JPS6383477A - Output device - Google Patents

Abstract

PURPOSE:To obtain high output by providing a plurality of pistons on a piston operating mechanism. CONSTITUTION:An operation object mechanism 7 is disposed in a cylinder 1, and a plurality of pistons 11, 12 are fixed on the outer periphery of a piston rod 8. The cylinder 1 is provided with a separator 14 fixed by a fixing ring and with a plurality of inflow chambers 15, 16 corresponding to a plurality of pistons 11, 12. Normally a valve portion 25 of a piston rod 8 is opened by a pressure spring 21. In case of closing the valve, a control fluid is left flow in inflow chambers 15, 16 between pistons 11, 12. At this time the pressure receive areas of the pistons 11, 12 are about doubled as compared with that of one piston, so that the valve portion 25 is forced to produce large output through the piston rod 8.

Description

DETAILED DESCRIPTION OF THE INVENTION Field of Industrial Application The present invention relates to output devices, and is applicable to control devices operated using fluid, such as air-operated valves, and various other devices using pistons. It is used to obtain output, and it is intended to make it possible to obtain large output with a small size.

BACKGROUND OF THE INVENTION Conventionally, in fluid-operated control devices and other devices using pistons, when trying to obtain a large output, the fluid pressure applied to the piston is increased. There was no other way but to increase the diameter and the pressure receiving area. However, in the former case, there is a limit to the strength of the device against fluid pressure, and high-pressure fluid cannot be used in small devices. Furthermore, the method of increasing the diameter of the piston to increase the pressure receiving area also has the disadvantage that it cannot be used in small devices.

Problems to be Solved by the Invention The present invention eliminates the above-mentioned drawbacks, makes it possible to obtain a high-output output device j4 while reducing the diameter of the piston and keeping the fluid pressure relatively low. This is what we are trying to do.

Means for Solving the Problems In order to solve the above-mentioned problems, the present invention provides a plurality of pistons that slide closely against the inner peripheral surface of the cylinder on the outer periphery of the piston rod to which the actuating purpose mechanism is connected. Separators are used to airtightly divide and fix each piston, and a control fluid inflow chamber is formed on one side of each piston.
It is made by connecting.

Operation Since the present invention is configured as described above, if the control fluid is caused to flow into the plurality of inflow chambers formed in the plurality of pistons from the control fluid inlet opened in the cylinder, the control fluid can be controlled. Fluid pressure is applied to a plurality of pistons, and the pressure-receiving area of the pistons is multiple times that of - pistons, and a large output can be generated through the piston rod to the actuating target mechanism. Furthermore, since a plurality of pistons are formed on the outer periphery of the piston rod, the diameter of the device does not need to be increased, and a compact device can be provided.

Embodiment Below, an embodiment of the present invention in which the present invention is installed in a normally open air-operated valve that is used in a normally open state will be described with reference to FIG. 1. (1) is a sealing device whose upper end is hermetically fixed by a sealing body (3) via an O-ring (2), and the top surface of this sealing body (3) is fixed by a lid body (5) provided with an engaging protrusion (4). , and a control air inlet (6) is formed on the side surface in the axial direction. In addition, a piston rod (8) with an operating mechanism (7) fixed at one end is inserted into the cylinder (1), and an O-ring is placed on the outer circumference of the piston rod (8) and on the inner circumferential surface of the cylinder (1). A plurality of pistons (first) (12) are fixed, which slide closely on (10), and these pistons (first) (12) are fixed.
12) is airtightly divided by a separator (14) fixed to the syringe (1) with a fixing ring (13), and opened on the side surface of the syringe (1) in the axial direction.
The control fluid inlet (6) is connected to a plurality of pistons (first).
A plurality of inflow chambers (1
5) Connected to (16). These multiple inflow chambers (15
)(1(S), the control fluid is injected into the piston rod (
8) through an introduction path 17) formed in the axial direction from the upper end surface, and in the embodiment shown in FIG.
An inflow chamber (15) is formed in a space between the first piston (first) and the sealing body (3), and the first inflow chamber (15)
), an introduction path (17) formed in the axial direction from the upper end of the piston rod (8) opens into the inflow chamber (16) of ptS2.

Further, the cylinder (, 1) is rotatably fixed to the main body (18) by connecting and fixing one end to the main body (18) via a lock ring (20), and the cylinder (, 1) is rotatably fixed to the main body (18). A pressure spring (21) is interposed in the second piston (12N10), and the first and second pistons (12) are connected to the first and second inflow chambers (12) by this pressure spring (21). 1,5016) direction.When the control air 2'A is injected from the inlet (6), the control air flows through the introduction path (17) formed in the piston rod (8). Flowing in a direction to suppress the piston (first) (12) against the restoring force of the pressing spring (21),
Move the piston (first).

Further, the control fluid flow path (2) is provided on the inner periphery of the main body (18).
A connecting body (23) having a piston rod (8) is screwed and fixed through a threaded T portion (24), and inside this connecting body (23) there is also a mechanism (7) for the purpose of operation fixed to the piston rod (8). ) The valve part (25) facing the opening/closing part (26) of the flow passage (22) is designed to prevent the flow passage (22) from being closed at all times. In addition, the piston rod (8) has a valve part (25), which is an operating mechanism (7) fixed at one end, and a metal diaphragm (27) made of a material such as stainless steel.
This protects the clean control fluid flowing through the flow path (22) from being contaminated by contact with the piston rod (8). There is. Operation purpose 8 again! The connection between the structure (7) and the piston rod (8) is achieved by providing an engagement ball (30) on the engagement cylinder (28) that protrudes from the piston rod (8), and making this engagement 1. g (30) engages and fixes the engagement sleeve (31) of the active purpose mechanism (7), one end of which is inserted into the engagement tube (28).

In addition, on the side of the cylinder (1) on the side of the piston (1012), there is a pressure spring (212) on the side of the cylinder (1).
)] (32) is formed, but this is not necessarily necessary if the sliding distance of the piston (first) (12) is short.

In the device configured as described above, the pressure spring (21
) to the piston (first) (12),
The valve part (25) of the piston rod (8) keeps the control fluid flow passage (22) open at all times, and when it senses a closing signal, opens the control fluid flow passage (22) from the control fluid inlet (6) opened in the cylinder. Control fluid is supplied to two pistons (first) (first
2) If the control fluid is allowed to flow into the two inlet chambers (15) (1G) formed between the two pistons (first) (first
2), the pressure receiving area of the piston (first) (12) is nearly twice that of the case of - pistons, and a large output is transmitted through the piston rod (8) to achieve the operation purpose B.
! 4M (7) can be generated in the valve part (25), and even when the fluid flowing through the flow passage (22) is at high pressure, the valve part (25) can easily open and close the flow passage (22). (26)
can be closed.

In the above embodiment, an example in which the present invention is used as a normally open air operated valve has been described, but when used as a normally closed air operated valve, the first piston (first) and the sealing body are used. (3) A suppressing spring (21) with a pressing force that allows the opening/closing part (26) to be easily closed at all times by the valve part (25) against the pressure of the fluid flowing through the flow # (22). An inflow chamber (15) (1, 6) is formed on the side opposite to this pressing force. That is, a first inflow chamber (15) is provided between the first piston (first) and the separator (14), and a second inflow chamber (16) is provided between the second piston (12) and the main body (18). is formed.

In this normally closed air-operated valve, when a valve opening signal is sensed and control fluid is injected from the inlet (6), the control fluid is formed between the two pistons (first) (12). Flowing into the two inlet chambers (15) (16), control fluid pressure is applied to the two pistons (first) (12), and the control fluid pressure is applied to the two pistons (first) (12).
12) The pressure receiving area is compared to the case of - pistons,
It is almost twice as large and has a large output, '/FT, 1.
Vl! :1
- Even if the pressure spring (21) has a strong restoring force, the opening/closing part (26) of the flow path (22) can be easily opened.

Further, in the above embodiment, the piston and the inflow chamber are two parts.
Although the case of three or more is shown, it is of course possible to use a plurality of three or more, and in this case, even greater output can be obtained.

Further, in the above embodiment, the cross structure of the present invention is used in a two-gas actuated valve, but the present invention is not limited to this embodiment, and may be used in any other appropriate device. is possible.

Effects of the Invention Since the present invention is constructed as described above, if the control fluid is allowed to flow into the plurality of inflow chambers formed in the piston from the control fluid inlet opened in the cylinder, the control fluid pressure can be increased. is applied to a plurality of pistons, and the pressure-receiving area of the pistons is multiple times that of the case of - pistons, and a large output can be generated through the piston rod to several operating purposes. Further, since a plurality of pistons are formed on the outer periphery of the piston rod and in close contact with the inner periphery of the cylinder, it is possible to provide a compact device without increasing the diameter of the device.

[Brief explanation of the drawing]

The drawings show an embodiment of the present invention, and Figure f51 is a cross section when used in a normally open air-operated valve. FIG. 12 is a sectional view when used in a normally closed air-operated valve. (1)...Cylinder (6)...Inflow port (7)
......Operating purpose mechanism (8)...Piston rod (first) (12)...Piston (14)...
...Separator (15) (1G) ...Inflow chamber (17) ...
・Introduction path (18)...Body (20)...
... Lock ring (21) ... Suppression spring (22) ... Distribution path (2
5)・・・Valve part diagram 1

Claims (6)

[Claims] (1) A plurality of pistons that slide closely against the inner peripheral surface of the cylinder are airtightly divided and fixed with a separator on the outer periphery of the piston rod to which the actuation purpose mechanism is connected, and an inflow chamber for the control fluid is fixed. , are formed on one surface of the piston, and a control fluid inlet opening in the cylinder is connected to the control fluid inflow chamber. (2) The output device according to claim 1, wherein the control fluid is injected into the plurality of inflow chambers through an introduction path formed in the axial direction of the piston rod. (3) The piston is biased by a spring, and an inflow chamber for the control fluid is formed opposite to the biasing direction so that the piston can be operated against this biasing force. An output device according to claim 1. (4) The operation purpose mechanism is a valve part provided on the piston that uses the biasing force of the piston in a certain direction to always open or close the fluid flow path, and also senses an open/close signal and controls the valve. By applying fluid pressure to the piston,
2. The output device according to claim 1, wherein the output device is an air-operated valve that changes a fluid flow passage from a normally open state to a closed state or from a normally closed state to an open state. (5) The output device according to claim 4, wherein the cylinder of the air-operated valve is rotatable relative to the main body. (6) The output device according to claim 5, wherein the cylinder is rotatably fixed to the main body via a lock ring.