressure output operation, the tip of the rod portion 50 pushes the first hydraulic chamber 31 by the movement of the first piston 11 to generate an amplified hydraulic pressure from the third piston 13 to the output rod 7.

FIG. 6 shows a cross section in the thrust direction showing the configuration of the cylinder device 1d in the fifth embodiment.
7A and 7B show parts arranged in the cylinder 2. FIG. 7A shows a cross section of each part. FIG. 7B shows a front view and a side view of the first housing 61 and a retaining ring 29. FIG. FIG.
Note that portions having the same structure and the same function as those of the first embodiment are denoted by the same reference numerals, and description thereof is omitted as appropriate. In FIG. 6, O-rings for sealing each part are displayed, but the description thereof is omitted. Further, in order to make the drawing easy to see, like the other embodiments, the cross section is not displayed, but the reference numerals are displayed separately in FIG. 6 (a) and FIG. 6 (b). In FIG. 6 (a), hatched areas are added to areas where air is present, dots are added to areas where oil is present, and symbols are displayed in relation to the main parts and areas filled with air and oil.

As shown in FIGS. 6 and 7, in the cylinder device 1d of the present embodiment, instead of the piston housing 14 (see FIG. 1) in the first embodiment, a first housing 61, a second housing 62, and a third housing 63 are used. A piston housing 60 (not shown) is provided in the cylinder 2.
As shown in FIG. 6, in order from the input side, a second housing 62 that houses the rod portion 58 connected to the second piston 12, a first housing 61 that houses the first piston 11 to which the rod portion 50 is connected, The third housing 63 that houses the third piston 13 to which the output rod 7 is connected is arranged in this order.

Both ends of the second housing 62 are formed as thick portions, the portion between them forms the thin portion 15, and the inside of the thin portion 15 is the second hydraulic chamber 32.
The thick wall portions at both ends of the second housing 62 are formed with oil supply holes for filling the second hydraulic chamber 32 with oil. It is sealed.
The lid 39 is fixed to the input side end of the second housing 62 by a plurality of bolts 39a arranged on the circumference. The lid 39 corresponds to the overhang portion 57 in the first embodiment.
A cylindrical recess 39d (see FIG. 7A) is formed on the input side of the lid 39, and a through hole for the rod portion 58 is formed at the center of the bottom of the recess 39d. A communication hole 39c that penetrates the bottom of the recess 39d in the axial direction is formed on the outside. The communication hole 39c constitutes a part of a path that connects a fifth pneumatic chamber 65 and a third pneumatic chamber 41, which will be described later.
A flange portion having a clearance with the inner peripheral wall of the cylinder 2 is formed at an input side end portion of the lid 39, and a sliding assist ring 2a is disposed on the peripheral surface of the flange portion. The sliding assist ring 2a is made of a material (for example, resin) other than metal including the other sliding assist rings 2b and 2c, and avoids metal contact between the cylinder 2 and the lid 39 and the first housing 61. In order to smoothly slide between the inner peripheral surface of the second housing 62 and the second housing 62.

A rod portion 58 is inserted through the recess 39d of the lid 39 and the central through hole. The second piston 12 is fixed to the input side of the rod portion 58 with a connecting screw 12a.
The rod portion 58 includes a small-diameter portion 58d and a medium-diameter portion whose diameter increases in order from the output side to the input side. As the rod portion 58 moves in the lid 39 in the output direction, the second hydraulic chamber 32 formed in the second housing 62 is pressurized at the tip of the small diameter portion 58d, and the oil pressure causes the thin portion 15 to move. The piston housing 60 (61-63) is fixed in the cylinder 2 by elastically deforming in the radial direction.

A concave portion 58b is formed in the middle diameter portion of the rod portion 58 along the outer periphery of the small diameter portion 58d. A small diameter portion 58 d of the rod portion 58 is inserted into the coil spring 33, one end side of the coil spring 33 is disposed in the recess 58 b, and the other end side is in contact with the bottom surface of the recess 39 d formed in the lid 39.
A flange portion 58c projecting in the radial direction is formed on the output side end surface of the medium diameter portion of the rod portion 58.
In the rod portion 58, the retaining ring 29 is fixed to the lid 39 from the input side with the bolt 29 c in a state where the small diameter portion and the medium diameter portion of the rod portion 58 through which the coil spring 33 is inserted are passed through the lid 39. Since the inner diameter of the retaining ring 29 is formed smaller than the outer shape of the flange portion 58c of the rod portion 58, the rod portion 58 is prevented from being pulled out by being biased toward the input side by the coil spring 33.
As shown in FIG. 7B, the retaining ring 29 is divided into two parts, and the retaining ring 29 includes a through hole 29a through which a bolt 39a (for fixing the lid 39) passes on the same circumference and a bolt 29c. A plurality of bolt holes 29b for fixing the to the lid 39 are formed. Further, even if the seam divided into two is not attached to the lid 39, there is a gap, and the air inside the fifth pneumatic chamber 65 and the air inside the communication hole 39c can freely come and go.

In a state where the retaining ring 29 is fixed, the second piston 12 is fixed to the rod portion 58 with a connecting screw 12a. Thus, the rod part 58 and the second piston 12 are divided in order to fix the lid 39 with the bolt 39a and the retaining ring 29 with the bolt 29c.
A through hole is formed in the center of the rod portion 58, and an output rod 7 described later is inserted into the through hole.

  The second piston 12 forms an end surface on the input side together with the lid 3 and the inner peripheral surface of the cylinder 2 to form the second pneumatic chamber 22, and an end surface on the output side forms the fifth pneumatic chamber 65 together with the lid 39 and the cylinder 2. doing.

A part of the lid 34 is inserted into the output side end of the second housing 62 so as to face the lid 39. A flange portion is formed on the output side of the lid 34, and this flange portion is in contact with the thick portion of the output side end portion of the second housing 62 and is fixed by a bolt 34 a.
The central portion of the lid 34 projects to the input side (second hydraulic chamber 32 side), and a recess 34d is formed inside the projection, and a through-hole through which the output rod 7 is inserted is formed on the bottom surface of the recess 34d. Has been.
A communication hole 34b that penetrates the lid 34 in the axial direction is formed outside the concave portion 34d of the lid 34 in the radial direction. The communication hole 34 b and the communication hole 39 c of the lid 39 are communicated by a collar 28 disposed in the second hydraulic chamber 32.
On the output side end face of the lid 34, a communication groove 34c connected to the communication hole 34b is formed in the radial direction.

The first housing 61 is disposed on the output side of the second housing 62, and the lid 27 is fixed to the input side end portion with a plurality of bolts 27e.
The lid 27 is fixed to the lid 34 by bolts 27 a from the inside of the second housing 62 while being fixed to the second housing 62. Accordingly, the communication groove 34 c formed in the lid 34 is covered with the lid 27, and an air passage from the fifth pneumatic chamber 65 is formed.
The lid 27 has a recess 27f (see FIG. 7A) on the output side. The bottom surface of the recess 27 f functions as an input side end surface of the first pneumatic chamber 21.
The lid 27 is formed with a communication hole 27b that penetrates the bottom surface of the recess 27f and communicates with the recess 34d of the lid 34, and a communication groove 27d that communicates with the communication hole 27b is formed in the bottom surface of the recess 27f in the radial direction. ing.
In addition, a communication groove 27 c connected to the communication groove 34 c of the lid 34 is formed on the outer peripheral surface of the lid 27 in the axial direction.

In a state where the lid 27 is fixed to the lid 34 with bolts 27a, the first piston 11 having a rod portion 50 extending in the center is disposed in the first housing 61.
By disposing the first piston 11, the first housing 61 is partitioned by the first piston 11, and the first pneumatic chamber 21 is formed on the input side, and the fourth pneumatic chamber 64 is formed on the output side.

As shown in FIG. 7, the first housing 61 is formed with circumferential grooves 61a and 61b on both ends thereof over the entire circumference. As described above, the sliding auxiliary rings 2b and 2c are fitted in the circumferential groove 61a, and the sliding with the cylinder 2 is made smooth.
The first housing 61 has a communication groove 61e formed in the axial direction (longitudinal direction) over the entire length. The input side end portion of the communication groove 61 e is connected to the communication groove 27 c of the lid 27.
In order to prevent the communication groove 61e from being blocked by the sliding auxiliary rings 2b and 2c fitted in the circumferential grooves 61a and 61b, the sliding grooves are provided at the intersections of the circumferential grooves 61a and 61b and the communication groove 61e. Recesses 61c and 61d that are wider than the width of the auxiliary rings 2b and 2c and deeper than the thickness are formed. An air passage from the fifth pneumatic chamber 65 is formed between the communication groove 61e and the inner peripheral surface of the cylinder 2.

Returning to FIG. 6, the third housing 63 is fixed to the output-side end portion of the first housing 61 in which the first piston 11 is disposed inside by a plurality of bolts 63 e disposed in the circumferential direction.
The third housing 63 has convex portions formed on both the input side and the output side as seen from the fixing portion by the bolt 63e. The output side convex portion is formed smaller than the inner diameter of the cylinder 2, and a concave portion 63a is formed from the end surface in the axial direction. The input side convex portion is formed to be smaller than the inner diameter of the first housing 61, and a through hole 63b penetrating from the input side end portion to the bottom portion of the concave portion 63a is formed. The part 50 is inserted.
A flange portion is formed in the middle of the third housing 63 in the axial direction. As for the 3rd housing 63, the flange part is being fixed to the 2nd housing 62 with the volt | bolt 63e in the multiple places of the circumferential direction.
An axial groove 63c is formed on the outer peripheral surface of the flange portion.
The flange portion of the third housing 63 is formed with a communication hole 63d having an L-shaped cross section that extends in the radial direction from a position connected to the groove 63c and is bent in the axial direction from the middle.
The communication hole 63 d having an L-shaped cross section is connected to the fourth pneumatic chamber 64 by penetrating to the input side end surface of the third housing 63.
On the other hand, the groove 63 c has an input side connected to a communication groove 61 e formed on the outer periphery of the first housing 61, and an output side connected to the third pneumatic chamber 41.

The third piston 13 is disposed in the recess 63 a of the third housing 63. An output rod 7 that passes through the lid 3 on the input side through the through hole 63b is disposed at the center of the third piston 13. An output side end of the output rod 7 is fixed to the third piston 13 by screwing.
The output rod 7 includes a through hole 63b in the third housing 63, an axial through hole 50a (see FIG. 7) formed in the center of the first piston 11 and the rod portion 50, a through hole in the lid 27, and a through hole in the lid 34. A hole, an axial through hole formed at the center of the rod portion 58, and a length extending to the outside of the lid 3 through the through hole of the lid 3 are formed.
A claw 76 is screwed to the input end of the output rod 7 with a bolt 76a.

Further, on the input side of the output rod 7, an intake / exhaust passage 7b extending in the axial direction in the center is formed from the input-side tip to the position of the recess 34d. The end portion on the output side of the intake / exhaust passage 7b is connected to the through hole 7c penetrating in the radial direction at the position of the recess 34d. The depth (axial length) of the concave portion 34d of the lid 34 is formed larger than the operating range of the output rod 7 in the axial direction, so that the through hole 7c is always set regardless of the position of the output rod 7. It is located in the recess 34d.
A third intake / exhaust port 8 is disposed at the input side end of the output rod 7. The air supplied from the third intake / exhaust port 8 passes through the intake / exhaust passage 7b and the through hole 7c and is supplied to the first pneumatic chamber 21 via the recess 34d.

The recess 63a of the third housing 63 is partitioned by the third piston 13 being arranged, and the first hydraulic chamber 31 is formed on the input side.
The third piston 13 is formed with an oil supply hole for filling the first hydraulic chamber 31 with oil, and sealed with an oil filler plug 38 after the oil is injected.
The rod portion 50 slides on the inner peripheral surface of the through hole 63b, and the output rod 7 slides on the inner peripheral surface of the through hole of the rod portion 50. Part of the first hydraulic chamber 31 is configured by filling the space between the output rod 7 and the through hole 63b with oil.
Further, an O-ring (not shown) is arranged in the middle of the sliding portion of the through hole 50a of the rod portion 50 and the output rod 7 so that the oil in the first hydraulic chamber 31 does not leak from here.
The rod portion 50 pressurizes the first hydraulic chamber 31 by pushing the oil in the through hole 63b at its tip.

A retaining ring 37a is fixed to the output side end of the third housing 63 with a plurality of bolts 37b. The retaining ring 37a is fixed in a state in which the third piston 13 is disposed in the concave portion 63a, filled with oil, and the oil filler plug 38 is closed.
A concave portion 13b and a concave portion 37c are formed on the opposing surfaces of the third piston 13 and the retaining ring 37a, and a coil spring 36 that urges the third piston 13 to the input side is disposed.

The second housing 62 constitutes an input side housing together with the lid 39 and the lid 34, and the first housing 61 and the third housing 63 constitute an output side housing together with the lid 27 and the retaining nut 37.
Further, the lid 34 and the lid 27 are fixed by bolts 27a, whereby the input side housing is fixed to the input side (one end side) of the output side housing.

Next, the operation of the cylinder device 1d according to the fifth embodiment will be described.
FIG. 8 shows each state of operation by the cylinder device 1d.
In this operation, the claw 76 disposed at the tip of the output rod 7 contacts the workpiece 100 to fix the piston housing 60 (61, 62, 63), and thereafter, from the tip of the output rod 7 at an arbitrary timing. Outputs the amplified oil pressure.

First, an operation for setting the cylinder device 1d to an initial state will be described.
The initial state of the cylinder device 1d is a state where the piston housing 60 and the second piston 12 in the cylinder 2 are moved to the input side, and corresponds to the state shown in FIG.
In order to set the cylinder device 1d to the initial state shown in FIG. 8A, air is supplied from the second intake / exhaust port 6 at a predetermined pressure with the first intake / exhaust port 5 and the third intake / exhaust port 8 opened. Supply. The air supplied to the third pneumatic chamber 41 presses the output side end surface of the piston housing part 60 that forms the third pneumatic chamber 41, and the entire piston housing starts moving in the input direction. At the same time, the air supplied to the third pneumatic chamber 41 passes through the groove 63c, the recess 61d, the communication groove 61e, the recess 61c, the communication groove 27c, the communication groove 34c, the communication hole 34b, the collar 28, and the communication hole 39c, 5 reaches the pneumatic chamber 65 (see FIG. 6). The air supplied to the fifth pneumatic chamber presses the output side end face of the second piston 12 and moves to the input side. At this time, since the first intake / exhaust port 5 is opened, the second piston 12 and the rod portion 58 are not subjected to the air pressure in the output direction by the second air pressure chamber 22 and can be easily moved in the input direction. .
Further, since the flange portion 58c of the rod portion 58 engages with the ring 29, the entire piston housing 60 moves simultaneously. Here, the air supplied to the third pneumatic chamber 41 presses the output side end face of the piston housing 60, so that the entire piston housing 60 moves to the input side. At this time, the internal pressure due to the air supplied to the fifth pneumatic chamber 65 also presses the input side end face of the piston housing 60 at the same time, and the space of the fifth pneumatic chamber 65 is held by the bias of the coil spring 33. To move.
With the movement toward the input side, the air in the second pneumatic chamber 22 is discharged from the first intake / exhaust port 5.

Further, the supplied air passes from the third pneumatic chamber 41 through the groove 63c and the communication hole 63d, and the pressure in the fourth pneumatic chamber 64 also increases. The pressure from the fourth pneumatic chamber 64 moves the first piston 11 to the input side until it comes into contact with the lid 27. At this time, the air present in the first pneumatic chamber 21 is pushed by the first piston 11, passes through the communication groove 27d, the communication groove 27b, the recess 34d, the through hole 7c, and the intake / exhaust passage 7b, and enters the third intake / exhaust path. Released from the mouth 8.
Since the rod portion 50 also moves to the input side together with the first piston 11, the pressure in the first hydraulic chamber 31 decreases, so that the output rod 7 and the third piston 13 increase the pressure in the third pneumatic chamber 41. The coil spring 36 urges the input side to move to the input side.
The output rod 7 and the third piston 13 move until the third piston 13 comes into contact with the bottom surface of the recess 63 a of the third housing 63.
By the above movement, the cylinder device 1d is in the initial state shown in FIG.

In the initial state shown in FIG. 8 (a), the second intake / exhaust port 6 is opened while the third intake / exhaust port 8 is opened, and air is supplied from the first intake / exhaust port 5, whereby FIG. It will be in the state shown in
That is, the pressure of the second pneumatic chamber 22 is increased by the air supplied from the first intake / exhaust port 5, pushing the second piston 12 to the output side, and the second piston 12 is connected to the second hydraulic pressure via the rod portion 58. The chamber 32 is pressed. At this time, since the reaction force of the pressing force to the output side does not act on the entire piston housing 60, the oil in the second hydraulic chamber 32 is not constricted, and the thin portion 15 does not undergo elastic deformation. Therefore, when the rod portion 58 presses the second hydraulic chamber 32, the entire piston housing 60 moves to the output side. The coil spring 33 assists pushing the entire piston housing 60 in the output direction.
Since the third intake / exhaust port 8 is open, the air pressure in the first air pressure chamber 21 does not increase, so the first piston 11 and the rod portion 50 do not move in the output direction but abut against the lid 27. It remains. Further, since the rod portion 50 does not move in the output direction, the hydraulic pressure in the first hydraulic chamber 31 does not increase, and the third piston 13 remains in contact with the third housing 63.
As shown in FIG. 6, the third piston 13 moves in the output direction along with the movement of the second piston 12 and the piston housing 60, so that the output rod 7 also moves in the output direction. The provided claw 76 contacts the workpiece 100.

When the pawl 76 of the output rod 7 comes into contact with the workpiece 100, the movement of the entire piston housing 60 stops because the third piston 13 comes into contact with the third housing 63.
In this state, as shown in FIG. 8B, air is further supplied from the first intake / exhaust port 5. Then, since the piston housing 60 stops moving, the pressure in the second pneumatic chamber 22 further increases, exceeds the biasing force in the input direction by the coil spring 33, and the second piston 12 and the rod portion 58 are moved in the output direction. Moving.
The volume of the fifth pneumatic chamber 65 is reduced by the movement of the second piston 12, but the air in the fifth pneumatic chamber 65 moves to the third pneumatic chamber 41 and passes through the second intake / exhaust port 6. Discharged. As a specific path, as shown in FIG. 6, from the fifth pneumatic chamber 65, the recess 39d, the communication hole 39c, the collar 28, the communication hole 34b, the communication groove 34c, the communication groove 27c, the communication groove 61e, and the groove 63c. , A path that passes through the third pneumatic chamber 41 and is discharged from the second intake / exhaust port 6.

  By the movement of the rod portion 58, the second hydraulic chamber 32 is pressed at the tip end of the rod portion 58 as shown by the arrow in the axial direction in FIG. Due to this hydraulic pressure, the thin wall portion 15 is elastically deformed outward as indicated by a radial arrow, and the piston housing 60 is fixed to the cylinder 2 from a state where the movement is stopped.

In addition, in the state which is not fixed by the thin part 15, the piston housing 60 is a state which cannot be moved but is only stopped.
When the air supply from the first intake / exhaust port 5 is stopped and the air is supplied from the third intake / exhaust port 8 in this non-fixed state (the state shown in FIG. 6), the entire piston housing 60 is reversed (input direction). Will move to. That is, the first piston 11 and the rod portion 50 are moved by the pressure in the first pneumatic chamber 21 to increase the hydraulic pressure in the first hydraulic chamber 31, but the output rod 7 is fixed by the workpiece 100 that contacts the claw 76. Therefore, the entire piston housing 60 moves in the reverse direction (input direction) due to the reaction force from the workpiece 100.
Therefore, whether or not the piston housing 60 is fixed by elastic deformation of the thin portion 15 is caused by a pressure gauge applied to the cylinder 2 by the thin portion 15 by disposing a strain gauge (not shown) on the outer peripheral portion of the cylinder 2. The deformation strain of the cylinder 2 is detected, and the piston housing 60 is fixed by detecting a predetermined strain amount. Alternatively, a pressure sensor (not shown) for detecting the pressure in the second hydraulic chamber 32 may be arranged, and determination may be made based on whether or not this pressure exceeds a predetermined value (a value at which the thin portion 15 is elastically deformed). The detection target by the pressure sensor may be the second pneumatic chamber 22. Further, instead of the pressure sensor, a sensor for detecting the movement of the output rod 7 and the claw 76 is provided. After the movement stops, a predetermined time (from when the pressure in the second hydraulic chamber rises until the thin portion 15 is elastically deformed) is provided. It may be determined that it is fixed as time elapses.

In the state of FIG. 8B in which the piston housing 60 is fixed to the cylinder 2 by the elastic deformation of the thin wall portion 15, the output rod 7 is only in contact with the workpiece 100 and is amplified from the tip of the output rod 7. No thrust is output.
Therefore, the air supply from the first intake / exhaust port 5 is continued, and the second intake / exhaust port 6 is kept open, and the third intake / exhaust port 8 as shown in FIG. When the air is supplied from the air, the supplied air passes through the intake / exhaust passage 7b, the through hole 7c, the recess 34d, the communication hole 27b, and the communication groove 27d, and raises the pressure of the first pneumatic chamber 21.
Then, the first piston 11 receives the pressure of the first pneumatic chamber 21, and the first piston 11 and the rod portion 50 are moved in the output direction by the air-hydro stroke shown in FIG. The tip of 50 presses the first hydraulic chamber 31. Thereby, the third piston 13 receives the hydraulic pressure amplified in accordance with the ratio of the tip area of the rod portion 50 and the end area of the third piston 13, and the third piston 13, the output rod 7 and the claw 76 are hydraulically stroked. Only move in the output direction. At the time of this movement, the claw 76 presses the end area on the input side of the third piston 13 from the hydraulic pressure amplified in the first hydraulic chamber 31, and the increased thrust is output to the claw 76. The claw 76 pulls the workpiece 100 in the direction of the lid 3 with this large thrust, whereby the workpiece 100 is pushed into the workpiece setting table 101.

As described above, according to the fifth embodiment, the tip of the output rod 7 is separated from the first intake / exhaust port 5 for increasing the hydraulic pressure of the second hydraulic chamber 32 and fixing the piston housing 60 to the cylinder 2. A third intake / exhaust port 8 for generating a thrust from the claw 76 is provided.
Thereby, the fixing operation of the piston housing 60 and the thrust generating operation from the claw 76 at the tip of the output rod 7 can be made independent.

(Sixth embodiment)
The sixth embodiment will be described below.
In the fifth embodiment, the third intake / exhaust port 8 is disposed on the input side of the output rod 7, whereas in the cylinder device 1e of the sixth embodiment, the third intake / exhaust port is provided on the output side of the output rod 7. 8 is arranged.

FIG. 9 illustrates a configuration of a cylinder device 1e according to the sixth embodiment.
In the cylinder device 1e shown in FIG. 9, the same portions as those of the cylinder device 1d in the fifth embodiment are denoted by the same reference numerals, and the description thereof is omitted as appropriate.
As shown in FIG. 9, the cylinder device 1e is formed so as to penetrate the output rod 7 not only on the lid 3 side but also on the lid 4 side. The lid 4 is formed with a through hole through which the output rod 7 slides.
As in the fifth embodiment, the output rod 7 is formed with a through hole 7c at a position in the recess 34d in the operating range of the output rod 7. An intake / exhaust passage 7d penetrating from the through hole 7c to the output side end of the output rod 7 is formed in the output rod 7, and a third intake / exhaust port 8 is disposed at the output side end of the output rod 7. Yes.

The operation by the cylinder device 1e is the same as that of the fifth embodiment except that the air flowing between the third intake / exhaust port 8 and the first pneumatic chamber 21 passes through the intake / exhaust passage 7d.
According to the cylinder device 1e, since the third intake / exhaust port 8 is not in the vicinity of the claw 76, which is the point of action of the amplified thrust, the degree of freedom around the claw 76 can be increased.

(Seventh embodiment)
The seventh embodiment will be described below.
In the sixth embodiment, the degree of freedom around the claw 76 is increased by disposing the third intake / exhaust port 8 on the output side of the output rod 7, whereas in the seventh embodiment, the second embodiment is the same as the second embodiment. Similarly, the cam mechanism is used to change the rotation angle around the central axis of the claw 76 along with the movement of the output rod 7, thereby avoiding interference between the claw 76 and the workpiece when the workpiece is attached or detached. It is.

FIG. 10 illustrates a part of the configuration of the cylinder device 1f according to the seventh embodiment.
In the cylinder device 1f shown in FIG. 10, the same portions as those of the cylinder device 1d in the sixth embodiment are denoted by the same reference numerals, and the description thereof is omitted as appropriate.
Similarly to the case described with reference to FIG. 3, the straight line as shown in FIG. 9 serves as a guide for linear drive of the claw 76. In addition, the guide groove 83 is shown in a straight line for convenience of illustration, but the guide groove 83 may be formed in a spiral shape in a region corresponding to the turning range so that the claw 76 can be driven to turn in the middle.

The cylinder device 1f of the present embodiment includes a cylindrical portion 85 that constitutes a part of the cam mechanism and on which the output rod 7 slides. The cylindrical portion 85 has a flange portion formed on the input side, and the flange portion is fixed to the lid 4 with bolts 85a at a plurality of locations in the circumferential direction.
A radial through hole is formed on the output side of the cylindrical portion 85, and a cam pin 80 is inserted into the through hole and fixed by, for example, a screw mechanism.
A guide groove 83 constituting a part of the cam mechanism is formed at the output side end of the output rod 7. In the guide groove 83, the tip of the cam pin 80 is fitted (engaged).
A predetermined clearance (gap) is set between the end surface of the tip of the cam pin 80 and the bottom surface of the guide groove 83, so that when sliding, the outer peripheral side surface of the cam pin 80 and the guide groove The side surfaces of 83 are in contact with each other.

FIG. 10B is a diagram showing a state in which the guide groove 83 corresponding to the front view of FIG. 10A is developed on a plane in order to show the shape of the guide groove 83.
The guide groove 83 includes a spiral groove 83b for rotating the claw 76 with respect to the axial movement, and a linear groove 83a formed continuously with each of the output side and input side ends of the spiral groove 83, 83c.
That is, the guide groove 83 is formed with a spiral groove 83b so as to connect the circumferential phase positions corresponding to the rotation start and end positions of the output rod 7 and the claw 76, and from the input side end of the spiral groove 83b. Furthermore, a linear groove 83c extending in the axial direction toward the input side (the lid 3 side, see FIG. 6), and a straight line extending in the axial direction from the end on the output side further toward the output side (the third intake / exhaust port 8 side) A groove 83a is formed. The linear groove 83c is formed so that the claw 76 linearly pulls (pushes) the workpiece 100 in the axial direction.
As the output rod 7 and the claw 76 move from the initial state (input side) to the output side, the cam pin 80 slides in the guide groove 83 in the order of the straight groove 80a, the spiral groove 83b, and the straight groove 83c.
The cam mechanism of this embodiment is provided in order for the claw 76 to avoid interference with surrounding objects such as a workpiece. For this reason, it is preferable that the straight portion 83a in which the claw 76 moves linearly while avoiding interference from the initial state is formed as long as possible, and the length of the spiral groove 83b in which the claw 76 turns to the workpiece position is as short as possible. The position of the turning groove 83b may be on the input side or on the output side as long as the claw 76 is turned so as not to interfere with other components.
The spiral groove 83b of the guide groove 83 corresponds to the rapid feed operation of the output rod 7 by air pressure. The straight groove 83c corresponds to the rapid feed operation of the output rod 7 by air pressure halfway, before and after the air hydro stroke by the hydraulic pressure that is switched after the claw 76 contacts the workpiece 100 or after the retaining nut 37 contacts the lid 4. It corresponds to the stroke.
For this reason, the cylinder device 1f turns the claw 76 by a predetermined amount at the rapid feed portion of the output rod 7, and then switches to linear motion to make contact with the workpiece, hold it, and press it. The generated thrust is output.
Although the guide groove 83 is formed so that the claw 76 turns 90 degrees by the cam mechanism of the present embodiment, it may be formed at an arbitrary turning angle α (for example, 180 degrees). Alternatively, a plurality of cylindrical portions 85 formed to have different turning angles may be prepared, and the cylindrical portion 85 may be changed as appropriate according to the type of workpiece.

The overall length of the guide groove 83 in the axial direction is formed to be larger than the operating range of the output rod 7, and the guide pin 80 is formed so as to reach the straight portion 83c before the claw 76 contacts the workpiece.
In addition, although the linear part 83a is formed so that a guide pin may be located in the initial state demonstrated in Fig.8 (a), it is also possible to eliminate the linear part 83a.

While the embodiments of the present invention have been described above, the configurations described in the embodiments may be applied to other embodiments as far as possible.
For example, in the fifth embodiment, a strain gauge is provided on the outer peripheral portion of the cylinder 2, and the deformation strain of the cylinder 2 caused by the pressing force to the cylinder 2 by the thin portion 15 is detected to determine whether the piston housing 60 is fixed. Similarly, in the first to fourth embodiments, the sixth embodiment, and the seventh embodiment, whether or not the piston housing 14 is fixed by elastic deformation of the thin wall portion 15 by arranging the strain gauge. You may decide on.

In the fifth to seventh embodiments described, the case where the piston housing 60 is fixed to the cylinder 2 with the thin portion 15 of the second housing 62 has been described. In addition, the piston housing 60 may be fixed to the cylinder 2 by a clamper.
Also in the fifth to seventh embodiments, it is possible to form a punching process or a recessed part by press working in the same operation as described in FIG.
Note that the effects of the first to fourth embodiments described in paragraph 0090 can also be obtained in the fifth to seventh embodiments.

1, 1a, 1b, 1c Cylinder device 2 Cylinder 2a, 2b, 2c Sliding assist ring 3, 4, 34 Lid 5 First intake / exhaust port 6 Second intake / exhaust port 7 Output rod 7a Cavity 7d Intake / exhaust passage 8 3 intake / exhaust port 8a intake / exhaust rod 8b intake / exhaust passage 8d communication rod 8e, 8f communication passage 11 first piston 12 second piston 13 third piston 14 piston housing 15 thin part 16 collar 17 retaining bolt 18 retaining nut 19 coil spring 20 pneumatic chamber 21 first pneumatic chamber 22 second pneumatic chamber 27, 34, 39 lid 30 hydraulic chamber 31 first hydraulic chamber 32 second hydraulic chamber 33 coil spring 37 retaining nut 37a retaining ring 38 filler plug 40 , 53 Through hole 41 Third pneumatic chamber 43 Recess 44 Projection 50, 58 Rod part 51, 52, 54 Gap 54 Check valve 55 Pressure generating portion 57 Overhang portion 60 Piston housing 61 First housing 62 Second housing 63 Third housing 64 Fourth pneumatic chamber 65 Fifth pneumatic chamber 71 Pin 72 Parts 73 Installation stand 76 Claw 80 Cam pin 81 Blind hole 82 Cam Shaft rod 83 Guide groove 85 Cylindrical portion 85a Bolt 84 Protruding portion 90 Clamper 91 Ring member 92, 93 Tapered portion 94 O-ring 95 Column member 96 Coil spring 97 Nut 100 Work 101 Work installation base

Claims (26)

A cylinder,
A pneumatic chamber formed at one end in the cylinder;
A hydraulic chamber that moves inside the cylinder to the other end side by the pressure of the pneumatic chamber;
A fixing means for generating a radial force from a thrust force applied to the hydraulic chamber by the pneumatic chamber, and fixing the hydraulic chamber in the cylinder by the radial force;
A hydraulic amplifying means that is provided on the other end side of the pneumatic chamber and amplifies the hydraulic pressure generated in the fixed hydraulic chamber by the pneumatic chamber;
An output rod that extends through the hydraulic pressure amplifying means and the pneumatic chamber to the outside of the one end side of the cylinder, and outputs the amplified hydraulic pressure at the one end side;
A cylinder device comprising:   The hydraulic chamber generates hydraulic pressure by receiving the force in the other end side direction that the pneumatic chamber gives to the hydraulic chamber and the force in the one end side direction that the output rod gives to the hydraulic chamber. The cylinder device according to claim 1. The hydraulic chamber is composed of a first hydraulic chamber provided with the output rod, and a second hydraulic chamber provided with the fixing means,
The fixing means generates the radial force by the hydraulic pressure of the second hydraulic chamber to fix the second hydraulic chamber and the first hydraulic chamber,
The cylinder device according to claim 1, wherein the hydraulic pressure amplifying unit amplifies the hydraulic pressure generated in the first hydraulic chamber and outputs the amplified hydraulic pressure to the output rod.   The fixing means fixes the second hydraulic chamber and the first hydraulic chamber by pressing the side wall of the second hydraulic chamber elastically deformed by the radial force against the inner wall of the cylinder. The cylinder device according to claim 3.   The fixing means generates a radial force by pressing a taper member moving in the thrust direction against the clamper with the hydraulic pressure generated in the second hydraulic chamber, and presses the clamper against the inner wall of the cylinder by the force. The cylinder device according to claim 3, wherein the second hydraulic chamber and the first hydraulic chamber are fixed by doing so.   6. The cylinder device according to claim 3, wherein the first hydraulic chamber includes an output piston that presses the output rod in an output direction.   The output piston of the first hydraulic chamber does not move even in a state where the hydraulic pressure generated by being amplified in the first hydraulic chamber acts on the output rod to output thrust, and transmits only the output to the output rod. The cylinder device according to claim 6. The pneumatic chamber includes a first pneumatic chamber having a first piston that pressurizes the first hydraulic chamber, a second pneumatic chamber having a second piston that pressurizes the second hydraulic chamber, A pneumatic chamber and a communication hole communicating the second pneumatic chamber;
The first pneumatic chamber has a first intake / exhaust port and is formed on the one end side of the second pneumatic chamber,
The cylinder device according to any one of claims 3 to 7, wherein the cylinder device is provided. The first piston is the pressure of the first pneumatic chamber until the output rod comes into contact with the object to be pressed, or until the first hydraulic chamber reaches the movable end of the other end side, Moving the second pneumatic chamber, the first hydraulic chamber, and the second hydraulic chamber to the other end side;
The cylinder device according to claim 8. The amount of movement of the second piston when the second piston of the second hydraulic chamber generates an amplified hydraulic pressure in the second hydraulic chamber is that of the second hydraulic chamber disposed in the second piston. Within the range of elastic deformation of the seal member,
The cylinder device according to claim 9. The first pneumatic chamber has a first intake / exhaust port,
11. The cylinder device according to claim 9, further comprising a communication hole that allows the first pneumatic chamber and the second pneumatic chamber to communicate with each other. The first hydraulic chamber is formed on the other end side of the second hydraulic chamber,
The said 1st piston penetrates the said 2nd pneumatic chamber and the said 2nd hydraulic chamber, and is formed to the said 1st hydraulic chamber, The Claim 9, The Claim 10, or Claim 11 characterized by the above-mentioned. The cylinder device described.   The third air pressure chamber is provided on the other end side in the cylinder, has a second intake / exhaust port, and presses the hydraulic chamber toward the one end side. 12. The cylinder device according to 12.   The rotation angle changing means for changing the rotation angle around the center axis of the output rod when the output rod is moved is provided. The cylinder device described in 1. The rotation angle changing means is
Of the output rod and the sliding surface facing the output rod, a protruding member formed on one side, formed on the other side, engages with the protruding member and moves in the moving direction of the output rod. The cylinder device according to claim 14, wherein a rotation angle of the output rod is changed by a sliding mechanism with the formed groove portion. A cylinder device according to claim 11,
A workpiece setting means for setting a workpiece at a predetermined position with respect to the cylinder device;
A pressing means for driving the cylinder device and pressing the installed workpiece with a tool attached to the output rod;
Detaching means for detaching the pressed workpiece from the predetermined position;
The press apparatus characterized by the above-mentioned. A cylinder device according to claim 13;
A workpiece setting means for setting a workpiece at a predetermined position with respect to the cylinder device;
Means for driving the cylinder device and pressing and clamping the workpiece with the tool attached to the output rod;
Detaching means for detaching the clamped workpiece from the predetermined position;
A workpiece clamping device comprising: A cylinder device operating method for operating the cylinder device of claim 13, comprising:
The first hydraulic chamber and the second hydraulic chamber are brought to one end side by pressurizing the third pneumatic chamber from the second intake / exhaust port and depressurizing the first pneumatic chamber and the second pneumatic chamber from the first intake / exhaust port. A first step of moving and setting the initial state;
The first pneumatic chamber and the second pneumatic chamber are pressurized from the first intake / exhaust port and the third pneumatic chamber is depressurized from the second intake / exhaust port. A second step of moving the second pneumatic chamber to the other end side to bring the output rod into contact with the object to be pressed, or to reach the end portion on the other end side where the first hydraulic chamber can move; When,
A third step of fixing the first hydraulic chamber and the second hydraulic chamber to a cylinder by further pressurizing the first intake / exhaust port to operate the fixing means;
A fourth step of further pressurizing from the first intake / exhaust port to operate the hydraulic pressure amplifying means and pressing the output rod against the pressing object;
The third air pressure chamber is pressurized from the second intake / exhaust port and the first intake / exhaust port is depressurized to move the first hydraulic chamber and the second hydraulic chamber to the one end side to return to the initial state. And a fifth step
A cylinder device operating method characterized by comprising: A method of operating the cylinder device according to claim 13 to clamp a workpiece in a predetermined position,
A first step of placing the workpiece in place;
The cylinder device is driven until the tool mounted on the output rod comes into contact with the workpiece and stops, or until the first hydraulic chamber reaches the movable end of the other end and stops. A second step of moving by the air pressure of the first air pressure chamber;
A second step of moving by air pressure;
A third step of fixing the first hydraulic chamber and the second hydraulic chamber by the fixing means;
A fourth step in which the hydraulic pressure in the first hydraulic chamber is amplified by the hydraulic amplifying means;
A fifth step in which the tool mounted on the output rod presses the workpiece with the hydraulic pressure and clamps it in place by the hydraulic pressure amplified in the fourth step;
A method for clamping a workpiece, comprising: A method for pressing a workpiece by operating the press device according to claim 16,
A first step of driving the cylinder device to return the position of the output rod to an initial state;
A second step of placing the workpiece in place;
The cylinder device is driven until the tool mounted on the output rod comes into contact with the workpiece and stops, or until the first hydraulic chamber reaches the movable end of the other end and stops. A third step of moving with the pressure of the first pneumatic chamber;
A fourth step of fixing the first hydraulic chamber and the second hydraulic chamber by the fixing means;
A fifth step in which the hydraulic pressure in the first hydraulic chamber is amplified by the hydraulic amplifying means;
A sixth step in which the tool attached to the output rod presses the workpiece with hydraulic pressure by the hydraulic pressure amplified in the fifth step, and presses the workpiece;
A seventh step of driving the cylinder device to disengage the tool mounted on the output rod together with the output rod from the workpiece by pneumatic pressure;
An eighth step of releasing the pressed workpiece from a predetermined position;
A method for pressing a workpiece characterized by comprising: The pneumatic chamber includes a first pneumatic chamber having a first piston that pressurizes the first hydraulic chamber, and a second pneumatic chamber having a second piston that pressurizes the second hydraulic chamber. ,
The second pneumatic chamber is disposed on the one end side of the second hydraulic chamber,
The first pneumatic chamber is disposed on the other end side of the second hydraulic chamber,
A first intake / exhaust port for pressurizing the second pneumatic chamber;
A third intake / exhaust port that pressurizes the first pneumatic chamber through the second pneumatic chamber and the second hydraulic chamber,
The cylinder device according to any one of claims 3 to 7, wherein the cylinder device is provided. The output rod penetrates to the outside of the one end side of the second pneumatic chamber, the second hydraulic chamber, and the cylinder,
The third intake / exhaust port pressurizes the first pneumatic chamber through a part of the output rod from the one end side of the output rod.
The cylinder device according to claim 21. The output rod penetrates from the outside on the one end side to the outside on the other end side in the entire length of the cylinder,
The third intake / exhaust port pressurizes the first pneumatic chamber through a part of the output rod from the other end side of the output rod.
The cylinder device according to claim 21. An input side housing having the second hydraulic chamber; an output side housing having the first pneumatic chamber and the first hydraulic chamber 31;
The input side housing is fixed to the one end side of the output side housing,
The cylinder device according to claim 21, claim 22, or claim 23. The second piston is disposed between the input-side housing and the second pneumatic chamber, moves to the other end side by the pressure from the second pneumatic chamber, and moves to the second hydraulic pressure. A rod portion for pressurizing the chamber,
The cylinder device according to claim 24, wherein: A cylinder device operating method for operating the cylinder device of claim 25, comprising:
A step of moving the second piston, the input side housing, and the output side housing to the other end side by pressurizing the second pneumatic chamber from the first intake / exhaust port;
A movement stopping step of stopping the movement of the input side housing and the output side housing by bringing the output rod into contact with the pressing object;
The second pneumatic chamber is further pressurized from the first intake / exhaust port, and the second piston is moved to the other end side, whereby the second hydraulic chamber is pressurized by the rod portion and the fixing means. A fixing step of fixing the input side housing and the output side housing to the cylinder;
After the fixing, a thrust generating step of pressurizing the first pneumatic chamber from the third intake / exhaust port to operate the hydraulic pressure amplifying means to generate a thrust by the hydraulic pressure amplified from the tip of the output rod;
A cylinder device operating method characterized by comprising:

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