JPH0612121B2 - Direction switching valve - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION (Industrial field of application) The present invention has a tandem passage and a parallel passage, and is used for connecting a plurality of actuators to one pump, such as a power shovel, for example. Regarding the switching valve.

(Prior Art) FIG. 5 shows a conventional directional control valve, in which actuator ports 11 and 12 are formed in a valve body 10 of the directional control valve a, and a spool 13 is slidably provided. .

A guide pipe 14 is engaged with the valve body 10. The upper end of the guide pipe 14 is closed by a plug 15, while the tip end opening is open to a tandem passage 18 '.

Further, a first check valve 19 and a second check valve 20 are slidably engaged with the outer circumference of the guide pipe 14, and the first check valve 19 has a poppet at the upper end of its cylindrical portion 19a. While forming the portion 19b, the second check valve 20 has a large diameter portion 20b formed at the upper end of the tubular portion 20a. A spring 21 is interposed between the poppet portion 19b and the large-diameter depression 20b.

The first check valve 19 thus configured normally causes the poppet portion 19b to be in pressure contact with the seat portion 22 and allows only oil to flow from the parallel passage 17 to the communication passage 16. Further, the second check valve 20 is normally operated by the spring 21 so that the large-diameter portion 20
b closes the through hole 23 formed in the guide pipe 14. Then, a gap is formed between the inner peripheral surface of the large-diameter portion 20b and the guide pipe 14, and the gap is used as a pressure receiving surface,
When the pressure is applied to the pressure receiving surface, the through hole 23 is opened, and thus the second check valve 20 allows only the flow from the tandem passage 18 'to the communication passage 16.

The directional control valve a thus configured is used in a multiple manner. In this connection state, when the directional control valve on the upstream side is in the neutral position, the tandem passage 18 'of the directional control valve on the downstream side is provided.
The discharge oil of the pump P is supplied to.

The pump discharge oil thus supplied to the tandem passage 18 'acts on the pressure receiving surface of the second check valve 20 via the through hole 23 and pushes down the second check valve 20 against the spring 21. . When the second check valve 20 is pushed down, the tandem passage 18 ′ and the communication passage 16 communicate with each other through the through hole 23.

Therefore, the tandem passage 18 'of the upstream directional control valve a
The discharged oil that has passed through is supplied to the communication passage 16 of the downstream direction switching valve a. In this state, when the spool 13 is pushed to the right in the drawing, for example, the communication passage 16 and the actuator port 11 communicate with each other, while the actuator port 12 communicates with the tank port 24, so that the actuator ports 11 and 12 are connected. The driven actuator will be driven.

When the spool 13 is pulled leftward contrary to the above, the actuator port 12 communicates with the communication passage 16 and the actuator port 11 communicates with the tank port 24.

When the upstream side directional control valve a is switched to the left or right, the tandem passage 18 'is closed, so that pump discharge oil is supplied to the downstream side directional control valve via the parallel passage 17. It

When the pressure oil is supplied to the parallel passage 17 in this way, the pressure acts on the first check valve 19 and the pressure is applied to the spring 21.
Since the parallel passage 17 and the communication passage 16 are communicated with each other by pushing up against them, the pressure oil is supplied to the communication passage 16. Therefore, the actuators connected to the actuator ports 11 and 12 can be driven by switching the spool 13 to the left or right as in the above case.

(Problems to be Solved by the Present Invention) In the conventional directional control valve as described above, when the upstream actuator and the downstream actuator are simultaneously driven, if one actuator has a low load, the low Pressure oil is preferentially supplied to one actuator, and sufficient pressure oil is not supplied to the actuator with the higher load,
After all, there was a drawback that both actuators could not be operated simultaneously.

Further, in the case of an actuator having different loads on the extension side and the contraction side, when driving the actuator on the light load side, in order to drive another actuator at the same time, pressure oil is supplied to the low load side. An orifice must be provided in the flow path. However, an orifice is not required in the flow path for supplying pressure oil to the high load side.

Therefore, in order to solve the above-mentioned point with this conventional directional control valve, it is necessary to separately provide a parallel passage communicating with the low load side, and to provide an orifice in the separately provided parallel passage.

However, the formation of such another passage has a problem that the manufacturing process increases and the switching valve becomes large.

SUMMARY OF THE INVENTION An object of the present invention is to provide a directional control valve capable of driving an actuator having different loads on the extension side and the contraction side simultaneously with another actuator without providing a separate passage as in the prior art. .

(Means for Solving Problems) The present invention forms a pair of actuator ports in a valve body, and a spool is slidably provided on the valve body, and when the spool is held at a neutral position, When the tandem passage is opened and the spool is switched to any position, the tandem passage is closed, while the communication passage formed in the valve body communicates with either one of the actuator passages, and the valve body is connected to the neutral passage. A guide pipe that directly communicates is provided, the parallel passage and the communication passage are communicated via the outer circumference of the guide pipe, and a first check valve is slidably provided on the outer circumference of the guide pipe. Only the flow passage from the parallel passage to the communicating passage is allowed, and the communicating passage and the tandem passage are communicated with each other through the guide pipe. A second check valve is provided in the communication process, and the second check valve is premised on a direction switching valve configured to allow only the flow from the tandem passage to the communication passage.

Based on the above directional switching valve, the present invention provides a communication passage independently from the outer periphery of the guide pipe on the left and right sides, and allows one communication passage to directly communicate with the downstream side of the first check valve and the other communication passage. The feature is that the passage is communicated with the downstream side of the first check valve through an orifice formed on the downstream side of the first check valve.

(Operation of the present invention) The present invention, when the load is different between the expansion side and the contraction side,
Throttling resistance can be applied only to the pressure oil supplied to the low load side.

(Example of the present invention) the second and third view, the directional control valve a ₁ on the upstream side, above the conventional manner of construction, the direction switching valve a ₂ provided on the most downstream, these directional control valve a ₁ The directional control valve a ₃ of the present invention is provided between the a and the a ₂ .

The directional control valve a ₂ on the downstream side is characterized in that an orifice is provided in the flow path process of the parallel passage and the communication passage, and the other points are the same as the directional control valve of FIG.

The directional control valve a ₂ is, as shown in FIG.
An orifice 25 is provided between the parallel passage 17 and the seat portion 22 of the first check valve 19.

Therefore, when the upstream side directional control valve a ₁ and the downstream side directional control valve a ₂ are simultaneously switched and the actuators connected to them are simultaneously driven, the parallel passage 17 of the downstream side directional control valve a ₂ is The pressure oil of the pump P is supplied.

The pressure oil supplied to the parallel passage 17 is supplied to the orifice 25.
And is supplied to the communication passage 16 via the first check valve 19. The pressure oil supplied to the communication passage 16 is supplied to one of the actuator ports 11 depending on the switching direction of the spool 13.
Alternatively, it is supplied from 12 to the actuator.

When pressure oil is supplied to the actuator via the parallel passage 17 of the direction switching a ₂ as described above, the pressure is always generated via the orifice 25 and the pressure is generated on the upstream side of the orifice 25. Even if the actuator connected to a ₂ has a light load, the actuator connected to the upstream directional control valve a ₁ can be operated simultaneously.

The directional control valve a ₃ shown in FIG. 1 has one actuator port 11 thereof connected to the rod side chamber 26 of the cylinder C,
The other actuator port 12 is communicated with the bottom side chamber 27, and a counter load acts on the cylinder C during its extension operation.

Then, the guide pipe 14 communicating with the tandem passage 18 '
Has an enlarged diameter portion 14a at its upper end, and the enlarged diameter portion 14a
The annular groove 14b is formed around a and the annular groove is formed.
A through hole 14c is formed in 14b. Furthermore, the enlarged diameter part
A second check valve 28 is internally provided in 14a. This second check valve 28 is normally in pressure contact with the seat portion 30 by the action of a spring 29 so that the tandem passage 18 'leads to the through hole 14c. Only the distribution is allowed.

Then, in the directional control valve a _3, to separate the left and right communication passage 16, the left side of the drawing the first communication passage 16a, the right the second communication passage
16b. The first communication passage 16a has its tip open to the annular recess 31 around the first check valve 19, and the second communication passage 16b has its tip opened to the annular groove 14b.

Further, an orifice 32 that connects the annular recess 31 and the annular groove 14b is formed around the enlarged diameter portion 14a.

Now, when the upstream directional control valve a ₁ is switched and the directional control valve a ₃ is simultaneously switched, the pressure oil of the pump P is supplied to the parallel passage 17 of the directional control valve a ₃ .

At this time, when the spool 13 is pulled to the right in the drawing, the one actuator port 11 and the first communication passage 16a communicate with each other, and the other actuator port 12 becomes the tank port.
Connect to 24.

Therefore, in this state, the pressure oil supplied to the parallel passage 17 passes through the first check valve 19 → the annular recess 31 → the first communication passage 16a → the one actuator port 11,
It is supplied to the rod side chamber 26 of the cylinder C, and the cylinder C concerned
Contract.

In addition, if the spool 13 is pushed to the left in the drawing in the above state, one actuator port 11 will move to the tank port 24
And the other actuator port 12 communicates with the first communication passage.
Connect to 16b.

Therefore, in this state, the pressure oil supplied to the parallel passage 17 is the first check valve 19 → the annular recess 31 → the orifice.
It is supplied to the bottom side chamber 27 of the cylinder C via 32 → annular groove 14b → first communication passage 16b → the other actuator port 12 and extends the cylinder C.

As described above, when the cylinder C extends, the counter load acts, but even if the counter load acts, the pressure oil is supplied to the bottom side chamber 27 via the orifice 32. So the orifice
The pressure on the upstream side of 32 rises, and the pressure oil from the pump P is also supplied to other actuators.

If the upstream directional control valve a ₁ is held in the neutral position shown in the figure, the oil discharged from the pump P will be supplied to the tandem passage 18 ′ on the downstream side via the neutral passage 18. . Therefore, when the spool 13 is pulled to the right in the drawing, the pressure oil from the neutral passage 18 passes through the tandem passage 18 '→ the second check valve 28 → the orifice 32 → the first communication passage 16a → the one actuator port 11 Is supplied to the rod side chamber 26. Further, if the spool 13 is pushed to the left, the pressure oil will flow into the tandem passage 18 '→ the second check valve 28 → the through hole 14
It is supplied to the bottom side chamber 27 via c → annular groove 14b → second communication passage 16b → the other actuator port 12.

In the case where the load is different between the extension side and the contraction side as in the cylinder C described above, when the pressure oil is supplied to the lower load side, the throttling resistance is applied to the supply oil. Otherwise, other high load actuators cannot be driven at the same time.

However, in the directional control valve a _3, when supplying pressure oil to the bottom chamber 27 of the light load, since so as to via the orifice 32, other actuators high load can also be simultaneously driven. Moreover, when the pressure oil is supplied to the rod-side chamber 26 having a high load, the pressure oil can be supplied without passing through the orifice 32.

Therefore, using the directional control valve a _3, together selectively the communication path to the first communication passage 16a and the second communication passage 16b, when supplying pressure oil to the second communication passage 16b is such that through the orifice 32 Therefore, it is not necessary to specially form the parallel passage.

(Effect of the Invention) According to the present invention, when the load is different between the extension side and the contraction side, throttling resistance can be imparted to the pressure oil supplied to the low load side. Therefore, even when the pressure oil is supplied to the low load side, other actuators can be simultaneously driven.

Moreover, in this case, since it is not necessary to specially form the parallel passages, the number of manufacturing processes for the parallel passages does not increase or the size of the device is not changed.

[Brief description of drawings]

Figure 1 is a sectional view of the directional control valve a ₃ of the present invention, FIG. 1 along line II-II cross-sectional view in FIG. 2 connecting state, FIG. 3 is a second
FIG. III-III line sectional view, FIG. 4 is a sectional view of the directional control valve a ₂ , and FIG. 5 is a conventional sectional view. a ₃ ...... Direction switching valve, 10 ...... Valve body, 11, 12 ...... Actuator port, 13 ...... Spool, 14 ...... Guide pipe, 16 ...... Communication passage, 17 ...... Parallel passage, 18 '...... Tandem Passageway, 19 ... First check valve, 28 ... Second check valve, 32 ... Orifice.

Claims (1)

[Claims] 1. A pair of actuator ports are formed on a valve body, and a spool is slidably provided on the valve body. When the spool is held at a neutral position, a tandem passage is opened and either spool is opened. When switching to the position, the tandem passage closes, while the communication passage formed in the valve body communicates with either one of the actuator passages, and further, the valve body is provided with a guide pipe that directly communicates with the tandem passage. The parallel passage and the communication passage are communicated with each other via the outer circumference of the pipe, and the first check valve is slidably provided on the outer circumference of the guide pipe. This first check valve only allows the passage from the parallel passage to the communication passage. In addition, the communication path and the tandem flow path are communicated with each other via the inside of the guide pipe, and the second check is performed in the communication process. The second check valve is a directional switching valve configured to allow only the flow from the tandem passage to the communication passage, and the communication passage is provided independently from the outer circumference of the guide pipe to the left and right. First passage
Directly communicate with the downstream side of the check valve, and the other communication path through an orifice formed on the downstream side of the first check valve,
A directional control valve that is in communication with the downstream side of the first check valve.