JP2002243057A - Solenoid valve device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a solenoid valve device capable of restraining an increase in manufacturing cost due to assembling of a non-magnetic member. SOLUTION: A non-magnetic plate 16 is clamped by a spool 30 energized to the armature side and an armature 18, and abuts to a projecting part 15b of a stator core 13 to prevent contact between the armature 18 and the projecting part 15b of the stator core 13. The armature 18 has a penetrating hole 20 penetrating from the spool side end face to the counter-spool side end face, and the non-magnetic plate 16 is clamped by the spool 30 and the armature 18 with the spool side of the penetrating hole 20 opened, so that the area of the moving passage for the hydraulic fluid with the movement of the armature 18 can be secured enough.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

[0001] The present invention relates to a solenoid valve device.

[0002]

2. Description of the Related Art In an electromagnetic valve device that generates a magnetic force between a stator and a plunger and attracts the plunger to the spool, a non-magnetic material is provided between the stator and the plunger to prevent the stator and the plunger from coming into contact with each other. The members are arranged. Such a non-magnetic member is disclosed in, for example,
According to the description in JP-A-122412, the shaft is fixed by press-fitting or the like to a shaft that moves together with the spool.

According to the description of Japanese Patent Application Laid-Open No. 10-122412, the space surrounded by the inner wall surface of the stator and the outer wall surface of the plunger changes in volume as the plunger moves, so that when the plunger moves, the space changes. The fluid will enter and exit the. JP 2001-2635A
Japanese Patent Publication No. 21 discloses an electromagnetic drive device in which the magnetic resistance of the stator is increased by forming a hole in the peripheral wall of the stator. According to this electromagnetic drive device, the magnetic resistance flowing from the stator to the plunger increases due to the increase in the magnetic resistance of the stator, and the magnetic attraction for driving the plunger increases.

[0004]

However, Japanese Patent Laid-Open No.
As disclosed in JP-A-122412, when a nonmagnetic member is fixed to a mating member such as a shaft,
Since a fixing step between the non-magnetic member and the mating member is required, the manufacturing cost is increased by the equipment cost of the fixing step. Also, when the non-magnetic member and the mating member are fixed by press-fitting, the cost of parts increases due to the demand for precision machining by press-fit dimensional control.

Further, in the solenoid valve device disclosed in Japanese Patent Application Laid-Open No. 10-122412, since the area of the fluid passage for the fluid accompanying the movement of the plunger is not sufficient, the resistance acting on the plunger when the plunger moves the fluid is reduced. This is a factor that reduces the responsiveness of the solenoid valve device. Further, in the electromagnetic driving device disclosed in Japanese Patent Application Laid-Open No. 2001-263521, it is difficult for the shape of the stator to realize a flat suction force characteristic.

[0006] The present invention has been made to solve the above-mentioned problem, and has as its object to provide an electromagnetic valve device that improves the attraction force characteristics. Another object of the present invention is to provide an electromagnetic valve device that reduces manufacturing costs.

[0007]

According to the electromagnetic valve device of the present invention, since the protruding portion of the plunger facing the spool-side end face is formed on the stator, the stator sucks the plunger toward the spool. Power is great. Further, the non-magnetic plate is sandwiched between the movable member biased to the plunger side and the plunger, and abuts on the projection of the stator to prevent contact between the plunger and the projection of the stator. Therefore, according to the solenoid valve device of the first aspect, the contact between the plunger and the projection of the stator can be prevented without fixing the non-magnetic plate to any other member. An increase in manufacturing cost can be suppressed.

Further, the plunger has a breathing flow passage penetrating from the spool side end surface to the opposite spool side end surface, and the non-magnetic plate is sandwiched between the spool and the plunger with the spool side of the breathing flow passage opened. Therefore, a sufficient fluid passage area for the movement of the plunger is ensured. Therefore, according to the electromagnetic valve device of the first aspect, since the resistance acting on the plunger when the plunger moves the fluid is small, the responsiveness of the electromagnetic valve device can be improved and the attraction force characteristics can be improved.

According to the second aspect of the present invention, the non-magnetic plate has a disk shape with a notch formed on the outer periphery, and has an outer edge formed at an edge of an opening of a respiratory flow passage at an end surface of a plunger on a spool side. Since they are locked, the positional relationship between the movable member, the non-magnetic plate, and the plunger does not deviate perpendicularly to the moving direction of these members. Further, since the non-magnetic plate is locked to the opening of the breathing channel, the shape of the plunger is simplified, so that an increase in manufacturing cost due to assembling the non-magnetic member can be further suppressed.

According to the solenoid valve device of the third aspect, by preventing the contact between the plunger and the stator without providing the non-magnetic member, it is possible to suppress an increase in manufacturing cost due to the assembly of the non-magnetic member. it can. Since the stator is not provided with a projection facing the spool-side end surface of the plunger, when the plunger moves near the flange of the stator, the force with which the stator sucks the plunger sharply decreases. Therefore, if the plunger is urged to the side opposite to the suction direction via the movable member, the plunger can be localized at a predetermined relative position with respect to the stator. As described above, according to the electromagnetic valve device of the third aspect, by balancing the urging force of the urging means and the attraction force of the stator when the attraction force of the stator is reduced,
The plunger can be positioned at a predetermined relative position with respect to the stator without providing a protrusion facing the spool-side end surface of the plunger on the stator and without providing a non-magnetic member.

On the other hand, not providing the stator with a projection facing the spool-side end surface of the plunger causes a reduction in the force with which the stator sucks the plunger. However, according to the solenoid valve device of the third aspect, the outer diameter of the stator is reduced toward the other pipe end from a position separated from the base end of the flange to the other pipe end by 0 mm or more and 2 mm or less, and the base of the flange is reduced. Since the peripheral wall taper of the stator is formed near the end, the reduction of the attractive force due to magnetic saturation on the peripheral wall of the stator is suppressed, and the attractive force of the tapered part itself is increased, whereby the plunger is strongly attracted to the flange side. Can be. Therefore, according to the electromagnetic valve device of the third aspect, the attraction force characteristic of the plunger can be improved.

According to the fourth aspect of the present invention, since the respiratory flow path is formed eccentrically from the axis of the plunger, the vicinity of the axis of the movable member can be brought into contact with the plunger. The shapes of the member and the plunger can be simplified.

According to the solenoid valve device of the fifth aspect, the wall thickness of the suction portion becomes thinner as it goes away from the spool.
Since the thin portion is adjacent to the spool of the suction portion far from the spool, a flat suction force characteristic can be realized in a range where the spool-side end of the plunger is near the suction portion of the thin portion or opposed to the suction portion. 0.5m from suction part in thin part
Since a hole having a center is formed at a position apart from m to 1 mm, the magnetic resistance of the thin portion increases. When the magnetic resistance of the thin part increases, the magnetic flux flowing from the suction part to the plunger increases, so that the plunger is moved to the suction part side in a range in which the spool side end of the plunger faces the thin part slightly distant from the suction part. The applied magnetic force increases. Therefore, according to the electromagnetic valve device of the fourth aspect, it is possible to suppress a change in the suction force as the plunger moves relative to the suction portion, and to improve the suction force characteristic to a flatter one. . Preferably, the hole penetrates a peripheral wall of the stator.

[0014]

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a block diagram showing a first embodiment of the present invention; (First Embodiment) FIG. 1 shows an electromagnetic valve device according to a first embodiment of the present invention. The electromagnetic valve device 1 is a spool-type hydraulic control device that controls the hydraulic pressure of hydraulic oil supplied to a hydraulic control device of an automatic transmission such as a vehicle.

The linear solenoid 10 has a yoke 11, a stator core 13, a plunger 18, a coil 21, a non-magnetic plate 16, and the like. The yoke 11 and the stator core 13 constitute a stator described in the claims. Yoke 11, stator core 13, plunger 1
8 is made of a magnetic material.

The yoke 11 has a cylindrical shape with a bottom and is caulked to an end of the housing 31 to fix the coil 21 and the stator core 13 sealed in the resin molded body 22 to the housing 31. .

The stator core 13 has an accommodating portion 14 for accommodating the plunger 18 in a reciprocating manner, a suction portion 15 for generating a magnetic force for attracting the plunger 18 to the spool side, and a flange portion 19, and is integrally formed. I have. Housing 1
An annular concave portion 14a is formed in the outer peripheral wall of No.4. The housing part 14 and the suction part 15 have a cylindrical peripheral wall, and are formed coaxially from the opposite spool side to the spool side in this order. By forming an annular concave portion 14 a in the outer peripheral wall of the stator core 13, the spool-side end of the housing portion 14 is formed to be thin. It is desirable that the thickness of the spool-side end of the housing portion 14 be set to about 0.6 mm.
The suction portion 15 includes a tapered portion 15a formed adjacent to the spool side of the concave portion 14a, and a projection 15b having an inner diameter smaller than the inner diameter of the housing portion 14 and having a greater thickness than the housing portion 14. The tapered portion 15a is formed in a cylindrical shape whose wall thickness becomes thinner as the distance from the spool 30 increases. Projection 1
Since the inner diameter of the tapered portion 5b is different from that of the tapered portion 15a, the inner wall surface of the stator core 13 forms a step, and the step forms an opposing surface 13a facing the spool-side end surface of the plunger 18. The flange portion 19 is formed on the outer periphery of the suction portion 15 at the spool-side tube end of the stator core 13, and is sandwiched between the yoke 11 and the housing 31. The tapered surface of the outer wall of the tapered portion 15a is formed at a position of about 3 mm from the base end of the flange portion 19 to the side opposite to the spool.

The coil 21 is sealed in a resin molded body 22,
It is accommodated in a space formed by the outer peripheral wall of the stator core 13 and the inner peripheral wall of the yoke 11. When a current is supplied to the coil 21 from a terminal (not shown) that is electrically connected to the coil 21, a magnetic flux flows through a magnetic circuit formed by the yoke 11, the plunger 18, and the stator core 13, and the suction portion 15 of the stator core 13 Magnetic attraction is generated between the plunger 18 and the plunger 18. Then, the plunger 18
And the shaft 30a moves to the left in FIG.

The plunger 18 is slidably supported by the inner wall surface of the housing portion of the stator core 13. A through hole 20 as a breathing passage is formed in the axial direction from the spool-side end surface of the plunger 18 to the opposite spool-side end surface, and the plunger 18 has a cylindrical shape. The through-hole 20 is formed by a multi-stage inner wall surface of the plunger 18, and the small-diameter straight portion, the tapered portion, the large-diameter straight portion, and the edge formed in the order from the spool side to the spool side increase in diameter in this order. ing. The small-diameter straight portion has the longest axial length as compared with the other portions, and the axial length is the plunger 18.
Occupies most of the axial length. Thus, plunger 1
8 has a large diameter and a large diameter only in the vicinity of the spool-side end because the through-hole 20 is formed in the spool-side end surface of the plunger 18, the inner wall surface of the stator core 13, and the outer wall surface of the spool 30. The volume of the space surrounded by changes according to the movement of the plunger 18, whereby when the hydraulic oil moves to the side opposite to the spool of the plunger 18, while ensuring a sufficient passage cross-sectional area for the hydraulic oil to move, This is because the magnetic force acting between the stator core 13 and the plunger 18 is not reduced by making the plunger 18 thick.

The non-magnetic plate 16 is a disk-shaped non-magnetic member having a notch formed on the outer peripheral edge as shown in FIG. The non-magnetic plate 16 is fitted into the edge of the through-hole 20, and the spool 3 is biased by the spring 40.
0 and the plunger 18. The spool-side end surface of the non-magnetic plate 16 is made to project more toward the spool than the spool-side end surface of the plunger 18, so that contact between the step surface 13 a of the stator core 13 and the plunger 18 can be prevented. Therefore, the non-magnetic plate 1
6 has a thickness longer than the axial length of the edge of the through hole 20, and is fitted into the edge of the through hole 20. The maximum radius R1 of the non-magnetic plate 16 is smaller than the radius R3 of the edge of the through hole 20, larger than the radius R2 of the small straight portion of the through hole 20, and the suction portion 1 of the stator core 13
It suffices that the diameter is larger than the minimum radius of the inner peripheral wall of No. 5. The notch of the non-magnetic plate 16 has a minimum radius R of the non-magnetic plate 16.
4 is formed so as to be sufficiently smaller than the radius R2 of the small-diameter straight portion of the through-hole 20, and the spool-side opening area of the through-hole 20 is sufficiently ensured.

The housing 31 of the spool 30 is cylindrical and accommodates the spool 30 in a reciprocating manner.
The housing 31 has an input port 32, an output port 3
3, a feedback port 34 and a discharge port 35 are formed. The input port 32 is a port into which hydraulic oil supplied by a pump from a tank (not shown) flows. The output port 33 is a port for supplying hydraulic oil to an engagement device of an automatic transmission (not shown). Output port 33
The feedback port 34 communicates with the outside of the solenoid valve device 1, and a part of the operating oil flowing out of the output port 33 is introduced into the feedback port 34. The feedback chamber 36 communicates with the feedback port 34. The discharge port 35 is a port for discharging hydraulic oil to the tank.

A large-diameter land 37, a large-diameter land 38,
Small-diameter lands 39 are formed in this order. The small-diameter land 39 has a smaller outer diameter than the large-diameter lands 37 and 38. A shaft 30a is provided at the linear solenoid side end of the spool 30.
Are formed to protrude toward the linear solenoid. The end face of the shaft 30a is in contact with the center of the non-magnetic plate 16. The shaft 30a may be formed separately from the spool 30.

A spring 40 as a biasing means provided on the side opposite to the plunger of the spool 30
0 is urged to the plunger side. The spool 30 is urged to the left in FIG. 1 by the plunger 18 via the non-magnetic plate 16, and the plunger 18 is
1 to the right in FIG. 1 to reciprocate in the housing 31 in synchronization with the plunger 18.

The feedback chamber 36 is formed between the large-diameter land 38 and the small-diameter land 39, and the area on which the feedback hydraulic pressure acts differs depending on the outer diameter difference of the land. Therefore, the hydraulic pressure in the feedback chamber 36 acts to press the spool 30 in the direction opposite to the linear solenoid. The feedback of a part of the hydraulic pressure output from the solenoid valve device 1 is to prevent the output pressure from fluctuating due to the fluctuation of the supplied hydraulic oil pressure, that is, the input pressure. The spool 30 causes the stator core 1 to move by the urging force of the spring 40 and the current supplied to the coil 21.
3 stops at a position where the force by which the plunger 18 pushes the spool 30 by the electromagnetic attraction force generated by the plunger 3 and the force that the spool 30 receives from the oil pressure in the feedback chamber 36 are balanced.

The amount of hydraulic oil flowing from the input port 32 to the output port 33 is determined by the seal length, which is the length of the overlap between the inner peripheral wall 31a of the housing 31 and the outer peripheral wall of the large diameter land 38. As the seal length decreases, the amount of hydraulic oil flowing from the input port 32 to the output port 33 increases.
The amount of hydraulic oil flowing to the tank decreases. Similarly, output port 33
The amount of hydraulic oil flowing from the housing to the discharge port 35 depends on the housing 3
1 is determined by the seal length between the inner peripheral wall 31b and the outer peripheral wall of the large-diameter land 37.

When the current is supplied to the coil 21 and the spool 30 moves toward the spring 40, that is, to the left in FIG. 1, the seal length between the inner peripheral wall 31a and the large-diameter land 38 becomes longer, and the inner peripheral wall 31b becomes larger than the inner peripheral wall 31b. Since the seal length with the diameter land 37 is shortened, the output port 3
3 decreases, and the flow rate of hydraulic oil flowing from the output port 33 to the discharge port 35 increases. as a result,
The hydraulic pressure of the working oil flowing out of the output port 33 decreases.

On the other hand, when the spool 30 is the linear solenoid 1
When moving in the 0 direction, the seal length between the inner peripheral wall 31a and the large-diameter land 38 becomes shorter and the seal length between the inner peripheral wall 31b and the large-diameter land 37 becomes longer. And the flow rate of the hydraulic oil flowing from the output port 33 to the discharge port 35 decreases. As a result, the hydraulic pressure of the working oil flowing out of the output port 33 increases.

The solenoid valve device 1 controls the value of the current supplied to the coil 21 to adjust the force of the linear solenoid 10 pushing the spool 30 in the direction opposite to the linear solenoid 10.
The hydraulic pressure of the working oil flowing out of the output port 33 is adjusted.
When the value of the current supplied to the coil 21 is increased, the electromagnetic attraction of the stator core 13 increases in proportion to the current value, and the force of the shaft 30a pushing the spool 30 in the direction opposite to the linear solenoid 10 increases. The force acting on the spool 30 from the plunger 18 due to the electromagnetic attraction force, the spring 40
The spool 30 is stopped at a position where the biasing force of the spool 30 and the force of pushing the spool 30 toward the anti-linear solenoid 10 by the feedback of the hydraulic oil are balanced. Therefore, the hydraulic pressure of the hydraulic oil flowing out of the output port 33 decreases in proportion to the value of the current supplied to the coil 21.

According to the solenoid valve device 1 of the first embodiment described above, since the projection 15b is formed on the stator core 13, the force by which the stator core 13 attracts the plunger 18 toward the spool is large. The non-magnetic plate 16
Is held between the plunger 18 and the spool 30 urged toward the plunger, and the protrusion 1
The contact between the plunger 18 and the protrusion 15b of the stator core 13 is prevented by contacting the plunger 18 with the protrusion 5b. Therefore,
According to the solenoid valve device 1 of the first embodiment, the non-magnetic plate 1
Since the contact between the plunger 18 and the projection 15b of the stator core 13 can be prevented without fixing the member 6 to any other member, it is possible to suppress an increase in manufacturing cost due to assembling the non-magnetic plate 16.

The plunger 18 has a through hole 20 penetrating from the spool side end surface to the opposite spool side end surface.
Since the non-magnetic plate 16 is sandwiched between the spool 30 and the plunger 18 with the through-hole 20 having the spool side open, a sufficient passage area for the hydraulic oil to move with the movement of the plunger 18 is ensured. Therefore, according to the electromagnetic valve device 1 of the first embodiment, since the resistance acting on the plunger 18 when the plunger 18 moves the hydraulic oil is small, the responsiveness of the electromagnetic valve device 1 can be improved.

Since the outer edge of the non-magnetic plate 16 is locked to the wall surface of the opening of the through hole 20 at the end surface of the plunger 18 on the spool side, the positional relationship between the spool 30, the non-magnetic plate 16 and the plunger 18 is established. Does not deviate perpendicularly to the moving direction of these members. Further, since the non-magnetic plate 16 is locked in the opening of the through hole 20, the shape of the plunger 18 is simplified, and the non-magnetic plate 1
6 can be further suppressed from increasing the production cost.

(Second Embodiment) FIG. 3 shows an electromagnetic valve device according to a second embodiment of the present invention. The solenoid valve device 2 is a spool-type hydraulic control device that controls the hydraulic pressure of hydraulic oil supplied to a hydraulic control device of an automatic transmission such as a vehicle. The same components as those of the solenoid valve device 1 of the first embodiment are denoted by the same reference numerals, and description thereof will be omitted.

The stator core 50 includes a housing portion 51 for housing the plunger 60 in a reciprocating manner, a suction portion 53 for generating a magnetic force for attracting the plunger 60, and a flange portion 54.
And are integrally formed. The housing section 51 and the suction section 53 have cylindrical peripheral walls, and are formed coaxially from the opposite spool side to the spool side in this order. Since the inner peripheral walls have the same diameter, the stator core 50 is formed in a cylindrical shape having a straight inner peripheral wall surface 50a. By forming an annular concave portion 51 a on the outer peripheral wall of the stator core 13, the spool-side end of the housing portion 51 is formed to be thin. It is desirable that the thickness of the end of the storage section 51 on the spool side be set to about 0.6 mm.

The suction portion 53 is formed in a cylindrical shape whose peripheral wall thickness increases toward the spool. The tapered surface 53a, which is the outer peripheral wall surface of the suction portion 53, has a flange portion 54.
Intersects with the end surface 54a on the side opposite to the spool. The flange portion 54 is formed on the outer periphery of the suction portion 53 at the spool-side tube end of the stator core 50, and the yoke 11 and the housing 3
1 pinched. Tapered surface 53a of suction part 53
Is formed from the position intersecting with the end face 54a of the flange portion 54 in order to avoid that the magnetic flux concentrates in the suction portion 53, magnetic saturation occurs, and the force of the suction portion 53 to attract the plunger 60 is reduced. is there. By forming the tapered surface 53a of the suction portion 53 from a position intersecting with the end surface 54a of the flange portion 54, the magnetic flux concentrated on the suction portion 53 is diffused in the flange portion 54 located at the nearest position, so that the magnetic flux concentration in the suction portion 53 is reduced. Can be eased.

In this embodiment, the tapered surface 53a is formed from the end surface 54a on the side opposite to the spool of the flange portion 54. However, the magnetic flux concentration in the suction portion 53 is reduced, and the stator core 50 attracts the plunger 60 to the spool 30. As long as the force required in the design can be exhibited as the force,
Between the tapered surface 53a and the end surface 54a of the flange portion 54, a short straight surface having a cylindrical outer peripheral wall shape perpendicular to the end surface 54a may be formed. The axial length of such a straight surface is desirably 2 mm or less.

The plunger 60 is formed in an eccentric cylindrical shape.
It is slidably supported by the inner wall surface of the stator core 50. A through hole 61 as a breathing passage extends in the axial direction from the end face of the plunger 60 on the spool side to the end face on the opposite side of the spool.
Are formed eccentrically. The reason why the through hole 61 is formed eccentrically in the plunger 60 is that the through hole 61
In order to prevent the opening on the spool side from being closed by the shaft 30a of the spool 30.

According to the solenoid valve device 2 of the second embodiment, the contact between the plunger 60 and the stator core 50 is prevented without providing a non-magnetic member, thereby suppressing an increase in manufacturing cost due to assembling the non-magnetic member. can do. Since the stator core 50 does not have a projection facing the spool-side end surface of the plunger 60, when the plunger 60 moves to the vicinity of the flange portion 54 of the stator core 50, the stator core 50 sucks the plunger 60 as shown in FIG. The force decreases rapidly. Therefore, if the plunger 60 is urged through the spool 30 in the direction opposite to the suction direction, the plunger 60 can be localized at a predetermined relative position with respect to the stator core 50. As described above, according to the solenoid valve device 2 of the second embodiment, when the attraction force of the stator core 50 becomes small, the spring 4
By balancing the biasing force of 0 and the attraction force of the stator core 50, the protrusion facing the spool-side end surface of the plunger 60 is not provided on the stator core 50, and the non-magnetic member is not provided. The plunger 60 can be localized at a predetermined relative position.

On the other hand, not providing the stator with a protrusion facing the spool-side end surface of the plunger 60 causes a reduction in the force with which the stator core 50 sucks the plunger 60, as shown in FIG. However, according to the solenoid valve device of the second embodiment, since the taper surface of the suction portion 53 is formed from the end surface 54a on the side opposite to the spool of the flange portion 54, a decrease in suction force due to magnetic saturation in the suction portion 53 is suppressed. By increasing the suction force of the suction portion 53 itself, the plunger 60 can be strongly attracted to the flange side.

Further, according to the solenoid valve device 2 of the second embodiment, since the through hole 61 of the plunger 60 is formed eccentrically from the axis of the plunger 60, the shaft 30a protruding from the axis of the spool 30 is formed. Since the plunger 60 can be brought into contact with the plunger 60, the shapes of the spool 30 and the plunger 60 can be made simple and easy to process.

(Third Embodiment) FIG. 5 shows an electromagnetic valve device according to a third embodiment of the present invention. The solenoid valve device 3 is a spool-type hydraulic control device that controls the hydraulic pressure of hydraulic oil supplied to a hydraulic control device of an automatic transmission such as a vehicle. The same components as those of the solenoid valve device 2 of the second embodiment are denoted by the same reference numerals, and description thereof is omitted.

The diaphragm 70 is made of rubber, has a central portion fitted in an annular groove formed in the shaft 30 a of the spool 30, and has outer peripheral edges formed of the valve housing 31 and the stator core 50.
Is sandwiched between. Since the diaphragm 70 moves as the spool 30 and the plunger 60 reciprocate, the diaphragm 70 absorbs a change in volume of the plunger 60 on the spool 30 side. Further, the diaphragm 70 prevents foreign matter from entering the plunger 60 from the spool 30.

As shown in FIG. 6, a plurality of holes 55 are formed in the end portion (thin portion) 52 of the accommodation portion 87 on the spool side. The hole 55 desirably penetrates the thin portion 52 in the radial direction, but need not penetrate. The holes 55 are formed by laser irradiation, cutting, pressing, water jet processing, or the like. From the suction unit 53, that is, the suction unit 5
The distance D from the position where the tapered surface 53a, which is the outer peripheral wall surface of the third part 3, and the outer peripheral wall surface of the thin portion 52 intersect to the center of the hole 55
Is desirably set to 0.5 mm or more and 1 mm or less. Also, the coil 21 is not energized and the plunger 6
It is preferable that the end face of the plunger 60 on the spool side be separated from the center of the hole 55 by 0.1 mm or more toward the spool in a state in which 0 is pressed against the spool by the urging force of the spring 40. It is desirable that the distance between the centers of the holes 55 adjacent to each other in the circumferential direction of the housing portion 87 is set to be 0.35 mm or more and 0.4 mm or less on the outer wall surface of the thin portion 52. It is desirable that the diameter of the hole 55 be set to about 0.2 mm.

Incidentally, as shown in FIG.
The rows may be arranged, or the rows may be arranged in a plurality of rows spaced apart in the axial direction. When the holes 55 are arranged in a plurality of rows, the positions of the holes 55 in the reciprocating movement direction of the plunger 60 are
The center of the hole 55 belonging to the row closest to No. 3 is set as a reference. For example, it is desirable that the center of the hole 55 belonging to the row closest to the suction unit 53 is set to be separated from the suction unit by 0.5 mm or more and 1 mm or less. Also, the coil 21
Is not energized and the plunger 60 is pressed against the spool by the biasing force of the spring 40, the spool-side end face of the plunger 60 moves from the center of the hole 55 belonging to the row closest to the suction part 53 to the spool side. .1
mm or more.

The through hole 6 formed in the plunger 60
Instead of 1, a passage communicating between a space surrounded by the end surface of the plunger 60 on the opposite side to the spool and the inner wall surface of the yoke 11 and the outer space of the yoke 11 may be provided as a breathing passage.

The configuration of the solenoid valve device 3 according to the third embodiment has been described above. Hereinafter, the operation of the solenoid valve device 3 according to the third embodiment will be described. When current is supplied to the coil 21 from a terminal (not shown), magnetic flux flows through a magnetic circuit formed by the yoke 11, the plunger 60, and the stator core 50, and the stator core 50 and the plunger 6
A magnetic attraction force is generated between zero. Then, the plunger 60 and the spool 30 move to the left in FIG.

Since a plurality of holes 55 are formed in the thin portion 52, the cross-sectional area through which magnetic flux passes in the thin portion 52 is smaller than in the third embodiment, and the magnetic resistance of the thin portion 52 is larger. Therefore, when supplying current to the coil 21, the magnetic flux leaking from the thin portion 52 to the side opposite to the spool of the housing portion 51 decreases and the magnetic flux flowing from the suction portion 53 to the plunger 60 increases as compared with the case where the hole 55 is not provided. I do.
Therefore, in a range where the stroke of the plunger 60 is small, that is, in a range where the distance between the spool-side end surface of the plunger 60 and the housing 31 is large, the suction force for moving the plunger 60 toward the spool can be increased. Further, since the wall thickness of the tapered portion 53 decreases as the distance from the spool 30 increases, the plunger 60 is moved to the spool side mainly within a stroke range in which the taper portion 53 moves to the spool side by a suction force acting between the tapered portion 53 and the plunger 60. The suction force to be moved is kept almost constant.

FIG. 7 is a graph showing the relationship between the position of the hole 55 and the suction force characteristic. The effect of suppressing the reduction of the suction force as compared with the case where the hole 55 is not formed at all is greatest when the distance D from the suction portion 53 to the center of the hole 55 is 0.5 mm or more and 1 mm or less. When the distance D from the suction part 53 to the center of the hole 55 is less than 0.5 mm, the effect of suppressing the reduction of the suction force is large within a predetermined stroke range, but when the distance exceeds the range, the suction force rapidly decreases. I do.
When the distance D from the suction part 53 to the center of the hole 55 exceeds 1 mm, the effect of suppressing the reduction of the suction force is small.

(Fourth Embodiment) FIG. 8 shows an electromagnetic valve device 4 according to a fourth embodiment of the present invention. The solenoid valve device 4 is a spool-type hydraulic control device that controls the hydraulic pressure of hydraulic oil supplied to a hydraulic control device of an automatic transmission such as a vehicle. The same components as those of the solenoid valve device 3 of the third embodiment are denoted by the same reference numerals, and description thereof will be omitted.

The stator core 80 includes a housing portion 87 for housing the plunger 60 in a reciprocating manner, a suction portion 88 for generating a magnetic force for sucking the plunger 60, and a flange portion 81.
And are integrally formed. The accommodation portion 87 and the suction portion 88 have a cylindrical peripheral wall, and are formed coaxially from the opposite spool side to the spool side in this order. By forming an annular concave portion 86 on the outer peripheral wall of the storage portion 87, the spool-side end of the storage portion 87 is formed to be thin. The thickness of the spool side end portion (thin portion) 84 of the storage portion 87 is
It is desirable to set it to about 0.6 mm.

The suction portion 88 comprises a tapered portion 85 formed adjacent to the thin portion 84 on the spool side, and a projection 89 having an inner diameter smaller than the inner diameter of the storage portion 87 and having a larger thickness than the storage portion 87. . The tapered portion 85 is formed in a cylindrical shape whose wall thickness becomes thinner as the distance from the spool 30 increases. Since the projection 89 and the tapered portion 85 have different inner diameters, the inner wall surface of the stator core 80 forms a step, and the step forms an opposing surface that faces the spool-side end surface of the plunger 60. A non-magnetic member 71 is provided on the facing surface. The non-magnetic member 71 prevents the plunger 60 from directly abutting on the opposing surface of the projection 89 and being attracted. The flange portion 81 is formed on the outer periphery of the suction portion 15 at the spool-side tube end of the stator core 80, and the yoke 11
And the housing 31. Tapered part 85
The tapered surface 82 of the outer wall is formed at a position about 3 mm away from the base end of the flange portion 81 on the side opposite to the spool.

The thin portion 84 has a plurality of holes 83 formed therein. The hole 83 desirably penetrates the thin portion 84 in the radial direction, but does not have to penetrate. The holes 83 are formed by laser irradiation, cutting, pressing, water jet processing, or the like. From the suction part, that is, the tapered part 8
The distance D from the position where the tapered surface 82, which is the outer peripheral wall surface of No. 5, to the bottom surface of the concave portion 84 to the center of the hole 83 is 0.5
It is desirable that the distance be set to not less than 1 mm and not more than 1 mm. When the coil 21 is not energized and the plunger 60 is pressed against the spool by the urging force of the spring 40, the end face of the plunger 60 on the spool side is
It is desirable that the distance from the center to the spool is 0.1 mm or more. Holes 8 adjacent in the circumferential direction of stator core 80
It is desirable that the center-to-center distance of No. 3 is set to 0.35 mm or more and 0.4 mm or less. The diameter of the hole 83 is desirably set to about 0.2 mm.

The holes 83 may be arranged in a row in the circumferential direction, or may be arranged in a plurality of rows, each row being axially separated. When the holes 83 are arranged in a plurality of rows, the positions of the holes 83 in the reciprocating direction of the plunger 60 are set based on the centers of the holes 83 belonging to the row closest to the suction unit.

The configuration of the solenoid valve device according to the fourth embodiment has been described above. Hereinafter, the operation of the solenoid valve device according to the fourth embodiment will be described. When a current is supplied to the coil 21 from a terminal (not shown), a magnetic flux flows through a magnetic circuit formed by the yoke 11, the plunger 60 and the stator core 80, and a magnetic attraction force is generated between the stator core 80 and the plunger 60. Then, the plunger 60
And the spool 30 moves to the left in FIG.

FIG. 9 is a graph showing the attraction force characteristics of the solenoid valve device according to the fourth embodiment. The broken line graph shows the suction force characteristics of the comparative example having the same configuration as the fourth embodiment except that the holes 83 and the protrusions 54 are not formed.

A plurality of holes 55 are formed in the thin portion 84 of the accommodation portion 87.
Are formed, the cross-sectional area through which the magnetic flux can pass in the thin portion 84 is smaller than in the comparative example, and the magnetic resistance in the thin portion 84 is larger. Therefore, coil 2
When the current is supplied to No. 1, the magnetic flux leaking from the thin portion 84 to the opposite side to the spool of the housing portion 87 decreases compared to the comparative example,
The magnetic flux flowing from the suction part 88 to the plunger 60 increases. Therefore, in a range where the stroke of the plunger 60 is small, that is, in a range where the distance between the spool-side end surface of the plunger 60 and the non-magnetic member 71 is large, the suction force for moving the plunger 60 toward the spool can be increased. The wall thickness of the tapered portion 85 is 30
Because it becomes thinner as it gets away from the
Within the stroke range in which the plunger 60 is moved toward the spool by the suction force acting between the plunger 60 and the plunger 60, the suction force for moving the plunger 60 toward the spool is kept substantially constant.
When the distance between the spool-side end surface of the plunger 60 and the non-magnetic member 71 becomes equal to or less than a predetermined value, the suction force by the tapered portion 85 decreases while the plunger 60 is moved between the opposing surface of the projection 89 and the plunger 60. Since the suction force for moving the plunger 60 toward the spool increases, a decrease in the suction force acting on the plunger 60 when the plunger 60 moves to the spool side is suppressed as compared with the comparative example. According to the solenoid valve device 4, the hole 55,
The opposing surfaces of the tapered portion 85 and the projection 89 act in this order to maintain a constant suction force for moving the plunger 60 toward the spool.

[Brief description of the drawings]

FIG. 1 is a sectional view showing a solenoid valve device according to a first embodiment of the present invention.

FIG. 2 is a plan view showing a plunger and a non-magnetic plate viewed from a direction A in FIG.

FIG. 3 is a sectional view showing an electromagnetic valve device according to a second embodiment of the present invention.

FIG. 4 is a schematic diagram for explaining the relationship between the stroke of the plunger and the force with which the plunger is attracted to the stator core in the solenoid valve device according to the first and second embodiments of the present invention.

FIG. 5 is a sectional view showing a solenoid valve device according to a third embodiment of the present invention.

FIG. 6 is a sectional view showing a stator core according to a solenoid valve device according to a third embodiment of the present invention.

FIG. 7 is a graph showing an attraction force characteristic of a solenoid valve device according to a third embodiment of the present invention.

FIG. 8 is a sectional view showing an electromagnetic valve device according to a fourth embodiment of the present invention.

FIG. 9 is a graph showing an attraction force characteristic of an electromagnetic valve device according to a fourth embodiment of the present invention.

[Explanation of symbols]

 1, 2, 3, 4 Solenoid valve device 10 Linear solenoid 11 Yoke 13 Stator core 15b Projection 16 Nonmagnetic plate 18 Plunger 19 Flange 20 Through hole (respiratory flow passage) 21 Coil 30 Spool (movable member) 30a Shaft (movable member) 31) Housing 40 Spring (biasing means) 50 Stator core (stator) 53a Tapered surface 60 Plunger 61 Through hole (breathing passage)

 ────────────────────────────────────────────────── ─── Continuing on the front page (72) Kenichi Oishi 1-1-1, Showa-cho, Kariya-shi, Aichi Prefecture Inside Denso Corporation (72) Inventor Seiji Tachibana 1-1-1, Showa-cho, Kariya-shi Aichi Prefecture F term (reference) 3H106 DA04 DA23 DB02 DB12 DB23 DB32 DC09 DD06 EE07 EE16 GA15 GC07 GC23 KK03 KK17

Claims (7)

[Claims] 1. A movable member having a housing having a plurality of fluid flow paths penetrating a cylindrical peripheral wall, a spool for opening and closing the plurality of fluid flow paths by reciprocating in the housing, and A plunger disposed in series in the direction of movement of the spool and having a respiratory flow passage penetrating from the spool-side end surface to the opposite spool-side end surface; and a projection facing the spool-side end surface of the plunger. A stator that forms a magnetic circuit that attracts the plunger toward the protrusion; a biasing unit that biases the movable member toward the plunger; and the spool and the plunger in a state where the spool side of the breathing flow path is opened. A non-magnetic plate, which is sandwiched between the plunger and the projection to prevent contact between the plunger and the projection. Place. 2. The respiratory flow path increases in diameter in the vicinity of the spool-side end surface of the plunger toward the spool, and the non-magnetic plate has a disk shape with a notch formed on the outer periphery thereof. The solenoid valve device according to claim 1, wherein an outer edge portion is locked to an edge of an opening of the breathing flow path on a spool side end surface. A movable member having a housing having a plurality of fluid flow paths penetrating a cylindrical peripheral wall; a movable member having a spool for opening and closing the plurality of fluid flow paths by reciprocating in the housing; On the other hand, a plunger that is arranged in series in the moving direction of the spool and abuts on the movable member and has a breathing flow passage penetrating from the spool-side end face to the opposite spool-side end face, and is located on the spool side of the plunger. A tubular stator having a flange at one tube end and forming a straight hole for accommodating the plunger by an inner wall surface and forming a magnetic circuit for moving the plunger to the one tube end side, wherein a base of the flange is provided. A stator whose outer diameter is reduced toward the other pipe end from a position separated from the end by 0 mm or more and 2 mm or less from the other pipe end; Solenoid valve apparatus characterized by comprising a biasing means for urging the movable member in. 4. The solenoid valve device according to claim 3, wherein the respiratory flow path is formed eccentrically from an axis of the plunger. 5. A movable member having a housing having a plurality of fluid flow paths penetrating a cylindrical peripheral wall, a spool for opening and closing the plurality of fluid flow paths by reciprocating in the housing, On the other hand, a plunger arranged in series in the moving direction of the spool, a suction portion having a wall thickness reduced as the distance from the spool increases, a thin portion adjacent to the suction portion far from the spool, and the thin portion 0.5 from the suction unit
a stator having a cylindrical peripheral wall formed with a hole having a center at a position separated by not less than 1 mm and not more than 1 mm, a stator forming the magnetic circuit for storing the plunger and moving the plunger to the spool side, An urging means for urging the movable member. 6. The solenoid valve device according to claim 5, wherein the hole penetrates a peripheral wall of the stator. 7. The solenoid valve device according to claim 5, wherein the plunger has a respiratory flow passage penetrating from an end surface on a spool side to an end surface on a side opposite to the spool.