JP6367432B1 - Sequence valve with check valve - Google Patents

Abstract

A sequence valve with a check valve is compactly configured to facilitate application to a hydraulic circuit and to save space.
A valve element working chamber 3 in which a composite valve element 1 is fitted and slid is formed between hydraulic oil passages C1 and C2 of manifolds 2a and 2b. The composite valve body 1 has a structure of a poppet type valve in which a second poppet 20 that is fitted and slid in the first poppet 10 is urged forward by a coil spring 30. A road is constructed. The composite valve body 1 is urged rearward by a weak coil spring 5 having a bush 4 on the side of the flow path C1 as a seat, and the flow path between the conical valve portion 15 on the outer peripheral portion of the rear end and the valve body working chamber 3 A poppet type valve is configured with the C2 side valve seat 2c. A cut portion 16 is formed on the outer peripheral surface of the first poppet 10 along the generatrix. By supplying hydraulic oil from the flow path C2, the composite valve body 1 moves forward, and the valve body working chamber 3 and The hydraulic oil returns through the gap in the cut portion 16.
[Selection] Figure 1

Description

  The present invention relates to a sequence valve with a check valve that is applied when a plurality of fluid pressure actuators are sequentially operated, and can be incorporated into a fluid pressure actuator body by miniaturization and space saving. The present invention relates to an improvement for facilitating application to a fluid pressure circuit.

The sequence valve with a check valve is used for sequentially operating a plurality of hydraulic actuators, and generally has a basic structure as shown in FIG.
In the figure, 100 is a main body casing, 101 and 102 are supply / discharge ports, 103 is a drain, 104 is a cylinder, 105 is a spool, 106 is a coil spring, 107 is a poppet, 108 is a coil spring, and 109 is a pressure adjusting screw.

  When the hydraulic oil is raised to a predetermined pressure with the supply / discharge port 101 as the primary side, the coil spring 106 is compressed by the pressure received by the piston portion of the spool 105 as shown in FIG. , The hole 110 closed by the piston portion of the spool 105 is opened, so that hydraulic oil of a predetermined pressure flows from the primary side to the secondary side and is discharged from the supply / discharge port 102. The predetermined pressure is set by the pressure adjusting screw 109.

  On the other hand, when the supply / discharge port 102 is switched to the primary side and the supply / discharge port 101 is switched to the secondary side, the spool 105 returns to the original position by the restoring force of the coil spring 106 as shown in FIG. Although closed, the coil spring 108 is compressed by the pressure received by the poppet 107. As a result, the poppet 107 is pushed downward and the hole 111 is opened, so that the hydraulic oil from the supply / discharge port 102 is discharged from the supply / discharge port 101. Discharged. However, since the spring constant of the coil spring 108 is set to be extremely smaller than that of the coil spring 106, the hole 111 is opened with a small pressure.

Therefore, the piston rod of the first hydraulic cylinder is moved to the stroke end with the hydraulic oil in the state where the supply / discharge port 101 side is the predetermined pressure or less as the primary side, and when the operation is completed, the supply / discharge port 101 side exceeds the predetermined pressure. At that time, the second hydraulic cylinder can be operated with the hydraulic oil on the supply / discharge port 102 side, and the sequential operation of the plurality of hydraulic cylinders can be realized.
Further, since the check valve by the poppet 107 and the coil spring 108 is incorporated, when the connection between the primary side and the secondary side with respect to the supply / discharge ports 101 and 102 is switched, the first and second hydraulic cylinders are returned to the original state. be able to.

  By the way, since the sequence valve performs control using the spool, a configuration in which the hydraulic oil supply / discharge flow path is necessarily arranged in a direction perpendicular to the operation direction of the spool is employed. The same applies not only to the sequence valve as a single hydraulic control device, but also to the case where the sequence valve is configured in the hydraulic circuit in the manifold block. Also, the check valve is generally provided in a positional relationship parallel to the spool.

For example, the sequence valve of Patent Document 1 below is of a system that is built into a fluid system, but the hydraulic oil supply / discharge flow path is provided in a direction perpendicular to the operating direction of the spool, The check valve is arranged in the member by fitting the spool in a positional relationship parallel to the spool.
The sequence valve of the following Patent Document 2 is devised to prevent and suppress vibrations such as spool hunting and chattering, and the check valve is arranged coaxially with the spool. The oil supply / discharge port is also arranged in a direction perpendicular to the operating direction of the spool.

Japanese Patent No. 3989242 JP 2017-44327 A

  As described above, in the conventional sequence valve with a check valve, since the supply / discharge control of the hydraulic oil is performed by the operation of the spool, the supply / discharge flow path of the hydraulic oil is perpendicular to the operation direction of the spool. If a check valve is disposed in parallel with the spool, a large-sized block-like device is inevitably produced.

In addition, when a sequence valve with a check valve is provided in the middle of a hydraulic circuit configured in the hydraulic actuator body, such as a cylinder tube or a head cover of a hydraulic cylinder, it becomes a factor that makes circuit design difficult and increases the mounting density. It becomes a hindrance.
Further, in the case of a sequence valve with a check valve as a single device, it is needless to say that downsizing is required, and it is desirable that the hydraulic oil flow path be easily installed.

  Therefore, in view of the problems of the conventional sequence valve with a check valve as described above, the present invention provides a hydraulic oil flow path by configuring the functions of the sequence valve and the check valve as a composite poppet valve. The purpose is to realize a space saving when applied to a fluid pressure circuit constructed in a member of a fluid pressure actuator so that the sequence valve with a check valve itself can be miniaturized and can be mounted and applied coaxially. And

The present invention comprises a cylindrical body having one end and a cylindrical screw in which an axial center hole is formed, and an outer peripheral surface of the outer surface of the bottomed end wall portion of the cylindrical body protrudes from an outer peripheral area. And an axial center hole is formed, and the entire or part of the radial section region of the opening side end portion of the cylindrical body is formed as a conical surface valve portion and the opening side end portion The cylindrical screw is screwed into the cylinder , and a part or a plurality of portions of the outer periphery of the cylinder are cut out in a planar shape along the generatrix or formed as a groove along the axial direction. A first poppet having a bottom end which is fitted inside and slides in a cylinder of the first poppet, and an outer surface of the end wall portion forms a conical valve portion, and the conical surface in a state where the shaped valve portion is in contact with the axial center hole of the bottom end wall portion of the first poppet as a valve seat, the person Second poppet through hole leading from the surface position of the outer circumferential side of the section into the interior of the tubular body is one or more forms, and between the inner surface and the second poppet of the cylindrical screw of the first poppet A composite valve body comprising a first coil spring that is interposed and biases the conical surface valve portion of the second poppet to the axial center hole of the bottomed end wall portion of the first poppet with a predetermined pressure; A cylindrical hollow part formed in the middle of the flow path of the working fluid and in which the composite valve body is fitted and slid, and one inner wall includes an inner wall of the bottomed end wall part of the first poppet. A hole communicating with one flow path is formed in each of the opposed regions of the peripheral region and the peripheral region, and the conical surface valve portion at the opening side end portion of the first poppet is formed on the other inner wall. The valve seat is formed, and the inner peripheral side of the valve seat communicates with the other flow path The composite valve body is interposed between the working chamber, the one inner wall of the valve body working chamber, and the composite valve body, and with a force sufficiently smaller than an urging force of the first coil spring against the second poppet. And a second coil spring that urges the second inner wall toward the other inner wall.

The sequence valve with a check valve according to the present invention is configured such that, in a neutral state where there is no differential pressure between the one flow path and the other flow path with respect to the valve body working chamber, the composite valve body is moved by the second coil spring. The valve seat is biased to the other inner wall of the body working chamber, and the conical surface valve portion at the opening side end of the first poppet is formed on the other inner wall of the valve body working chamber. It is pressed. Further, the conical surface valve portion of the second poppet that is fitted into the first poppet is attached to the valve seat (shaft center hole) of the bottomed end wall portion of the first poppet by the first coil spring. It is pressed.

  Therefore, when the working fluid is supplied from the one flow path through the one inner wall to the valve body working chamber from the neutral state, the composite valve body and the one inner wall of the valve body working chamber The pressure of the working fluid increases until the pressure reaches a level (cracking pressure) enough to retract the second poppet against the biasing force of the first coil spring. There is no flow.

However, when the pressure of the working fluid exceeds the cracking pressure, the first coil spring is compressed, so that the conical surface valve portion of the second poppet is a valve seat on the bottomed end wall portion of the first poppet ( The working fluid flows from the through hole of the second poppet into the cylinder and flows to the other flow path through the axial hole of the cylindrical screw at the opening side end .

On the other hand, when the working fluid is supplied from the other flow path to the valve body working chamber, the composite valve body is pressed toward the second coil spring. Since the two-coil spring is easily compressed with a small force, the conical surface valve portion at the opening side end of the first poppet is detached from the valve seat on the other inner wall of the valve body working chamber, and the working fluid Flows into the one inner wall side of the valve body working chamber through the cut portion or groove formed on the outer periphery of the first poppet and the inner peripheral wall surface of the valve body working chamber, and is formed on the inner wall thereof. It circulates to the said one flow path through the hole which is open.
The inner wall of the valve body working chamber has holes formed in an inner peripheral region and an outer peripheral region, but the bottomed end wall portion of the first poppet which is an outer cylinder of the composite valve body Since the outer peripheral surface of the outer peripheral surface is formed so that the inner peripheral side region protrudes from the outer peripheral side region, the hole in the outer peripheral side region is formed even when the composite valve body is in contact with the one inner wall of the valve body working chamber. It always communicates with the one flow path.

In the check valve with a sequence valve of the present invention, the tubular body of the second poppet has become a seat giving fitted in one end section of the first coil spring, the cylindrical screw before Symbol first poppet It is preferable that a seat for fitting the other end side section of the first coil spring is formed in the.
According to this configuration, the first coil spring can be reliably held without increasing fluid resistance in the composite valve body, and the cracking pressure is required by adjusting the screwing position of the cylindrical screw in advance. Can be set to pressure.

In the sequence valve with a check valve according to the present invention, a cylindrical bush having a seal member attached to the outer peripheral surface of the one inner wall of the valve body working chamber is fitted to the end of the valve body working chamber. The bush has a shaft center hole provided with a receiving seat into which a part of the second coil spring is fitted, and an outer peripheral side of the bottomed end wall portion of the first poppet. A plurality of outer peripheral holes are perforated at equal intervals in the circumferential direction at a portion facing the region, and the shaft center hole and the plurality of outer peripheral holes are the one through the recess formed on the back side of the bush. It is desirable to be connected to the flow path.
According to this configuration, the second coil spring can easily realize communication between the hole provided in the inner peripheral side region and the outer peripheral side region of the one inner wall in the valve body working chamber and the one side flow path. Can be securely held.

In the sequence valve with a check valve of the present invention, it is desirable to provide a pressure passage hole having an inner diameter sufficiently smaller than the inner diameter of the through hole at the axial center position of the end wall portion of the second poppet.
When the pressure of the flow path on one side exceeds the cracking pressure and the valve is opened by the retraction of the second poppet, the working fluid is connected to the fluid pressure actuator connected to the other flow path through a sequence valve with a check valve. However, if the flow of the working fluid is stopped by the load applied to the fluid pressure actuator, the dynamic pressure changes to static pressure at any point in the flow path, and the total pressure becomes only static pressure. The differential pressure between the static pressures before and after the end wall portion (conical surface valve portion) of the two poppets decreases and becomes smaller than the cracking pressure. As a result, the second poppet advances and the valve closes.
By the way, since the differential pressure of the static pressure when the valve is closed has a magnitude corresponding to the pressure loss corresponding to the biasing force of the first coil spring, the pressure of the other flow path is the one side It is often the case that the pressure of the working fluid is less than the pressure of the flow path, and the pressure of the working fluid is not sufficient to counter the load in the fluid pressure actuator after the valve is closed.
With regard to this problem, if the pressure hole is provided, the pressure of the flow path on the one side continues to be applied as a static pressure to the other flow path through the pressure hole even after the valve is closed. A high static pressure can be applied to the fluid pressure actuator.
Since the pressure hole is a hole having a sufficiently small inner diameter that allows the flow of hydraulic oil to be ignored, it hardly affects the opening and closing conditions of the valve, and only allows the static pressure to pass through in the closed state of the valve. is there.

The sequence valve with a non-return valve according to the present invention includes a composite valve body in which a second poppet urged by a first coil spring is fitted in a cylinder of a first poppet, and is formed in the middle of a flow path of a working fluid. The sequence valve, the check valve, and the hydraulic fluid flow path (or supply / discharge port) can be configured coaxially and compactly by being fitted inside the valve body working chamber. This facilitates the design when applied to a fluid pressure circuit configured in a member such as a cylinder tube or a head cover, and realizes space saving.
Further, the sequence valve with a check valve of the present invention realizes simpler use as a cylindrical rod-like form provided with supply / exhaust ports at both ends even when the device is a single valve device.

It is an axial sectional view of a sequence valve with a check valve according to an embodiment. It is a disassembled perspective view of each component (each component disassembled about a composite valve body) built in the valve body working chamber. 1 (A) is a cross-sectional view taken along arrow AA, (B) is a cross-sectional view taken along arrow BB, (C) is a cross-sectional view taken along arrow C-C, and (D) is D -D arrow sectional drawing, (E) is an EE arrow sectional drawing], and the enlarged view of F part. It is a hydraulic circuit diagram of a hydraulic drive system according to an application example of a sequence valve with a check valve. It is an axial sectional view showing a sequential operation state in a sequence valve with a check valve. It is an axial sectional view showing the reverse flow state in a sequence valve with a check valve. It is an axial sectional view of a sequence valve with a check valve according to another embodiment. It is GG arrow sectional drawing in FIG. (A) is a basic structure figure of the sequence valve with a non-return valve concerning a prior art, (B) and (C) are figures showing the operation state.

Hereinafter, embodiments of a sequence valve with a check valve of the present invention will be described in detail with reference to the drawings.
FIG. 1 is an axial sectional view of a sequence valve with a check valve according to the present embodiment. For example, a head cover of a hydraulic cylinder is used as a manifold block, and a sequence with a check valve is provided in the middle of a hydraulic fluid passage formed in the manifold block. This applies when a valve is configured.
In the figure, reference numeral 1 denotes a composite valve element composed of a first poppet 10, a second poppet 20, and a coil spring 30, and is formed in a cylindrical shape in the middle of hydraulic fluid passages C1 and C2 in the manifold blocks 2a and 2b. The valve body working chamber 3 formed as a hollow portion is fitted inside and slides.
Further, the front inner wall (right side) of the valve body working chamber 3 is configured by fitting a cylindrical bush 4, and the bush 4 has a flow for communicating between the valve body working chamber 3 and the hydraulic oil passage C 1. A path is formed and also serves as a seat for the coil spring 5 that biases the composite valve body 1 toward the rear inner wall (left side).

  2 is an exploded perspective view of each component 10, 20, 30 of the composite valve body 1, the bush 4 and the coil spring 5. FIG. 3 is a cross-sectional view taken along the arrows [(A) to (E) in FIG. )] And an enlarged view of the F portion. Hereinafter, each part and its function will be described in detail with reference to these drawings.

First, the first poppet 10 which is a component of the composite valve body 1 includes a cylindrical body portion 11 having a front end and a cylindrical screw 12.
Here, the bottomed side (front end side) of the cylindrical portion 11 is a truncated cone-shaped end portion 13 in which the inner peripheral side protrudes forward from the outer peripheral side, and the shaft center hole 14 is formed in the end portion 13. In addition, a shallow spot facing that serves as a seat for the coil spring 5 is also formed on the tip surface.
On the other hand, on the opening side (rear end side) of the cylindrical portion 11, a conical surface valve portion 15 formed as an inclined surface slightly from the outer peripheral side to the outermost peripheral side from the opening portion is formed [FIG. (See (F)), and a female thread for screwing the cylindrical screw 12 inward is formed in a certain section in the cylinder at the opening.

  In addition, the outer peripheral surface of the cylindrical portion 11 is not a complete circumferential surface, but is cut in a planar shape along the generatrix at every 90 ° at a central angle viewed from the axial center (removed portion 16). The outer diameter in the intermediate section is slightly smaller than the other sections as an oil groove.

  The cylindrical screw 12 is screwed to the rear end side of the cylindrical portion 11 as described above, but has an axial center hole 17 and a seat 18 for the coil spring 30 on the front end side. However, a slit 19 is formed on the rear end side for use in screwing into the cylindrical body portion 11.

Next, the second poppet 20 which is a component of the composite valve body 1 is a bottomed cylinder body that is fitted inside and slides into the cylinder portion 11 of the first poppet 10, and an outer surface on the front end side thereof. Is formed as a conical surface valve portion 21, and a poppet type valve is configured with the axial center hole 14 of the cylindrical body portion 11 in the first poppet 10 as a valve seat.
The front end portion of the second poppet 20 has a conical surface valve portion 21 in contact with the axial center hole 14 of the first poppet 10 as a valve seat, and the surface position on the outer peripheral side of the annular contact portion. Four through-holes 22 leading from the inside to the cylinder are formed at equal intervals in the circumferential direction.
Furthermore, a pressure hole 23 is formed in which the front end of the second poppet 20 (the tip of the conical surface valve portion 21) and the inside of the cylindrical body communicate with each other at the axial center. It is sufficiently smaller than that of the through hole 22.

The composite valve body 1 is configured such that the second poppet 20 is fitted in the cylindrical body portion 11 of the first poppet 10 and the coil spring 30 is fitted in the cylindrical body of the second poppet 20. The rear end side of 30 is fitted and held in the seat 18 of the cylindrical screw 12, and the cylindrical screw 12 is screwed to the rear end portion of the cylindrical body portion 11 to be assembled.
Therefore, regarding the cracking pressure of the poppet type valve composed of the conical surface valve portion 21 of the second poppet 20 and the valve seat by the shaft center hole 14 of the first poppet 10, the compression load characteristics of the coil spring 30 and the cylindrical shape are used. The biasing force is set to the second poppet 20 based on the screwing position of the screw 12.

  On the other hand, as described above, the valve body working chamber 3 formed in the manifold blocks 2a and 2b is a cylindrical hollow portion in which the composite valve body 1 is fitted and slid. On the inner wall surface on the path C2 side, a valve seat 2c with respect to the conical surface valve portion 15 formed at the rear end portion of the first poppet 10 of the composite valve body 1 is formed as an annular step portion. It is connected to the hydraulic oil flow path C2 in such a manner that the diameter is reduced from the portion.

Further, the inner wall surface on the front end side of the valve body working chamber 3 is constituted by the cylindrical bush 4 as described above, but the bush 4 is fitted and fixed at the joint between the manifold blocks 2a and 2b. Yes.
The bush 4 has a shaft center hole 42 that also serves as a seat 41 for the coil spring 5, and a shaft center hole 42 in the outer peripheral region of the composite valve body 1 that faces the conical surface of the end portion 13 of the first poppet 10. Four outer peripheral holes 43 arranged at equal intervals in the circumferential direction in parallel relation are formed, and a concave portion 44 is formed in a circular region including the axial center hole 42 and each outer peripheral hole 43 on the rear end surface side. Two circumferential grooves are formed on the outer peripheral surface. When the O-ring 45 is applied to each groove and fitted and fixed to the manifold blocks 2a and 2b, the shaft center hole 42 and each outer periphery groove are formed. The hole 43 is connected to the hydraulic oil passage C1 through the recess 44.

Next, the operation of the sequence valve with a check valve having the above configuration will be described.
However, here, a case where two hydraulic cylinders, which are typical usage forms of a sequence valve with a check valve, are sequentially operated by a hydraulic drive system as shown in FIG. 4 will be described as an example. .
In FIG. 4, the sequence valve 60 with a check valve and / or one of the hydraulic cylinders 61 and 62 according to the embodiment, and the hydraulic circuit that connects them are mounted in the manifold block, and the 4-port 2-position The connection between the primary port P and the tank port T is switched by the switching valve 63.

First, the sequence valve 60 with a check valve is in the state shown in FIG. 1, the 4-port 2-position switching valve 63 is in the position shown in FIG. 4, and hydraulic fluid is supplied from the primary port P to the hydraulic fluid passage C1. In this case, the composite valve body 1 is originally biased rearward by the coil spring 5, and when the pressure in the valve body working chamber 3 rises from the recess 44 of the bush 4 through the shaft center hole 42 and each outer peripheral hole 43, The conical surface valve portion 15 on the rear end side of the composite valve body 1 is brought into more tight contact with the valve seat 2c on the rear end side of the valve body working chamber 3.
In the composite valve body 1, the first poppet 10 has the second poppet 20 fitted therein. As described above, the conical surface valve portion 21 of the second poppet 20 and the axial center hole of the first poppet 10. A predetermined cracking pressure is set for the poppet type valve composed of 14 (valve seat).

Therefore, in the supply state of the hydraulic oil from the primary port P, the cracking is caused by the load applied to the piston rod by the pressure on the A1 port of the hydraulic cylinder 61 connected to the hydraulic oil flow path C1 side of the sequence valve 60 with a check valve. Until the pressure is exceeded, as shown in FIG. 1, the poppet type valve 21 is kept in close contact with the conical surface valve portion 21 of the second poppet 20 and the shaft center hole 14 (valve seat) of the first poppet 10. Is closed, and hydraulic oil does not flow to the hydraulic oil flow path C2 through the sequence valve 60 with a check valve.
As a result, the hydraulic oil is supplied to the A1 port of the hydraulic cylinder 61 and the other port B1 is connected to the tank port T. Therefore, only the hydraulic cylinder 61 performs the piston rod projecting process in advance. .

  However, the load applied to the piston rod in the projecting process of the hydraulic cylinder 61 increases, and the pressure of the A1 port, that is, the pressure of the hydraulic oil passage C1 of the sequence valve 60 with a check valve increases, and the [valve operating chamber 3 -Inside of coil spring 5-When the pressure in the axial center hole 14 of the first poppet 10 exceeds the cracking pressure, the coil spring 30 is compressed in the first poppet 10 as shown in FIG. The poppet 20 moves backward, the contact state between the conical surface valve portion 21 of the second poppet 20 and the shaft center hole 14 (valve seat) of the first poppet 10 is released, and the poppet valve is opened. .

  Then, as shown in FIG. 5, the hydraulic oil [the hydraulic oil passage C1 → the recess 44 of the bush 4 → the shaft center hole 42 of the bush 4 and the inside of the coil spring 5 → the shaft center hole 14 of the first poppet 10 → the first 1 through the passage of the inside of the poppet 10 → the through hole 22 of the second poppet 20 → the inside of the second poppet 20 → the inside of the coil spring 30 → the axial center hole 17 of the cylindrical screw 12 → the hydraulic oil passage C2] Since the hydraulic oil is supplied to the port A2 of the hydraulic cylinder 62 connected to the hydraulic oil flow path C2 and the port B2 is connected to the tank port T, the hydraulic cylinder 62 starts the piston rod protruding process.

  With the supply of hydraulic oil from the primary port P, the piston rod in the hydraulic cylinder 62 continues to run against the load, but the hydraulic oil pressure at the A1 port of the hydraulic cylinder 61 is A pressure higher than the cracking pressure is maintained, and the position of the piston rod of the hydraulic cylinder 61 is held against the load.

  In this way, the hydraulic cylinders 61 and 62 are sequentially operated by the sequence valve 60 with a check valve, but the piston rod projecting process of the hydraulic cylinder 62 switches the 4-port 2-position switching valve 63 at a preset position. To finish.

When the 4-port 2-position switching valve 63 is switched, the piston rods of the hydraulic cylinders 61, 62 are pulled in by the supply of hydraulic oil to the ports B1, B2, and return to the initial positions.
However, the port A1 of the hydraulic cylinder 61 is directly connected to the tank port T, but the port A2 of the hydraulic cylinder 62 is connected to the tank port T via the sequence valve 60 with a check valve. The check valve function of the valved sequence valve 60 is used.

In other words, the hydraulic oil returns from the port A2 of the hydraulic cylinder 62 to the hydraulic oil passage C2, but in the sequence valve 60 with a check valve, the pressure on the hydraulic oil passage C2 side is increased, while the hydraulic oil passage C1 is in the tank. Since it is connected to the port T, as shown in FIG. 6, in the composite valve body 1, the second poppet 20 returns to the front in the first poppet 10 by the biasing force of the coil spring 30, and the conical surface valve portion 21 is The poppet valve is closed by closely contacting the shaft center hole 14 (valve seat), and the composite valve body 1 itself moves forward in the valve body working chamber 3 so that the end 13 of the first poppet 10 is bushed. Abut against the inner wall of 4.
In this case, the coil spring 5 interposed between the bush 4 and the composite valve body 1 is compressed and becomes a resistance against the movement of the composite valve body 1, but the biasing force of the coil spring 5 is sufficiently small. Therefore, there is almost no trouble in operation.

As a result, the conical surface valve portion 15 at the rear end portion of the composite valve body 1 is released from the close contact with the valve seat 2c on the inner wall of the rear end side of the valve body working chamber 3 and moves forward. As shown by the arrows, the hydraulic oil is [hydraulic fluid flow path C2 → valve working chamber 3 (rear) → respective gaps between the cut portion 16 of the cylindrical body 11 and the inner peripheral wall surface of the valve working chamber 3 → valve. It flows through the path of the working chamber 3 (front) → the respective outer peripheral holes 43 of the bush 4 → the recess 44 of the bush 4 → the working oil passage C1] and is collected into the tank port T.
The valve body working chamber 3 (front) in the path is secured by the front end portion 13 of the first poppet 10 being formed in a truncated cone shape, and each outer peripheral hole 43 of the bush 4 is It is formed at a position communicating with the secured space portion.

  By the way, the second poppet 20 is formed with a pressure hole 23 for communicating the front end thereof (the tip of the conical surface valve portion 21) and the inside of the cylindrical body, and the inner diameter thereof is sufficiently small. However, the pressure hole 23 has the following functions.

First, as described above, when the pressure in the hydraulic oil passage C1 exceeds the cracking pressure due to the load applied to the piston rod of the hydraulic cylinder 61, the second poppet 20 moves backward in the first poppet 10, and FIG. As shown, the hydraulic oil flows from the hydraulic oil passage C1 to the hydraulic oil passage C2 through the sequence valve 60 with a check valve, and the hydraulic cylinder 62 is driven.
At this time, the dynamic pressure of the hydraulic oil blocked at the front surface of the second poppet 20 changes to static pressure, and the static pressure changes to dynamic pressure as a flow in the pipe in the cylinder of the second poppet 20. Since the pressure differential pressure is greater than the urging force of the coil spring 30, the second poppet 20 is maintained in the retracted position, and the poppet valve is kept open.

However, when the piston rod of the hydraulic cylinder 62 moves to a position close to a predetermined position and stops when the load becomes large, the flow of hydraulic oil disappears, and the dynamic pressure changes to static pressure in all sections of the flow path. Since the differential pressure is smaller than the urging force of the coil spring 30, the second poppet 20 moves forward and the conical surface valve portion 21 and the shaft center hole 14 (valve seat) of the first poppet 10 come into close contact with each other. Closes the poppet valve.
In that case, the pressure on the hydraulic oil flow path C2 side, that is, the pressure on the port A2 of the hydraulic cylinder 62 is the pressure on the hydraulic oil flow path C1 side minus the pressure loss corresponding to the urging force of the coil spring 30. When the poppet valve is closed, the piston rod of the hydraulic cylinder 62 is fixed by the pressure (static pressure), but this may not be sufficient because the pressure loss is the subtracted pressure.

The pressure hole 23 is formed to eliminate this problem. Even when the poppet valve is closed, the pressure from the primary port P side is statically applied to the port A2 of the hydraulic cylinder 62 through the pressure hole 23. The piston rod of the hydraulic cylinder 62 can be stably fixed against the load.
In the second poppet 20, the inner diameter of the pressure hole 23 is sufficiently smaller than that of the through hole 22, and the flow of hydraulic oil is negligible. There is almost no effect on the open / close conditions of the poppet type valve composed of one poppet 10.

As described above, according to the sequence valve 60 with a check valve of the present embodiment, the sequence valve and the check valve can be rationally and compactly incorporated into the manifold blocks 2a and 2b as a coaxial mechanism. It can also be configured as a sequence valve with a check valve of a single device.
Specifically, as shown in FIG. 7, a valve body working chamber 3 is configured by using an outer casing 7 and a headed bush 8 instead of the manifold block, and a composite valve is provided in the valve body working chamber 3. The body 1 is internally fitted, and pipe connecting female screws 71 and 81 are formed on the rear end side of the outer cylinder housing 7 and the front end side of the headed bush 8.
7 are the same as those shown in FIG. 1, and the fixing portion of the headed bush 8 with respect to the outer casing 7 is indicated by GG in FIG. It is shown in FIG. 8 which is a cross-sectional view taken along the arrow, and is secured by four hexagon socket head bolts 82.

  In this way, by configuring as a sequence valve with a check valve of a cylindrical single unit, it can be coaxially interposed in the middle of the piping of the hydraulic circuit, and the cracking pressure as the sequence valve is the spring constant of the coil spring 30. Since it can be set freely depending on the screwing position of the cylindrical screw 12, it can be used very easily in a hydraulic circuit of a system in which a large number of hydraulic actuators are sequentially operated.

  The sequence valve with a check valve of the present invention can be applied as a control valve in the case where fluid actuators are sequentially operated in a fluid pressure circuit.

1 ・ Composite valve, 2a, 2b ・ Manifold block, 2c ・ Valve seat, 3 ・ Valve working chamber, 4 ・ Bush, 5 ・ Coil spring, 7 ・ Outer cylinder housing, 8 ・ Bush, 10 ・ First poppet 11 ・ Cylindrical part, 12 ・ Cylindrical screw, 13 ・ End, 14 ・ Axial center hole, 15 ・ Conical surface valve part, 16 ・ Removal part, 17 ・ Axial center hole, 18 ・ Receiver, 19 ・Slot, 20 · 2nd poppet · · · conical valve portion · · · through hole, · · · pressure hole, 30 · coil spring, 41 · seat, 42 · shaft center hole, 43 · outer circumference Hole, 44 / recess, 45 / O-ring, 60 / sequence valve with check valve, 61/62 / hydraulic cylinder, 6/3 port 2-position switching valve, 71/81 / female thread for pipe connection, 82 / hex socket Attached bolt, A1 ... port, C1, ... hydraulic oil flow path, P / primary port, T / tank port, 100 / body housing, 101,102 / supply / discharge port, 103 / Drain, 104 cylinder, 105 spool, 106 -Coil spring, 107-Poppet, 108-Coil spring, 109-Pressure adjusting screw, 110, 111-Hole

Claims (4)

It consists of a cylindrical body with one end and a cylindrical screw in which an axial center hole is formed, and the outer surface of the bottomed end wall portion of the cylindrical body is formed such that the inner peripheral region protrudes from the outer peripheral region. and the axial center hole is formed with have, in the cylindrical body of the cylinder of the open end with the entire surface or part of the radial section area of the open end is formed as a conical shape valve portion The first poppet in which the cylindrical screw is screwed and a part or a plurality of parts of the outer periphery of the cylindrical body are cut out in a planar shape along the generatrix or as a groove along the axial direction A cylindrical body having one end and slidingly fitted inside the cylinder of the first poppet, the outer surface of the end wall portion forming a conical surface valve portion, and the conical surface valve portion being an axial central hole of said bottom end wall portion of the first poppet as a valve seat while abutting, external from the abutment Is interposed from the surface position of the side second poppet through hole leading to the interior of the tubular body is one or more forms, and between the inner surface and the second poppet of the cylindrical screw of the first poppet A composite valve body comprising a first coil spring that biases the conical surface valve portion of the second poppet toward the axial center hole of the bottomed end wall portion of the first poppet with a predetermined pressure;
A cylindrical hollow part formed in the middle of the flow path of the working fluid and in which the composite valve body is fitted and slid, and one inner wall includes an inner wall of the bottomed end wall part of the first poppet. A hole communicating with one flow path is formed in each of the opposed regions of the peripheral region and the peripheral region, and the conical surface valve portion at the opening side end portion of the first poppet is formed on the other inner wall. And a valve body working chamber in which the inner peripheral side of the valve seat communicates with the other flow path,
The composite valve body is interposed between the one inner wall of the valve body working chamber and the composite valve body, and the composite valve body is attached to the other valve with a force sufficiently smaller than an urging force of the first coil spring against the second poppet. A sequence valve with a check valve, comprising: a second coil spring biased toward the inner wall side. The tubular body of the second poppet is the first has become seat giving fitted in one end section of the coil spring, before SL in the cylindrical screw of the first poppet other end section of the first coil spring The sequence valve with a non-return valve according to claim 1, wherein a seat for internally fitting is formed. The one inner wall of the valve body working chamber is formed by fitting a cylindrical bush having a sealing member mounted on the outer peripheral surface thereof at an end of the valve body working chamber, and the bush includes the second coil A shaft center hole provided with a receiving seat into which a part of the spring is fitted is formed, and a circumferentially uniform portion is provided at a portion facing the outer peripheral region of the bottomed end wall portion of the first poppet. A plurality of outer peripheral holes are formed at intervals, and the shaft center hole and the plurality of outer peripheral holes communicate with the one flow path through a recess formed on the back side of the bush. A sequence valve with a check valve according to claim 1 or 2.   The check valve according to claim 1, 2 or 3, wherein a pressure passage hole having an inner diameter sufficiently smaller than an inner diameter of the through hole is provided at an axial center position of an end wall portion of the second poppet. Sequence valve.

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