KR20170115654A - Solenoid valve - Google Patents

Abstract

The present invention relates to a solenoid valve capable of preventing deformation due to heat and performance deterioration, and includes a valve for interrupting the flow of fluid and a solenoid for operating the valve. The solenoid includes a case coupled to one end of the valve, a bobbin accommodated in the case, a core interposed between the valve and the bobbin, and an elastic member provided between the bobbin and the core. do. At this time, the elastic member elastically supports the bobbin toward the other end side of the case to minimize deformation by heat.

Description

SOLENOID VALVE

The present invention relates to a solenoid valve, and more particularly, to a solenoid valve capable of preventing deformation due to heat and performance deterioration.

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.

Korean Patent Registration No. 10-1574999 (Jan. 1, 2015) discloses a solenoid valve applied and registered by the present applicant.

The solenoid valve is a hydraulic control solenoid valve for controlling the hydraulic pressure (oil pressure) of the automatic transmission, and includes a valve for controlling the hydraulic pressure and a solenoid for operating the valve. The valve includes a holder having a plurality of ports formed therein, and a spool for connecting or disconnecting a plurality of ports is provided in the holder. The solenoid includes a bobbin having a coil wound around its outer circumference. A core and a yoke are coupled to both ends of the bobbin, and a plunger and a rod are installed inside the bobbin.

The oil temperature of the automatic transmission rises to 150 degrees while the vehicle is running. When the solenoid valve described above is continuously exposed to high-temperature oil, there is a fear of causing thermal deformation. In particular, the bobbin provided inside the solenoid is made of synthetic resin unlike other parts, so that it is very vulnerable to heat and is easily deformed.

The thermal deformation of the solenoid valve affects the stroke of the spool, and when the stroke of the spool is changed, the opening amount of each port changes and the flow of the oil can not be completely blocked or connected. In addition, the hydraulic pressure discharged from the solenoid valve can not be controlled, which adversely affects the performance of the automatic transmission.

Korean Registered Patent No. 10-1574999 (Dec. 01, 2015)

SUMMARY OF THE INVENTION It is an object of the present invention to provide a solenoid valve capable of preventing deformation due to heat and performance deterioration.

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 solenoid includes a case coupled to one end of the valve, a bobbin accommodated in the case, a core interposed between the valve and the bobbin, and an elastic member provided between the bobbin and the core. do. At this time, the elastic member elastically supports the bobbin toward the other end side of the case to minimize deformation by heat.

According to the present invention, the elastic member is provided between the bobbin and the core to elastically support the bobbin, so that the bobbin is not deformed even if it is exposed to the high-temperature oil for a long time. Therefore, since the stroke of the spool is always constant and each port is opened / closed in proportion to the movement of the spool, the flow of oil can be completely blocked or connected, and the hydraulic pressure discharged to the outside can be effectively controlled.

1 is a sectional view of a solenoid valve according to an embodiment of the present invention;
2 is an enlarged view of a solenoid of a solenoid valve according to an embodiment of the present invention;
3 illustrates a wave spring of a solenoid according to one embodiment of the present invention.
4 is a view showing a bobbin provided with elastic pieces among solenoid valves according to an embodiment of the present invention.
5 is a sectional view of a solenoid valve according to another embodiment of the present invention.
6 is an enlarged view of the portion "A" in Fig. 5; Fig.
7 is a view showing a modification of a solenoid valve according to another embodiment of the present invention.

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. (See Fig. 1).

The valve 100 is a portion mounted on a valve body (not shown) having a plurality of flow paths. A spool 120 movably installed in the holder 110; a cap 130 coupled to an upper portion of the spool 120; a spool 120 connected to the spool 120; 130, which are spaced apart from each other.

The holder 110 is in the form of a hollow pipe. A plurality of ports 152 to 158 are formed on an outer circumferential surface of the holder 110 and a plurality of chambers 162 to 168 are formed in the holder 110 through a plurality of ports 152 to 158. For example, a supply port 152 for supplying oil from the outside is formed at the end of the holder 110, and a control port 154 for discharging the controlled oil at a predetermined pressure is formed at an upper portion of the supply port 152 do. A discharge port 156 for discharging the oil introduced through the control port 154 to the outside is formed at a lower portion of the supply port 152. An upper portion of the control port 154 A feedback port 158 is formed to feed back a part of the feedback signal.

The spool 120 is a rod having a predetermined length. A seating groove 122 is formed in the upper surface of the spool 120 to receive a spring 140 and an operating groove 124 for pressing the oil filled in the chamber 150 is formed on the outer circumference of the spool 120. The spool 120 of this shape changes the volume of the chambers 162 to 168 during its movement or opens and closes the ports 152 to 158. Thus, the oil filled in the chambers 162 to 168 is controlled to a predetermined pressure and then discharged through the ports 152 to 158. [

The cap 130 is coupled to the upper end of the holder 110 to seal the open top of the holder 110. At this time, the cap 130 is hollow and press-fitted into the upper end of the holder 110, and a mounting protrusion 132 for mounting the spring 140 protrudes on the lower surface of the cap. When the cap 130 is press-fitted into and fixed to the upper end of the holder 110, there is no clearance due to the screw connection, which is advantageous in setting the hydraulic pressure of the solenoid valve. In addition, since the joining operation for preventing the clearance after the screw coupling can be omitted, the work is easy.

On the other hand, the spring 140 is installed to be inserted into the seating groove 122 in a state of being fitted in the mounting projection 132. The spring 140 elastically supports the spool 120 downward so that the control port 154, which is not normally powered, remains closed. In addition, it absorbs the impact generated when the spool 120 moves.

Although the structure of the valve 100 is illustrated in the present embodiment as described above, it is needless to say that the valve 100 having various structures may be applied.

The solenoid 200 is a means for operating the valve 100 upon power-on. 1 and 2, 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 plate 240 coupled to the bobbin 220 and penetrating the bobbin 220 and coupled to the lower portion of the bobbin 220 and inserted into the lower end of the core 240, A plunger 270 movably installed inside 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 222 and 224 projecting 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 solenoid 200 according to the present embodiment further includes an elastic member 290 for preventing the bobbin 220 from being thermally deformed by the high temperature oil. The elastic member 290 is interposed between the upper flange 222 of the bobbin 220 and the flange 242 of the core 240 to elastically support the bobbin 220 downward to prevent thermal deformation of the bobbin 220 .

The elastic member 290 should be able to press the bobbin 220 evenly. To this end, the wave spring 290 shown in Fig. 3 may be used, or the elastic piece 290 shown in Fig. 4 may be used. The elastic piece 290 is composed of an inclined member 292 protruding from the upper flange 222 of the bobbin 220 and a contact member 294 formed at the end of the inclined member 292. The resilient pieces 290 are composed of a plurality of radially arranged upper flanges 222. The elastic pieces 290 may be inclined in the same direction or may be inclined in directions opposite to each other.

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 222 upon engagement with the bobbin 220 and seated in the latch 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 insertion hole 252 of the plate 250.

A magnetic force strengthening groove 248 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 248. [ Therefore, the magnetic field generated in the coil 230 is concentrated in the magnetic force strengthening groove 248, so that sufficient magnetic force is secured to easily attract the plunger 270. 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 groove 248 is 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 252 through 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 in contact with the spool 120, and the lower end thereof is in contact 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.

The elastic member 290 is installed in the bobbin 220 and the core 240 to prevent the bobbin 220 from being deformed even if the solenoid valve is exposed to the high temperature oil for a long time. That is, by suppressing deformation of the bobbin 220 by using the elastic member 290, the performance of the solenoid valve is prevented from deteriorating.

5 shows a solenoid valve according to another embodiment of the present invention.

As shown in FIG. 5, the solenoid valve includes a valve 300 for interrupting the entry and exit of oil, and a solenoid 400 for actuating the valve 300.

The valve 300 includes a holder 310, a spool 320 movably installed in the holder 310, a cap 330 coupled to an upper portion of the spool 320, And a spring 340 interposed between the spring 330 and the spring 340.

The cap 330 of the present embodiment is an adjustment screw screwed to the upper end of the holder 110 so as to adjust the elasticity of the spring 340. However, the cap 330 is not necessarily limited to this, Of course, can be applied.

The solenoid 400 includes a case 410, a bobbin 420 installed inside the case 410, a coil 430 wound around the outer circumferential surface of the bobbin 420, A plate 460 coupled to a lower portion of the bobbin 420 and inserted into the lower end of the core 440, a rod 460 passing through the upper portion of the core 440, A plunger 470 movably installed inside the core 440 and a connector 480 provided at the lower portion of the case 410. [

The lower end of the spool 320 provided inside the holder 310 is in contact with the upper end of the core 440 and the upper end of the rod 460 provided inside the core 440 is spaced apart from the lower end of the spool 320 Respectively. That is, a clearance (G in FIG. 6) is formed between the spool 320 and the rod 460.

The solenoid valve according to the present embodiment is a structure for preventing the performance of the solenoid valve from deteriorating due to the thermal deformation of the bobbin 420 unlike the above embodiment. The gap between the spool 320 and the rod 460 G to accommodate thermal deformation of the bobbin 420. That is, when the solenoid valve is exposed to the high temperature oil for a long time, the bobbin 420 is deformed (extended in the longitudinal direction). Since the lower end of the spool 320 contacts the upper end of the core 440, The core 440, the holder 310, the spool 320, the cap 330, and the spring 340 are raised together. Therefore, the opening amount of each port formed in the holder 310 and the elastic force of the spring 340 are not changed, so that the performance of the solenoid valve is not affected.

On the other hand, even if the temperature around the solenoid valve is lowered, the gap G is provided between the spool 320 and the rod 460 even if the bobbin 420 contracts, so that the opening amount of the port and the elastic force of the spring 340 are maintained.

7 shows a structure in which a clearance G is provided inside the solenoid valve to accommodate thermal deformation of the bobbin 420 and a gap G is provided between the spool 320 and the plunger 470. That is, the valve 300 and the solenoid 400 are formed. The spool 320 provided in the holder 310 extends through the core 440 to the plunger 470. The lower end of the large diameter portion 322 is in contact with the upper end of the core 440 and the lower end of the large diameter portion 322 is in contact with the small diameter portion 324 Is spaced apart from the plunger 470. Therefore, a clearance G is provided between the spool 320 and the plunger 470.

When the solenoid valve of the above-described structure is exposed to the high temperature oil for a long time, the bobbin 420 is deformed (extended in the longitudinal direction). Since the lower end of the spool 320 (large diameter portion 322) is in contact with the upper end of the core 440, The holder 310, the spool 320, the cap 330, and the spring 340 are lifted together by an amount corresponding to the elongation of the spring 420. Therefore, the opening amount of each port formed in the holder 310 and the elastic force of the spring 340 are not changed, so that the performance of the solenoid valve is not affected.

On the other hand, even when the temperature around the solenoid valve is lowered, the gap G is provided between the spool 320 and the plunger 470 even if the bobbin 420 contracts, so that the opening amount of the port and the elastic force of the spring 340 are maintained.

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 130: cap
140: spring 200: solenoid
210: Case 220: Bobbin
230: coil 240: core
250: plate 260: rod
270: plunger 280: connector
290: elastic member

Claims (8)

A solenoid valve comprising a valve for interrupting the flow of fluid and a solenoid for actuating the valve,
The solenoid includes:
A case coupled to one end of the valve;
A bobbin accommodated in the case;
A core interposed between the valve and the bobbin; And
And an elastic member provided between the bobbin and the core,
Wherein the elastic member elastically supports the bobbin toward the other end side of the case to minimize deformation due to heat.
The method according to claim 1,
Wherein the bobbin is spool-shaped at both ends with a flange protruding therefrom,
Wherein the core has a shape in which a flange protrudes from only one end of a body inserted into the bobbin,
Wherein the elastic member is interposed between a flange of the bobbin and a flange of the core.
The method of claim 2,
Wherein the elastic member is a wave spring.
The method according to claim 1,
Wherein the bobbin is spool-shaped at both ends with a flange protruding therefrom,
Wherein the core has a shape in which a flange protrudes from only one end of a body inserted into the bobbin,
Wherein the elastic member is an elastic piece formed on the flange of the bobbin.
The method of claim 4,
Wherein the elastic piece comprises an inclined member protruding from a flange of the bobbin and a contact member formed at an end of the inclined member,
Wherein the resilient piece comprises a plurality of radially arranged flanges along the flange of the bobbin.
The method according to any one of claims 1 to 5,
Wherein the valve comprises:
A pipe-shaped holder having a plurality of ports formed therein;
A cap coupled to one end of the holder;
A spool movably installed in the holder; And
And a spring interposed between the cap and the spool,
Wherein the cap is hollow and is press-fitted into one end of the holder.
A solenoid valve comprising a valve for interrupting the flow of fluid and a solenoid for actuating the valve,
The valve includes a pipe-shaped holder having a plurality of ports formed therein, a cap coupled to one end of the holder, a spool movably installed in the holder, and a spring interposed between the cap and the spool ,
The solenoid includes a case coupled to a lower end of the holder, a bobbin installed inside the case, a core coupled to penetrate the bobbin, a plunger movably installed in the core, And a rod in contact with the spool,
Wherein a lower end of the spool is in contact with an upper end of the core and is spaced apart from an upper end of the rod.
A solenoid valve comprising a valve for interrupting the flow of fluid and a solenoid for actuating the valve,
The valve includes a pipe-shaped holder having a plurality of ports formed therein, a cap coupled to one end of the holder, a spool movably installed in the holder, and a spring interposed between the cap and the spool ,
The solenoid includes a case coupled to a lower end of the holder, a bobbin installed inside the case, a core coupled to penetrate the bobbin, and a plunger movably installed in the core and moving the spool ≪ / RTI &
Wherein the lower end of the spool comprises a large diameter portion and a small diameter portion, the large diameter portion is in contact with an upper end of the core, and the lower end of the small diameter portion is spaced apart from the plunger.

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