KR200300085Y1 - valve plate - Google Patents

Abstract

The disclosed subject matter is particularly intended to prevent the axial piston pump or the axial piston motor from being damaged by erosion and cavitation due to hydraulic oil and to operate with low noise and low vibration.

In order to realize this, in the present invention, in a valve plate which is used in a hydraulic piston pump or a hydraulic piston motor, and a high pressure port and a low pressure port are formed on the circumference of the same radius, the hydraulic fluid flowing through the inside of the valve plate A curved inlet is formed in the high pressure switch 11a adjacent to the high pressure port 11 of the valve plate 7 to prevent erosion, and the low pressure port 10 and the high pressure port 11 Induction holes 16 are formed in the vicinity, and the low pressure switch 10a and the high pressure switch 11a are formed at positions adjacent to the low pressure port 10 and the high pressure port 11, respectively. The curved inlet port 15 is formed in the low pressure switch 10a adjacent to the low pressure port 10 of the valve plate 7 to prevent the cavitation phenomenon due to the hydraulic fluid flowing through the inside of the Valve plate Is provided.

Description

Valve plate

The present invention relates to a valve plate, and in particular, to prevent the axial piston pump or the axial piston motor from being damaged by the erosion and cavitation caused by the hydraulic oil, and to prevent the hydraulic oil from operating at high speed and high pressure to operate with low noise and low vibration. A valve plate adapted to change direction.

The hydraulic piston pump acts as a pump by the reciprocating motion of the piston in the cylinder. Since the leakage can be reduced at high pressure, the hydraulic piston pump maintains high efficiency and is used for high pressure.

Such piston pumps are basically divided into radial type, axial type, and reciprocal type according to the arrangement of the piston.

On the other hand, the axial piston pump has a structure in which the piston is disposed in the cylindrical surface around the axis parallel to the cylinder block axis, and is divided into a swash plate type, a rotary swash plate type, and a bent axis type by a reciprocating operation method of the piston. .

1 shows a swash plate axial piston pump. That is, the cylinder block 3 is coupled by the drive shaft 1 and the spline 1a, and the swash plate 9 is rotated by the rotation of the drive shaft 1, so that the piston in the cylinder block 3 (4) rotates and reciprocates according to the tilt angle of the swash plate (9).

By this operation, the hydraulic oil is sucked from the low pressure port 10 formed in the valve plate 7 fixed to the valve block 6 and discharged to the high pressure port 11 (see Fig. 2). The discharge flow rate may be changed according to the tilt angle of the swash plate (9).

In addition, the hydraulic piston motor has the same structure as the hydraulic piston pump, but in operation, the cylinder block is rotated by the reciprocating motion of the piston by the high pressure oil to transmit the driving force through the drive shaft in the opposite operation. have.

In such a piston pump or piston motor, the cylinder block 3, which is connected to the spline 1a of the drive shaft 1 and forms the plurality of piston chambers 2, is fixed to the valve block 6. The fluid is sucked and discharged in accordance with the angle of the swash plate 9 while rotating in contact with the surface of (7).

In this process, when the piston chamber 2 of the cylinder block 3 is switched from the low pressure port 10 of the valve plate 7 to the high pressure port 11, the pressure of the piston chamber 2 suddenly increases rapidly. It rises rapidly and periodically explodes. Accordingly, the pump or motor vibrates and noise is generated.

In addition, as shown in FIGS. 2 to 5, the induction hole 16 and the induction port 14 are formed in adjacent portions of the high pressure port 11 and the low pressure port 10 so that the pressure in the piston chamber 12 is increased. Slowly rising or falling.

However, in such a solution, as shown in FIG. 5, a high pressure, high speed hydraulic fluid is introduced into the piston chamber 2 of the cylinder block 3 through an inlet 14 formed in a straight surface on the valve plate 7. Since it flows in, it collides with the surface of the valve plate 7 and the wall surface of the cylinder block 3, causing the erosion phenomenon.

However, in the prior art as described above, when the piston chamber 2 is switched from the high pressure port 11 to the low pressure port 10 to communicate with each other, a sudden pressure drop phenomenon occurs in the piston chamber 2. Therefore, since cavitation occurs and no means for preventing the cavitation phenomenon is taken, there is a problem that the wall surface of the cylinder block 3 is destroyed, causing damage to the pump or the motor.

The present invention is devised to solve the problems as described above, the purpose of the present invention is to prevent the damage of the axial piston pump or axial piston motor due to the erosion and cavitation phenomena and to operate at low noise and low vibration at high speed, high pressure An object of the present invention is to provide a valve plate in which a guide hole is formed in a curved shape so as to change a direction of hydraulic oil flowing into the pump.

1 is a cross-sectional view of an axial piston pump or axial piston motor.

2 is a front view of a valve plate according to the prior art.

3 is a cross-sectional view taken along the line A-A of FIG.

4 is a cross-sectional view taken along the line B-B of FIG. 2.

Fig. 5 is a sectional view showing the flow of hydraulic oil in the valve plate according to the prior art.

6 is a front view of a valve plate according to a preferred embodiment of the present invention.

7 is a cross-sectional view taken along line C-C of FIG. 6 showing the flow of hydraulic oil in a valve plate according to a preferred embodiment of the present invention.

* Explanation of symbols used in the main part of the drawing *

7: valve plate

10: low pressure port

10a: low pressure switch

11: high pressure ball

11a: high pressure switch

15: curved guide

In order to realize this, the present invention, in a valve plate which is used in a hydraulic piston pump or a hydraulic piston motor and is formed with a high-pressure port and a low-pressure port on the circumference of its same radius, is provided by a hydraulic fluid flowing through the interior thereof. A curved induction port is formed in the high pressure switching portion adjacent to the high pressure port of the valve plate to prevent erosion, and the induction hole 16 is provided in the vicinity of the low pressure port 10 and the high pressure port 11, respectively. And a low pressure switching unit 10a and a high pressure switching unit 11a are formed at positions adjacent to the low pressure port 10 and the high pressure port 11, respectively. Provided is a valve plate, characterized in that the curved inlet is formed in the low pressure switch adjacent to the low pressure port of the valve plate to prevent cavitation phenomenon.

Hereinafter, a valve plate according to a preferred embodiment of the present invention will be described in detail with reference to FIGS. 6 and 7.

In the valve plate 7 according to the preferred embodiment of the present invention, as shown in Figure 6, the low pressure port 10 and the high pressure port 11 are formed on the circumference of the same radius as in the valve plate according to the prior art.

Induction holes 16 are formed in the vicinity of the low pressure port 10 and the high pressure port 11, respectively. In addition, each of the low pressure switch 10a and the high pressure switch 11a adjacent to the low pressure port 10 and the high pressure port 11 is formed with a curved inlet 15.

The curved guide hole 15 is formed in a curved surface, as shown in cross section in FIG.

Thus, when the cylinder block 3 rotates in contact with the sliding surface 17 of the valve plate 7, the piston chamber 2 of the cylinder block 3 is released from the low pressure port 10 of the valve plate 7. It is switched to the high-pressure port (11).

At this time, when the piston chamber 2 communicates with the curved induction hole 15 through the induction hole 16, the high-pressure, high-speed hydraulic fluid is classified along the curved surface of the curved induction port 15. Since it is changed, the impact force is prevented from being applied to the wall surface of the piston chamber 2.

As a result, the cylinder block 3 is prevented from being eroded.

In addition, when the piston chamber 2 of the cylinder block 3 is switched from the high pressure port 11 of the valve plate 7 to the low pressure port 10, the piston chamber 2 passes through the induction hole 16. Communicating with the curved inlet 15, the high-pressure, high-speed hydraulic fluid is made gentle to the pressure drop because the direction of the classification is changed to a curve along the curved surface of the curved induction port (15).

Accordingly, a rapid rapid pressure drop is prevented and the cavitation phenomenon is prevented.

Even in the hydraulic motor, the erosion phenomenon is eliminated and cavitation is prevented on the same principle as described above.

The present invention as described above, in the hydraulic piston pump or the hydraulic piston motor, the erosion phenomenon by the high pressure, high speed classification of the hydraulic fluid is eliminated, and prevents cavitation by preventing instantaneous high pressure generation and sudden pressure drop, and noise at the same time This has the advantage of providing an effect of reducing vibration and vibration.

Claims (1)

In a valve plate for use in a hydraulic piston pump or a hydraulic piston motor, the valve plate having a high pressure port and a low pressure port formed on a circumference of its same radius, A curved induction port is formed in the high pressure switch 11a adjacent to the high pressure port 11 of the valve plate 7 to prevent erosion caused by the working oil flowing through the inside thereof. Induction holes 16 are respectively formed in the vicinity of the low pressure port 10 and the high pressure port 11, The low pressure switch 10a and the high pressure switch 11a are formed at positions adjacent to the low pressure port 10 and the high pressure port 11, respectively. A curved inlet 15 is formed in the low pressure switch 10a adjacent to the low pressure port 10 of the valve plate 7 to prevent cavitation caused by the hydraulic fluid flowing through the inside of the valve. Valve plate.