KR101845247B1 - Flow switching valve selectively distribuiting fluid to multiple outlets - Google Patents

Abstract

The present invention relates to a flow path switching valve for selectively distributing a fluid flowing into an inlet to a plurality of outflow ports, wherein the flow path switching valve of the present invention comprises: an inflow chamber to which fluid is supplied from a fluid supply source; A plurality of discharge chambers for selectively introducing fluid from the inlet chamber and connected to respective flow paths to supply the fluid; A blocking member that opens or closes the inlet of the discharge chamber by linearly moving to a path of movement perpendicular to the inlet of each of the discharge chambers; Each of the first and second ends being configured to constantly supply fluid from the inlet chamber and selectively supply fluid from the inlet chamber to the second end, wherein a space through which the blocking member moves linearly between the first end and the second end A plurality of pressure difference chambers; The flow path turning body being configured such that the at least one second end portion of the second end portions of the differential pressure chamber is selectively in communication with the inlet chamber to thereby supply the fluid to the second end portion of the differential pressure chamber selected from the inlet chamber; And pressure means for urging the blocking member toward the second end side of the differential pressure chamber.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a flow switching valve for selectively distributing a fluid to a plurality of flow paths,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a flow path switching valve, and more particularly, to a multi-directional flow path switching valve that can be switched so as to selectively distribute a fluid flowing into an inlet port to one or more flow paths among a plurality of flow paths.

Multi-directional flow path switching valves are used in various devices and industries.

As an example thereof, Japanese Patent Application Laid-Open No. 10-2011-0112190 (Document 1) discloses a multi-directional switching valve used in a refrigeration cycle. The multi-directional switching valve of Document 1 has a structure in which a plurality of outflow ports are provided in the valve body, and a port through which the fluid flows is determined by the rotating body rotated by the servomotor or the stepping motor.

A valve of the same type as that of Document 1 has various sealing members used for cutting the metal material to precisely process and secure the watertightness, but the manufacturing cost thereof is considerable.

A washing machine is an example of a device for distributing and distributing fluid in multiple directions.

When the washing water is supplied from the washing machine, the washing water may be directly supplied to a plurality of positions of the washing tub, if necessary, or may be supplied through a box containing a detergent or a fabric softening agent.

In a typical washing machine, in supplying laundry water supplied from a supply source of washing water such as a tap water to a washing tub, a detergent box, and a fabric softener box as needed, a solenoid valve is provided in a flow path connected to each supply source, Each solenoid was operated according to the washing mode, and the supply of washing water was controlled by opening and closing the valves.

However, in such a configuration, since the solenoid valve must be provided for each flow channel in which the washing water is supplied, the manufacturing cost of the washing machine is increased.

There is a detergent dispenser for washing machine disclosed in Patent Document No. 10-1223561 (Document 2) disclosing a variable flow path switching valve to be applied to a washing machine.

The apparatus of Document 2 is provided with a detergent dispensing member, and the detergent dispensing member is partitioned by a partition wall into a detergent dispensing groove for containing the respective detergent. A water supply guide member for supplying wash water to each of the detergent input grooves of the detergent supply member is provided. The water supply guide member is provided with a plurality of flow paths for dropping and supplying the wash water into the respective detergent supply grooves.

And a flow path switching member for distributing wash water to a flow path selected from the flow paths of the water supply guide member. The flow path switching member is provided with a nozzle in which the motor drives a plurality of gears and the final gear is rotated in accordance with the rotation of the motor. The nozzle rotates in accordance with the rotation of the motor, So that the washing water is supplied dropwise.

According to the structure of the apparatus of Document 2, in supplying washing water to a plurality of flow paths from one washing water supply source, the flow paths are switched by the flow path switching member driven by one motor without providing valves for each flow path .

On the other hand, in a recently-marketed washing machine, the washing water is not selectively supplied to only one of the washing tub and the plurality of detergent boxes according to the operation mode, but the washing water is simultaneously supplied to a plurality of positions of the washing tub, Washing water is supplied to the detergent box at the same time, and washing water is supplied to the washing tub and the detergent box at the same time.

In a drum type washing machine or a washing machine having a drying function, the washing water is mainly supplied to the washing tub by a falling method, but the washing water may be sprayed or sprayed to the washing tub.

However, since the apparatus of Document 2 can not be configured to supply the washing water to a plurality of flow paths, the apparatus can not be applied to a washing machine in which washing water is supplied to a plurality of positions at the same time It has structural limitations.

Further, in order to spray or spray the washing water to the washing tub, a constant pressure must be applied to the washing water. However, the apparatus of Document 2 supplies the washing water from the nozzle to the flow path and from the flow path to the detergent loading groove The nozzle, the flow path, and the detergent injection groove are not watertight. Therefore, there is a structural limitation in that even a washing water having a slight water pressure such as water supplied from the water supply can not be distributed.

Document 1: Published Patent Application No. 10-2011-0112190 Document 2: Registration No. 10-1223561

The present invention provides a multi-directional flow path switching valve that can be switched so as to selectively distribute a fluid flowing into an inlet port to one or more outflow ports of a plurality of outflow ports and to discharge the fluid, The present invention is to provide a flow path switching valve having a configuration capable of reducing the flow rate.

Particularly, the present invention is intended to provide a flow path switching valve of a configuration that can be constructed simply because the watertightness structure is not complicated while maintaining the watertightness.

The present invention also provides a flow path switching valve having a configuration capable of selecting one or two or more flow paths from a plurality of flow paths to distribute the fluid, .

The above-described object of the present invention is achieved by a flow path switching valve according to the present invention, which selectively distributes a fluid flowing into an inlet port to a plurality of outlet ports.

The flow path switching valve of the present invention includes: an inflow chamber in which fluid is supplied from a fluid supply source; A plurality of discharge chambers for selectively introducing fluid from the inlet chamber and connected to respective flow paths to supply the fluid; A blocking member that opens or closes the inlet of the discharge chamber by linearly moving to a path of movement perpendicular to the inlet of each of the discharge chambers; Each of the first and second ends being configured to constantly supply fluid from the inlet chamber and selectively supply fluid from the inlet chamber to the second end, wherein a space through which the blocking member moves linearly between the first end and the second end A plurality of pressure difference chambers; The flow path turning body being configured such that the at least one second end portion of the second end portions of the differential pressure chamber is selectively in communication with the inlet chamber to thereby supply the fluid to the second end portion of the differential pressure chamber selected from the inlet chamber; And pressure means for urging the blocking member toward the second end side of the differential pressure chamber,

The passage crystal rotator is disposed between the inlet chamber and the second ends of the differential pressure chamber and has a through hole communicating between the inlet chamber and the second end of the differential pressure chamber, Pressure chamber in a position where the through-hole is disposed in the second end, and each of the blocking members is operable to move from the first end of the differential pressure chamber to the second end of the differential pressure chamber when the fluid supply to the second end of the differential pressure chamber is blocked And the fluid is supplied to the second end portion of the differential pressure chamber, the fluid is moved to the second end side of the differential pressure chamber by the pressure means to close the inlet of the discharge chamber, .

According to this configuration of the present invention, when the flow path turning body rotates and the through hole is disposed at the position of the second end of the specific differential pressure chamber, fluid is supplied from the inlet chamber to the second end of the differential pressure chamber through the through hole .

The blocking member disposed in the differential pressure chamber is configured such that the fluid is constantly introduced into the first end of the differential pressure chamber from the inlet chamber to act on the supply pressure of the fluid and the fluid is selectively supplied to the second end of the differential pressure chamber on the other side And it becomes a condition that it is not supplied.

In the differential pressure chamber in which the fluid is supplied to the second end, the same fluid pressure acts on both ends of the blocking member and the blocking member moves toward the first end side of the differential pressure chamber by the pressure means to close the inlet of the discharge chamber.

In the differential pressure chamber in which the fluid is not supplied to the second end, the pressure of the fluid flowing into the first end overcomes the pressing force of the pressure means and moves to the second end side of the differential pressure chamber, thereby opening the inlet of the discharge chamber .

As described above, in the flow path switching valve according to the present invention, the fluid is not selectively supplied or supplied to the second end portions of the plurality of differential pressure chambers in accordance with the rotation of the flow path turning body, so that the linear movement of the blocking member disposed in the differential pressure chamber is performed Whereby the fluid is selectively supplied to the discharge chamber.

This operation is performed by adjusting the position of the through hole by rotating the flow path crystal revolution body. Therefore, in the present invention, the fluid can be selectively distributed to a plurality of flow paths only by rotating the flow path revolution body.

Particularly, it is possible to distribute the fluid to a plurality of flow paths at the same time by adjusting the arrangement and the number of the through holes formed in the flow path crystal revolution body and the rotation angle.

That is, in the present invention, only the second end of one of the plurality of differential pressure chambers is closed, and the through holes are disposed in the flow path revolution body so as to communicate with the second end of the remaining differential pressure chamber, can do.

In addition, only the second end of the two or three differential pressure chambers among the plurality of differential pressure chambers is closed, and the through holes of the flow path crystal rotator are arranged so as to communicate with the second end of the remaining differential pressure chambers, As shown in FIG.

In addition, by adjusting the rotation angle of the flow path turning body so that only the second end of one of the differential pressure chambers is closed or the second end of the two or more differential pressure chambers is closed simultaneously, one or more It may be operated to distribute fluid to the flow path.

In one embodiment of the present invention, the second end portions of the differential pressure chamber and the through-holes of the flow path determination rotary body are disposed at positions of the same diameter eccentricity with respect to the rotation axis of the flow path determination rotor, It is preferable that the one side thereof is disposed so as to be in contact with the entrance of the passages so as to close the passages.

In this case, since all the through holes can be communicated with the second end portions of all the differential pressure chambers without making the specific through holes correspond to the second end portions of the specific differential pressure chambers, The second end of the differential pressure chamber and the through hole of the flow path crystal rotating body can be prevented from being communicated or communicated with each other.

Particularly, the second end of the differential pressure chamber is arranged at equal intervals in the circumferential direction with respect to the axis of rotation of the passage rotating crystal body, and the through holes of the flow path determination rotating body are arranged in the circumferential direction with respect to the rotation axis of the passage rotating crystal body, It is possible to select the number of the differential pressure chambers in which the second ends are closed by adjusting the rotation angle of the flow path crystal rotator. By doing so, it becomes possible to supply the fluid only to one channel or to supply the fluid to the two channels at the same time according to necessity.

On the other hand, as another embodiment of the present invention, a gap is provided between the flow path crystal revolution body and the second end portion of each of the differential pressure chambers so as to communicate with the fluid, and this gap is formed so as to function as an orifice can do.

In a state in which fluid is being supplied to the second end portion in any one of the differential pressure chambers, the blocking member is maintained in a state of being moved toward the first end side of the differential pressure chamber by the urging means. When the second end portion of the differential pressure chamber is closed by the flow path turning body, no fluid pressure acts on the second end side of the differential pressure chamber in the blocking member and only the fluid pressure at the first end side of the differential pressure chamber The blocking member moves to the second end side.

By this movement, the volume on the second end side of the differential pressure member is reduced. As the volume decreases, the fluid that has flowed into the second end side returns to the inlet chamber through the gap, and movement of the blocking member becomes smooth . However, since this gap functions as an orifice in which the pressure is lowered, the pressure of the fluid acting on the second end of the differential pressure chamber from the inlet chamber through the gap is lowered, so that the gap interferes with the movement of the blocking member to the second end Does not occur.

In a further aspect of the invention, the inlet chamber, the differential pressure chamber and the discharge chamber may be provided in a single housing. In this case, the housing preferably has the inlet chamber, the flow channel crystallization rotor, the differential pressure chamber, and the outlet chamber sequentially formed from one side with respect to the direction of the axis of rotation of the flow path crystallization body. With this configuration, the configuration of the flow path switching valve becomes very compact.

It is preferable that the differential pressure chamber is formed radially with respect to the rotation axis of the flow path crystal rotating body and the second end portion of the differential pressure chamber is disposed radially inward with respect to the rotation axis of the flow path determination rotating body.

In the case of such a construction, the main constituent elements constituting the flow path switching valve of the present invention are arranged radially around the rotation axis of the flow path crystal revolution body, so that the overall structure becomes very simple and compact.

The flow path switching valve according to the present invention as described above can selectively distribute the fluid to a plurality of flow paths by rotating one flow path determination rotor without having a plurality of operating elements, And the manufacturing cost can be lowered.

Particularly, in the flow path switching valve of the present invention, the discharge chamber to which the fluid is to be distributed is determined by the positional relationship between the differential pressure chamber and the passage through the channel flow field plate, The selection of the flow path for distributing the fluid can be accurately performed by merely communicating the second end of the chamber with the inlet chamber.

Further, the flow path switching valve of the present invention is configured such that the flow path is opened and closed in accordance with the pressure balance in the differential pressure chamber, but the operation of the blocking member in the differential pressure chamber is not precisely operated due to a strict pressure difference, It is not necessary to precisely form each constitution of the flow path switching valve.

Therefore, the flow path switching valve of the present invention does not need to be formed by precision machining of the material, and can be manufactured simply and inexpensively by injection molding of a polymer material or the like.

Further, the flow path switching valve of the present invention can be used for various purposes and functions because it can selectively distribute the fluid selectively to one or a plurality of flow paths in one configuration.

Further, in the flow path switching valve of the present invention, since the fluid to be dispensed to the outflow chamber flows under a constant pressure, it can be used for supplying the fluid under a constant pressure.

1 and 2 are longitudinal sectional views of a flow path switching valve according to an embodiment of the present invention.
Figures 3 and 4 are cross-sectional views along line AA of Figure 2.

Hereinafter, the configuration and operation of a flow path switching valve according to a preferred embodiment of the present invention will be described with reference to the drawings.

First, a schematic configuration will be described with reference to Figs. 1 and 2, which are longitudinal cross-sectional views of the flow path switching valve of the present embodiment.

In the following description, the expressions indicating the directions of the upper side, the lower side, the left and right, and the like mean only the arrangement on the drawing, which means that they have such a positional relationship in the apparatus in which the flow path switching valve of this embodiment is mounted Do not.

The flow path switching valve of the present embodiment is provided with a housing 10 and an inlet chamber 20 is provided at the upper end of the housing 10 in which fluid from a fluid supply source is supplied through an inlet 21.

The lower portion of the inlet chamber 20 is formed in a cylindrical shape, and a flow path crystal rotating body 30 is disposed in the lower portion. The channel crystal rotary body 30 is formed in a disk shape and is inserted into a guide groove 22 formed in the housing 10 in a circumferential manner around the lower portion of the inlet chamber 20, A clearance 24 having a narrow width is formed between the circumference of the guide groove 30 and the guide groove 22.

A servomotor 35 is disposed below the inlet chamber 20 in a space isolated from the inlet chamber 20 by the housing 10. The output shaft 36 of the servomotor passes through the housing 10 And is projected into the inlet chamber 20. The flow path turning rotation body 30 is coupled to the output shaft 36 so as to be rotatable by the servo motor 35. [

3, which is a cross-sectional view along the line AA in Fig. 1, the axis of rotation B of the flow path crystallization rotating body 30 is disposed approximately at the geometric center of the housing 10 and the inlet chamber 20, Six differential pressure chambers 40 extending radially on a plane perpendicular to the axis of rotation B about the axis of rotation B are formed in the lower part of the inlet chamber 20. The differential pressure chambers 40 are spaced equidistantly from one another by 60 degrees with respect to the axis of rotation B in the circumferential direction.

The differential pressure chamber 40 is formed in the same shape as the cylinder and the first end portion 41 in the longitudinal direction is disposed on the outer side with respect to the rotation axis B and the second end portion 42 is disposed on the inner side.

A passage 43 is formed at the upper side of the second end portion 42 of each of the differential pressure chambers 40 so as to extend vertically toward the inlet chamber 20 and connected to the inlet chamber 20. The passage 43, Is part of the second end 42 of the differential pressure chamber.

The channel crystal rotary body 30 is arranged so that the lower surface of the channel crystal rotary body 30 can abut the portion 11 of the housing between the inlet chamber 20 and the differential pressure chamber 40 to close the passage 43 of the differential pressure chamber.

3, the through-hole 31 is formed around the rotation axis B in the thickness direction, that is, vertically passing through the through-hole 31. The through- 9 are formed adjacent to each other at intervals of 30 degrees, and no through holes are formed in the remaining portion.

The through hole 31 of the channel crystal rotary body and the passage 43 of the differential pressure chamber are formed at positions in the same radial direction with respect to the axis of rotation B, (31) allows the fluid from the inlet chamber (20) to flow into some of the passages (43).

Six discharge chambers 50 are formed below the differential pressure chamber 40. The discharge chamber 50 is configured to allow fluid to flow from the differential pressure chamber 40 to the discharge chamber 50 by placing the inlet 51 between the first end 41 and the second end 42 in the differential pressure chamber 40 It is possible.

A blocking member 60 is disposed in the space between the first end 41 and the second end 42 in the differential pressure chamber 40.

The blocking member 60 can slide between the first end portion 41 and the second end portion 42 in a state of being in tight contact with the wall surface of the differential pressure chamber 40. The side surface of the blocking member 60, The opening 51 of the discharge chamber which is exposed to the inside of the discharge chamber is closed or opened.

A fluid inlet 44 is formed in the first end 41 of each differential pressure chamber and six outlets 23 are formed in the inlet chamber 20 radially with respect to the axis of rotation B, A conduit 70 is coupled between the inlet 44 of the chamber and the outlet 23 of the inlet chamber so that fluid can always flow from the inlet chamber 20 to the first end 41 of the differential pressure chamber State.

The blocking member 60 is provided with a first end face 61 facing the first end 41 of the differential pressure chamber in its linear movement direction and a second end face 62 facing the second end 42 of the differential pressure chamber, A compression coil spring 63 is disposed between the wall surface of the housing 10 defining the second end portion 42 of the differential pressure chamber and the second end portion 62 of the blocking member.

The compression coil spring 63 urges the blocking member 60 toward the first end portion 41 of the differential pressure chamber and acts on the first end surface 61 and the second end surface 62 of the blocking member 60 The blocking member 60 is moved to the first end portion 41 side of the differential pressure chamber when the force based on the pressure of the fluid is equal.

By the movement of the blocking member 60, the blocking member 60 closes the inlet 51 of the discharge chamber and the first end face 61 of the blocking member 60 is located inside the inlet 44 of the differential pressure chamber To the surface.

The operation of the flow path switching valve of this embodiment according to the above configuration will be described.

First, the outflow chamber 50 shown on the right side in Figs. 1 and 2 is in a state in which the fluid does not pass.

The passage 43 of the interruption chamber 40 through which the inlet port 51 of the outlet chamber communicates is formed in such a manner that the passage hole 31 of the flow path crystallization rotating body 30 is disposed on the upper portion thereof, And is in a state of being able to flow through the through hole 31.

The fluid supply pressure acts on the first end surface 61 of the blocking member 60 through the conduit 70 and the first end 41 of the differential pressure chamber and the second end 62 has a The supply pressure of the fluid through the passage 43 and the second end portion 42 and the pressing force by the compression coil spring 63 act.

The force due to the supply pressure of the fluid acting on the first and second end faces 61 and 62 of the blocking member 60 is in an equilibrium state but the blocking member 60 is urged by the urging force of the compression coil spring 63 The inlet port 51 of the discharge chamber is kept closed so that the fluid from the inlet chamber 20 is not supplied to the discharge chamber 50 while maintaining the movement toward the first end 41 side of the differential pressure chamber.

In this state, the initial state in which the flow path turning rotor 30 rotates and the through hole 31 is closed without being communicated with the passage 43 of the differential pressure chamber is the state shown on the left side in FIG.

In this state, since the supply pressure of the fluid from the inlet chamber 20 does not act on the passage 43 of the differential pressure chamber, the supply pressure of the fluid from the inlet chamber 20 acts only on the first end surface 61 of the blocking member And the pressure of the fluid is not applied to the second end surface 62. Since the compression coil spring 63 is in the tensioned state, there is no pressing force on the blocking member 60 or the state is very weak.

Thus, the blocking member 60 is moved toward the second end portion 42 of the differential pressure chamber by the supply pressure of the fluid acting on the first end surface 61 thereof.

A state in which the blocking member 60 is moved toward the second end portion 42 of the differential pressure chamber is shown in Fig.

When the blocking member 60 moves toward the second end portion 42 of the differential pressure chamber, the fluid at the second end portion 42 of the differential pressure chamber flows through the clearance between the circumference of the flow path turning body 30 and the guide groove 22 24 to the inlet chamber 20.

The inlet 51 of the discharge chamber 50 which has been closed by the movement of the blocking member 60 is opened and the fluid from the inlet chamber 20 flows through the conduit 70 and the first end 41 of the differential pressure chamber And flows to the discharge chamber 50 through the discharge port.

As described above, the discharge chamber 50 connected to the through hole 31 and the passage 43 according to the rotation of the channel crystal rotary plate 30 is provided with a discharge chamber 50 in which the fluid is not distributed and the passage 43 is closed ) ≪ / RTI >

Next, referring to Figs. 3 and 4, the arrangement of the through holes 31 in the flow path turning body 30 and the distribution of the fluid to the specific discharge chamber 50 in accordance with the rotation will be described.

Referring to the plan view of FIG. 3 and FIG. 4, nine flow holes 31 are formed adjacent to each other at equal intervals of 30 degrees in the flow path crystal rotating body 30. When the through holes 31 are formed at equal intervals of 30 degrees, a total of twelve holes can be formed. In the present embodiment, nine holes are formed adjacent to each other. Therefore, Is not formed. In the housing 10, six differential pressure chambers 40 are formed at equal intervals of 60 degrees.

3, the outflow hole 31 of the flow path turning body 30 is aligned with the position of the differential pressure chamber 40 among the through holes 31 adjacent to each other, And the passage 43 of the differential pressure chamber is closed by the flow path turning rotation body 30 so that the fluid is supplied to the discharge chamber 50 connected to the differential pressure chamber 40 .

It is possible to distribute the fluid only to one discharge chamber 50 through the adjustment of the position of the through hole 31, that is, the rotation angle adjustment of the flow path turning rotary body 30.

In the state shown in Fig. 4, the through-hole adjacent to the two outermost through holes 31 among the adjacent through holes 31 is aligned with the position of the differential pressure chamber 40 in the flow path turning rotor 30. Two adjacent discharge chambers 40 are placed between the two outermost through holes 31 so that the two discharge chambers 50 connected to the passage 43 of the differential pressure chambers 40 are closed, The fluid can be dispensed to.

The fluid can be distributed to two adjacent discharge chambers 50 at the same time through the position adjustment of the through holes 31 in this manner.

In the present embodiment, the through holes 31 are arranged adjacently to each other in the flow path crystal rotating body 30, and the fluid is distributed to the discharge chamber at the position where the area is located However, the arrangement of the through holes may be adjusted so that the fluid is distributed to the two outflow chambers separated from each other by separating the regions where the through holes are not formed. In addition, it is also possible that the fluid is simultaneously supplied to the three or more discharge chambers by adjusting the width of the region where the through holes are not arranged in the flow path crystal rotating body and the angle of separation of the through holes.

The flow path switching valve of the above-described construction and operation can be applied as it is to supply the washing water in the washing machine.

A water supply control valve such as a solenoid valve is connected to an external wash water supply source such as a water supply and the conduit connected to the water supply control valve is connected to the inlet 21 of the inlet chamber 20 of the flow path switching valve according to the present embodiment Thereby supplying wash water to the flow path switching valve of the present embodiment.

The discharge chamber 50 is connected to a hose or a pipe as a flow path connected to a place where wash water is to be supplied from a washing machine.

For example, the two discharge chambers are connected to a conduit supplying wash water to different locations in the washing tub, and to the remaining discharge chambers to a water supply conduit in a box containing various detergents or fabric softening agents. The connection of these conduits to the discharge chamber may be tailored to the mode of operation provided in the washing machine.

For example, in an operating mode in which adjacent discharge chambers are connected to conduits for supplying wash water to different locations in a washing tub, respectively, and fluid is simultaneously supplied to these discharge chambers in operation, fluid is supplied to the two discharge chambers 50 The fluid crystal rotating body is rotated so that only one of the discharge chambers is supplied with the washing water.

In this way, the conduit connected to the place where the wash water is to be supplied is appropriately connected to the discharge passage according to the operation mode of the washing machine, so that the operation mode of the washing machine and the operation mode of the washing machine The flow path switching valve of this embodiment can be used as it is.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. It is obvious that all of the components are included in the scope of the present invention.

10: housing 20: inlet chamber
30: channel crystal rotating body 40: differential pressure chamber
50: exhaust chamber 60: blocking member
70: conduit

Claims (9)

A flow path switching valve for selectively distributing a fluid to a plurality of flow paths,
An inlet chamber through which fluid is supplied from a source of fluid;
A plurality of discharge chambers for selectively introducing fluid from the inlet chamber and connected to respective flow paths to supply the fluid;
A blocking member that opens or closes an inlet of the discharge chamber by linearly moving to a path of movement that lies at an inlet of each discharge chamber;
Each of the first and second ends being configured to constantly supply fluid from the inlet chamber and selectively supply fluid from the inlet chamber to the second end, wherein a space through which the blocking member moves linearly between the first end and the second end A plurality of pressure difference chambers;
The flow path turning body being configured such that the at least one second end portion of the second end portions of the differential pressure chamber is selectively in communication with the inlet chamber to thereby supply the fluid to the second end portion of the differential pressure chamber selected from the inlet chamber; And
The pressure member for urging the blocking member toward the first end side of the differential pressure chamber
/ RTI >
The passage crystal rotator is disposed between the inlet chamber and the second ends of the differential pressure chamber and has a through hole communicating between the inlet chamber and the second end of the differential pressure chamber, The fluid is supplied to the second end of the differential pressure chamber at a position where the through hole is disposed in the second end,
Each of the blocking members is moved to the second end side by the pressure of the fluid acting from the first end of the differential pressure chamber when the fluid supply to the second end of the differential pressure chamber is blocked to open the inlet of the discharge chamber, And is configured to move toward the second end side of the differential pressure chamber by the pressurizing means when the fluid is supplied to the two end portions to close the inlet port of the discharge chamber. The method according to claim 1,
Wherein the second end portions of the differential pressure chamber and the through holes of the flow path determination rotary body are disposed at positions in the same radial direction with respect to the rotation axis of the flow path determination rotary body and the flow path determination rotating body is disposed in the inflow chamber, And the two end portions are disposed so as to be able to close. [Claim 2]
A gap is provided between the flow path turning crystal body and the second end portion of each of the differential pressure chambers so that the fluid communicates with the fluid, and the gap is formed to function as an orifice in which the pressure of the supplied fluid drops. The method of claim 2,
The second ends of the differential pressure chambers are arranged at equal intervals in the circumferential direction with respect to the axis of rotation of the flow path rotating crystal body and the through holes of the flow path determination rotating body are arranged in the circumferential direction with respect to the rotation axis of the flow path rotating crystal body And are spaced apart from each other at an interval of half the interval. The method according to claim 1,
The first end face in the longitudinal direction of the blocking member faces the first end of the differential pressure chamber and the second end face opposing the first end face is formed to face the second end of the differential pressure chamber, Wherein the shut-off member is in close contact with the inner surface of the space through which the shut-off member moves linearly in the chamber to close the inlet of the flow path. The method of claim 5,
Wherein the pressure means comprises a compression coil spring having one end abutting against the second end surface of the blocking member and the other end abutting the inner surface of the differential pressure chamber. The method according to claim 1,
Wherein the inlet chamber, the differential pressure chamber and the discharge chamber are provided in one housing. The method of claim 7,
Wherein the housing is formed with an inlet chamber, a flow path crystallization rotating body, a differential pressure chamber and a discharge chamber in sequence from one side with respect to the direction of the axis of rotation of the flow path turning body. The method of claim 8,
Wherein the differential pressure chamber is formed radially with respect to the rotation axis of the flow path determination rotor and the second end of the differential pressure chamber is disposed diametrically inward with respect to the rotation axis of the flow path determination rotating body.

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