JP6888451B2 - solenoid valve - Google Patents

Description

The present invention relates to a solenoid valve.

Conventionally, a solenoid valve using a spool having three lands having different diameters is known (see Patent Document 1).

Japanese Unexamined Patent Publication No. 2014-70727

In the conventional solenoid valve, the fluid pressure of the output port can be adjusted by the feedback mechanism. However, since it has a large number of ports, it is easy to cause an internal leak through the sliding surface between the spool and the sleeve.

One aspect of the present invention is to provide a solenoid valve in which internal leakage is suppressed.

According to one aspect of the present invention, a sleeve having a plurality of ports through which fluid flows and arranged along a central axis, a spool housed in the sleeve and opening and closing the port as it moves in the axial direction, and the like. A spring member that pushes the spool to one side in the axial direction and a solenoid that pushes the spool against the elastic force of the spring member are provided, and the sleeve has an input port and an output port along the axial direction. The spool has a first land portion having a first diameter and facing the feedback port along the axial direction, and has a discharge port and a feedback port connected to the output port on the outside of the sleeve. A second land portion having a second diameter smaller than the first diameter and opening and closing between the output port and the discharge port, and a third diameter smaller than the first diameter. It has a third land portion that opens and closes between the output port and the input port, and has an end surface of the first land portion on the solenoid side and an end surface of the second land portion on the spring member side or the said. Provided is an electromagnetic valve in which the end surface of the third land portion on the spring member side is arranged so as to face in the axial direction.

According to one aspect of the present invention, a solenoid valve in which internal leakage is suppressed is provided.

FIG. 1 is a cross-sectional view showing a solenoid valve of the embodiment. FIG. 2 is a cross-sectional view showing an excited state of the solenoid valve of the embodiment.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is a cross-sectional view showing a solenoid valve of the present embodiment. FIG. 2 is a cross-sectional view showing an excited state of the solenoid valve of the present embodiment.

In this embodiment, the central axis J extends in the left-right direction in FIGS. 1 and 2. In the following description, the axial direction of the central axis J is simply referred to as "axial direction", the radial direction centered on the central axis J is simply referred to as "diameter direction", and the circumferential direction centered on the central axis J is simply referred to as "axial direction". Called "circumferential".

The solenoid valve 1 of the present embodiment has a spool valve 10 and a solenoid 70 for driving the spool valve 10. The solenoid valve 1 is a normally open type solenoid valve in which the valve is opened when the energization of the solenoid 70 to the coil is cut off.

The spool valve 10 has a sleeve 20, a spool 30, a fixing portion 50, and a spring member 80. The sleeve 20 is connected to the solenoid 70 at one end on the left side of the drawing. The spool 30 and the spring member 80 are housed in the sleeve 20. The fixing portion 50 is fixed to the end portion of the sleeve 20 opposite to the solenoid 70.

The sleeve 20 has a spool hole portion 21 extending in the axial direction about the central axis J. The spool hole portion 21 opens on both sides of the sleeve 20 in the axial direction. The cross-sectional shape of the spool hole portion 21 orthogonal to the axial direction is circular.
The sleeve 20 has an input port 22, an output port 23, an discharge port 24, a feedback port 25, and a breathing port 26. The input port 22, the output port 23, the discharge port 24, the feedback port 25, and the breathing port 26 are holes penetrating from the radial outer surface of the sleeve 20 to the radial inner surface of the spool hole portion 21, and are outside the sleeve 20. And the inside of the spool hole portion 21 are connected. The position at which each port opens in the circumferential direction of the sleeve 20 can be changed as appropriate.

The input port 22, the output port 23, the discharge port 24, the feedback port 25, and the breathing port 26 are arranged in this order from the solenoid 70 side toward the fixed portion 50 side in the axial direction. The output port 23 and the feedback port 25 are connected outside the sleeve 20. A part of the fluid flowing out from the output port 23 flows into the feedback port 25.

The spool 30 is a columnar shape extending in the axial direction about the central axis J. The spool 30 is arranged so as to be movable in the axial direction in the spool hole portion 21 along the central axis J. The end of the spool 30 on the solenoid 70 side comes into contact with the pin 71 of the solenoid 70. The end of the spool 30 on the fixed portion 50 side is in contact with the spring member 80. The spool 30 has a first land portion 31, a first groove portion 30a, a second land portion 32, a second groove portion 30b, and a third land portion 33 in this order from the fixed portion 50 side.

The first land portion 31 has a first diameter L1. The second land portion 32 has a second diameter L2 that is smaller than the first diameter L1. The third land portion 33 has a third diameter L3 that is smaller than the first diameter L1. In the case of this embodiment, the second diameter L2 and the third diameter L3 have the same size. By setting the outer diameter of the land portion of the spool 30 to two types, the spool 30 and the sleeve 20 can be easily manufactured.
The first groove portion 30a has a diameter smaller than the first diameter and the second diameter. The second groove portion 30b has a diameter smaller than the second diameter and the third diameter.

The outer diameters of the first land portion 31, the second land portion 32, and the third land portion 33 are substantially the same as the inner diameter of the spool hole portion 21 at the position where each is accommodated. The spool hole portion 21 has a feedback chamber 21a, a pressure adjusting chamber 21b, and a spring chamber 21c that are axially partitioned by the first land portion 31, the second land portion 32, and the third land portion 33. The feedback chamber 21a is connected to the feedback port 25. The pressure regulating chamber 21b is connected to the input port 22, the output port 23, and the discharge port 24. The spring chamber 21c is connected to the breathing port 26.

The first groove portion 30a is located between the first land portion 31 and the second land portion 32, and has a diameter smaller than the second diameter. The first groove portion 30a is located in the feedback chamber 21a.

The second groove portion 30b is located between the second land portion 32 and the third land portion 33, and has a diameter smaller than the second diameter and the third diameter. The second groove portion 30b is located in the pressure regulating chamber 21b. The second groove portion 30b is passed through the output port 23 and the discharge port 24 in the portion on the second land portion 32 side. The second groove portion 30b is passed through the input port 22 and the output port 23 in the portion on the third land portion 33 side.

The fixing portion 50 is fixed to the end portion of the sleeve 20 opposite to the solenoid 70, and closes the opening of the spool hole portion 21.
The spring member 80 is a coil spring in this embodiment. The spring member 80 is housed in the spring chamber 21c. The spring member 80 is housed in a compressed state between the spool 30 and the fixing portion 50 in the spool hole portion 21, and pushes the spool 30 toward the solenoid 70.

The solenoid 70 includes a pin 71 that can move in the axial direction, a drive unit 72 that drives the pin 71, a housing 73 that fixes the drive unit 72 and the sleeve 20, and a connector 75 that is connected to the drive unit 72. Have.

The pin 71 is a columnar pin made of a non-magnetic material. The pin 71 is arranged along the central axis J, and a part of the pin 71 is inserted into the drive unit 72. The portion of the pin 71 protruding from the drive portion 72 is inserted into the spool hole portion 21 of the sleeve 20. In the spool hole portion 21, the pin 71 and the spool 30 come into axial contact with each other.

The drive unit 72 has a plunger, a coil and a core (not shown). The plunger is a cylindrical member made of a ferromagnetic material, is arranged inside a cylindrical core, and can move in the axial direction in the drive unit 72. The plunger is in contact with or connected to the end of the pin 71 opposite the spool 30. The connector 75 is electrically connected to the coil of the drive unit 72.

When the coil is energized by the electric power supplied through the connector 75 in the drive unit 72, the plunger moves toward the spool 30 side along the axial direction due to the magnetic force generated by the coil, and the pin 71 is moved to the spool 30 side. Push. The pin 71 moves the spool 30 toward the fixed portion 50 against the spring force of the spring member 80.

As the spool 30 moves in the axial direction with respect to the sleeve 20, the connected state of the input port 22, the output port 23, and the discharge port 24 changes.
In the state shown in FIG. 1, the third land portion 33 closes the space between the output port 23 and the discharge port 24, and the second groove portion 30b connects the input port 22 and the output port 23. The fluid flowing in from the input port 22 flows out to the output port 23.
When the spool 30 moves to the right with respect to the sleeve 20 from the state shown in FIG. 1, the third land portion 33 closes the space between the input port 22 and the output port 23, and the second groove portion 30b discharges the output port 23 and the output port 23. It is connected to the port 24. The fluid in the output port 23 flows out to the discharge port 24 via the second groove portion 30b.

In the solenoid valve 1, in the state shown in FIG. 1, the end surface 31a of the first land portion 31 on the solenoid 70 side and the end surface 32a of the second land portion 32 on the spring member 80 side are in the axial direction in the feedback chamber 21a. It is placed facing the. There is a difference in outer diameter between the first land portion 31 and the second land portion 32, and the areas of the end face 31a and the end face 32a are different. Therefore, a feedback force is generated in the spool 30 due to the difference in the force with which the fluid flowing from the feedback port 25 pushes the end faces 31a and 32a. In the solenoid valve 1, the pressure of the fluid flowing out to the output port 23 is determined by the balance between the feedback force, the spring force of the spring member 80, and the electromagnetic force of the solenoid 70.

The feedback mechanism of the solenoid valve 1 moves the spool 30 according to the pressure fluctuation of the fluid flowing in from the input port 22, and automatically adjusts the opening degree of the spool valve 10. For example, when the pressure of the fluid flowing in from the input port 22 increases, the pressure of the fluid flowing out from the output port 23 increases, and the pressure in the feedback chamber 21a increases. Then, the force pushing the end face 31a having a relatively large area becomes larger than the force pushing the end face 32a, and the spool 30 moves toward the spring member 80 side. When the spool 30 moves to the spring member 80 side, the flow path connecting the input port 22 and the output port 23 becomes narrow, and the pressure of the fluid flowing through the output port 23 decreases. In this way, the pressure of the fluid flowing out of the output port 23 is kept constant.

In the solenoid valve 1, the outer diameter (second diameter L2) of the second land portion 32 that opens and closes between the output port 23 and the discharge port 24, and the third that opens and closes between the input port 22 and the output port 23. The outer diameter of the land portion 33 (third diameter L3) is smaller than the outer diameter of the first land portion 31 (first diameter L1). With this configuration, internal leakage in the spool valve 10 can be reduced. Hereinafter, a specific description will be given.

In the feedback chamber 21a, the end surface 31a of the first land portion 31 and the end surface 32a of the second land portion 32 are arranged so as to face each other. The inside of the feedback chamber 21a is maintained at a high pressure by the fluid flowing in from the feedback port 25. There is a gap between the outer peripheral surface of the spool 30 and the inner peripheral surface of the spool hole 21 that allows the spool 30 to move in the axial direction, and the fluid leaks to the adjacent room through this gap. In the present embodiment, the gap between the second land portion 32 having a relatively small outer diameter and the spool hole portion 21 is smaller than the gap between the first land portion 31 and the spool hole portion 21, so that the second land portion The leak to the discharge port 24 through the sliding surface between the 32 and the spool hole 21 is less than the leak to the spring chamber 21c side.

Further, also in the pressure adjusting chamber 21b, the outer diameter of the second land portion 32 that opens and closes between the output port 23 and the discharge port 24 is smaller than the outer diameter of the first land portion 31. The outer diameter of the third land portion 33 that opens and closes between the input port 22 and the output port 23 is smaller than the outer diameter of the first land portion 31. Therefore, in the pressure regulating chamber 21b of the present embodiment, in both the second land portion 32 and the third land portion 33, as compared with the case where a large-diameter land portion such as the first land portion 31 is used as a valve. , The leakage of fluid through the sliding surface with the spool hole portion 21 is reduced.

As described above, the solenoid valve 1 of the present embodiment is provided with a feedback mechanism that utilizes the pressure difference between the end faces of the land portions, and has a small diameter second land portion 32 and a third land portion 33 in which the amount of leakage is relatively small. By using the above to open and close the port, leakage through the sliding surface between the land portion and the spool hole portion 21 can be minimized.

In the solenoid valve 1, the diameter of the opening of the feedback port 25 is smaller than the diameter of the opening of the output port 23. With this configuration, the pulsation of the fluid pressure of the output port 23 can be suppressed. Here, for example, when the pressure of the fluid flowing into the input port 22 suddenly fluctuates, the moving speed of the spool 30 by the feedback mechanism increases, so that the spool 30 reciprocates before and after the stop position due to inertial force, and the output port 23 Fluid pressure pulsates.
In the solenoid valve 1, since the diameter of the opening of the feedback port 25 is small, when the spool 30 moves due to the pressure fluctuation of the feedback chamber 21a, the inflow and outflow of the fluid through the feedback port 25 is restricted. As a result, the spool 30 moves slowly, so that the spool 30 is less likely to vibrate due to the feedback mechanism, and the pulsation of the liquid pressure can be suppressed.

In the present embodiment, the feedback chamber 21a is arranged next to the spring chamber 21c, and among the first land portion 31 and the second land portion 32 constituting the feedback mechanism, the first land portion 31 having a relatively large outer diameter is used. It is arranged on the spring chamber 21c side. With this configuration, the pulsation of the fluid pressure of the output port 23 can be further suppressed.

In the feedback chamber 21a, the gap between the first land portion 31 having a relatively large outer diameter and the spool hole portion 21 is larger than the gap between the second land portion 32 and the spool hole portion 21, so that the first land A large amount of fluid leaks to the adjacent spring chambers 21c via the portion 31.

Due to the above action, the fluid flows from the feedback chamber 21a into the spring chamber 21c, and the fluid accumulates in the spring chamber 21c. As a result, the spring member 80 and the fluid in the spring chamber 21c function as a damper for decelerating the spool 30. As a result, even when the pressure of the fluid flowing into the input port 22 suddenly fluctuates, the movement of the spool 30 by the feedback mechanism can be slowed down, and the pulsation of the fluid pressure of the output port 23 can be suppressed.

Further, in the present embodiment, the diameter of the opening of the breathing port 26 connected to the spring chamber 21c is smaller than the diameter of the opening of the discharge port 24. With this configuration, the resistance when the fluid flows out from the breathing port 26 increases, so that the damping effect of the spring member 80 and the fluid increases. As a result, the pulsation of the fluid pressure of the output port 23 can be further suppressed.

In the present embodiment, the configuration in which the input port 22, the output port 23, and the discharge port 24 are arranged in this order in the spool valve 10 from the solenoid 70 side has been described, but the positions of the input port 22 and the discharge port 24 are different. It may be replaced. That is, in the spool valve 10, the discharge port 24, the output port 23, and the input port 22 may be arranged in this order from the solenoid 70 side. In this configuration, the positions of the second land portion 32 and the third land portion 33 of the spool 30 are also exchanged, and in the feedback chamber 21a, the surface of the first land portion 31 facing the solenoid 70 side end surface 31a in the axial direction is the first. 3 The end face of the land portion 33 on the spring member 80 side.
Even in the above configuration, the effect of the solenoid valve 1 of the present embodiment described above can be obtained.

1 ... Solenoid valve, 20 ... Sleeve, 21c ... Spring chamber, 22 ... Input port, 23 ... Output port, 24 ... Discharge port, 25 ... Feedback port, 26 ... Breathing port, 30 ... Spool, 31 ... 1st land part, 31a, 32a ... end face, 32 ... second land portion, 33 ... third land portion, 70 ... solenoid, 80 ... spring member, J ... central axis, L1 ... first diameter, L2 ... second diameter, L3 ... Third diameter

Claims (6)

A sleeve that has multiple ports through which fluid flows and is arranged along the central axis,
A spool that is housed in the sleeve and opens and closes the port as it moves in the axial direction.
A spring member that pushes the spool to one side in the axial direction,
A solenoid that pushes the spool against the elastic force of the spring member,
With
The sleeve has an input port, an output port, an discharge port, and a feedback port connected to the output port on the outside of the sleeve along the axial direction.
The spool has a first land portion having a first diameter and facing the feedback port along the axial direction, and a second diameter smaller than the first diameter, and the output port and the discharge port. It has a second land portion that opens and closes between the output port and a third land portion that has a third diameter smaller than the first diameter and opens and closes between the output port and the input port.
The end face of the first land portion on the solenoid side and the end face of the second land portion on the spring member side or the end face of the third land portion on the spring member side are arranged so as to face each other in the axial direction.
solenoid valve. The input port, the output port, and the discharge port are arranged in order from the solenoid side along the axial direction.
The third land portion and the second land portion are arranged in order from the solenoid side along the axial direction.
The solenoid valve according to claim 1. The discharge port, the output port, and the input port are arranged in order from the solenoid side along the axial direction.
The second land portion and the third land portion are arranged in order from the solenoid side along the axial direction.
The solenoid valve according to claim 1. The solenoid valve according to any one of claims 1 to 3, wherein the diameter of the opening of the feedback port is smaller than the diameter of the opening of the output port. The spring member is housed in a spring chamber in the sleeve.
The sleeve has a breathing port leading to the spring chamber.
The solenoid valve according to any one of claims 1 to 4, wherein the diameter of the opening of the breathing port is smaller than the diameter of the opening of the discharge port. The solenoid valve according to any one of claims 1 to 5, wherein the second diameter and the third diameter have the same size.

Images