KR20180002973A - Solenoid valve - Google Patents

Abstract

The present invention relates to a solenoid valve capable of simplifying the configuration of a flow path and reducing the size of a valve device by implementing a feedback structure inside a spool. The solenoid valve is composed of a valve for interrupting the flow of a fluid and a solenoid for actuating the valve. The valve includes a pipe-shaped holder extending in one direction. A drain port is formed at an upper end of the holder. A control port is located below the drain port. A supply port is located below the control port. A chamber connected to each port is formed in the holder. A drain chamber is formed in the upper end of the holder. A control chamber is formed below the drain chamber. A supply chamber is formed below the control chamber. A feedback chamber is formed below the supply chamber. A spool is installed in the holder to be able to move. A land for connecting or disconnecting the port is formed on an outer circumferential surface of the spool. A feedback flow path connecting the control chamber and the feedback chamber is formed in the spool.

Description

SOLENOID VALVE

The present invention relates to a solenoid valve, and more particularly, to a solenoid valve installed in an engine and a power train of an automobile to intermittently control the flow of fluid such as fuel, oil or control the pressure.

Generally, a solenoid valve is installed in a power train including an engine of an automobile to control the flow of fluid such as fuel, oil or control the pressure. For example, the fuel system controls the fuel supply and injection, the cooling system controls the circulation for lubrication and cooling, and the power transmission system controls the pressure.

5, the conventional solenoid valve is a hydraulic pressure control solenoid valve for controlling the hydraulic pressure (oil pressure) of the automatic transmission, and includes a valve 10 for controlling the hydraulic pressure, a solenoid for operating the valve 10, (20). The valve 10 includes a holder 12 having a plurality of ports 12a to 12d formed therein and a spool 14 for connecting or disconnecting a plurality of ports 12a to 12d is provided in the holder 12 . The solenoid 20 includes a bobbin 22 wound around a coil 21 on its outer circumference and a core 23 and a yoke 24 are coupled to both ends of the bobbin 22 and a plunger 25 are installed.

The above-described solenoid valve is a normal high (NH) type in which the normal spool 14 without the power source is lowered to connect the supply port 12a and the control port 12b. When the power is applied to the NH type solenoid valve, the spool 14 rises due to the magnetic field generated by the coil 21 to cut off the connection between the supply port 12a and the control port 12b.

The conventional NH type solenoid valve is configured to raise the spool 14 by the elastic force of the spring 16 provided on the valve 10 and the pressure of the oil discharged from the control port 12b and flowing through the feedback port 12c .

Therefore, the feedback port 12c must be provided for the NH type solenoid valve, and the length of the holder 12 is longer than that of the NL (Normal Low) type solenoid valve.

Korean Registered Patent No. 10-1160470 (Jun. 21, 2012)

SUMMARY OF THE INVENTION It is an object of the present invention to provide a solenoid valve that can simplify the configuration of a flow path and reduce the size of a valve device by implementing a feedback structure inside a spool.

According to an aspect of the present invention, there is provided a solenoid valve including a valve for interrupting a flow of a fluid, and a solenoid for actuating the valve.

The valve includes a pipe-shaped holder extending in one direction.

A drain port is formed at the upper end of the holder, a control port is located below the drain port, and a supply port is located below the control port.

A chamber connected to each port is formed in the holder. That is, a drain chamber is formed in the upper end of the holder, a control chamber is formed below the drain chamber, and a supply chamber is formed below the control chamber. And a feedback chamber is formed below the supply chamber.

A spool is movably installed in the holder. A land for connecting or disconnecting the port is formed on an outer circumferential surface of the spool, and a feedback path for connecting the control chamber and the feedback chamber is formed in the spool.

The spool includes a first land formed at an upper end of the spool, a second land formed at an end of the spool, and a third land formed at a lower end of the spool.

The lower portion of the second land and the upper portion of the third land are positioned on the feedback chamber and a pressure-receiving groove is formed between the second land and the third land, in which the pressure of the fluid introduced into the feedback chamber is applied . At this time, the second land is formed to have a larger diameter than the third land, and the upper surface of the surface pressure groove is formed to have a larger area than the lower surface, so that the spool is raised when the fluid flows into the feedback chamber.

A spring for elastically supporting the spool downward is provided in the holder.

According to the present invention configured as described above, the spool descends through the balance between the pressure of the normal spring when the power is not applied and the pressure of the feedback chamber to connect the supply port and the control port. On the other hand, when the power is applied, the spool rises due to the solenoid operating force and the pressure of the feedback chamber, thereby disconnecting the supply port from the control port.

Since the solenoid valve according to the present invention has a structure in which the feedback chamber is connected to the control chamber through the feedback flow path formed in the spool, there is no need to add a feedback port to the holder, Can be simplified.

1 is a sectional view of a solenoid valve according to an embodiment of the present invention;
2 is a view showing a valve of a solenoid valve according to an embodiment of the present invention.
3 is an enlarged view of a portion "A" in Fig.
4 is a view showing an operating state of a solenoid valve according to an embodiment of the present invention.
5 is a view showing a conventional NH type solenoid valve.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Referring to the accompanying drawings, embodiments of the present invention will be described in detail. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

A solenoid valve according to an embodiment of the present invention is a solenoid valve installed in a fuel system, a cooling system, and a power transmission system, for controlling the flow of fluid and controlling the pressure of the fluid. Among them, a hydraulic pressure control solenoid valve provided in the automatic transmission for controlling the hydraulic pressure will be described as an example.

The hydraulic pressure control solenoid valve controls the oil supplied from an external hydraulic pressure source to a predetermined pressure and then supplies the oil to the clutch (not shown) side. The valve 100 controls the flow of oil into and out of the solenoid valve. And a solenoid 200 for driving the solenoid 200.

The valve 100 will be described in detail with reference to FIGS. 1 to 4. FIG.

The valve 100 is a portion mounted on a valve body (not shown) having a plurality of flow paths. A spool 120 movably installed inside the holder 110; an adjusting screw 130 screwed to an upper end of the holder 110; a spool 120; And a spring 140 between the adjusting screws 130.

The holder 110 is in the form of a hollow pipe extending in one direction (upper and lower in the figure). A plurality of ports 152 to 156 are formed on an outer circumferential surface of the holder 110 and a plurality of chambers 162 to 166 connected to the plurality of ports 152 to 156 are formed in the holder 110.

The holder 110 of the present embodiment has a structure in which the feedback port is omitted, unlike the conventional NH type solenoid valve (see Fig. 5). That is, a supply port 152 for supplying oil from the outside is formed on the outer peripheral surface of the lower end of the holder 110, and a control port 154 for discharging oil controlled at a predetermined pressure is formed on the upper portion of the supply port 152 And a drain port 156 for discharging the oil recovered through the control port 154 to the outside is formed on the upper portion of the control port 154.

The chambers 162 to 166 are respectively connected to the above-described ports 152 to 156 to temporarily store the oil introduced through the ports 152 to 156 or the oil transferred from the adjacent other chambers 162 to 166. These chambers 162 to 166 are connected through the operating grooves 184 formed in the spool 120 when the spool 120 is moved.

The supply chamber 162 is located inside the stop of the holder 110 and is connected to the supply port 152. The control chamber 164 is located above the supply chamber 162 and is connected to the control port 154. The drain chamber 166 is located above the control chamber 164 and is connected to the drain port 156.

On the other hand, a feedback chamber 168 is formed in the lower end of the holder 110, more specifically, below the supply chamber 162. The feedback chamber 168 is connected to the control chamber 164 through a feedback channel 122 to be described later so that when a part of the oil introduced into the control chamber 164 flows into the feedback channel 122, ).

The spool 120 is movably installed inside the holder 110 and moves by the solenoid 200 and the spring 140 to connect or disconnect the ports 152 to 156 described above. The spool 120 is in the form of a multi-stage shaft extending in the longitudinal direction of the holder 110. The feedback passage 122 connecting the control chamber 164 and the feedback chamber 168 is formed in the spool 120.

A plurality of lands 172 to 176 are formed on the outer circumferential surface of the spool 120 and grooves 182 and 184 are formed between the plurality of lands 172 to 176. A spring 140 is seated on the upper end of the spool 120 A seating groove 188 is formed.

The lands 172 to 176 are formed on the outer circumferential surface of the holder 110 and are in contact with the inner wall of the holder 110. The lands 172 to 176 cut off the connection of the ports 152 to 156 when the spool 120 moves. A first land 172 is formed at an upper end of the spool 120. A second land 174 is formed at an end of the spool 120 and a third land 176 is formed at a lower end of the spool 120 .

3, the lower portion of the second land 174 and the upper portion of the third land 176 are positioned on the feedback chamber 168. As shown in Fig. A surface pressure groove (182) is formed between the second land (174) and the third land (176) where the pressure of oil introduced through the feedback flow path (122) acts. At this time, the diameter D ₁ of the second land 174 is formed to be larger than the diameter D ₂ of the third land 176, and the upper surface 182a of the surface pressure grooves 182 is formed to have a larger area than the lower surface 182b .

The predetermined pressure is applied to the upper surface 182a and the lower surface 182b of the surface pressure grooves 182 when the feedback pressure F is introduced through the feedback path 122. [ Since the upper surface 182a of the pressure-receiving groove 182 has a larger area than the lower surface 182b, a larger pressure is applied to the upper surface 182a of the pressure-receiving groove 182. [ Therefore, the feedback pressure F flowing through the feedback oil passage 122 acts in the direction of raising the spool 120.

Referring to FIG. 2, an operating groove 184 is formed between the first land 172 and the second land 174. The second land 174 blocks the supply port 152 and the control port 154 when the spool 120 rises. The operating groove 184 connects the control port 154 and the drain port 156 when the spool 120 rises. On the other hand, the operating groove 184 at the time of descent of the spool 120 connects the supply port 152 and the control port 154.

On the other hand, the second land 174 is formed with a notch groove 192 for gradually increasing or decreasing the connection between the supply port 152 and the control port 154 (see FIG. 3). The notch groove 192 has a half-moon-like groove shape so that the holder 110 and the second land 174 can be gradually opened (or closed) when the spool 120 moves. That is, the notch groove 192 gradually blocks the supply port 152 and the control port 154 while reducing the area of the spool 120 when the spool 120 is lifted, So that the supply port 152 and the control port 154 are gradually connected.

The feedback flow path 122 is a flow path for feeding back a part of the oil introduced into the control chamber 164. This feedback flow path 122 extends from the lower end of the spool 120 to the upper end and opens through the upper surface of the spool 120. The spool 120 is provided with a first feedback port 124 for connecting the feedback flow path 122 and the operating groove 184 and a feedback flow path 122 and a feedback chamber 168 are formed at the lower end of the spool 120, A second feedback port 126 is formed.

A guide pin 128 for guiding the movement of the spool 120 is coupled to the open top of the feedback path 122. The guide pin 128 is formed of a small diameter portion 128a inserted into the feedback oil passage 122 and a large diameter portion 128b formed in the upper portion of the small diameter portion 128a. At this time, the small diameter portion 128a is inserted into the upper end of the feedback oil passage 122 to guide the movement of the spool 120 and to seal the feedback oil passage 122. [ The upper end of the large diameter portion 128b is brought into contact with the adjusting screw 130 to prevent the spool 120 from rising above a predetermined height and guides the spring 140 installed around the spool 120 to buckle.

The adjustment screw 130 is coupled to the upper end of the holder 110 to seal the open top of the holder 110. The adjusting screw 130 is screwed to the upper end of the holder 110 and an insertion groove 132 into which the spring 140 is inserted is formed on the lower surface of the adjusting screw 130. When the adjusting screw 130 is screwed to the upper end of the holder 110, the hydraulic pressure of the solenoid valve can be variously set as necessary.

The spring 140 is installed to be inserted into the insertion groove 132 and the seating groove 188. The spring 140 elastically supports the spool 120 downward so that the supply port 152 and the control port 154, which are not normally powered, are connected.

As described above, when the adjusting screw 130 is tightened or loosened, the elastic force applied to the spool 120 side is adjusted to variously set the hydraulic pressure of the solenoid valve. In addition, power is applied to the solenoid 200 to absorb the shock generated when the spool 120 rises.

1, the solenoid 200 includes a case 210, a bobbin 220 installed inside the case 210, a coil 230 wound on the outer circumferential surface of the bobbin 220, a bobbin 220, A plate 250 coupled to the bobbin 220 through the upper portion of the bobbin 220 and positioned below the bobbin 220 and inserted into the lower end of the core 240, A rod 260 penetrating therethrough, a plunger 270 movably installed in the core 240, and a connector 280 provided at a lower portion of the case 210.

The case 210 has an upper surface opened and a lower surface closed cup shape. A housing space 212 is formed in the case 210 and parts 220 to 270 except for the connector 280 are provided in the housing space 212. A locking protrusion 214 is formed on the upper inner circumferential surface of the case 210 and a flange 242 of the core 240 is seated on the locking protrusion 214. At this time, the upper end of the case 210 is caulked so as to surround the lower end of the holder 110 and the upper end of the core 240 to prevent the components 220 to 270 installed inside the case 210 from flowing And prevents foreign matter from entering the upper portion of the case 210.

The bobbin 220 has a hollow spool shape with flanges protruding from both ends thereof. The core 240 and the plate 250 are coupled to the upper and lower portions of the bobbin 220, respectively, and the coil 230 for generating a magnetic field is wound on the outer circumferential surface thereof. The bobbin 220 is made of synthetic resin so as to electrically block the coil 230 and the core 240, between the coil 230 and the plate 250, and between the coil 230 and the plunger 270 .

The coil 230 generates a magnetic field around the bobbin 220 when the power is applied. The coil 230 is tightly and uniformly wound around the outer circumferential surface of the bobbin 220 to form a cylindrical shape. The magnetic field generated in the coil 230 when the power is applied is induced by the core 240 and the plate 250 to lift the plunger 270. At this time, the intensity of the magnetic field is proportional to the intensity of the current flowing along the coil 230 and the number of the coils 230 wound on the bobbin 220. Therefore, as the coil 230 is strongly energized or the coil 230 is heavily coiled, a strong magnetic field is generated, so that the movement of the plunger 270 can be reliably controlled.

The core 240 is composed of a flange 242 and a body 244 protruding downward from the lower surface of the flange 242. An operation space for reciprocating motion of the plunger 270 246 are formed. The flange 242 of the core 240 is spaced apart from the upper flange when engaged with the bobbin 220 and seated in the latching jaw 214 upon engagement with the case 210. The body 244 is coupled to penetrate the bobbin 220 and the lower end thereof is inserted into the plate 250.

A magnetic force strengthening groove 246 is formed on the outer peripheral surface of the body 244 at the stop. The magnetic flux density is increased on the wall surface of the body 244 whose thickness is thinned by the magnetic force strengthening groove 246. Therefore, a magnetic field generated in the coil 230 is concentrated in the magnetic force strengthening groove 246, so that a sufficient magnetic force is secured so that the plunger 270 can be easily sucked. Therefore, the solenoid valve of high pressure and high flow rate can be reliably controlled. At this time, it is preferable that the magnetic reinforcing grooves 246 are formed in a tapered shape so as to improve the concentration of the magnetic field.

The plate 250 is for inducing a magnetic force together with the core 240. The plate 250 is in the shape of a disk having a predetermined thickness, and at the center thereof, an insertion hole into which the lower end of the core 240 is inserted is formed.

The rod 260 serves to move the spool 120 when the solenoid 200 is operated. The rod 260 is a metal rod having a predetermined length and is coupled to penetrate the core 240. At this time, the upper end of the rod 260 is spaced apart from the spool 120, and the lower end thereof is contacted with the plunger 270.

The plunger 270 is a movable iron core reciprocating by a magnetic field generated by the coil 230. A passage 272 is formed in the plunger 270 so as to penetrate the plunger 270 up and down. The passage 272 allows the fluid above the plunger 270 to move downward and the fluid under the plunger 270 to move upward when the plunger 270 reciprocates. At this time, the passage 272 is eccentric by a predetermined distance from the center of the plunger 270 in order to prevent the passage 272 from being closed by the contact with the rod 260.

The lower surface of the plunger 270 is curved and makes point contact with the bottom of the case 210. When the plunger 270 and the case 210 are in point contact, the flow of the magnetic field directly coupled to the plunger 270 through the bottom of the case 210 is blocked, so that the plunger 270 can smoothly move. Further, even if the bottom of the case 210 is slightly inclined, it does not affect the inclination of the plunger 270, so that the frictional resistance due to the inclination of the plunger 270 can be solved.

The connector 280 is a means for applying power to the solenoid 200. A plurality of terminals 282 are provided inside the connector 280.

Although the structure of the solenoid 200 is illustrated as described above in the present embodiment, it is not necessarily limited to this, and a solenoid having various structures may be applied.

The operation of the solenoid valve will be described with reference to FIGS. 1 and 4. FIG.

1 is a state in which power is not applied to the solenoid 200. In Fig. The normal spool 120 without power is lowered by the elastic force of the spring 140 so as to connect the supply port 152 and the control port 154 and at the same time to connect the control port 154 and the drain port 156 Disconnect the connection.

The hydraulic pressure S supplied through the supply port 152 is discharged through the control port 154 and a part of the hydraulic pressure C discharged through the control port 154 is supplied to the feedback flow path 122, (F). Therefore, the spool 120 is urged by the urging force of the spring 140 (downward support force of the spool 120) and the force of the feedback chamber 168 (upward support force of the spool 120) At this time, since the elastic force of the spring 140 is greater than the pressure of the feedback chamber 168, the spool 120 is lowered to a specific position. That is, the spool 120 is lowered to a specific position through a balance between the pressure of the spring 140 and the pressure of the feedback chamber 168.

When the power is applied in the above-described state, the plunger 270 rises due to the magnetic field generated by the coil 230, and the rod 260, which is in contact with the plunger 270, lifts the spool 120. The second land 174 blocks the supply port 152 and the control port 154 when the spool 120 rises and the operation groove 184 connects the control port 154 and the drain port 156 . At this time, the feedback pressure F supplied through the feedback flow path 122 is applied to the surface pressure grooves 182 to act to raise the spool 120 (see FIG. 4).

Accordingly, when power is applied to the solenoid 200, the hydraulic pressure C is supplied through the control port 154 and the supplied hydraulic pressure C is discharged to the outside through the drain port 158.

While the present invention has been particularly shown and described with reference to preferred embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. Those skilled in the art will understand. Therefore, the scope of protection of the present invention should be construed not only in the specific embodiments but also in the scope of claims, and all technical ideas within the scope of the same shall be construed as being included in the scope of the present invention.

100: valve 110: holder
120: spool 122: feedback channel
124: first feedback port 126: second feedback port
128: guide pin 130: adjusting screw
140: spring 152: supply port
154: control port 156: drain port
162: supply chamber 164: control chamber
166: drain chamber 166: feedback chamber
172: first land 174: second land
176: third land 182: surface pressure groove
184: operating groove 188: seat groove
192: Notch groove 200: Solenoid

Claims (8)

A solenoid valve comprising a valve for interrupting the flow of fluid and a solenoid for actuating the valve,
Wherein the valve comprises:
A pipe-shaped holder extending in one direction;
A port formed at an upper end of the holder, a control port positioned at a lower portion of the drain port, and a supply port located at a lower portion of the control port;
A chamber formed in the upper end of the holder and composed of the drain port, the control port, the drain chamber respectively connected to the supply port, the control chamber, the feed chamber, and the feedback chamber located below the feed chamber;
A spool in which a feedback channel connecting the control chamber and the feedback chamber is formed, the spool being movably installed in the holder and having a land formed on an outer circumferential surface for connecting or disconnecting the port; And
And a spring for supporting the spool so as to be elastically biased downward,
The spool is lowered by the spring when the power is not applied to connect the supply port and the control port, and when the power is applied, the solenoid is actuated to raise the spool, thereby disconnecting the connection between the supply port and the control port The solenoid valve.
The method according to claim 1,
Wherein the spool includes a first land formed on an upper end of the spool, a second land formed on an end of the spool, and a third land formed on a lower end of the spool,
A lower portion of the second land and an upper portion of the third land are positioned on the feedback chamber and a surface pressure groove in which the pressure of the fluid introduced into the feedback chamber is applied is formed between the second land and the third land Features a solenoid valve.
The method of claim 2,
Wherein the second land is formed to have a larger diameter than the third land, the upper surface of the surface-pressing groove is formed to have a larger area than the lower surface,
Wherein when a fluid flows into the feedback chamber, hydraulic pressure is applied to the upper and lower surfaces of the surface pressure grooves, and a larger pressure is applied to the upper surface side of the surface pressure grooves to raise the spool.
The method of claim 3,
And an operating groove is formed between the first land and the second land, the operating groove connects the control port to the supply port when the spool descends, and the control port is connected to the drain port Wherein the solenoid valve is connected to the solenoid valve.
The method of claim 4,
And a second feedback port is formed at a lower end of the spool to connect the feedback channel to the feedback chamber. The solenoid valve according to claim 1, .
The method of claim 5,
Wherein the feedback passage extends from the lower end to the upper end of the holder and opens through the upper surface of the holder, and a guide pin for guiding the movement of the holder is coupled to the opened upper portion of the feedback passage.
The method of claim 6,
Wherein the guide pin includes a small diameter portion inserted into the feedback passage and a large diameter portion formed on the small diameter portion,
And the spring is provided on the large-diameter portion.
The method of claim 7,
And a notch groove connecting the supply port and the control port is formed around the upper end of the second land.

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