KR101486141B1 - solenoid valve - Google Patents

Abstract

The present invention relates to a solenoid valve, in which a lower portion of a flange (1) constituting a flow path control portion is integrally formed by over-molding an upper magnetic disc (5) 1 between the lower coupling plate 1g and the coil assembly 7 of the magnetic path portion.
Accordingly, since there is no gap between the flow path control portion and the magnetic path portion, foreign substances are prevented from flowing into the flow path portion, so that deterioration of the operating performance of the armature 8 due to foreign matter can be prevented. Loss can be prevented.

Description

A solenoid valve

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a solenoid valve, and more particularly, to a hydraulic control solenoid valve capable of supplying or interrupting an operating hydraulic pressure depending on whether power is supplied or not.

Generally, a solenoid valve is used in an engine and an automatic transmission of an automobile to control the supply and the injection of fuel, or to control the operation of an actuator for a shift control such as a clutch and a brake.

Normally, the solenoid valve is constituted by a solenoid valve which is supplied with electric power to generate a magnetic force, and a flow control unit which operates component parts such as a rod by magnetic force generated in the magnetic path unit to open or shut off the supply passage of the operating oil.

An example of a conventional solenoid valve is disclosed in Korean Patent Publication No. 10-1158423 (Kepco, Inc., a hydraulic solenoid valve for an automatic transmission of a vehicle, hereinafter referred to as reference 1).

1, a rod 12 is inserted into a flange 10 formed with hydraulic oil inlet / outlet holes to constitute a flow control unit, and a coil (not shown) is inserted into the housing 28 16 and an armature 14 are installed to form a magnetic circuit.

The housing 28 is connected to one end of the flange 10 and a cylindrical pole body 22 is installed inside the bobbin 18 wound with the coil 16. The pole body 22, The armature 14 can move linearly in the axial direction.

The core 20 is inserted into the end of the bobbin 18 on the side of the flange 20 and one end of the rod 12 is extended and protruded through a guide hole formed at the center of the core 20, As shown in Fig.

Therefore, when a power supply is supplied to the coil 16 and a magnetic path connecting the bobbin 18 and the core 20 is formed, the armature 14 moves toward the core 20 to push the rod 12, As the rod 12 moves, the flow path in the flange 10 is opened to the connected actuator and the working hydraulic pressure is transmitted.

When the supply of power to the coil 16 is stopped, the rod 12 is returned to its original position due to the restoring force of the coil spring installed at the other end of the rod 12, It is pushed by the rod 12 so that the armature 14 also returns to its original position.

In the conventional solenoid valve as described above, the flange 10 is simply press-fitted into the housing 28, and the flange 10, the bobbin 18, and the core 20 interposed therebetween are both made of metal There is a problem that foreign substances are introduced from outside through fine gaps therebetween.

Therefore, the foreign matter is fixed to the surface of the armature 14 and the pole body 22, and the movement of the armature 14 is not smoothly performed. As a result, the operating performance of the solenoid valve is lowered. As a result, Resulting in the failure of an operating device (such as an automatic transmission).

In addition, the operating oil existing in the inner space of the magnetic path portion, that is, the moving space of the armature 14, leaks to the outside of the solenoid valve through the gap, so that it is difficult to apply to the unsealed space.

In addition, since the core 20 is made up of independent parts, there is a problem that the number of assembly operations increases when the solenoid valve is assembled.

In the case of an engine or an automatic transmission, most of the parts are made of an iron-based or aluminum-based material, and fine burrs, chips, etc. generated therefrom Is introduced into the magnetic path portion through the guide hole of the core 20 and is fixed to the armature 14 and the pole body 22 to thereby hamper the operation of the armature 14 .

SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention to provide a solenoid valve that prevents foreign matter from entering the inside of the magnetic path portion and prevents the solenoid valve from failing due to foreign matter adherence, And it is an object of the present invention to provide a solenoid valve capable of preventing contamination around the mounting portion, preventing loss of operating oil, and reducing the number of assembling operations by integrating the flange and the parts of the magnetic path portion.

According to an aspect of the present invention,

A flow control unit having a flange having a flow path formed therein, a ball for opening and closing a hydraulic oil supply hole of the flange, and a rod for operating the ball and opening and closing a connection hole between the hydraulic control hole and the hydraulic pressure discharge hole of the flange;

A sleeve inserted into the inner diameter portion of the coil assembly and an armature, a spindle inserted into the inner diameter portion of the sleeve to push the rod by the operation of the armature, And a magnetic path portion provided at the lower portion and having an upper magnetic disk and a lower magnetic disk, which form a magnetic force,

And the lower portion of the flange is overmolded integrally with the upper magnetic disk and the sleeve.

In addition, an upper coupling plate and a lower coupling plate are formed on the lower portion of the flange so as to be in close contact with both side surfaces of the upper magnetic disk.

The upper coupling plate and the lower coupling plate are integrally connected through a coupling hole formed in the upper magnetic disk.

In addition, the upper and lower coupling plates are respectively provided with engaging protrusions, and the engaging protrusions of the engaging protrusions are closely inserted into the grooves formed on the outer circumferential surface of the sleeve.

Further, a seal ring is interposed between the lower coupling plate and the coil assembly.

In addition, the sleeve is press-fitted into the coupling hole of the upper magnetic disk, and a stopper is formed on the outer circumferential surface of the sleeve so as to limit the depth of the insertion.

A disc groove is formed at an end of the flange, and a disc spring is installed in the disc groove to elastically support the ball against the operating direction of the armature.

A disc filter is formed in the end portion of the flange, and a disc filter is provided in the disc groove to filter impurities of the operating oil supplied into the flow path of the flange.

According to the present invention as described above, the upper magnetic disc and the sleeve are integrally coupled to the flange during injection molding of the flange, and a seal ring is provided between the flange and the coil assembly, thereby forming a gap between the flange and the upper magnetic disc, There is no gap between the flange and the coil assembly, and foreign matter is prevented from flowing into the magnetic path portion through the gap.

In addition, a disk filter is provided in the operating fluid supply port of the flange to filter out foreign matter contained in the operating fluid supplied to the solenoid valve, thereby preventing foreign matter from flowing into the magnetic path portion.

Accordingly, foreign matter adhesion on the armature operating surface is prevented, and the armature can be normally operated, so that the operation of the solenoid valve can be normally performed. That is, failure of the hydraulic device due to failure of the solenoid valve can be prevented.

In addition, since there is no gap between the flange, the sleeve and the upper magnetic disc, and the gap between the flange and the coil assembly as described above, leakage does not occur from the inside of the magnetic path portion to the outside, thereby preventing contamination of the solenoid valve mounting portion, There is an effect that loss of operating oil is prevented.

Further, since the upper magnetic disk and the sleeve are integrated with the flange, it is not necessary to separately assemble them when assembling the solenoid valve, thereby reducing the number of assembling operations.

1 is a cross-sectional view of a solenoid valve according to the prior art;
2 is a sectional view of a solenoid valve according to the present invention;
3 is a plan view and a sectional view taken along the line II of the disk spring which is a constitution of the present invention.
4 is a perspective view of a disk filter which is an embodiment of the present invention.

Hereinafter, a solenoid valve according to the present invention will be described in detail with reference to the accompanying drawings.

FIG. 2 is a cross-sectional view of a solenoid valve according to the present invention. The solenoid valve according to the present invention includes a flow control unit for opening and closing a flow path of operating oil, and a magnetic path portion connected to one end of the flow control unit, .

The flow control unit includes a flange 1 having flow passages and hydraulic oil inlet / outlet holes formed therein and a rod 2 provided so as to be linearly movable in the longitudinal direction inside the flange 1.

The flange 1 is formed in a cylindrical shape and has a plurality of outer diameters in a stepped shape, and a hydraulic control hole 1a and a hydraulic pressure discharge hole 1b are formed in a cylindrical radial direction in the upper step portion and the intermediate step portion, respectively .

A hydraulic oil supply hole 1c connected to the hydraulic control hole 1a is formed at an upper end of the flange 1 and an upper portion of the hydraulic oil supply hole 1c is formed by expansion molding to form a ball seat portion 1ca And a ball 3 is provided on the ball receiving portion 1ca.

The lower portion of the ball seating portion 1ca is formed of an inclined valve face 1cb and the hydraulic oil supply hole 1c is opened or closed depending on whether the valve face 1cb and the ball 3 are in contact with each other.

A connecting hole 1d and a guide hole 1e are formed on the coaxial line with the hydraulic oil supply hole 1c at the intermediate step portion and the lower step portion of the flange 1, And connects the oil pressure control hole 1a and the oil pressure discharge hole 1b.

The rod 2 is inserted into the guide hole 1e so that the outer diameter surface of the rod 2 and the inner diameter surface of the guide hole 1e are in sliding contact with each other so that the rod 2 can be linearly moved up and down in a stable manner Respectively.

A pin 2a whose diameter is smaller than that of the lower portion is formed on the upper portion of the rod 2. The pin 2a is connected to the ball 2 via the connection hole 1d and the hydraulic oil supply hole 1c, 3).

The rod 2 is provided with an inclined valve face 2b around the lower end of the pin 2a and a valve face 1da inclined at the same angle to the lower end of the connecting hole 1d, . Therefore, the connection hole 1d is opened or closed depending on whether the valve surfaces 1da and 2b are in contact with each other.

In addition, a sealing groove is formed in the outer peripheral surface of each step portion of the flange 1, and seal rings 4a, 4b, and 4c are provided in the respective sealing grooves. These seal rings 4a, 4b, and 4c serve to maintain the airtightness between the hydraulic control hole 1a and the hydraulic pressure exhaust hole 1b.

On the other hand, on the lower side of the flange 1, a disk-shaped upper magnetic disk 5 constituting the magnetic path portion and a cylindrical sleeve 6 are integrally coupled.

The upper magnetic disc (5) and the sleeve (6) are assembled before being coupled to the flange (1). That is, the sleeve 6 is press-fitted into the circular coupling hole 5a formed at the center of the upper magnetic body disk 5 and assembled with each other.

A stopper 6a is formed on the outer circumferential surface of the sleeve 6 to keep the indentation depth constant when the sleeve 6 is pressed into the engaging hole 5a of the upper magnetic disk 5. [

The flange 1 is formed by injection molding with a plastic material. After the upper magnetic disc 5 and the sleeve 6 assembled as described above are linearly arranged in the mold, the plastic material is injected into the mold, Is over-molded on the upper magnetic disc 5 and the sleeve 6. [ So that the upper magnetic disc 5 and the sleeve 6 are integrally coupled to the flange 1.

A plurality of coupling holes 5b are formed in the upper magnetic disk 5 on the same radial line at regular intervals and a plastic material is inserted into the coupling holes 5b during injection molding, And the lower portion of the flange 1 is over-molded in such a manner as to cover the upper surface and the lower surface of the upper magnetic disk 5.

That is, an upper coupling plate 1f and a lower coupling plate 1g, which are in close contact with the upper surface and the lower surface of the upper magnetic disc 5, are formed, and the upper coupling plate 1f and the lower coupling plate 1g, And is integrally connected through the hole 5b.

Grooves 6b and 6c are formed on the outer circumferential surface of the sleeve 6 at positions corresponding to the upper and lower coupling plates 1f and 1g, 6b and 6c in the upper and lower engaging plates 1f and 1g so that engaging protrusions 1fa and 1ga are formed in the upper engaging plate 1f and the lower engaging plate 1g to be inserted into the recesses 6b and 6c.

The coupling between the flange 1 and the upper magnetic disc 5 and the sleeve 6 with the structure described above makes the flange 1, the upper magnetic disc 5 and the sleeve 6 integral with each other, There is no gap between them.

The magnet assembly includes a coil assembly 7 that forms a magnetic force when a power is supplied, and an armature 8 that linearly moves within the magnet assembly when the coil assembly 7 is magnetized.

The coil assembly 7 is installed in a state in which the sleeve 6 is inserted into the inner diameter of the bobbin 7a when the coil 7b is wound on the outer periphery of the bobbin 7a.

The armature 8 is inserted into a lower portion of the inner diameter of the bobbin 7a and a spindle 9 is provided between the armature 8 and the rod 2. That is, the spindle 9 is inserted into a guide hole 6d formed through the sleeve 6 in the axial direction (longitudinal direction), and both ends of the spindle 9 are connected to the rod 2 and the armature 8 And abuts the corresponding end.

A lower magnetic disc 10 is provided under the coil assembly 7 and a guide hole 10a having the same diameter as the inner diameter of the bobbin 7a is formed inside the lower magnetic disc 10 So that it is possible to guide upward and downward linear movement of the armature 8.

The flange 1 (integrated state of the upper magnetic disk 5 and the sleeve 6), the coil assembly 7, the armature 8 and the lower magnetic disk 10 are both made of a metal And is inserted into the housing (11).

That is, the flange 1, the coil assembly 7, the armature 8, and the lower magnetic body disk 10 are sequentially inserted into the housing 11.

An upper locking piece 11a is formed at an upper end of the housing 11 to cover the outer circumferential end of the upper magnetic disc 5 and a lower locking piece 11b is formed at a lower end of the lower locking piece 11b, .

Therefore, when the flange 1, the coil assembly 7, the armature 8 and the lower magnetic disk 10 are inserted into the housing 11 and the lower engaging piece 11b is bent at right angles, And the coupling of the magnetic path portions is completed.

A connector C electrically connected to the coil 7b is provided on the outer side of the housing 11. The connector C may be integrally formed with a plastic coil housing 7c surrounding the outer periphery of the coil assembly 7. [

On the bottom surface of the lower coupling plate 1g of the flange 1, a concave groove is formed so that a seal ring can be installed, and a seal ring 12 is inserted into the groove. The seal ring 12 is in close contact with the upper surface of the coil assembly 7 to seal the gap between the flange 1 and the coil assembly 7 when the solenoid valve assembly is completed.

A disc-shaped disc groove 1h is formed on the top of the ball receiving portion 1ca at the upper end of the flange 1. A disc spring 13 and a disc filter 14 are inserted into the disc groove 1h. Are sequentially inserted and installed.

3, the disk spring 13 has a through hole 13a formed in a disk-shaped body, and a plurality of elastic pieces 13b are centered on the inner circumferential surface of the through hole 13a at regular intervals As shown in Fig.

Therefore, in the assembled state, the elastic piece 13b is brought into contact with the upper surface of the ball 3, and the ball 3 is elastically supported downward corresponding to the upward movement of the ball 3. [

4, the disc filter 14 has a through hole 14a formed in a circular body, and a plurality of partition walls 14b that cross the through hole 14a in the radial direction are formed And a filtering net 14c for blocking the through hole 14a.

The sieve 14c has a mesh size of about 100 meshes (about the number of meshes in a range of 1 inch), and can filter out fine particles contained in the operating oil.

Now, the operation of the solenoid valve according to the present invention will be described.

The state shown in Fig. 2 is a state in which the solenoid valve is off, and the ball 3 is lowered by the disc spring 13 to block the hydraulic oil supply hole 1c.

Therefore, the hydraulic pressure is not transmitted through the hydraulic control hole 1a, so that the hydraulic actuators connected to the solenoid valve are not operated.

When the coil 7b is supplied with power (the solenoid valve is on), the armature 8 is raised around the upper magnetic disk 5, the coil assembly 7, and the lower magnetic disk 10 A moving magnetic field is formed.

The armature 8 pushes up the spindle 9 and the spindle 9 pushes the rod 2 so that the pin 2a of the rod 2 pushes up the ball 3, 1c are opened. At this time, the valve face 2b of the rod 2 is brought into close contact with the valve face 1da of the connecting hole 1d of the flange 1 so that the connecting hole 1d is closed, .

Accordingly, the hydraulic fluid introduced into the hydraulic fluid supply hole 1c is supplied through the hydraulic control hole 1a, thereby actuating the hydraulic actuators connected to the solenoid valve.

The elastic piece 13b of the disc spring 13 pushes the ball 3 downward and the ball 3 is pulled out of the pin 2a The rod 2, the spindle 9 and the armature 8 are sequentially pushed back to the original position.

Therefore, the ball 3 is brought into close contact with the valve surface 1cb to cut off the supply of the working oil through the hydraulic oil supply hole 1c and the valve surface 1da of the connection hole 1d and the valve surface 1d of the rod 2 The operating oil of the hydraulic control hole 1a is discharged to the hydraulic pressure discharge hole 1b through the connecting hole 1d and the hydraulic pressure is no longer applied to the hydraulic actuators connected to the solenoid valve The operation of the hydraulic actuators is stopped.

Meanwhile, in the solenoid valve according to the present invention, there is no gap in the connection portion between the flow path control portion and the magnetic path portion. That is, since the flange 1 is overmolded integrally with the upper magnetic disc 5 and the sleeve 6, the distance between the flange 1 and the upper magnetic disc 5, between the flange 1 and the sleeve 6 And there is no gap between the upper magnetic body disk 5 and the sleeve 6 for connecting the magnetic path portion and the outer space.

Particularly, the connection portion between the upper coupling plate 1f and the lower coupling plate 1g of the flange 1 is completely and completely filled in the coupling hole 5b of the upper magnetic disc 5, and the upper coupling plate 1f And the engaging protrusions 1fa and 1ga of the lower engaging plate 1g are closely inserted into the recesses 6b and 6c of the sleeve 6 so that the flange 1, the upper magnetic disc 5, The clearance is more reliably prevented from occurring between the sleeves 6.

 Therefore, foreign matter infiltration from the outside through the flange 1, the upper magnetic disc 5, and the sleeve 6 and the leakage of the operating oil from the inside are prevented.

Since the seal ring 12 provided on the lower coupling plate 1g of the flange 1 is in close contact with the upper surface of the coil assembly 7, a gap between the lower coupling plate 1g and the coil assembly 7 There is no gap. Therefore, foreign matter penetration from outside through this portion and leakage of operating oil from the inside are prevented.

The disk filter 14 is installed at the upper end of the flange 1 so that foreign matter contained in the operating oil supplied from the operating oil supply source to the inside of the solenoid valve can be filtered in advance.

Therefore, it is possible to block the penetration of the foreign matter introduced into the inside of the solenoid valve, in particular the operating space of the armature 8, together with the operating oil.

As described above, since the solenoid valve according to the present invention is prevented from penetrating the inner space of the magnetic path portion, that is, the working space of the armature 8, foreign matter is adhered between the armature 8 and the coil assembly 7 So that deterioration of the operating performance of the armature 8 due to foreign matter adhesion is prevented.

Therefore, it is possible to prevent the malfunction of the solenoid valve due to the deterioration of the operating performance of the armature 8 and the malfunction of the hydraulic actuator connected to the solenoid valve.

In addition, since the sealing structure as described above prevents the hydraulic oil from leaking from the operating space of the armature 8 to the outside of the solenoid valve, contamination of the solenoid valve itself and the peripheral portion due to leakage of hydraulic oil is prevented, Is prevented.

Since the upper magnetic disc 5 and the sleeve 6 are integrated with the flange 1 as described above, it is not necessary to separately assemble the upper magnetic disc 5 and the sleeve 6 during assembly of the solenoid valve, Therefore, the number of assembly operations of the solenoid valve is advantageously reduced.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It is understandable. Accordingly, the true scope of the present invention should be determined by the following claims.

1: Flange 2: Load
3: balls 4a, 4b, 4c: sealing ring
5: Upper magnetic disc 6: Sleeve
7: coil assembly 8: armature
9: spindle 10: lower magnetic disk
11: housing 12: sealing ring
13: disk spring 14: disk filter

Claims (8)

A flow control unit having a flange having a flow path formed therein, a ball for opening and closing a hydraulic oil supply hole of the flange, and a rod for operating the ball and opening and closing a connection hole between the hydraulic control hole and the hydraulic pressure discharge hole of the flange;
A sleeve inserted into the inner diameter portion of the coil assembly and an armature, a spindle inserted into the inner diameter portion of the sleeve to push the rod by the operation of the armature, And a magnetic path portion provided at the lower portion and having an upper magnetic disk and a lower magnetic disk, which form a magnetic force,
And a lower portion of the flange is overmolded integrally with the upper magnetic disk and the sleeve. The method according to claim 1,
Wherein an upper coupling plate and a lower coupling plate are formed in the lower portion of the flange so as to be in close contact with both side surfaces of the upper magnetic disk. The method of claim 2,
Wherein the upper coupling plate and the lower coupling plate are integrally connected through a coupling hole formed in the upper magnetic disk. The method of claim 2,
Wherein a coupling protrusion is formed on each of the upper coupling plate and the lower coupling plate, and each of the coupling protrusions is closely inserted into a groove formed on an outer circumferential surface of the sleeve. The method of claim 2,
And a seal ring is interposed between the lower coupling plate and the coil assembly. The method according to claim 1,
Wherein the sleeve is press-fitted into the coupling hole of the upper magnetic disc, and a stopper is formed on the outer circumferential surface of the sleeve so as to limit the depth of the press-fit. The method according to claim 1,
Wherein a disc groove is formed at an end of the flange, and a disc spring is provided in the disc groove to elastically support the ball against an armature operating direction. The method according to claim 1,
Wherein a disk groove is formed at an end of the flange, and a disk filter for filtering impurities of the operating oil supplied into the flow path of the flange is provided in the disk groove.

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