KR20190096598A - Fluid switching valve - Google Patents

Abstract

The present invention relates to a fluid direction switching valve and, more specifically, to a fluid direction switching valve enabling a magnet ring to fix a plunger to reduce current consumption, and provided with a pilot ring to increase airtightness, operability, and durability of a pilot. Moreover, the pilot ring having a double structure and including an elastic body ring and a Teflon seal covering the elastic body ring is arranged at an outer side of a pilot ring body to increase airtightness, operability, and durability of the pilot. In addition, the fluid direction switching valve is provided with the magnet ring for fixing the plunger even when power is not applied to reduce current consumption.

Description

FLUID SWITCHING VALVE

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a fluid direction switching valve, and more particularly, to a fluid direction switching valve having a plunger fixed by a magnet ring to reduce current consumption and having a dual structure pilot ring to increase airtightness, operability and durability of the pilot.

The fluid direction switching valve is a valve for controlling the refrigerant of the air conditioning apparatus and is used in an air conditioning apparatus such as a vehicle. The solenoid valve of the fluid direction switching valve controls the valve body by using the solenoid, and the direction of the refrigerant is switched by this control. In addition, for this purpose, the valve body is provided with a pilot for changing the direction of the refrigerant.

However, since the existing pilot is mainly provided with O-rings to enhance the airtightness, there is a problem that the airtightness of the pilot is reduced by the wear of the O-rings and the elasticity decreases and eventually the fluid direction switching valve itself needs to be replaced.

Republic of Korea Patent Publication No. 10-2004-0107736 (published Dec. 23, 2004)

It is an object of the present invention to provide a fluid direction switching valve that can increase the airtightness, operability and durability of the pilot.

In order to achieve the above object, the present invention provides a main passage formed between a refrigerant inflow path through which the refrigerant flows in, a refrigerant outflow path through which the refrigerant introduced into the refrigerant inflow path flows out, and the refrigerant inflow path and the refrigerant outflow path. It includes a holder, a pilot provided in the main passage to control the refrigerant flowing into the refrigerant outflow path flowing in the refrigerant outflow path, and a solenoid for controlling the pilot, the solenoid is a cylindrical bobbin A bobbin assembly wound around a coil, a magnet ring provided on the bobbin, a plunger provided in the bobbin and the magnet ring, a core provided below the plunger, and provided between the plunger and the core to provide the plunger. Provided is a fluid direction valve including a plunger spring to pressurize upwards.

And a pilot ring provided on an outer surface of the pilot, wherein the pilot ring includes a teflon seal and an elastic ring fitted to the teflon seal. The Teflon seal is a '-' shaped ring formed with a recess, the elastic ring is fitted to the recess.

The pilot may include a first pilot body having a diameter that increases stepwise toward an upper portion, a second pilot body fastened to an upper portion of the first pilot body, and a pilot that is fitted and fixed between the first pilot body and the second pilot body. A pilot passage including a ring, the first pilot body penetrating a central portion from top to bottom, and a communication path spaced apart from and parallel to the pilot passage and having only an upper portion open and having the same diameter from the upper portion to the lower portion; A connecting passage is formed through the side of the furnace.

The pilot may include a first pilot body that forms a pilot connection path connected to a refrigerant inlet path and a refrigerant outlet path in the main passage, and a ring shape provided at an upper portion of the first pilot body, and is eccentric to a side to have a lower portion from an upper portion thereof. A second pilot body having a second pilot body orifice having the same diameter from the top to the bottom through, a third pilot body coupled to an upper portion of the second pilot body, and being fitted and fixed between the second pilot body and the third pilot body A pilot ring which is connected to a central hole of the second pilot body and partially exposed to an upper portion of the second pilot body, and has a pilot spool communication path penetrating up and down, and the first pilot spooling and The pilot spooling includes a pilot spool formed spaced apart on the outer surface.

In addition, the present invention may further include a frame ring provided on the bobbin assembly.

The present invention may be provided with a double-shaped pilot ring including an elastic ring and a Teflon seal surrounding the outer ring of the pilot body, thereby increasing the airtightness, operability and durability of the pilot.

In addition, the present invention can be provided with a magnet ring for fixing the plunger even if the power is not applied can reduce the current consumption.

1 is a cross-sectional view of a fluid direction switching valve according to a first embodiment of the present invention.
Figure 2 is a cut perspective view of the pilot ring in the fluid direction switching valve according to the first embodiment of the present invention.
Figure 3 is a perspective view of the magnet ring in the fluid direction switching valve according to the first embodiment of the present invention.
Figure 4 is a perspective view of the frame ring in the fluid direction switching valve according to the first embodiment of the present invention.
5 is a cross-sectional view for explaining the operation of the fluid direction switching valve according to the first embodiment of the present invention.
6 is a sectional view of a fluid direction switching valve according to a second embodiment of the present invention.
7 is a cross-sectional view for explaining the operation of the fluid direction switching valve according to a second embodiment of the present invention.

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

However, the present invention is not limited to the embodiments disclosed below, but will be implemented in various forms, and only the embodiments are intended to complete the disclosure of the present invention, and to those skilled in the art to fully understand the scope of the invention. It is provided to inform you. Like reference numerals in the drawings refer to like elements.

1 is a cross-sectional view of a fluid direction switching valve according to a first embodiment of the present invention.

As shown in FIG. 1, the fluid direction switching valve according to the first embodiment of the present invention is combined with the valve body 1000 and the valve body 1000 to control the flow of the refrigerant to control the valve body 1000. It includes a solenoid (2000).

The valve body 1000 directly controls the flow of the refrigerant under the control of the solenoid 2000. For this purpose, the valve body 1000 includes the refrigerant inlet 110 and the refrigerant outlet 120 and the main passage 130. It includes a holder 100 is formed, and the pilot 200 is provided in the main passage 130 to control the refrigerant inlet 110 and the refrigerant outlet 120.

The holder 100 is a body of the valve body 1000 and includes a main passage 130 formed between a refrigerant inflow path 110 formed at one side of the holder 100 and a refrigerant outlet path 120 formed at the other side. In addition, the main passage 130 communicates with the coolant inflow path 110 and the coolant outlet path 120 and is also opened to the upper portion of the holder 100 to insert the rod 700 of the solenoid 2000. The pilot 200 is provided in the main passage 130 of the holder 100.

The pilot 200 controls the flow of the refrigerant flowing into the holder 100 by opening and closing the refrigerant inlet 110 and the refrigerant outlet 120. The pilot 200 includes a pilot body 210 and 220, a pilot ring 240, a pilot absorber 250, a pilot guide 260, and a pilot spring 270.

The pilot bodies 210 and 220 have a cylindrical shape having a step size in which diameters are gradually expanded upward, and an elastic ring 242 is provided at an upper edge thereof. The pilot bodies 210 and 220 include a first pilot body 210 and a second pilot body 220 coupled to an upper portion of the first pilot body 210.

The first pilot body 210 substantially serves as a pilot body, and the first pilot body 210 has a pilot passage 211 penetrating the center of the first pilot body 210 and a pilot passage 211. A communication path 212 formed to be spaced apart from each other, a connection path 213 connecting the communication path 212 and the refrigerant inflow path 110, and an orifice 214 formed through the side surface of the pilot passage 211 are formed.

The pilot passage 211 penetrates the upper part from the lower part of the first pilot body 210 but is formed to have the same diameter from the lower part to the upper part of the part, and then the diameter is reduced.

The communication path 212 is formed to be spaced apart from the pilot passage 211, and is formed through the upper portion of the first pilot body 210 toward the inside. Here, the diameter of the communication path 212 is the same from the top to the bottom.

The connection path 213 is formed to penetrate the side of the communication path 212 so as to connect the outside of the side of the communication path 212 and the first pilot body 210. In addition, the diameter of the portion connected to the communication path 212 is smaller than the side of the first pilot body 210 of the connection path (213).

The orifice 214 is formed to penetrate the side of the pilot passage 211 to connect the pilot passage 211 and the holder 100. In addition, even when the refrigerant outlet passage 120 is closed, the refrigerant flows to some extent by the orifice 213, which is always filled in the refrigerant outlet passage 120, thereby increasing the reaction speed of the fluid direction switching valve.

The second pilot body 220 is for fixing the pilot ring 240, and covers the upper end portion of which the diameter of the first pilot body 210 is reduced, and fits the upper end portion of which the diameter of the first pilot body 210 is reduced. The losing pilot ring 240 is provided between the first pilot body 210 and the second pilot body 220. Accordingly, only the elastic ring 242 of the pilot ring 240 is exposed to the side of the pilot body. That is, the first pilot body 210 serves as a substantial pilot body, and the second pilot body 220 fixes the upper end of the elastic ring 242 so that the elastic ring 242 is not separated from the outside of the pilot body. Do not

The filter 230 is provided outside the connection path 213 so that foreign matters contained in the refrigerant flowing into the connection path 213 from the outside of the first pilot body 210 are transferred to the first pilot through the connection path 213. It prevents the inflow into the body 210. The filter 230 is an annular filter 230, and is provided in a form surrounding the outer surface of the first pilot body 210 to cover the connection path 213.

Figure 2 is a cut perspective view of the pilot ring in the fluid direction switching valve according to the first embodiment of the present invention.

The pilot ring 240 is provided on the outer surface of the pilot body to reduce the friction force during the up and down movement of the pilot body and to prevent the refrigerant from moving between the pilot body and the core 600. In addition, to effectively do this, the pilot ring 240 includes a Teflon seal 241 and an elastomer ring 242, as shown in FIG. In addition, the Teflon seal 241 is manufactured in a 'c' shape, as shown, the elastic ring 242 is located in the groove formed by the shape. Accordingly, the elastomer ring 242 pushes the Teflon seal 241 outward, and the Teflon seal 241 rubs against the inner surface of the core 600 as the pilot moves up and down. However, according to the present invention, the teflon seal 241 reduces the friction force, and the elastic ring 242 with elasticity pushes the teflon seal 241 by elasticity so that the same friction force and airtightness can be maintained at all times. On the other hand, such a pilot ring 240 may be provided in the pilot by curling. That is, after the pilot ring 240 is inserted into the first pilot main body 210, the second pilot main body 220 is inserted into the upper part of the second pilot main body 220, and thereafter, the first pilot main body ( 210, the upper protrusion is bent to the inner surface of the second pilot main body 220 so that the second pilot main body 220 is not separated from the first pilot main body 210. However, the present invention is not limited thereto, and the pilot ring 240 may be forced into the combined first pilot body 210 and the second pilot body 220.

The pilot absorber 250 is provided at the bottom of the pilot body to block the refrigerant flowing into the refrigerant inlet 110 from moving to the refrigerant outlet 120 through the outside of the pilot body. That is, the pilot absorber 250 serves to seal the contact between the pilot passage 211 and the coolant outlet passage 120 when the pilot body descends. For this purpose, the pilot absorber 250 is made of a rubber material. desirable.

The pilot guide 260 is for maintaining the concentricity of the pilot body and the coolant outlet passage 120, and has a ring-shaped pilot guide 260 body and a bar guide pilot guide extending to one side from the pilot guide 260 body. 260 bars. Here, the pilot guide 260 bar may include a plurality of pilot guide 260 bars spaced apart from each other, and this embodiment illustrates three pilot guide 260 bars.

The pilot spring 270 is provided so that one side is in contact with the stepped lower portion formed on the side of the pilot body, the other side is in contact with the lower portion of the main passage 130, and raises the pilot body by elasticity.

Meanwhile, in the present invention, a guide 280 is formed between the pilot 200 and the cap 700.

The guide 280 is formed in a cylindrical shape having one surface open to surround one surface and an outer surface of the plunger 500 and a portion of the outer surface of the core 600. In addition, the guide 280 is provided between the bobbin assembly 410, the magnet ring 420 and the frame cover 440, and a portion of the plunger 500 and the core 600, and thus, the core 600 and the plunger. The refrigerant flowing into the 500 is prevented from leaking to the outside.

The solenoid 2000 is coupled to the upper end of the valve body 1000 and pushes the pilot bodies 210 and 220 downward through the upper main passage of the holder 100 to open the refrigerant inlet 110 and the refrigerant outlet 120. Enforce. The solenoid 2000 includes a bobbin assembly 410 in which a coil 412 is wound around a bobbin, a magnet ring 420 provided at a bottom of the bobbin assembly 410, and upper and lower sides and side surfaces of the bobbin assembly 410. The frame 430 to cover and protect the frame, the frame cover 440 covering the upper portion of the frame 430, the frame ring 450 provided on the upper portion of the core, the bobbin assembly 410 is provided therein and the core 600 By the magnetic force generated by the magnetic plunger 500, the magnetic force generated in the coil 412, the core 600, and the cap 700 is included.

The bobbin assembly 410 includes a cylindrical bobbin 411 and a coil 412 wound around the bobbin 411. In addition, the magnetic field is generated using the power applied through the connector 460.

3 is a perspective view of a magnet ring in the fluid direction switching valve according to the first embodiment of the present invention.

The magnet ring 420 is to maintain the magnetic force generated in the bobbin assembly 410, and is formed in a ring shape, as shown in FIG. The magnet ring 420 is provided on the upper end of the bobbin assembly 410 to surround the outer surface of the plunger 500. That is, the plunger 500 is wrapped around the outer surface by the bobbin assembly 410 and the magnet ring 420, even if the power is cut off after the power is applied and the plunger 500 rises, the plunger (420) 500) can be fixed. In addition, when applied to the heat pump system, it is not necessary to continuously supply power to maintain the plunger 500 in a raised state, thereby reducing the current consumption. Of course, the plunger 500 fixed by the magnet ring 420 is lowered again when reverse power is applied to the coil.

The frame 430 is formed in a 'c' shape to surround the upper, lower, and some side surfaces of the bobbin assembly 410, and supports an outer surface of the magnet ring 420. Accordingly, only the upper portion of the above-described magnet ring 420 is exposed to the outer surface, and the upper portion is also covered by the frame cover 440 to be described later. This frame 430 rotates the magnetic force generated by the coil 412 and protects the coil 412 wound on the bobbin.

The frame cover 440 is provided on an upper portion of the frame 430 to cover the upper portion of the frame 430 and to prevent the magnet ring 420 from escaping upward. To this end, the frame cover 440 is formed to cover both the upper portion of the frame 430 and the magnet ring 420 so as to cover the upper portion of the magnet ring 420 exposed only by the frame 430.

Figure 4 is a perspective view of the frame ring in the fluid direction switching valve according to the first embodiment of the present invention.

The frame ring 450 is for rotating the magnetic force, and is provided in the form of a ring on the bobbin assembly 410 as shown in FIG. 4. The frame ring 450 rotates the magnetic force of the coil 412 so that the bobbin assembly 410 has an extended effect.

The connector 460 transmits power applied from the outside to the bobbin assembly 410 to allow the bobbin assembly 410 to generate a magnetic field.

The plunger 500 is magnetized when the magnetic force is generated in the bobbin assembly 410 to be in close contact with the core 600 to be described later. If the magnetic force is not generated, the plunger 500 is spaced apart from the core 600 by the plunger spring 510. The plunger 500 has a cylindrical shape but decreases in diameter toward the area in contact with the core 600. In addition, a cross-type plunger flow passage communicating with the outside is formed in the plunger 500, and a plunger absorbent body 520 is provided at a lower end of the plunger flow passage communicating in the longitudinal direction of the plunger 500.

The plunger absorber 520 is provided at the lower portion of the plunger 500 to open and close the pilot passage 211 of the first pilot body 210 according to the vertical reciprocation of the plunger 500. The plunger absorber 520 is preferably a rubber material.

Seat 530 is in the form of a ring, provided in the lower portion of the core to reduce the impact and noise caused by the reciprocating motion of the plunger 500.

The core 600 is fixed to the inside of the bobbin assembly 410 and the magnetic force generated by the coil 412 is concentrated. In addition, when the magnetic force generated in the coil 412 is concentrated, the plunger 500 provided at the upper side is attracted so that the plunger 500 is in contact with the upper portion of the core 600. The core 600 has a cylindrical shape and a recess is formed in the lower portion, and the upper portion of the plunger 500 is interpolated in the recess. In this case, a protrusion is formed in the recess of the core 600, and a plunger spring 510 is positioned in the protrusion to press the lower plunger 500.

The cap 700 is positioned to be surrounded by the lower part of the frame 430 and the holder 100 and the core 600, and is formed in the form of a circular ring. The cap 700 prevents the inner parts of the fluid direction switching valve according to the present embodiment from being separated, and a thread part is formed on the outside.

Next, the operation of the fluid direction switching valve according to the present invention described above will be described with reference to the drawings.

5 is a cross-sectional view for explaining the operation of the fluid direction switching valve according to the first embodiment of the present invention.

In the fluid direction switching valve according to the first embodiment of the present invention, the plunger 500 maintains the lowered state as shown in FIG. 1 when the power is turned off. In this case, the pilot 200 is closed by the upper pressure of the pilot 200, and the refrigerant flow path 120 is closed, and the refrigerant flowing into the refrigerant inflow path 110 flows through the main passage 130. Can't move to 120. Thereafter, when power is applied, as shown in FIG. 5, the plunger 500 starts to rise, so that the plunger absorber 520 opens the upper part of the pilot passage 211 of the pilot 200 and opens the pilot ( 200) The pressure at the top drops. Thereafter, when power is maintained, the pilot 200 rises as the pressure of the upper part of the pilot 200 rises to open the refrigerant outlet passage 120, and the refrigerant in the refrigerant inlet passage 110 is the refrigerant outlet passage 120. Go to. Of course, when the power is turned off again, the plunger spring 510 returns to the state of FIG. 1.

Next, a fluid direction switching valve according to a second embodiment of the present invention in which one refrigerant inlet passage and two refrigerant outlet passages are formed will be described with reference to the accompanying drawings. Among the contents to be described later, the description overlapping with the description of the fluid direction switching valve according to the first embodiment of the present invention will be omitted or briefly described.

6 is a cross-sectional view of a fluid direction switching valve according to a second embodiment of the present invention.

As shown in FIG. 6, the fluid direction switching valve according to the second embodiment of the present invention is coupled to the valve body 1000 for controlling the flow of the refrigerant and the valve body 1000 to control the valve body 1000. It includes a solenoid (2000). Here, since the description of the solenoid 2000 is the same as the description of the fluid direction switching valve according to the first embodiment of the present invention described above it will be omitted.

The valve body 1000 directly controls the flow of the refrigerant under the control of the solenoid 2000. For this purpose, the valve body 1000 includes the refrigerant inlet 110 and the refrigerant outlet 120 and the main passage 130. The holder 100 is formed, and the pilot 300 is provided in the main passage 130 to control the refrigerant inlet 110 and the refrigerant outlet 120.

Holder 100 is a body of the valve body 1000, the main passage 130 formed so as to communicate between the refrigerant inlet passage 110 formed on one side of the holder 100 and the refrigerant outlet passage 120 formed to be spaced apart from the other side. ). Here, the present embodiment includes a first refrigerant outlet 121 and a second refrigerant outlet 122 in which the refrigerant outlets 120 are spaced apart from each other, and thus, the pilot 300 of the present embodiment to be described below The pilot according to the first embodiment of the present invention described above and its shape are different.

The pilot 300 controls the flow of the refrigerant flowing into the holder 100 by opening and closing the refrigerant inlet 110 and the refrigerant outlet 120. To this end, the pilot 300 includes a pilot body 310, 320, 330, a pilot spool 340, a pilot absorber 350, a filter 360, a pilot ring 370, a pilot guide 260, and a pilot A spring 270. Here, the description of the filter 360, the pilot ring 370, and the pilot guide 260 itself is the same as the first embodiment described above, and thus will be omitted.

The pilot bodies 310, 320, and 330 are located in the main passage 130 of the holder 100, and the first pilot body 310 main passage connecting the refrigerant inflow path 110 and the refrigerant outlet path 120 ( The first pilot body 310 having the 130 formed therein, the second pilot body 320 provided in the main passage 130 and rising and falling, and the pilot ring 370 to be described below are fixed to the second pilot body 320. And a pilot spool 340 connected to the third pilot body 330 and the second pilot body 320 and provided in the first pilot body 310 main passage 130 of the first pilot body 310. do.

The first pilot body 310 forms a pilot connection path connected to the refrigerant inlet 110 and the refrigerant outlet 120 in the main passage 130 inside the holder 100. More specifically, the first pilot main body 310 penetrates up and down, but the lower part communicates with the first refrigerant outlet passage 121, and the first pilot main body 310 main passage 130 and the first pilot main body 310 main body. First pilot body connecting the first pilot body 310, the refrigerant inlet 110, the first pilot body 310, the main passage 130 and the second refrigerant outlet 122 formed in parallel with the passage 130 A refrigerant flow path 120 is formed.

The second pilot body 320 is positioned in the main passage 130 of the holder 100 but is spaced apart from the upper portion of the first pilot body 310. The second pilot main body 320 is in the shape of a disc and is provided inside the core 600 to be raised and lowered by the pressure of the upper part of the pilot 300 which changes according to the movement of the rod 700. Of course, for this purpose, a second pilot body orifice penetrating the second pilot body 320 up and down is formed on a side surface of the second pilot body 320, and the second pilot body is formed by the refrigerant introduced into the second pilot body orifice. When the upper pressure of 320 is increased, the second pilot body 320 moves downward. Here, in FIG. 5, the diameter of the second pilot body orifice is illustrated as being different from the top and the bottom thereof, but is not limited thereto. The diameter of the second pilot body orifice may be the same from the top to the bottom. In addition, a jaw due to the diameter difference is formed on the outer surface of the second pilot body 320, and the pilot ring 370 is provided on the jaw.

The third pilot body 330 is coupled to the upper portion of the second pilot body 320 to prevent the pilot ring 370 from being separated from the second pilot body 320. That is, as the third pilot body 330 is coupled to the second pilot body 320, the outer surfaces of the combined second pilot body 320 and the third pilot body 330 become a 'c' shape, and Pilot ring 370 is located in the groove by the shape so as not to fall out. In addition, a hole penetrating the third pilot body 330 up and down is formed in the center of the third pilot body 330.

The pilot spool 340 is fixed to the upper part is inserted into the hole formed in the center of the second pilot body 320. Accordingly, the upper part of the pilot spool 340 is exposed to the upper part of the second pilot main body 320, and the combined second pilot main body 320 and the pilot spool 340 have a 'T' shape. In addition, the pilot spool 340 is formed with a pilot spool 340 communication path penetrating the inside up and down. A first pilot spool 340 ring is formed at the outer periphery of the central portion of the pilot spool 340, and a second pilot spool 340 ring is spaced apart from the lower portion of the first pilot spool 340 ring. The first pilot spool 340 ring is formed to correspond to the diameter of the first pilot main body 310 main passage 130 to control the refrigerant moving through the first pilot main body 310 main passage 130. In addition, the second pilot spool 340 ring is formed to cover the second pilot absorber 352 to form a hole formed at the center of the first pilot body 310 main passage 130 and the second pilot absorber 352. The refrigerant moving to the first refrigerant outflow passage 121 is intermittently intercepted. In addition, the pilot spool 340 exposed to the upper portion of the second pilot body 320 is opened and closed by a rod absorber, and thus, the pilot spool communication path is interrupted.

The pilot absorber 350 is to control the movement of the refrigerant to the first refrigerant outflow path 121. The pilot absorber 350 is to control the movement of the refrigerant from the holder 100 main passage 130 to the first refrigerant outflow path 121. And a second pilot absorber 352 contacting the second pilot spool 340 ring to control the movement of the refrigerant. The pilot absorber 350 is formed of a rubber material, it is preferable that the insert is injected.

The pilot spring 270 is provided between the upper portion of the first pilot body 310 and the lower portion of the second pilot body 320 to press the second pilot body 320 upward. Accordingly, the second pilot body 320, the third pilot body 330, and the pilot spool 340 rise together by the pilot spring 270 when the plunger 500 rises.

7 is a cross-sectional view for explaining the operation of the fluid direction switching valve according to the second embodiment of the present invention.

In the fluid direction switching valve according to the second embodiment of the present invention, the plunger 500 maintains the lowered state as shown in FIG. 6 when the power is turned off. In this case, the pilot 200 is closed by the upper pressure of the pilot 200, and the refrigerant flow path 120 is closed, and the refrigerant introduced into the refrigerant inflow path 110 is the first refrigerant through the main passage 130. It cannot move to the outflow passage 121 and only moves to the second refrigerant outflow passage 122. Thereafter, when power is applied, as shown in FIG. 7, the plunger 500 starts to rise, so that the plunger absorber 520 opens the pilot passage 211 of the pilot 200 and opens the pilot ( 200) The pressure at the top drops. Subsequently, when the power is applied, the pilot 200 rises as the pressure of the upper part of the pilot 200 decreases to open the first refrigerant outlet 121 and close the second refrigerant outlet 122. Accordingly, the refrigerant in the refrigerant inflow path 110 moves to the second refrigerant outflow path 120. Of course, when the power is turned off again, the plunger spring 510 returns to the state of FIG. 6.

As described above, the present invention may include a dual-type pilot ring including an elastic ring and a Teflon seal surrounding the outer ring of the pilot body to increase airtightness, operability, and durability of the pilot. In addition, the present invention can be provided with a magnet ring for fixing the plunger even if the power is not applied can reduce the current consumption.

Although described above with reference to the drawings and embodiments, those skilled in the art can be variously modified and changed within the scope of the invention without departing from the spirit of the invention described in the claims below. I can understand.

100: holder 110: refrigerant inlet
120: refrigerant flow passage 121: first refrigerant flow passage
122: second refrigerant outlet passage 130: main passage
200, 300: pilot 210, 310: first pilot body
211: pilot passage 212: communication path
213: connection 214: orifice
220, 320: second pilot body 230, 360: filter
240, 370: pilot ring 241, 371: teflon seal
242, 372: elastomer ring 250, 350: pilot absorber
260: pilot guide 270: pilot spring
280: guide 290, 380: cover
330: third pilot body 340: pilot spool
351: first pilot absorber 352: second pilot absorber
410: bobbin assembly 411: bobbin
412: coil 420: magnet ring
430: frame 440: frame cover
450: frame ring 460: connector
500: plunger 510: plunger spring
520: plunger absorbent 530: sheet
600: core 700: cap
810, 820, 830, 840, 850, 860: O-ring
1000: valve body 2000: solenoid

Claims (6)

A holder including a refrigerant inflow path through which the refrigerant flows in, a refrigerant outflow path through which the refrigerant flowing into the refrigerant inflow path flows out, and a main passage formed between the refrigerant inflow path and the refrigerant outflow path;
A pilot provided in the main passage to control a coolant flowing from the coolant inlet and moving to the coolant outlet;
A solenoid controlling the pilot,
The solenoid may include a bobbin assembly in which a coil is wound around a cylindrical bobbin, a magnet ring provided on the bobbin, a plunger provided in the bobbin and the magnet ring, a core provided below the plunger, and the plunger and the And a plunger spring provided between the cores to pressurize the plunger upward. The method of claim 1,
It includes a pilot ring provided on the outer surface of the pilot,
The pilot ring includes a teflon seal and an elastic ring fitted to the teflon seal. The method of claim 2,
The Teflon seal has a concave '-' shaped ring is formed, the fluid directional valve that the elastic ring is fitted to the concave portion. The method of claim 3,
The pilot is,
A first pilot body that increases in diameter stepwise toward the upper portion,
A second pilot body fastened to an upper portion of the first pilot body, and
It includes a pilot ring that is sandwiched between the first pilot body and the second pilot body,
The first pilot body has a pilot passage penetrating a central portion from the top to the bottom, a communication path spaced apart from the pilot passage and formed in parallel and having only an upper portion and having the same diameter from the top to the lower portion, penetrating to the side of the communication passage. Directional valves with connected connections. The method of claim 3,
The pilot is,
A first pilot body forming a pilot connection path connected to the refrigerant inflow path and the refrigerant outflow path in the main passage;
A second pilot body having a ring shape provided on an upper portion of the first pilot body, and having a second pilot body orifice having an eccentric side surface, penetrating from an upper side to a lower side, and having the same diameter from an upper side to a lower side;
A third pilot body coupled to an upper portion of the second pilot body,
A pilot ring fitted between the second pilot body and the third pilot body and fixed;
The first pilot spooling and the second pilot spooling connected to the central hole of the second pilot main body are partially exposed to the upper part of the second pilot main body, and have a pilot spool communication path penetrating up and down. Fluid directional valve comprising a pilot spool formed spaced apart on the outer surface. The method according to claim 4 or 5,
And a frame ring provided on the bobbin assembly.

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