JPH0526385Y2 - - Google Patents

Description

[Detailed Description of the Invention] [Industrial Application Field] The present invention relates to a two-position directional control valve that switches the flow direction of fluid.

[Prior Art] Conventionally, a two-position directional switching system has been used in which a return force is always applied to one end of the valve stem, and the valve stem is driven and returned by the action force of pilot fluid applied to the other end of the valve stem. Valves are well known.

In the above-mentioned well-known directional control valve, it is preferable that the driving force and the return force acting on the valve stem are approximately equal in the normally used fluid pressure range in order to smooth the switching operation of the valve stem.

Conventionally, the return force of the valve stem in such a directional control valve has been applied only by the urging force of a return spring, only by the acting force of fluid pressure, or by combining the urging force of the return spring and the acting force of fluid pressure. Although they are sometimes used together in the same direction, the application of restoring force by these means all have drawbacks as described below.

In other words, if the restoring force is applied only by the urging force of the return spring, the restoring force is practically limited.Moreover, if you try to increase the urging force of the spring, the drive force that drives the valve stem against this force is limited. Since it is necessary to increase the force, it is necessary to increase the pressure acting area of the pilot chamber or to increase the lower limit of the pilot fluid pressure, but in the former case the valve itself has to be larger, and in the latter case In some cases, it may be necessary to increase the fluid pressure normally used.

Furthermore, if the returning force of the valve stem is applied only by fluid pressure, it becomes impossible to return the valve to its original position when the fluid pressure on the return side disappears for some reason.

Furthermore, when the return force of the valve stem is applied by the biasing force of a return spring and the acting force of fluid pressure, there are problems as will be explained below with reference to FIGS. 3 and 4.

That is, the conventional switching valve that applies a return force to the valve stem using a return spring and fluid pressure has a return pressure chamber 33 formed at the end of the valve stem 32 in the valve body 31, as shown in FIG. A return spring 34 is disposed in the
A port 35 for supplying and discharging return pressure fluid is communicated with the return pressure chamber 33, so that the biasing force of the spring 34 is applied to the valve stem 32 regardless of the magnitude of the fluid pressure.

FIG. 4 shows the relationship between the acting force due to the fluid pressure on the driving side and the return side and the biasing force of the return spring in such a conventional directional control valve, where f ₁ and f ₂ are the biasing forces of the return spring 34. , F ₁ ′ is the driving force acting on the valve stem 32 due to the pilot fluid pressure acting on the piston on the driving side (not shown), and F ₂ ′ is the driving force of the return spring when the urging force of the return spring is f ₂ . F 2 ″ is the return force of the valve stem 32 which is the resultant force of the urging force and the acting force of the fluid pressure on the return side, F ₂ ″ is the return force of the valve rod 32 when the urging force of the return spring is f ₁ , and F ₁ ″ is the return force of the valve stem 32 when the urging force of the return spring is f 1 . In case valve stem 3
It shows the driving force acting on 2.

Note that θ is a value proportional to the area of action of fluid pressure, and increases as the area of pressure action increases.

In Fig. 4, in order to obtain sufficient return force even when the fluid pressure on the return side disappears, the driving force F ₁ ' of the valve stem and the return force F ₂ ' must be approximately equal at the minimum operating pressure P ₁ . A biasing force f ₁ is required for the return spring 34, but in this case, the required return force can be obtained only with the biasing force f ₁ of the spring 34, so this biasing force is not affected by the fluid pressure on the return side. If a force is applied, the return force becomes F ₂ ″ and the driving force becomes F ₁ ″, which is not preferable because the balance between the driving force and the return force is lost. Therefore, if the biasing force of the return spring is set to a relatively large _f1 , pilot fluid pressure cannot be used in combination on the return side.

On the other hand, if the biasing force of the return spring 34 is set to _f2 so that the return force _F2 ' passes through the point at pressure _P1 , the return force _F2 ' of the valve stem 32, the biasing force _f2 of the return spring, and the return side However, in this case, when the fluid pressure on the return side disappears, the return force will be f ₂ , and not only will the return force be insufficient, but the fluid pressure will not be used. This is not preferable because the balance between the driving force F ₁ ′ and the return force F ₂ ′ when the maximum pressure reaches P ₂ is lost.

Therefore, in conventional directional control valves, when the urging force of the return spring and the acting force of fluid pressure are used together, when the fluid pressure disappears, the return force of the valve stem becomes insufficient, or the fluid pressure The problem was that the balance between the driving force and the restoring force was lost in the normal range of use.

[Problems to be solved by the invention] The invention is capable of balancing the driving force and return force of the valve stem within the practical pressure range of normally used fluids, and moreover, when the fluid pressure disappears. The problem to be solved is to obtain a two-position directional control valve that can return the valve stem with a sufficient return force even in the case of the present invention.

[Means for Solving the Problems] In order to solve the above problems, the two-position switching valve of the present invention has a return force applied to one end of the valve stem by the resultant force of the fluid pressure and the urging force of the return spring. In a two-position directional control valve in which the flow direction of the fluid is switched by driving and returning the valve stem by applying force to the other end of the valve stem and applying force to the other end of the valve stem, the valve stem is driven and returned. to the side, away from the valve stem,
A return piston is provided to apply a force of return fluid to the valve stem, and the return spring is provided between the return piston and the valve stem, and return fluid pressure is supplied from a return pressure port behind the return piston. A return pressure chamber is provided, and the biasing force of the return spring is set to approximately 1/2 of the force of the pilot fluid acting on the valve stem at the lowest working fluid pressure, so that the returning fluid pressure reaches the minimum working fluid pressure. When the pressure is lower than the above pressure, the return piston is separated from the valve stem, and when the return fluid pressure is greater than the above fluid pressure, the return piston is brought into contact with the valve stem so that the biasing force of the return spring does not act on the valve stem. It is characterized by what it did.

[Operation] When the pilot fluid's acting force is not acting on the valve stem, the valve stem is returned to its returning state by the return force that is the result of the acting force of the fluid pressure and the urging force of the return spring. .

In this case, when the force of the fluid pressure acting on the return piston is larger than the set biasing force of the return spring, the return piston comes into contact with the valve stem and the force acting on the piston becomes the return force, and the force acting on the return piston becomes the return force. When is smaller than the set biasing force of the return spring, the return piston separates from the valve stem and the biasing force of the return spring becomes the return force.

Therefore, the biasing force of the return spring can be set larger than in the conventional example, and even when fluid pressure disappears, it is possible to return the valve stem with sufficient return force.

When a pilot fluid action force is applied to the valve stem, the valve stem slides toward the driving piston against the return force, thereby switching the direction of fluid flow.

[Example] Figure 1 shows an example of the present invention, in which a valve body 1 is shown.
The valve body 2 is composed of a first cover 3 and a second cover 4 at both ends of the valve body 2, which are integrally connected by appropriate means such as bolts.

The valve body 2 includes a central input port 5, first and second output ports 6, 7 on both sides thereof, and first and second exhaust ports 8, 9 outside the ports 6, 7. A valve stem 10 is disposed slidably in the axial direction inside the valve body 2 with which the valve body 2 is in communication.

The land provided on the valve stem 10 is
When the slider slides toward the first cover 3 side, as shown in FIG. When the second discharge port 9 is closed and slid in the opposite direction, the input port 5 and the first output port 6, and the second output port 7 and the second
While making the discharge ports 9 communicate with each other, the first
This closes the discharge port 8.

The first cover 3 has a pilot chamber 12 therein.
The drive piston 13 is arranged to drive the valve stem 10 in the direction of the second cover 4 by the fluid pressure of pilot fluid supplied from a pilot port 14 to a pilot chamber 12 behind the drive piston 13.

The second cover 4 also has a return piston 16 that slides in the return pressure chamber 15.
6 is the return piston 16 from the return pressure port 17
The valve stem 10 is returned in the direction of the first cover 3 by the fluid pressure of the fluid supplied to the return pressure chamber 15 behind the valve, but the return does not occur until the acting force due to the fluid pressure reaches a certain value. Piston 16 and valve stem 1
0 via the return spring 18 provided between the valve stem 10 and
It is configured to press the

That is, spring insertion recesses 20 and 21 are provided on opposing surfaces of the return piston 16 and the valve rod 10, respectively, and the valve rod 10 and the return piston 16 are spaced apart between these recesses 20 and 21. Biasing force in direction f ₁
The above-mentioned return spring 18 having a diameter is compressed. Therefore, the acting force of the fluid pressure supplied to the return pressure chamber 15 behind the return piston 16 is applied to the return spring 18.
When the biasing force _f1 of the return spring 18 is smaller than the biasing force f1, the return spring 18 applies a return force to the valve stem ₁₀ , and when the acting force of the fluid pressure becomes larger than the biasing force f1 of the return spring 18, the return piston 16 and the valve stem 10 are opposed to each other. The force of the fluid pressure acting on the return piston 16 when the surfaces come into contact is directly applied to the valve stem 10.
The restoring force is transmitted by acting on the In this case, since the return piston 16 and the valve rod 10 are in contact with each other, the biasing force of the return spring 18 does not become the return force of the valve rod 10.

Further, the valve stem 10 has a through hole 23 in the axial direction, and the valve stem sides of the covers 3 and 4 are communicated with each other through the through hole 23, and are open to the outside through a breathing hole 24 on the cover 3 side. .

Note that the return pressure chamber 15 containing the return piston 16 can be provided within the valve box 2, and its diameter can be made larger or smaller than the diameter of the valve rod 10.

Next, with reference to FIG. 2, the relationship between the driving force and the return force acting on the valve stem 10 of the directional control valve will be explained.

In FIG. 2, F ₁ is the driving force due to the fluid pressure of the pilot fluid applied to the drive piston 13, and F ₂
indicates the return force acting on the return piston 16, and _f1 indicates the biasing force of the return spring 18. Further, the biasing force f ₁ of the return spring 18 is set to be approximately half of the force exerted by the fluid pressure acting on the drive piston at the pressure P ₁ , while the force F ₂ of the return piston is Biasing force f ₁ of return spring 16 at pressure P ₁
is set to be approximately equal to .

Furthermore, since the urging force of the return spring 18 acts in a direction to separate the valve stem 10 and the return piston 16, the return force of the valve stem 10 is caused by the acting force F2 of the fluid acting on the return piston ₁₆ . When the biasing force f ₁ of the spring 18 is greater than the biasing force f 1 of the return piston 16 , the return piston 16 compresses the return spring 18 and its acting force acts directly on the valve stem, and the acting force F ₂ of the return piston 16 is the biasing force of the return spring 18 . When f becomes smaller than ₁ , the return spring 1
Only the biasing force f ₁ of 8 acts on the valve stem 10.

Therefore, the return force of the valve stem 10 is determined by the force _F2 of the fluid acting on the return piston 16.
When the biasing force f of 8 is larger than ₁ , the return spring 18
Since the biasing force f ₁ does not become the return force of the valve stem 10,
The fluid pressure changes along the straight line - _{in FIG} . A certain minus sign in FIG. 2 is the return force of the valve stem 10, and even if the fluid pressure disappears, the return force of the valve stem 10 by the return spring 18 will not be insufficient.

To explain the operation of the directional switching valve, FIG. 1 shows a state in which the return pressure fluid is supplied to the return pressure chamber 15 and the pilot fluid in the pilot chamber 12 is discharged, and the valve stem 10 is connected to the return pressure fluid. Since the acting force is smaller than the biasing force f ₁ of the return spring 18, the biasing force f ₁ of the return spring 18 returns to the first cover 3 side, and the fluid from the input port 5 is transferred to the second output port 7. is supplied to. When the force F ₂ acting on the return piston 16 due to the pressure fluid in the return pressure chamber 15 becomes larger than the biasing force f ₁ of the return spring 18, the return piston 16 comes into contact with the valve stem 10 and is directly applied to it. A restoring force will be applied.

In the state shown in FIG.
When pilot fluid is supplied to the drive piston 1
Since the acting force F ₁ of No. 3 is larger than the acting force F ₂ of the return piston 16 or the biasing force f ₁ of the return spring 18,
The valve stem 10 slides toward the second cover 4, and fluid from the input port 5 is supplied to the first output port 6, and fluid from the second output port is discharged from the second discharge port 9.

When the pilot fluid supplied to the pilot chamber 12 is discharged, the valve stem 10 is moved to the first cover by the acting force F ₂ of the pressure fluid supplied to the return pressure chamber 15 or the biasing force f ₁ of the return spring 18. be returned to the side.

As is clear from comparing FIG. 2 and FIG. 4, in the above-mentioned directional control valve, the urging force of the return spring 18 and the acting force of the return piston 16 are used to return the valve stem 10.
Since F ₂ is used in combination and the return spring 16 is interposed between the valve stem 10 and the return piston 16, the biasing force of the return spring 16 can be increased as f ₁ , and the return piston 16 Even if the fluid pressure acting on the valve rod 10 disappears, the return force exerted by the return spring 18 on the valve stem 10 will not be insufficient.

In addition, P ₁ , P ₂ which is the normal usage range of fluid pressure
During this period, the balance between the driving force F ₁ and the return force F ₂ used for the valve stem 10 will not be lost.

The return pressure port 17 may be communicated with the input port 5, or the fluid supplied from the input port 5 may be introduced into the pilot port 14 by being switched by another directional switching valve.

[Effects of the invention] The present invention uses both the action force of the fluid and the action force of the return spring as the return force applied to the valve stem, but it increases the biasing force of the return spring compared to the conventional example. Therefore, even if the fluid pressure disappears and its acting force disappears, the return force of the valve stem will not be insufficient.

Further, it is possible to maintain a balance between the driving force and the return force within the practical range of normally used fluid pressures. Moreover, when the acting force of the return fluid becomes larger than the biasing force of the return spring, the biasing force of the return spring becomes independent of the return force of the valve stem, and the return force is directly applied from the return piston to the valve stem. In order to act,
Since the force of the return spring does not act on the valve stem, and the eccentric force that generally occurs when a coil spring is used does not act on the valve stem, wear on the valve sliding portion can be reduced.

[Brief explanation of drawings]

Fig. 1 is a longitudinal sectional front view of an embodiment of the present invention, Fig. 2 is a diagram showing the relationship between driving force and return force in the embodiment of the present invention, Fig. 3 is a sectional view of main parts of a conventional example, and Fig. 4 is a conventional example. FIG. 3 is a relationship diagram between driving force and return force in an example. 10... Valve stem, 15... Return pressure chamber, 16...
Return piston, 17...Return pressure port, 18...
...Return spring.

Claims (1)

[Claims for Utility Model Registration] Applying a return force to one end of the valve stem, which is the result of the force exerted by fluid pressure and the biasing force of a return spring,
In a two-position directional control valve that switches the direction of fluid flow by driving and returning the valve stem by the acting force of a pilot fluid applied to and removed from the other end of the valve stem, the valve stem is placed on one end of the valve stem from the valve stem. A return piston is provided that is spaced apart and applies the force of a return fluid to the valve stem, and the above-mentioned return spring is provided between the return piston and the valve stem, and the return fluid is supplied from a return pressure port behind the return piston. A return pressure chamber to which pressure is supplied is provided, and the biasing force of the return spring is set to approximately 1/2 of the force of the pilot fluid acting on the valve stem at the lowest working fluid pressure, so that the return fluid pressure is When the fluid pressure for return is lower than the above minimum working fluid pressure, the return piston is separated from the valve stem, and when the return fluid pressure is higher than the above fluid pressure, the return piston is brought into contact with the valve stem, and the biasing force of the return spring is applied to the valve stem. A two-position directional valve characterized in that the valve does not operate.