KR101856716B1 - Flow control valve - Google Patents

Abstract

The present invention provides a flow control valve comprising: a cylindrical rotating body whose diameter gradually decreases along a longitudinal direction; an inlet formed at one end along a rotating shaft of the rotating body to allow fluid to flow from the outside; A motor coupling part formed at the other end along a rotation axis, and a plurality of flow path parts passing through the rotation axis and spaced apart from each other so that fluid can move; A flow path forming member disposed at an inner side of the flow path forming member and having a flow path defining a flow path inside the flow path, A valve housing including a plurality of discharge portions formed therein; And a valve housing disposed in the valve housing so as to be formed in the vicinity of the inflow portion, wherein one end is coupled to the valve housing and the other end is coupled to the flow path determination rotating body to elastically return the flow path determination body in a direction opposite to a direction in which the fluid flows An elastic spring for moving the elastic spring; And a motor that includes a motor shaft penetrating through the valve housing and engaged with the motor coupling portion and transmitting the motor shaft rotational force so that the flow path portion selectively communicates with the discharge portion, It is essential. Accordingly, it is possible to select one of the multi-directional flow paths so as to move the fluid to the desired flow path by regulating one valve, and the flow path determination rotating body, which has been in contact with the valve housing by the fluid pressure, So that the position of the channel crystal rotor can be returned to the position.

Description

Flow control valve

[0001] The present invention relates to a flow control valve, and more particularly, to a flow control valve capable of controlling a single valve so as to select a flow path for moving a fluid to a desired flow path among multiple flow paths, The present invention relates to a flow regulating valve capable of returning to the position of a flow path turning body so that the rotating body can return to its original position and rotate again.

Generally, a washing machine is a device for separating contaminants from clothes such as clothes, towels or sheets by applying energy such as pressure or impact to the laundry. In accordance with a method of applying energy to the laundry, And a drum type washing machine. The washing machine is provided with a flow control valve for circulating water in the rotary washing tub through which the laundry is introduced through the circulation pipe, and the flow control valve is installed integrally or separately with the pump. At this time, the washing machine is additionally provided with a water supply line for supplying water to the rotary washing tub.

Herein, the flow control valve used in the conventional washing machine will be schematically described. The flow control valve includes a drain motor used to drain water inside the rotary drum, and a motor used to circulate the water inside the spin drum during washing And a circulation motor, and the flow control member is moved according to the operation of the delivery motor or the circulation motor to regulate the flow of the water to drain or circulate the water in the rotating drum. However, the conventionally used washing machine flow control valve has disadvantages of separately operating the delivery motor and the circulation motor, and has the flow control structure and the design thereof, so that the operation efficiency due to the flow control is not high, Is increased. In addition, since the conventional flow control valve is installed at the lower part of the rotary washing basket existing in the washing machine housing in order to exhibit the efficient function, it is not structurally simple in the prior art and essentially includes a drainage motor and a circulation motor, And thus there is a problem in that space restriction is followed.

In order to solve this problem, in a conventional 'Korean Utility Patent Registration Utility Utility Model No. 20-0447221', a housing body having an inlet, a drain and a circulation hole and having a flow passage for water flow in the housing body, A shaft disposed on the flow path and connected to the rotation shaft of the motor so as to be rotatable and having a thread formed at a central portion of the outer circumferential surface thereof; a shaft disposed on the flow path of the housing body in facing the drain hole and the circulation hole, A first impeller and a second impeller, which are provided opposite to each other and have a flow path-type success, and a corresponding thread which is installed between the first impeller and the second impeller and which is inserted on the shaft and is coupled to the threads of the shaft, And is used for switching the flow path.

However, in this conventional technique, the flow path can be adjusted through rotation of the shaft. When the flow path switching movable body for adjusting the flow path is brought into close contact with the housing, the flow path switching movable body does not rotate properly even if the shaft rotates, There is a disadvantage that the valve may be damaged.

Registered Utility Model Registration No. 20-0447221 Korea Patent Office Registration No. 10-1025495 Korean Patent Application Publication No. 10-2015-0045760

SUMMARY OF THE INVENTION It is therefore an object of the present invention to provide a method and a device for controlling the flow of fluid in a multi-directional flow path by controlling one valve, And to return to the position of the channel crystal rotary body so as to be able to rotate again.

The above-described object is achieved by a fluidized-bed granulator comprising a cylindrical rotating body whose diameter gradually decreases along a longitudinal direction, an inlet formed at one end along a rotating shaft of the rotating body so as to allow fluid to flow from the outside, And a plurality of flow path portions formed so as to be able to move fluid through the rotating shaft and spaced apart from each other; A flow path forming member disposed at an inner side of the flow path forming member and having a flow path defining a flow path inside the flow path, A valve housing including a plurality of discharge portions formed therein; And a valve housing disposed in the valve housing so as to be formed in the vicinity of the inflow portion, wherein one end is coupled to the valve housing and the other end is coupled to the flow path determination rotating body to elastically return the flow path determination body in a direction opposite to a direction in which the fluid flows An elastic spring for moving the elastic spring; And a motor which includes a motor shaft penetrating through the valve housing and engaged with the motor coupling portion and transmitting the motor shaft rotation force so that the flow path portion selectively communicates with the discharge portion to rotate the flow path determination rotary body And the flow control valve is controlled by the control valve.

Here, the end of the rotation shaft further includes a clutch, and the flow path determination rotating body is rotated while the clutch is in contact with the flow path determination rotating body. In a state where the clutch and the flow path determination rotating body are spaced apart from each other, It is preferable to block rotation of the crystal rotation body.

The elastic spring may be elastically protruded by a pressure when the fluid flows into the flow path of the flow path, between the valve housing and the elastic spring, When the flow of the fluid into the channel crystal rotary body is stopped, it is elastically contracted and the channel crystal rotary body is returned to the home position.

The motor may be a step motor capable of adjusting a rotation angle of the flow path determination rotary body such that the flow path portion selectively communicates among the plurality of discharge portions.

According to the structure of the present invention described above, one of the valves can be adjusted to select a flow path so that the fluid moves to a desired flow path among the multi-direction flow paths, and the flow path turning body in contact with the valve housing It is possible to obtain the effect that the position of the channel crystal rotary body can be returned to the position so that the channel can be rotated again.

1 is a sectional view of a flow control valve according to an embodiment of the present invention,
2 is a cross-sectional view of a flow control valve in which a fluid flows therein,
3 is a perspective view of the flow path turning rotor,
4 is an operational state view of the valve housing and the flow path crystal rotating body.

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

1, the flow control valve 10 includes a flow path crystal rotating body 100, a valve housing 300, an elastic spring 500, and a motor 700. As shown in FIG. The channel crystal rotating body 100 includes a rotating body 110, an inlet 130, and a plurality of flow paths 150. The rotating body 110 has a cylindrical shape with a gradually decreasing diameter along the longitudinal direction, and is configured to be rotationally driven by the motor 700. An inlet 130 is formed at one end of the rotating body 110 along the rotating shaft and a motor coupling 170 is formed at the other end along the rotating shaft of the rotating body 110. The inlet 130 is formed to allow the fluid to flow from the outside, and the inlet is protruded so that the fluid does not leak to an area other than the inlet 130 when the fluid flows from the outside. A fluid supply means such as a hose may be connected to the protruding shape to allow the fluid to flow easily.

A plurality of flow path portions 150 are formed in the flow path turning crystal body 100 so that the plurality of flow path portions 150 penetrate through the flow path of the flow path turning body 100 with a gap therebetween, And is formed to be movable to the outside of the entire body 100. That is, the fluid introduced through the inlet 130 is selectively discharged to any one of the plurality of flow paths 150, and the fluid can be supplied to the desired flow path. The plurality of flow paths 150 passing through the rotation axis at intervals are preferably spaced apart by an angle difference of 40 to 90 degrees around the rotation axis. As shown in FIG. 2, since the plurality of flow paths 150 are opened when one flow path portion 150 is opened, the remaining flow path portions 150 must be closed to prevent fluid movement to the undesired flow path portions 150, They should be spaced apart at different angular distances rather than being formed at the same angle. At this time, it is preferable that the channel portions 150 are separated from each other by an angle difference of 40 to 90 degrees, which is easy to adjust the angle, without overlapping each other on the axis of rotation between the channel portions 150. The most preferable angle is 60 degrees will be.

The valve housing 300 includes a flow path turning body 100 and includes an inflow supporting portion 310 and a plurality of discharge portions 330. The flow path crystal rotating body 100 disposed inside the valve housing 300 does not have a problem that the inflow portion 130 is supported by the inflow support portion 310 and is released to the outside even when the inflow portion 130 is pressurized by the inflow of the fluid, There is no problem that the channel crystal rotating body 100 is tilted to one side in the valve housing 300. [ Here, the valve housing 300 is formed in a cylindrical shape whose diameter gradually decreases along the longitudinal direction, like the flow path determination rotating body 100. When the valve housing 300 and the flow path crystal rotating body 100 are formed in a cylindrical shape having the same diameter without a gradual decrease in diameter, the flow path forming member 100 is moved to the end of the valve housing 300 In this case, the inflow portion 130 and the discharge portion 330 are not properly connected to each other, which is not suitable for discharging the fluid to the outside. In contrast, when the valve housing 300 and the channel crystal rotating body 100 are formed in a cylindrical shape whose diameter gradually decreases, even if the fluid crystal rotating body 100 moves due to the pressure of the fluid, The position where the flow path portion 150 and the discharge portion 330 communicate with each other can be adjusted.

The plurality of discharge portions 330 are formed in the valve housing 300 along the longitudinal direction so as to communicate with any one of the plurality of flow paths 150 by the rotation of the flow path turning body 100 to discharge the fluid to the outside . Unlike the flow path portion 150, the discharge portion 330 may be formed at an angle that is the same as or similar to the rotation axis, not about different angles about the rotation axis. In other words, it is preferable that the plurality of discharge portions 330 are spaced apart in a straight line along the longitudinal direction at a predetermined interval. When the discharge portion 330 is formed at a different angle in a state where the flow path portion 150 is formed at a different angle, when the pair of flow path portions 150 and the discharge portion 330 are communicated with each other, And the discharge unit 330 may communicate with each other and the fluid may be discharged to the unwanted discharge unit 330. Therefore, the discharge unit 330 may be arranged in a straight line for the convenience of driving. In some cases, the plurality of discharge portions 330 may be formed as a pair facing each other along the central axis.

As shown in FIG. 3, the flow path portion 150 is connected to the flow path portion 150 at a different angle from the flow path forming portion 100, As shown in FIG. 2, the valve housing has outlet portions 330 A1, A2, and A3 formed in a straight line so as to be interlocked with the flow path portion 150. B2, and B3 discharge portions 330 are similarly formed in a straight line in a region opposed to the A1, A2, and A3 discharge portions 330, respectively. 4A, when the flow path portion 150 is matched with the A1 discharge portion 330, the flow path forming portion 100 communicates with the A1 discharge portion 330 The fluid is discharged to the outside through the fluid passage 330. At this time, the discharging part 330 excluding the A1 discharging part 330 is completely closed, and the fluid is not discharged. Next, as shown in FIG. 4B through rotation, when the flow path portion 150 and the B3 discharge portion 330 are communicated with each other, the fluid is discharged to the B3 discharge portion 330 and the remaining discharge portion 330 is closed. This can be confirmed by the other FIGS. 4C to 4F. In FIG. 4, since the three flow paths 150 are formed, the angles are spaced apart by 60 degrees. However, when two flow paths 150 are formed, four flow paths 150 are formed at intervals of 90 degrees It can be adjusted in 45 ° intervals. As described above, only the desired discharge part 330 is selectively opened through the flow path forming part 100 of the present invention and the flow path part 150 and the discharge part 330 formed in the valve housing 300 to discharge the fluid .

A friction preventing rubber pad is additionally formed between the flow path turning body 100 and the valve housing 300 to prevent damage to the flow path turning body 100 and the valve housing 300 due to friction It is possible.

When the fluid flows into the channel crystal rotating body 100, the channel crystal rotating body 100 is brought into contact with the valve housing 300 by the pressure. After the fluid is discharged, the channel crystal rotating body 100 is rotated again The flow path crystal clearance 100 must be returned to its original position. Therefore, the elastic spring 500 is installed to return the flow crystal rotary body 100 to its original position. The elastic spring 500 is disposed in the valve housing 300 so as to be formed around the inlet 130. This is because the inflow of the fluid is directed toward the inflow part 130, so that the pressure is also applied in the inflow direction of the fluid. The resilient spring 500 is installed in the valve housing 300 around the inflow portion 130 so that the resilient spring 500 is installed in the valve housing 300 around the inflow portion 130. Therefore, . That is, one end of the elastic spring 500 is coupled to the valve housing 300, and the other end is coupled to the flow path crystal rotating body 100 to elastically move the flow path turning body 100 in a direction opposite to the direction in which the fluid flows. . Here, the spring support portion 510 may be further included between the valve housing 300 and the elastic spring 500 to stably support the elastic spring 500.

When the fluid flows into the channel crystal rotating body 100 from the outside, the channel crystal rotating body 100 elastically moves by the elastic spring 500 and the friction between the channel crystal rotating body 100 and the valve housing 300 Can be minimized. At this time, since the channel crystal rotating body 100 and the valve housing 300 are in contact with each other, the flow channel rotating body 100 is not easily rotated. When the fluid is no longer introduced and all of the fluid in the channel crystal rotating body 100 is discharged to the discharge part 330, the flow path determination rotating body 100, which is no longer subjected to pressure, Since the valve housing 300 and the channel crystal rotating body 100 are in contact with each other when the valve housing 300 is in contact with the flow channel forming body 100 through the elastic spring 500, Is rotated back to the home position. That is, the elastic spring 500 elastically protrudes due to pressure when the fluid flows into the flow path crystal rotating body 100, and elastically contracts when the flow of the fluid into the flow path rotating body 100 is stopped, And returns the rotating body 100 to the home position.

The motor 700 for rotating the flow path turning crystal 100 includes a motor shaft 710 that passes through the valve housing 300 and is coupled to the motor coupling portion 170. The motor coupling portion 170 is formed to penetrate the flow path determination rotating body 100 and the motor shaft 710 is inserted into the motor coupling portion 170 to rotationally drive the flow path determination rotating body 100. The motor 700 rotates the flow path turning rotor 100 by transmitting the rotational force to the motor shaft 710 so that the flow path portion 150 selectively communicates with the discharge portion 330. When the flow path portion 150 includes a plurality of The flow rate of the flow path of the flow path of the flow path of the flow path of the flow path of the flow path of the flow path of the flow path is changed.

In some cases, the motor shaft 710 may further include a clutch 900 at an end thereof. The clutch 900 is rotated in the state where it is in contact with the flow path crystal revolution body 100. When the flow path revolution body 100 is separated from the clutch 900, 100 can be blocked. In other words, since the flow path forming crystal 100 is in contact with the clutch 900 in the first position, the flow path forming crystal 100 can be rotated by receiving the rotational force of the motor 700, When the crystal rotating body 100 is protruded, it does not contact the clutch 900 and does not receive the rotational force of the motor 700.

The conventional valve has a plurality of valves, each of which is provided with a plurality of valves for discharging the fluid through the plurality of flow paths. In this case, however, a plurality of valves are arranged to occupy a large space. In contrast to this, according to the present invention, it is possible to select one of the multi-directional flow paths by controlling one flow control valve 10 so that the fluid can move to a desired flow path, It is possible to obtain the effect that the position of the channel crystal rotating body 100 can be returned so that the rotating body 100 can be returned to the home position and rotated again.

10: flow control valve 100: flow crystal rotation body
110: rotating body 130:
150: passage portion 170: motor coupling portion
300: valve housing 310: inflow support
330: discharge part 500: elastic spring
510: spring support part 700: motor
710: Motor shaft 900: Clutch

Claims (5)

An inlet portion formed at one end along a rotational axis of the rotating body so as to allow fluid to flow from the outside; a motor coupling portion formed at the other end along the rotational axis of the rotating body; And a plurality of flow path parts formed so as to be able to move through the gap with a gap therebetween along the rotation axis;
A flow path forming member disposed at an inner side of the flow path forming member and having a flow path defining a flow path inside the flow path, A valve housing including a plurality of discharge portions formed therein;
And a valve housing rotatably installed in the valve housing so as to be formed around the inlet portion, the valve housing having one end coupled to the valve housing and the other end connected to the flow path determination rotator, An elastic spring for moving the elastic spring;
And a motor that includes a motor shaft penetrating through the valve housing and coupled to the motor coupling portion, and a motor that rotates the flow path determination rotary body by transmitting the motor shaft rotation force so that the flow path portion selectively communicates with the discharge portion,
And a clutch is further provided at an end of the rotating shaft,
Wherein the flow path determination rotary body is rotated while the clutch is in contact with the flow path determination rotary body and the rotation of the flow path determination rotary body is blocked in a state where the clutch and the flow path determination rotary body are spaced apart from each other. Regulating valve. delete The method according to claim 1,
And a spring support portion between the valve housing and the elastic spring to stably support the elastic spring. The method according to claim 1,
The elastic spring is resiliently protruded by the pressure when the fluid flows into the flow path crystal rotation body and is elastically contracted when the inflow of the fluid into the flow path determination rotation body is stopped, Thereby returning the flow control valve. The method according to claim 1,
Wherein the motor is a step motor capable of adjusting a rotation angle of the flow path determination rotator so that the flow path portion selectively communicates among the plurality of discharge portions.

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