KR20000059412A - Control valve device - Google Patents

Abstract

PURPOSE: A control valve apparatus is provided to prevent, without extending width of the valve block, a valve block mounted with a spool, relief valve, and an additional valve from being protruded outwardly as compared with other valve blocks. CONSTITUTION: An apparatus comprises a relief valve(32) for maintaining a load pressure of a spool and an actuator lower than a predetermined level within a valve block, and an additional valve separated from the relief valve, wherein the apparatus further comprises a first block unit(21) having a spool(23) installed thereto, and a second block unit(22) having the relief valve and an additional valve, the first block unit and the second block unit being formed integrally in thicknesswise direction of the block.

Description

Control valve device

The present invention relates to a control valve device in which a valve block is provided with a spool, a relief valve, and a valve separate from the relief valve.

In the conventional apparatus shown in FIGS. 1 and 2, an actuator port 4, 5 is inserted into the valve block 1 so as to slide and move the spool 2, and at the same time communicates with the cylinder 3. Formed. Therefore, relief valves 6 and 7 are provided in each of the actuator ports 4 and 5. The lock valve 8 is provided upstream from the relief 6.

When the spool 2 is in the neutral position shown, each of the pump port 9, the actuator ports 4, 5 and the tank ports 10, 11 is in a relationship to block communication with other ports. When the spool 2 is moved to the left in the illustrated state, the pump port 9 and one actuator port 4 communicate with each other, and the other actuator port 5 and the tank port 11 communicate with each other. Therefore, the hydraulic pressure from the pump 12 is pushed open by the lock valve 8, flows out from the actuator port 4, and is supplied to the bottom side chamber 3a of the cylinder 3.

The oil in the rod side chamber 3b of the cylinder 3 is returned from the actuator port 5 to the tank 13 via the tank port 11. In this case, the cylinder 3 is extended.

When the spool 2 is returned to the neutral position shown in this state, the communication of each port is interrupted and the cylinder 3 stops at its extended position. In this case, since the lock valve 8 is closed by the pressure in the bottom chamber 3a of the cylinder 3, the load of the cylinder 3 is also reliably maintained.

Now, when the spool 2 is moved to the right, the pump port 9 and the other actuator port 5 communicate with each other, and at the same time, the actuator port 4 and the tank port 11 communicate with each other. Therefore, the hydraulic pressure in the pump 12 is supplied from the actuator port 5 to the rod side chamber 3b of the cylinder 3. At this time, since the pressure chamber 8a of the lock valve 8 communicates with the tank port 10 through the passage 14, the pressure in this pressure chamber 8a becomes equal to the pressure in the tank. For this reason, the poppet 8b is opened, and the oil of the bottom chamber 3a of the cylinder 3 is returned from the actuator port 4 to the tank 13 via the tank port 10. In this case, the cylinder 3 contracts.

However, in the conventional control valve device as described above, since three valves 6 to 8 are provided in one valve block 1, the width h becomes large. For this reason, for example, as shown in Fig. 5, when the valve block 1 is extended from another valve block 15, 16 having no lock valve, the actuator port 4, 5 side of the valve block 1 is different. It protrudes outward from the actuator ports 17, 18 of the valve blocks 15, 16. Thus, when only the valve block 1 protrudes, when it tries to attach the piping connector to the actuator ports 17 and 18 of the other valve blocks 15 and 16, it will interfere with the protruding valve block 1. Therefore, in the conventional control valve apparatus, there existed a problem that the piping connector of a standard specification cannot be used for the valve blocks 15 and 16 in such a state.

An object of the present invention is to provide a control valve device in which the valve block does not protrude outward from other blocks even when a valve, which is separate from the spool, the relief valve and the relief valve, is provided in the valve block.

1 is a cross-sectional view of a conventional control valve device.

2 is a view of a conventional valve block connected with another valve block.

3 is a cross-sectional view illustrating a state in which an apparatus according to an embodiment of the present invention is separated into a first block and a second block.

4A is a right side view of a valve block of an apparatus according to an embodiment of the present invention connected to another valve block.

4B is a left side view of the valve block of the apparatus according to an embodiment of the present invention connected to another valve block.

5 is a front view illustrating a state in which a valve block of the apparatus according to an embodiment of the present invention is connected to another valve block.

<Description of reference numerals for the main parts of the drawings>

21: first block portion 22: second block portion

23: spool 24, 25: pump passage

26: neutral communication passage 27: pump supply passage

28, 29: Actuator port 32: relief valve

33: Actuator port 38: Main poppet

39: pilot poppet 40: pressure chamber

41: spring 42: pilot piston

43: drain passage

The object of the present invention is to provide a control valve device comprising a relief valve for maintaining a load pressure of a spool and an actuator within a predetermined value in a valve block, and a separate valve distinct from the relief valve. This is achieved by a control valve device in which one block and a second block portion provided with a relief valve and another valve are continuously integrated in the thickness direction of the block. Preferably, said separate valve is a lock valve.

Hereinafter, an embodiment of a control valve device according to the present invention will be described in detail with reference to the drawings.

As can be seen from Fig. 3, the present embodiment includes a first block portion 21 and a second block portion 22, and these block portions are integrated in the width direction. The valve block a consists of the 1st block part 21 and the 2nd block part 22, and integrated both block parts 21 and 22 in the width direction of the block a.

In the first block 21, when the spool 23 is in the neutral position, the pump communication passages 24 and 25 and the neutral passage 26 communicate with each other, and both opening portions of the supply passage 27 connect to the spool. It is. An actuator port 28 is formed in the first block 21, and the actuator port 28 communicates with a connection port 30 that opens and closes the passage 29. A relief valve 32 is provided at the confluence point of the passage 29 and the tank passage 31. An actuator port 33 is formed in the second block portion 22 and communicates with the port 35 formed in the first block portion 21 on the upstream side of the passage 34 communicating with the port 33. do. In addition, the passage 34 is provided with a lock valve V so that the downstream side of the lock valve V is communicated with a relief port 35 formed in the second block portion 22, and a separate relief for this port. Install the valve (37).

The actuator port 28 formed in the said 1st block part 21 and the actuator port 33 formed in the 2nd block part 22 are set to the same position. The lock valve V is provided with the main poppet 38 and the pilot poppet 39, and the spring 41 is provided in the pressure chamber 40 between these poppets. By the action of the spring 41, the main poppet 38 remains closed in the neutral position and is opened by the action of the pressure from the connecting poppet 35 to the passage 34. Even if pressure is generated on the actuator port 33 side or the pressure acts on the pressure chamber 40, the main poppet 38 remains closed under the action of the spring 41. When the pilot poppet 39 is compressed in this state, the pressure chamber 40 and the drain passage 43 communicate with each other. The drain passage 43 communicates with the tank passage 31 such that the pressure inside the pressure chamber 40 is equal to the pressure of the tank. Accordingly, the pressure acting on the main poppet 38 opens the main poppet 38 while overcoming the pressure in the pressure chamber 40.

In this embodiment, when the spool is turned to the right, the neutral flow passage 26 is blocked, and the supply passage 27 and the connection passage 35 communicate with each other so that the pressure oil of the pump is connected to the pump passage 25, the supply passage 27, It flows into the passage 34 via the connection port 35 sequentially. This pressure oil pushes the main poppet 38 in the lock valve and is supplied from the actuator port 33 to the cylinder head chamber 44. In addition, the connection port 30 and the tank passage 31 communicate with each other, and the return oil flows from the rod side 45 of the cylinder C to the actuator port 28, the passage 29, the connection port 30, and the tank passage 31. ) Is sequentially returned to the tank T.

When the spool is in the neutral position, even if the pressure of the cylinder port 33 rises, the cylinder C maintains the load by the action of the pressure chamber of the main poppet 40.

When the spool is turned to the left, the pilot poppet 39 is opened by simultaneously applying pilot pressure to the upper end of the piston 42 of the lock valve V and the pressure in the pressure chamber 40 is transferred to the tank through the drain passage 40. The main poppet 38 is opened and the return oil of the cylinder returns to the tank.

4A and 4B show a right side view and a left side view, respectively, in a state in which the valve block a of FIG. 3 is extended to the other blocks 50 and 47. As can be seen from these figures, it can be seen that the valve block of this embodiment is larger than other valve blocks in the height direction with respect to the other blocks.

5 is a front view in a state in which the valve block a of the present invention is connected to another valve block. As can be seen from this figure, the valve blocks 60 and 67 which are extended to the valve block a are shown. In this embodiment, the valve block 60 has ports 48 and 49 connected to the actuator 62, and another valve block 67 is connected to the other actuators 69. Equipped with. As can be seen from the figure, the valve block (a) of the present invention does not protrude as compared to the other valve blocks (60, 67).

According to the control valve device of the present invention, even if the width of the valve block is not increased, a spool, a relief valve, and a valve separate from the relief valve can be installed there, so that only this valve block protrudes in the width direction from another valve block. Can be prevented.

Claims (2)

A control valve device having a valve block for maintaining a load pressure of a spool and an actuator within a predetermined value, and a separate valve separate from the relief valve, comprising: a first block provided with a spool; A control valve device in which a second block portion provided with a separate valve is continuously integrated in the thickness direction of the block. The control valve device according to claim 1, wherein the separate valve is a lock valve.