KR0166646B1 - Pressure reducing valve - Google Patents

Abstract

The present invention relates to a pressure reducing valve which makes it possible to form a pressure oil having a certain range of pressure at the outlet side regardless of the pressure at the inlet side.

In the present invention described above, the inflow side (2) having a discharge port (3) in which the pressurized oil is introduced: the screw of the cap (18) in a state in which the first slider (13) is slidably in communication with the discharge port (3). The first chamber (4) sealed by the coupling: the second slider in communication with the first chamber (4) and the surface through hole (6), longitudinal communication hole (11), secondary communication hole (12) inherently slidable ( The second chamber (5) sealed by screwing the pressure adjusting cap (19) to adjust the elastic force of the spring (16) after positioning the spring (16) on the side of the first: the first slider (13) and A check valve incorporating a check valve in communication with the bolt 17 for fastening the second slider 15 through the fastening hole 10 so as to interlock with each other, and the second chamber 5 and the vertical hole 7. Thread 8; And it provides a pressure reducing valve, characterized in that composed of the discharge side (9) in communication with the check valve chamber (8) as the pressure oil is discharged.

Description

Pressure Reducing Valve

Figure 1 shows only the main body of the pressure reducing valve of the present invention

(a) is sectional drawing of a main body.

(b) is a right side view of the main body.

2 is a sectional view showing the entire configuration of a pressure reducing valve according to the present invention.

* Explanation of symbols for main parts of the drawings

1: main body 2: inflow side

3: discharge side 4: first chamber

5: room 2 6: communication hole

7: vertical hole 8: check valve chamber

9: discharge side 10: slide ball

11: longitudinal communication hole 12: auxiliary communication hole

13: first slider 14: silicon

15: the second slider 16: the spring

17: bolt 18: cap

19: pressure control cap 20: silicone

21 Body 22: Spring

23: Cap 24, 25, 26: O-ring

The present invention relates to a pressure reducing valve which makes it possible to form a pressure oil having a certain range of pressure at the outlet side regardless of the pressure at the inlet side.

In general, the pressure reducing valve is installed in the hydraulic circuit to maintain a constant pressure of the hydraulic oil or to reduce the pressure to an appropriate condition. A typical example of such a pressure reducing valve is a direct operated pressure reducing valve.

The direct acting pressure reducing valve has a spring-loaded spring between the inlet and outlet sides, narrows the flow path according to the pressure of the hydraulic oil acting on it, controls the flow rate and reduces the pressure on the outlet side by pressure loss. It is supposed to be.

Such a direct acting pressure reducing valve not only has a fairly complicated configuration for depressurization but also requires precise manufacturing for decompression. In addition, since the configuration and manufacturing conditions are difficult, the pressure reducing valve is marketed at a considerable price.

The present invention is to solve the disadvantages of the conventional pressure reducing valve as described above, an object of the present invention is to provide a pressure reducing valve that is easy to manufacture because of its simple configuration.

Another object of the present invention to achieve the above object is to provide a low-cost pressure reducing valve.

In order to achieve the above object, the present invention is the inlet side having a discharge port as the pressure oil flows into: a first chamber sealed in four engagement in a state in which the first slider is slidably in communication with the discharge port: the first chamber A second chamber sealed by a screw coupling of a pressure adjusting cap which adjusts the elastic force of the spring after placing the spring on the side of the second slider which is slidable and communicated by the thread, the communication hole, the longitudinal communication hole, and the auxiliary communication hole; A check valve chamber having a check valve embedded therein, which is connected by a bolt through which the first slider and the second slider are interlocked so as to be interlocked with each other, the second chamber and a vertical hole, and a check valve in which pressure oil is discharged. It provides a pressure reducing valve, characterized in that configured to the discharge side in communication with the seal.

Hereinafter, the present invention will be described in more detail with reference to the accompanying drawings.

1 is a cross-sectional view showing the main body of the pressure reducing valve of the present invention.

In (a), the inflow side 2 which has the discharge port 3 is formed in the center of the main body 1, and it turns upward perpendicularly from a bottom part, and turns at right angles.

The first chamber 4 is formed on the right side of the main body 1. The first chamber 4 communicates with the discharge port 3.

The second chamber 5 is formed on the left side of the main body 1.

The first chamber 4 and the second chamber 5 communicate with each other by the communication hole 6 and the like, which will be described later.

In the second chamber 5, vertical holes 7 are formed vertically upward. The vertical hole 7 communicates with the check valve chamber 8. The discharge side 9 is formed horizontally on the side of the check valve chamber 8.

(B) of FIG. 1 is a right side view of the main body shown to (a).

This is for explaining the above-mentioned communication hole and the like.

The discharge port 3 is located in the center of the first chamber 4. In the radial position around the discharge port 3, a plurality of holes having different diameters are formed.

Holes formed on both sides of the discharge port 3 are slide holes 10.

The other holes are the communication hole 6, the longitudinal communication hole 11, and the auxiliary communication hole 12 serving as the flow path of the pressurized oil.

Holes other than the discharge port 3 are formed to communicate the first chamber 4 and the second chamber 5.

The inlet 2 is located at the bottom of the first chamber 4. In the upper part of the 1st chamber 4, the check valve chamber 8 which communicates with the discharge port 9 is located.

2 is a cross-sectional view showing a state in which the internal configuration of the main body is completed. This will be described together with FIG.

The first slider 13 is embedded in the first chamber 4. The first slider 13 is embedded in the first chamber 4 so as to slide left and right. The silicon 14 is immersed in the center of the left side surface of the first slider 13 to be in contact with the discharge port 3. The first chamber 4 is shielded from the outside by the cap 18, and an O-ring 26 is inserted inside the cap 18 to prevent the leakage of the pressurized oil.

The second slider 15 is embedded in the second chamber 5. The second slider 15 is also embedded in the second chamber 5 so as to slide left and right. On the left side of the second slider 15, a spring 16 is positioned to contact the left side thereof. A flaw is formed in the outer surface of the second slider 15, and an O-ring 25 is permanently placed in the groove to prevent the oil pressure from entering the second chamber 5.

The first slider 13 and the second slider 15 are fastened by two bolts 17 so as to interlock with each other. Specifically, the first slider 13 has a fastening hole in which spirals are formed while penetrating the first slider 13 on both sides of the silicon 14 as viewed from the side. Passed through each slider hole 10 shown in the) is screwed with the second slider (15). The bolt 17 has a spiral formed just before the head and at its end, and the surface is smoothly and precisely processed so as to slide through the slide hole 10 therebetween.

The first chamber 4 in which the first slider 13 is embedded is sealed by screwing the keep 18.

The second chamber 5 also has the second slider 15 embedded therein, the spring 16 is inserted therein, and the pressure adjusting cap 19 for adjusting the reaction force of the spring 16 is screwed and sealed.

The check valve chamber 8 includes a body 21 into which the silicon 20 capable of closing the vertical hole 7 is immersed, and a spring 22 for closely contacting the body 21 to the vertical hole 7. It is. The check valve chamber 8 is provided with an O-ring 24 on the inside thereof and sealed by a cap 23. The structure of the check valve chamber 8 is composed of a conventional check valve for preventing a backflow. same.

The operation of the present invention having the configuration as described above will be described.

The pressure oil flowing into the inflow side 2 is discharged to the first chamber 4 through the discharge port 3. The pressure oil introduced into the first chamber 4 passes through the communication hole 6, the longitudinal communication hole 11, and the auxiliary communication hole 12, enters the second chamber 5, and rises along the vertical hole 7 again. Toward the check valve chamber (8). The pressure oil rising along the vertical hole 7 acts on the body 21 above the spring force of the check valve to raise the body 21 and is discharged to the discharge side 9.

It describes a process in which the pressure oil having the flow path as described above is decompressed.

First, the pressure of the pressure oil of the 1st chamber 4 is set to Pl, and the pressure of the pressure oil of the 2nd chamber 5 is set to P2.

The pressurized oil flowing into the first chamber 4 through the inlet side 2 through the discharge port 3 passes through the communication hole 6, the longitudinal communication hole 11, and the auxiliary communication hole 12. Flows into. In this process, the discharge port 3 discharges the pressurized oil intensively in the central portion of the side of the first slider 13, and the communication hole 6, the longitudinal communication hole 11, and the auxiliary communication hole 12 are the second slider 15. Spray the pressure oil evenly over the whole side of the.

Here, when the pressure of the pressure oil flowing through the inlet side (2) flows into the pressure higher than the desired set value after the discharge side (9), the second slider (15) than the pressure Pl of the pressure oil acting on the first slider (13) The pressure P2 of the pressurized oil acting on) becomes larger. As a result, the second slider 15 slides to the left while overcoming the reflection force of the spring 16. As the second slider 15 moves to the left side, the bolt 17 penetrating the slide hole 10 also moves to the left side, whereby the first slider 13 also moves to the left side.

The first slider 13 moving to the left induces a pressure drop while controlling the flow rate of the pressure oil discharged through the discharge port 3. As a result, when the pressure P2 acting on the second slider 15 becomes lower than the reaction force of the spring 16, the pressure P2 is moved to the right side of the original position by the restoring force of the spring 16. Accordingly, the first slider 13 is also restored to its original position. When the pressure of the hydraulic oil is too high, the silicon 14 of the first slider 13 moving to the left closes the discharge port 3 as narrowly as possible to achieve an equilibrium state in which the flow of the hydraulic oil stops.

On the contrary, when the pressure of the hydraulic oil flowing through the inflow side 2 is lower than the set value, the pressure P2 acting on the second slider 15 is lowered so that the acting force becomes less than or equal to the spring force. As a result, the spring is in close contact with the pushing force.

That is, the first slider 13 is moved to the right as much as possible. As a result, the flow rate of the pressurized oil flowing into the discharge port 3 is maximized, and the pressure Pl of the first chamber 4 and the pressure P2 of the second chamber 5 are increased.

As described above, it is possible to adjust the pressure of the step-down valve of the present invention to discharge the set pressure so that the reflection of the spring 16 by tightening or releasing the pressure adjusting cap 19 screwed to the second chamber 5. It is possible by setting the position of the second slider 15 in advance by adjusting the force.

The pressure reducing valve of the present invention acting as described above is easy to manufacture due to its simple configuration, and the cost required for manufacturing is low due to its simple internal configuration.

In addition, it is possible to freely adjust the setpoint pressure on the discharge side using the pressure adjustment cap.

Claims (1)

An inflow side 2 having a discharge port 3 through which pressure oil is introduced; A first chamber (4) communicating with the discharge port (3) and sealed by screwing by a cap (18) in a state in which the first slider (13) is slidably installed; The spring 16 is connected to the first chamber 4 by the communication hole 6, the longitudinal communication hole 11, and the auxiliary communication hole 12, and is provided on the side of the second slider 15 slidably installed. A second chamber (5) sealed by engagement by screws formed in the pressure adjusting cap (19) for adjusting the elastic force of the spring (16) after positioning; A bolt 17 for fastening the first slider 13 and the second slider 15 through the fastening hole 10 so that the first slider 13 and the second slider 15 interlock with each other; A check valve chamber 8 in communication with the second chamber 5 and the vertical hole 7 in which a check valve is installed; And a discharge side (9) communicating with the check valve chamber (8) and discharging the pressurized oil.