KR101987469B1 - A valve apparatus - Google Patents

Abstract

The present invention relates to a valve device. A valve device according to one aspect, comprising: a cylinder defining a fluid flow space; An inlet provided at one side of the cylinder for allowing fluid to flow into the cylinder; A plurality of discharge portions provided on the other side of the cylinder and through which fluid in the cylinder is selectively discharged; A piston receiving at least a portion of the inside of the cylinder and having a projection; A driving unit connected to one side of the piston and providing a driving force to the piston; A damper unit coupled to the piston and selectively opening one of the plurality of discharge units; And a power supply unit for supplying power to the driving unit, wherein the driving unit includes: a sleeve including the piston and having a plurality of guides for guiding the movement of the piston; a core connected to the sleeve; And an elastic member for elastically supporting the piston, wherein each of the plurality of guides is formed with a latching groove for latching the protrusion of the piston.

Description

[0001]

The present invention relates to a valve device.

In general, a valve device is a device for controlling the amount and pressure of a fluid, and is configured to be able to change the fluid flow direction or adjust the flow rate. The valve device includes a four-way valve capable of guiding the discharge direction of the fluid introduced into the device in one direction or another direction.

For example, the four-way valve may be used in an air conditioner. The four-way valve is provided on the discharge side of the extruder constituting the air conditioner, and configured to switch the flow direction of the refrigerant.

In detail, the air conditioner includes a compressor, an outdoor heat exchanger, an expansion device, and an indoor heat exchanger constituting a refrigerant cycle. The refrigerant compressed in the compressor may be introduced into the outdoor heat exchanger or the indoor heat exchanger according to the operation mode of the air conditioner, that is, the cooling or heating operation mode.

Therefore, based on the operation mode, the refrigerant discharged from the compressor is diverted from the inlet side of the outdoor heat exchanger to the inlet side of the indoor heat exchanger or to the inlet side of the indoor heat exchanger to the inlet side of the indoor heat exchanger There is a need. At this time, a four-way valve is provided on the discharge side of the compressor to change the flow direction of the refrigerant.

The four-way valve includes a housing, a piston slidably disposed inside the housing, and a plurality of discharge portions selectively opened or closed by the piston. The piston can be driven by a piston driving part such as a solenoid, and is elastically supported by a spring.

For example, when the piston driving unit is turned on during the heating operation, the piston moves toward the piston driving unit, and the piston compresses the spring. And the piston driving unit is maintained in the ON state when the heating operation is performed.

On the other hand, during the cooling operation, the piston driving part is turned off and the piston moves in a direction away from the piston driving part by the restoring force of the spring.

According to such a conventional four-way valve, the position of the piston must be maintained in a state where the flow path is switched by the piston when the constant mode operation is performed, so that the piston driving part must be turned on until the mode is switched. Therefore, since the piston driving portion is continuously turned on, there is a problem in that the power consumption is large.

An object of the present invention is to provide a valve device with reduced power consumption.

A valve device according to one aspect, comprising: a cylinder defining a fluid flow space; An inlet provided at one side of the cylinder for allowing fluid to flow into the cylinder; A plurality of discharge portions provided on the other side of the cylinder and through which fluid in the cylinder is selectively discharged; A piston receiving at least a portion of the inside of the cylinder and having a projection; A driving unit connected to one side of the piston and providing a driving force to the piston; A damper unit coupled to the piston and selectively opening one of the plurality of discharge units; And a power supply unit for supplying power to the driving unit, wherein the driving unit includes: a sleeve including the piston and having a plurality of guides for guiding the movement of the piston; a core connected to the sleeve; And an elastic member for elastically supporting the piston, wherein each of the plurality of guides is formed with a latching groove for latching the protrusion of the piston.

A valve device according to another aspect of the present invention is a valve device including a driving part for moving a piston, the driving part including: a sleeve accommodating the piston and having a plurality of guides for guiding the movement of the piston; Wherein the piston is provided with a core connected to the sleeve and an elastic member elastically supporting the piston, wherein each of the plurality of guides has a latching groove for latching the protrusion of the piston, and the protrusion of the piston moves A path is formed.

According to the proposed invention, there is an effect that the structure of the valve device is simple and easy to assemble. Particularly, since a plurality of outflow portions are selectively opened and closed in the process of integrally moving the piston and the damper portion, there is an advantage that a separate pipe for moving the fluid is not needed.

Further, since there is no need for a separate piping or the like to which the fluid pressure acts, there is an effect that the loss of the flow path and the like that may occur when the fluid moves through the piping or the like is reduced.

Further, since the piston and the damper are provided in one cylinder, and the damper portion is configured to selectively block the discharge portion on one side of the cylinder, the whole size of the valve device can be miniaturized.

Further, since the damper portion is disposed on the inner side of the inflow portion and the damper portion is formed on the guide surface, the fluid can be easily guided to the discharge portion side, and the flow resistance of the fluid can be reduced.

In addition, due to the simple structure and operation of the valve device, there is an advantage that the possibility of occurrence of a failure in the device is reduced and the reliability of the operation of the device can be improved.

Further, when the flow path is switched, the power supply unit is turned on after being turned on for a certain period of time, thereby reducing the power consumption of the driving unit.

1 is a perspective view of a valve device according to an embodiment of the present invention;
FIG. 2 and FIG. 3 are views showing a partial configuration of a valve apparatus according to an embodiment of the present invention; FIG.
4 is a cross-sectional view taken along line AA of FIG.
5 is a bottom view of a damper unit according to an embodiment of the present invention.
6 is an exploded view showing a configuration of a driving unit according to an embodiment of the present invention;
7 is a cross-sectional view taken along line BB in Fig.
8 is a block diagram showing a configuration of a valve device according to an embodiment of the present invention.
9 is a view illustrating operation of a driving unit according to an embodiment of the present invention;
10 and 11 are sectional views showing the operation of a valve device according to an embodiment of the present invention;

Hereinafter, specific embodiments of the present invention will be described with reference to the drawings.

1 is a perspective view of a valve apparatus according to an embodiment of the present invention.

Referring to FIG. 1, the valve apparatus 100 according to the embodiment of the present invention may be a four-way valve.

In detail, the valve apparatus 100 includes a cylinder 110 having a substantially cylindrical main body 111 and forming a fluid flow space therein, and a cylinder 110 provided at one side of the cylinder 110, And a plurality of discharging units 115, 116 and 117 provided on the other side of the cylinder 110 and discharging the fluid in the cylinder 110. [

The plurality of discharging units 115, 116 and 117 includes a first discharging unit 115, a second discharging unit 116 and a third discharging unit 116 arranged in parallel and spaced apart from each other on the lower surface of the cylinder 110 117).

The thixotropic valve device 100 may further include a driving unit 170 coupled to the cylinder 110 and providing a driving force for moving the piston 190 (see FIG. 2). Hereinafter, configurations of the cylinder 110 and the driving unit 170 will be described in detail with reference to the drawings.

FIG. 4 is a cross-sectional view taken along line AA of FIG. 1, and FIG. 5 is a cross-sectional view of a damper according to an embodiment of the present invention. Fig.

FIG. 2 shows the internal structure of the cylinder 110 by removing the main body 111, and FIG. 3 shows a state where the damper unit 130 is removed in FIG.

2 to 5, a valve apparatus 100 according to an embodiment of the present invention includes a driving unit 170, a piston 190 provided movably by the driving unit 170, and a piston 190 And a damper unit 130 coupled to the piston 190 to selectively open at least a portion of the plurality of discharge units 115, 116, and 117.

The driving unit 170 includes a core 200 having an electromagnet 205 disposed to be spaced apart from the piston 190 and having a magnetic property when a current is applied to the core 200 and a core 200 disposed between the core 200 and the piston 190 And a sleeve 180 for receiving the piston 190 and guiding the movement of the piston 190. The elastic member 210 may be provided to the piston 190 to elastically support the piston 190.

One end of the elastic member 210 may be supported by the core 120 and the other end may be supported by the end of the piston 190. For example, the elastic member 210 may be a compression spring.

When the electromagnet 205 is magnetized, a force acts on the piston 190 in a direction toward the electromagnet 205. To this end, at least a portion of the piston 190, for example, the end of the piston 190, may be made of a material that interacts with the electromagnet 205.

When the electromagnet 205 loses its magnetic force, the attraction force does not act and the piston 190 moves in a direction away from the electromagnet 205 due to the restoring force of the elastic member 210.

The sleeve 180 has a hollow cylindrical shape. Specifically, one end of the sleeve 180 is coupled to one end of the cylinder 110, and the other end of the sleeve 180 is coupled to the core 200.

The elastic member 210 is disposed inside the sleeve 180, and a space for moving the piston 190 is formed.

At least a portion of the piston 190 may be located within the cylinder 110 and the remaining portion may be located within the sleeve 180. The piston 190 is moved in the lateral direction according to the action of the driving unit 170, and the length of the piston 190 located in the cylinder 110 is changed.

At one side of the piston 190, a piston engaging portion 125 for engaging the piston 190 and the damper portion 130 is provided. The piston coupling part 125 is located inside the cylinder 110 and can be coupled to one side of the damper part 130.

In detail, the piston coupling portion 125 is provided with a plurality of insertion portions 127 to be inserted into the first groove (see 192 in FIG. 6) of the piston 190 and a plurality of insertion portions 127 formed between the plurality of insertion portions 127 And a second groove (126) is formed to receive at least a portion of the piston (190).

The first groove (see 192 in FIG. 6) is understood as an incision groove that is recessed inward from the outer circumferential surface of the piston 190, and the second groove 126 extends downward from the upper end of the piston engagement portion 125 As a cutting incision.

The piston 190 may be rotated while the piston 190 is engaged with the piston engagement portion 125.

The damper unit 130 may include a damper main body 131 formed in a substantially plate-like shape. The damper main body 1310 may include a flow guide 134 for guiding the flow of the fluid and an opening 135 for passing the fluid.

The damper main body 131 is movably disposed on the upper side of the discharge coupling portion 140.

The discharge coupling unit 140 is connected to the plurality of discharge units 115, 116, and 117. For example, the discharging units 115, 116, and 117 may be provided in three, as shown in FIG. The discharge coupler 140 is disposed between the plurality of discharge units 115, 116, and 117 and the damper unit 130.

The discharge coupling unit 140 includes a coupling body 141 coupled to an upper portion of the plurality of discharge units 115 and 116 and a plurality of coupling members 141 formed to penetrate at least a portion of the coupling body 141 Through holes (142, 143, 144) of the substrate.

The plurality of through holes 142, 143, and 144 may include a first hole 142, a second hole 143, and a third hole 143, which are disposed corresponding to the plurality of discharge portions 115, 116, 144). The first through third holes 142, 143 and 144 are formed in the same size and spaced apart from each other in the transverse direction, that is, the direction in which the piston 190 and the damper unit 130 move.

The fluid in the cylinder 110 flows through one of the plurality of through holes 142, 143 and 144, and can be discharged through the discharge portion corresponding to the one hole.

The flow guide 134 serves to connect two of the three through holes 142, 143 and 144. The opening 135 may be selectively in communication with the third through hole 144.

Holes corresponding to the flow guide 134 and the opening 135 of the three through holes 142, 143 and 144 may be different from each other depending on the movement position of the damper portion 130. [

The damper part 130 may include a shielding part 132 protruding upward from the damper main body 131.

The flow path guide 134 is formed in the shielding portion 132. For example, when the flow path guide 134 is positioned above the first and second holes 142 and 143, the fluid in the cylinder 110 flows through the first and second holes 142 and 143 Can not pass.

On the upper surface of the shielding portion 132, a guide surface 133 formed to be inclined downward is formed. For example, the guide surface 133 may be rounded with a predetermined curvature from the upper portion of the shielding portion 132 adjacent to the inlet portion 11 downward.

When the fluid flows into the cylinder 110 through the inlet 112, the fluid is guided downward along the guide surface 133. The fluid may flow to one discharge portion (115, 116, 117) through one opened hole of the first to third holes (142, 143, 144). Thus, the guide surface 133 is configured so that the fluid can be easily guided to the one discharge portion in the cylinder 110. [

The upper surface of the shielding portion 132 is provided with a receiving portion 137 for receiving the elastic member 138 and a ball 139 which is elastically supported upward by the elastic member 138 accommodated in the receiving portion 137 .

The ball 139 supported by the elastic member 138 is in contact with the inner surface of the cylinder 110. At this time, the cylinder (110) presses the ball (139) as a reaction of the pressing force by which the ball (139) presses the inner surface (inner upper surface) of the cylinder (110). Therefore, the damper portion 130 is pressed toward the discharge coupling portion 140 in the cylinder 110, so that a gap is not generated between the damper portion 130 and the discharge coupling portion 140, Can be prevented from leaking between the damper part (130) and the discharge engaging part (140). In addition, since the ball 139 can be rotated while being in contact with the inner surface of the cylinder 110, the damper unit 130 can smoothly move in the horizontal direction.

The elastic member 138 and the ball 139 are pressed against the discharge coupling portion 140 and guided by the damper portion 130 in the direction You can name it Gur.

On the other hand, a coupling surface 136 to be coupled to the piston coupling part 125 is formed on one side of the damper main body 131. The damper part 130 is coupled to the piston coupling part 125 at the coupling surface 136 by a predetermined coupling method.

Accordingly, when the piston coupling part 126 moves in one direction, the damper part 130 moves with the piston coupling part 125. In other words, the piston 190, the piston coupling part 125, and the damper part 130 may be integrally formed by a predetermined coupling structure, and the piston coupling part 125 And the damper unit 130 may be moved together with the piston 190. [

FIG. 6 is an exploded view showing the structure of a driving unit according to an embodiment of the present invention, and FIG. 7 is a cross-sectional view taken along line B-B of FIG.

6 and 7, the piston 190 is formed in a cylindrical shape, and a first groove 192 is formed at one end of the piston 190, as described above. A plurality of protrusions 193 are formed at the other end of the piston 190. The plurality of protrusions 193 are circumferentially spaced.

The plurality of protrusions 193 may include a first inclined surface 194 formed on the left side in FIG. 6 and a second inclined surface 195 formed on the right side in FIG.

The first inclined surface 194 and the second inclined surface 195 are inclined in a direction in which they approach each other. Accordingly, the plurality of protrusions 193 may be formed in a trapezoidal shape, for example. The inclination angle of the first inclined surface 194 and the inclined surface 195 may be the same.

A plurality of guides 182 are formed on the inner circumferential surface of the sleeve 180 in a circumferential direction. For example, the plurality of guides 182 are elongated in the direction of the center axis of the sleeve 180 (leftward and rightward in FIG. 6). At this time, the plurality of guides 182 extend from the one side end (for example, the left side end in FIG. 6) of the sleeve 180 toward the right end of the sleeve 180. At this time, the length of the plurality of guides 182 is shorter than the entire length of the sleeve 180.

Since the plurality of guides 182 are spaced apart from each other in the circumferential direction of the sleeve 180, a path 181 through which the protrusion 193 of the piston 190 can move is formed between the adjacent two guides 182 do. At this time, the number of the paths 181 is equal to the number of the protrusions 193.

Each of the guides 182 is formed with a locking groove 183 and a second sleeve inclined surface 186 for engaging with the protrusion 193 of the piston 190. The engaging groove 183 has a first sleeve inclined surface 184 inclined at the same angle as the first inclined surface 194 of the protrusion 193 and a contact surface 185 parallel to the central axis direction of the sleeve 180 . The first sleeve inclined surface 184 and the second sleeve inclined surface 186 are inclined in the same direction.

Therefore, when the protrusion of the piston 190 is inserted into the latching groove 183, the piston 190 is no longer moved while being elastically supported by the elastic member 210.

At one end of the core 200, a plurality of contact protrusions 202 capable of contacting the protrusion 193 of the piston 190 may be formed.

The plurality of contact protrusions 202 may be spaced apart in the circumferential direction of the core 200. Each of the contact protrusions 202 includes a core inclined surface 203 inclined at the same angle as the second inclined surface 195 of the protrusion 193 of the piston 190 and a central inclined surface 203 And a contact surface 204 which is in parallel with the left-right direction in FIG.

The length of each of the inclined surfaces 194 and 195 of the protrusion 193 of the piston 190 is shorter than the length of the first sleeve inclined surface 184 and the core inclined surface 203. Accordingly, the first inclined surface 194 can be slid along the first sleeve inclined surface 184 in a state where the first inclined surface 194 is in contact with the first sleeve inclined surface 184. The second inclined surface 195 may be slid along the core inclined surface 206 while the second inclined surface 195 is in contact with the core inclined surface 203.

FIG. 8 is a block diagram showing a configuration of a valve apparatus according to an embodiment of the present invention, FIG. 9 is a view showing the operation of a driving unit according to an embodiment of the present invention, and FIGS. 10 and 11 are views Sectional view showing the operation of the valve device according to the embodiment.

9 (a) shows the operating state of the driving unit when the driving unit is turned on, and FIG. 9 (b) shows the operating state of the driving unit when the driving unit is off. Fig. 5 is a view showing an operating state of the driving unit when the driving unit is turned on again. 9 shows a state in which the sleeve and the core are expanded in a plane for easy understanding.

8, a valve apparatus 100 according to an embodiment of the present invention includes a power supply unit 220 for selectively applying a current to the electromagnet 205 to generate magnetism, and a power supply unit 220 (Not shown).

The power supply unit 220 may be a switching member that is on / off controlled. When the power supply unit 220 is turned on, magnetic force is generated in the electromagnet 205 and the piston 190 moves toward the electromagnet 205 by the attraction force of the electromagnet 205.

When the power supply unit 220 is turned off, the magnetism and attractive force of the electromagnet 205 disappear, and the piston 190 moves in a direction away from the electromagnet 205 due to the restoring force of the elastic member 210 .

Hereinafter, the operation of the valve device according to the embodiment of the present invention will be described.

9, the end portions of the sleeve inclined surfaces 184 and 186 are disposed at positions corresponding to substantially the middle portion of the core inclined surface 203. 9 (a), the imaginary line L extending in the horizontal direction at the ends of the sleeve inclined surfaces 184 and 186 passes through the middle portion of the core inclined surface 203.

A portion of the core 200 is inserted into the sleeve 180 and the guide 182 of the sleeve 180 and the core 180 of the core 180 are inserted into the sleeve 180, 200 are separated from each other. The reason for this is that the protrusion 193 of the piston 190 can move between the guide 182 of the sleeve 180 and the contact protrusion 202.

10 shows the operation of the valve device 100 when the power supply 220 is turned on for the first operating mode of the valve device.

9 (a) and 10, when the power supply unit 220 is turned on, the piston 190 moves in a direction toward the core 200 (right direction in FIG. 10). At this time, the protrusion 193 of the piston 190 moves along the path 181 of the sleeve 180. When the piston 190 moves to the right, the second inclined surface 195 of the protrusion 193 of the piston 190 comes into contact with the inclined surface 203 of the core. At this time, the elastic member 210 can be compressed.

In this state, since the power supply unit 220 is on, the second inclined surface 195 of the protrusion 193 slides along the core inclined surface 203 and the piston 190 rotates at a certain angle.

Then, the power supply unit 220 is turned off. Then, the piston 190 moves in a direction away from the core 200 (left direction in FIG. 10) by the restoring force of the elastic member 210. 9 (b), when the piston 190 moves to the left, the first inclined surface 194 of the protrusion 193 of the piston 190 contacts the first sleeve inclined surface 184 Contact. In this state, since the piston 190 is continuously receiving elastic force from the elastic member 210, the first inclined surface 194 slides along the first sleeve inclined surface 184, It is rotated at a constant angle.

When the protrusion 193 of the piston 190 contacts the contact surface 185 while the first slope 194 slides along the first sleeve slope 184, It will not move to the left.

When the movement of the piston 190 in the first operation mode is summarized, when the power supply unit 220 is turned off after the piston 190 moves to the right when the power supply unit 220 is turned on, And is stopped after a certain distance to the left due to the elastic force of the member 210.

When the piston 190 moves, the piston coupling part 125 and the damper part 130 move along with the piston 190 in the rightward direction, move to a certain distance in the leftward direction, and then stop. When the movement of the damper unit 130 is completed, the flow guide 134 is positioned above the second discharge unit 116 and the third discharge unit 117, and the second discharge unit 116 and the third discharge portion 117 are closed by the shielding portion 132.

As a result, the fluid introduced into the main body 111 through the inflow portion 112 is discharged to the first discharge portion 115 located below the inflow portion 112.

On the other hand, Fig. 11 shows the operation of the valve device 100 when the power supply 220 is turned on again for the second operating mode of the valve device.

Referring to FIGS. 9 (c) and 11, when the power supply unit 220 is turned on again, the piston 190 moves in a direction toward the core 200. When the piston 190 moves to the right, the second inclined surface 195 of the protrusion 193 of the piston 190 contacts the core inclined surface 203 again.

In this case, the contact protrusion of the piston in Fig. 9 (c) is different from the contact protrusion of the piston in Fig. 9 (a) in contact with the protrusion of the piston. In Fig. 9 (c), the contact protrusion on which the protrusion of the piston comes into contact is a protrusion located next to the contact protrusion on which the protrusion of the piston contacts in Fig. 9 (a).

The second inclined surface 195 is slid along the core inclined surface 203 after the second inclined surface 195 of the protrusion 190 contacts the core inclined surface 203 and the piston 190 has a constant Angle rotation. Then, when the power supply unit 220 is turned off, the piston 190 moves in the left direction due to the elastic force of the elastic member 210.

The first inclined surface 194 of the protrusion 193 comes into contact with the second sleeve inclined surface 186 when the piston 190 moves in the left direction. The first ramp surface 194 is then slid along the second sleeve ramp surface 186. The protrusion 193 is positioned on the path 181 of the sleeve 180 while the first inclined surface 194 is slid along the second sleeve inclined surface 186. Then, the protrusion 193 is finally moved to the left along the path 181.

When the movement of the piston 190 in the second operation mode is summarized, the piston 190 is moved to the right by a predetermined distance when the power supply unit 220 is turned on, and then the power supply unit 220 is turned off , The elastic member 210 moves to the left side by the elastic force of the elastic member 210 and then stops.

When the piston 190 is moved to the left, the piston coupling part 125 and the damper part 130 move in the left direction together with the piston 190. When the damper unit 130 is moved, the flow guide 134 is positioned above the first discharging unit 115 and the second discharging unit 116 so that the first discharging unit 115, And the second discharging portion 116 are closed by the shielding portion 132.

As a result, the fluid introduced into the main body 111 flows to the right along the guide surface 133 and is discharged to the opened third discharge portion 117. At this time, since the guide surface 133 is rounded downward at a predetermined curvature, the fluid can be easily guided to the third discharge portion 117 side.

According to the present embodiment, since the power supply unit 220 does not need to be continuously turned on when switching the flow path of the valve apparatus, the power supply unit 220 can be turned off after being turned on for a predetermined period of time. have. At this time, the ON time of the power supply unit 220 is a time required until the piston 190 moves and contacts the core 200. [

Further, there is an advantage that the internal structure of the valve device is simple, so that there is less concern about the occurrence of trouble, and the reliability regarding the operation of the device can be improved.

12 is a view showing a valve device according to another embodiment of the present invention.

12, a valve apparatus 300 according to another embodiment of the present invention includes a first piston 302 provided to be movable in accordance with the operation of the piston driving unit 303, And a plurality of pipes 307, 308, and 309 that are selectively opened and closed according to the movement of the first piston 302. The plurality of piping 307, 308, 309 may include a capillary.

The plurality of pipes 307, 308 and 309 may include a first pipe 307, a second pipe 308 and a third pipe 309 connected to the first cylinder 304. At the end of the first piston 302, a shielding portion 302a for selectively shielding at least two pipes among the plurality of pipes 307, 308 and 309 is provided.

The valve device 300 includes a second cylinder 310 and a second piston 311 movably provided in the second cylinder 310. The valve device 300 selectively opens and closes the second piston 310 by the second piston 311, 313, and 314, respectively. The plurality of discharge portions 312, 313 and 314 may include a first discharge portion 312, a second discharge portion 313 and a third discharge portion 314 provided below the second piston 311, .

One side of the second cylinder 310 is provided with an inlet 305 for allowing fluid to flow into the second cylinder 310. For example, when the valve apparatus 300 is used in an air conditioner, the inlet 305 is connected to the discharge side of the compressor, and the refrigerant compressed in the compressor flows into the second cylinder 310.

A capillary 306 is provided at one side of the inlet 305 to guide at least a portion of the fluid flowing through the inlet 305 to the first cylinder 304. The capillary 306 is connected to the first cylinder 304.

In this embodiment, the structure and operation of the piston driving unit 303 are the same as those described in the previous embodiment, and thus a detailed description thereof will be omitted.

The operation of the valve device 300 will be briefly described.

First, when an ON signal for the first mode of the valve apparatus 300 is recognized, the piston driving unit 303 is driven to push the first piston 302 to the right (state of FIG. 12) Accordingly, the first piston 302 opens the first pipe 307 and shields the second pipe 308 and the third pipe 309. Therefore, the fluid introduced into the first cylinder 304 through the capillary 306 flows into one side (left side in FIG. 12) of the second cylinder 310 via the first pipe 307. At this time, the piston driving unit 303 does not maintain the ON state, and is turned off after being turned on for a predetermined time, as described in the previous embodiment.

The second piston 311 is moved to the right by the pressure of the fluid flowing into the second cylinder 310 so that the first discharge portion 312 is opened and the second and third The discharge portions 313 and 314 are shielded. As a result, the fluid in the second cylinder 310 is discharged along the first discharge portion 312.

On the other hand, when the ON signal for the second mode of the valve device 300 is recognized, the first piston 302 moves to the left, so that the first piston 302 moves to the second pipe The second pipe 308 is opened and the first pipe 307 and the third pipe 309 are shielded. Therefore, the fluid introduced into the first cylinder 304 through the capillary 306 flows into the other side of the second cylinder 310 (right side in FIG. 9) through the second pipe 308.

The second piston 311 is moved to the left by the pressure of the fluid flowing into the second cylinder 310 so that the third discharge portion 314 is opened and the first and second The discharge portions 312 and 313 are shielded. As a result, the fluid in the second cylinder 310 is discharged along the third discharge portion 314.

100: valve device 110: cylinder
130: damper unit 170:
180: Sleeve 190: Piston
200: core 210: elastic member

Claims (14)

A cylinder defining a fluid flow space;
An inlet provided at one side of the cylinder for allowing fluid to flow into the cylinder;
A plurality of discharge portions provided on the other side of the cylinder and through which fluid in the cylinder is selectively discharged;
A piston receiving at least a portion of the inside of the cylinder and having a projection;
A driving unit connected to one side of the piston and providing a driving force to the piston;
A damper unit coupled to the piston and selectively opening one of the plurality of discharge units; And
And a power supply unit for supplying power to the driving unit,
The driving unit includes: a sleeve accommodating the piston and having a plurality of guides for guiding the movement of the piston;
A core coupled to the sleeve,
And an elastic member for elastically supporting the piston,
Wherein each of the plurality of guides is formed with a latching groove for latching the protrusion of the piston,
Wherein the core includes a plurality of contact protrusions having a core inclined surface,
Wherein each of the plurality of guides includes a first sleeve inclined surface and a second sleeve inclined surface for guiding protrusions of the piston, the first sleeve inclined surface constituting the latching groove,
The projection
A first inclined surface capable of contacting the sleeve inclined surface,
And a second inclined surface capable of contacting the core inclined surface. The method according to claim 1,
Wherein the plurality of guides are spaced apart to form a path through which protrusions of the piston can move. The method according to claim 1,
Wherein the plurality of guides and the core are spaced apart from each other,
Wherein protrusions of the piston are movable between the plurality of guides and the core. delete The method according to claim 1,
Wherein the first inclined surface and the second inclined surface are inclined in a direction approaching each other. 6. The method of claim 5,
Wherein when the power supply unit is turned on, the piston moves toward the core inclined surface, the second inclined surface contacts the core inclined surface,
The second inclined surface is slid along the core inclined surface in a state where the second inclined surface is in contact with the core inclined surface,
The power supply portion is turned off after the second inclined surface slides along the inclined surface of the core so that the piston moves in a direction away from the core inclined surface by the elastic member, Device. 6. The method of claim 5,
In a state in which the projecting portion of the piston is engaged with the engagement groove,
Wherein when the power supply unit is turned on, the piston moves toward the core inclined surface, the second inclined surface contacts the core inclined surface,
The second inclined surface is slid along the core inclined surface in a state where the second inclined surface is in contact with the core inclined surface,
The power supply portion is turned off after the second inclined surface is slid along the inclined surface of the core so that the piston moves in a direction away from the core inclined surface by the elastic member. The method according to claim 1,
Wherein the sleeve inclined surface and the core inclined surface are disposed such that a virtual line extending in a horizontal direction at an end of each sleeve inclined surface meets an intermediate portion of the core inclined surface. The method according to claim 1,
Further comprising a pressurizing mechanism that presses the damper portion toward the discharge portion and guides movement of the damper portion. A valve device comprising a driving part for moving a piston,
The driving unit includes: a sleeve accommodating the piston and having a plurality of guides for guiding the movement of the piston;
A core coupled to the sleeve,
And an elastic member for elastically supporting the piston,
Wherein each of the plurality of guides is formed with a latching groove for latching the protrusion of the piston,
A path through which the projection of the piston can move is formed between the plurality of guides,
Wherein the core includes a plurality of contact protrusions having a core inclined surface,
Wherein each of the plurality of guides includes a first sleeve inclined surface and a second sleeve inclined surface for guiding protrusions of the piston, the first sleeve inclined surface constituting the latching groove,
The projection
A first inclined surface capable of contacting the sleeve inclined surface,
And a second inclined surface capable of contacting the core inclined surface. 11. The method of claim 10,
Wherein the plurality of guides and the core are spaced apart from each other,
Wherein protrusions of the piston are movable between the plurality of guides and the core. delete 12. The method of claim 11,
Wherein the first inclined surface and the second inclined surface are inclined in a direction approaching each other. 12. The method of claim 11,
Wherein the sleeve inclined surface and the core inclined surface are disposed such that a virtual line extending in a horizontal direction at an end of each sleeve inclined surface meets an intermediate portion of the core inclined surface.

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