JP5209434B2 - solenoid valve - Google Patents

Description

  The present invention relates to an electromagnetic valve that controls, for example, hydraulic pressure.

  Conventionally, when a hydraulic pressure is controlled in a hydraulic circuit of an automatic transmission of an automobile, an electromagnetic valve 801 as shown in FIG. 4 has been used.

  A solenoid 812 is accommodated in the cover 811 of the electromagnetic valve 801, and a cylindrical yoke 813 is fitted in the solenoid 812 on the lower side in the figure. A core 815 having a flange 814 is accommodated on the upper side of the yoke 813, and the core 815 and the yoke 813 are connected in a state where a cylindrical shape is separated by a guide 816.

  A cylindrical plunger 821 is accommodated inside the yoke 813 and the core 815 so as to freely move up and down. The outer surface of the plunger 821 is on the inner surface of the yoke 813 and the inner surface of the core 815. It is configured to be in sliding contact.

  Accordingly, the plunger 821 is configured such that a sliding contact portion between the yoke 813 and the core 815 forms a magnetic delivery portion, and is attracted to the core 815 side when a magnetic force is generated from the solenoid 812. The spool valve 832 provided in the nozzle 831 can be moved.

  However, in such a conventional solenoid valve 801, when the plunger 821 is moved to the core 815 side as the solenoid 812 is energized, the attractive force increases as the lapping margin between the plunger 821 and the core 815 increases. (See arrow C in FIG. 4).

  As a result, there has been a problem that the flat area of the suction characteristic is shortened.

  The present invention has been made in view of such a conventional problem, and an object of the present invention is to provide an electromagnetic valve capable of expanding a flat region of suction characteristics.

In the electric solenoid valve of the present invention in order to solve the above problems, the solenoid valve opposite site of the outer surface and the inner surface of the core of the plunger constituting the magnetic transfer part during the plunger actuation, the plunger A protrusion having a diameter smaller than that of the general portion is provided at the tip to form a step on the outer surface of the plunger, and a protruding portion that protrudes inward is provided at the base end of the core. A small-diameter portion allowing insertion of the convex portion is formed , a step is formed on the inner side surface of the core , the magnetic delivery portion is a multi-stage structure, and when the plunger is attracted to the core, the plunger A first region in which the outer side surface and the inner side surface of the core are close to or in sliding contact with each other, and the outer side surface of the plunger and the inner side surface of the core are in close proximity or sliding after the plunger is attracted and moved by the core. Open While setting the second region, with Dp1 / Dp when the outside dimensions of the general portion was Dp1 the external dimensions of the protrusions and Dp of the plunger is set to be 0.57 or more 069 or less When the inner diameter dimension of the general part of the core is Dc and the inner diameter dimension of the small diameter part is Dc1, Dc1 / Dc is set to be 0.57 or more and 0.70 or less, and Lp / Lc was set to be 0.27 or more and 0.33 or less when the protrusion amount from the tip to the protrusion tip was Lp and the depth dimension from the tip of the core to the small diameter portion was Lc.

  That is, a step is formed between the outer side surface of the plunger and the inner side surface of the core, and a magnetic transfer part to which magnetism is transferred when the plunger is operated has a multistage structure, and the plunger is attracted to the core. A first region where the outer surface of the plunger and the inner surface of the core come close to or in sliding contact with each other, and after the plunger has been attracted and moved by the core, the outer surface of the plunger and the core A second region is formed in which the inner surface starts proximity or sliding contact.

  For this reason, at the start of movement when the plunger starts to be attracted by the core, in the first region, the outer side surface of the plunger and the inner side surface of the core are brought close to or in sliding contact with each other, and magnetism is transferred. The plunger is moved by the suction force generated in the first region.

  And after the said plunger is attracted | sucked and moved by the said core, the said outer surface of the said plunger and the said inner surface of the said core will start proximity | contact or a sliding contact in said 2nd area | region.

  As a result, when the suction force of the plunger starts to decrease with the increase of the lapping margin in the first region, the suction force generated in the second region is applied to the plunger.

Then, the tip of the plunger is generally portion and the convex portion of the small-diameter is projected from the tip end portion of the plunger, a step is formed by the general portion and the small diameter of the convex portion of the large diameter.

  Further, the base end portion of the core is provided with a protruding portion that protrudes inward to form a step, and the base end portion of the core is formed with a small-diameter portion that allows the protrusion to be inserted. Has been.

  For this reason, at the start of movement when the plunger starts to be attracted by the core, the outer surface of the general portion of the plunger approaches or slides on the inner surface of the general portion of the core, so that the magnetic delivery is performed. A region is formed.

  At this time, since the convex portion projecting from the tip of the plunger is formed with a smaller diameter than the general portion of the plunger, it does not approach or slide against the general portion of the core. However, when the plunger is sucked and moved by the core and the convex portion is inserted into the small diameter portion formed at the base end portion of the core, the outer surface of the convex portion is the inner diameter of the small diameter portion. In order to approach or slidably contact the side surface, the second region where the magnetism is transferred is formed.

And when the external dimension of the general part of the plunger is Dp and the external dimension of the convex part is Dp1, Dp1 / Dp is set to be 0.57 or more and 069 or less, and the general part of the core is Dc1 / Dc is set to be 0.57 or more and 0.70 or less when the inner diameter dimension is Dc and the inner diameter dimension at the small diameter portion is Dc1, and from the general portion of the plunger to the tip of the convex portion By setting Lp / Lc to be 0.27 or more and 0.33 or less when the protrusion amount is Lp and the depth dimension from the tip of the core to the small diameter portion is Lc, the plunger of the core by the core is set. Experiments require that the flat region of suction characteristics can be efficiently expanded.

In the electric solenoid valve of the present invention as described above, to attract the plunger in the core, when the suction force of the plunger by the first region begins to decrease, at the second region By applying the generated suction force to the plunger, when the suction force by the first region decreases as the plunger moves, the suction force generated in the second region is reduced. Can be increased.

  Thereby, the flat area | region of the attraction | suction characteristic of the said plunger by the said core can be expanded, and the improvement of an operating characteristic can be aimed at.

Further, by projecting the front SL diameter of the convex portion from the general portion in the distal end of the plunger, to form a stepped by general portion and the small diameter of the convex portion of the large diameter at the distal end of the plunger, groups of the core The first region and the second region are formed by providing a protruding portion projecting inward at the end portion to form a step, and forming a small-diameter portion allowing insertion of the convex portion at the base end portion of the core. Regions can be formed.

Furthermore, the prior SL Dp1 / Dp when the outside dimensions of the general portion was Dp1 the external dimensions of the protrusions and Dp of the plunger is set to be 0.57 or more 069 or less, the general portion of the core Dc1 / Dc is set to be 0.57 or more and 0.70 or less when the inner diameter dimension of the small diameter part is Dc and the inner diameter dimension of the small diameter part is Dc1, and from the general part of the plunger to the tip of the convex part Lp / Lc is set to be 0.27 or more and 0.33 or less when the protrusion amount of Lp is Lp and the depth dimension from the tip of the core to the small diameter portion is Lc. The flat area of the suction characteristic can be enlarged.

  Thereby, the attraction | suction characteristic of the said plunger by the said core can be brought close to an ideal characteristic.

  Hereinafter, an embodiment of the present invention will be described with reference to the drawings.

  FIG. 1 is a diagram showing an electromagnetic valve 1 according to the present embodiment, and the electromagnetic valve 1 controls hydraulic pressure by a hydraulic circuit in an automatic transmission of an automobile, for example.

  The electromagnetic valve 1 includes a cylindrical container-like cover 11, and a solenoid 12 is fitted in the cover 11. A flange portion 14 of the nozzle 13 is in contact with the end face of the solenoid 12, and a peripheral edge portion of the flange portion 14 is fixed by a crimping portion 15 formed by bending the edge of the cover 11.

  A cylindrical yoke 21 is fitted into the solenoid 12 on the lower side in the drawing, and a core 23 having a flange 22 is accommodated on the upper side of the yoke 21. One end of a cylindrical guide 24 is fitted on the tip of the core 23, and the tip of the yoke 21 is fitted on the other end of the guide 24, and the yoke 21, the core 23, Are connected by the guide 24.

  Plungers 31 are accommodated inside the yoke 21 and the core 23 so as to be movable up and down. The plunger 31 slides on the inner side 32 of the yoke 21 and the inner side 33 of the core 23. It is configured to touch.

  Accordingly, the plunger 31 is configured such that a sliding contact portion between the yoke 21 and the core 23 constitutes a magnetic delivery portion, and when the magnetic force is generated by the solenoid 12, the excited core 23 is used to generate the magnetic force. The plunger 31 is sucked and moved upward so that the spool valve 41 in the nozzle 13 extending from the cover 11 can be moved.

  A yoke-side inclined surface 51 that is inclined toward the center side toward the tip is formed at the tip of the yoke 21 and has a tapered shape. In addition, a core-side inclined surface 52 that is inclined toward the center side toward the tip is also formed at the tip of the core 23, and is formed in a tapered shape. Thereby, the yoke 21 and the core 23 are configured such that the magnetic flux concentrates at the tip portions thereof.

  The plunger 31 is formed in a cylindrical shape, and a through hole 61 penetrating in the axial direction is formed in the peripheral portion of the plunger 31. Thereby, when the plunger 31 moves in the axial direction, the fluid can be passed between the distal end side and the proximal end side of the plunger 31 so that the operation of the plunger 31 is facilitated. It is configured.

  As shown in the enlarged view of the main part on the left side of the drawing, a convex portion 72 having a smaller diameter than the plunger general portion 71 is projected at the center portion at the tip of the plunger 31. A step is formed by the plunger general portion 71 and the convex portion 72.

  The inner diameter of the core 23 in the core general portion 81 is set to a size that allows the plunger general portion 71 of the plunger 31 to be inserted, and the core 23 is excited to start attracting the plunger 31. In this case, the first attracting region 85 that transfers magnetism is formed at a location where the outer surface 82 of the plunger general portion 71 and the inner surface 33 of the core general portion 81 are close to or in sliding contact with each other. ing.

  A projecting portion 91 projecting inward is integrally formed on the base end portion of the core 23 over the entire circumference, and the base end portion of the core 23 has a smaller diameter than the core general portion 81. A portion 92 is formed. As a result, a step is formed on the inner side surface 33 of the core 23, and the magnetic delivery part formed by the outer side surface 82 of the plunger 31 and the inner side surface 33 of the core 23 forms a multistage structure. Yes.

  The small diameter portion 92 is set to a size that allows the convex portion 72 to be inserted, and after the core 23 sucks and moves the plunger 31, the outer surface of the plunger 31 at the convex portion 72. The second suction region 101 is formed at a location where the inner surface 33 of the projecting portion 91 that forms the small diameter portion 92 of the core 23 starts approaching or sliding contact.

  As shown in FIG. 2, when the outer dimension of the plunger general portion 71 of the plunger 31 is Dp and the outer dimension of the convex portion 72 is Dp1, Dp1 / Dp is 0.57 or more and 069. When the inner diameter of the core 23 in the core general portion 81 is Dc and the inner diameter of the small diameter portion 92 is Dc1, the Dc1 / Dc is 0.57 or more. It is set to be 0.70 or less. Further, when the protrusion amount from the plunger general portion 71 to the tip of the convex portion 72 in the plunger 31 is Lp and the depth dimension from the tip of the core 23 to the small diameter portion 92 is Lc, Lp / Lc is It is set to be 0.27 or more and 0.33 or less, and these relations are the best patterns (best modes) obtained by experiments.

  In the present embodiment according to the above configuration, a step is formed on the outer side surface 82 of the plunger 31 and the inner side surface 33 of the core 23, and the magnetic delivery part to which magnetism is delivered when the plunger 31 is operated has a multistage structure. A first suction region 85 in which the outer surface 82 of the plunger 31 and the inner surface 33 of the core 23 come close to or slidably contact with each other when the plunger 31 is sucked into the core 23; A second suction region 101 is formed in which the outer surface 82 of the plunger 31 and the inner surface 33 of the core 23 start approaching or sliding after being sucked by the core 23 and moved upward.

  For this reason, at the start of movement when the core 31 starts sucking the plunger 31, the outer surface 82 of the plunger 31 and the inner surface 33 of the core 23 come close to each other or slidably contact each other in the first suction region 85. Magnetism is transferred and the plunger 31 is moved by the attractive force generated in the first attractive region 85.

  After the plunger 31 is sucked and moved by the core 23, the outer surface 82 of the plunger 31 and the inner surface 33 of the core 23 start to approach or slide in the second suction region 101, A suction force is generated.

  Thereby, when the suction force of the plunger 31 starts to decrease with the increase of the lap allowance in the first suction region 85, the suction force generated in the second suction region 101 is reduced to the plunger 31. The suction force reduced in the first suction region 85 as the plunger 31 moves can be supplemented with the suction force generated in the second suction region 101.

  Therefore, the flat region of the suction characteristic of the plunger 31 by the core 23 can be expanded, and the operation characteristic of the electromagnetic valve 1 can be improved.

  A specific structure will be described. A protruding portion 72 having a smaller diameter than the plunger general portion 71 is provided at the tip of the plunger 31, and a large diameter plunger general portion is provided at the tip of the plunger 31. A step is formed by 71 and the small-diameter convex portion 72. Further, the base 23 of the core 23 is provided with a protruding portion 91 that protrudes inward to form a step, and the base 72 of the core 23 is allowed to pass through the convex portion 72. A small diameter portion 92 is formed.

  For this reason, at the start of movement when the plunger 3 starts sucking the plunger 31, the outer surface 82 of the plunger 31 in the plunger general portion 71 approaches or slides on the inner surface 33 of the core 23 in the core general portion 81. By the contact, the first attraction area 85 where the magnetic transfer is performed is formed.

  At this time, the convex portion 72 protruding from the tip of the plunger 31 is formed to have a smaller diameter than the plunger general portion 71 of the plunger 31, and thus is sufficiently separated from the core general portion 81 of the core 23. ing.

  When the plunger 31 is sucked and moved by the core 23 and the convex portion 72 is inserted into the small diameter portion 92 formed at the base end portion of the core 23, the outer surface of the convex portion 72 is The second attracting region 101 is formed in which 82 is brought close to or in sliding contact with the inner surface 33 of the small-diameter portion 92 and magnetic transfer is performed.

  Thus, by projecting the convex portion 72 having a smaller diameter than the plunger general portion 71 at the distal end of the plunger 31, the large diameter plunger general portion 71 and the small diameter convex portion 72 are formed at the distal end portion of the plunger 31. The small diameter is formed so that a step is formed by providing the protruding portion 91 protruding inward at the base end portion of the core 23 to form a step, and the convex portion 72 can be inserted into the base end portion of the core 23. By forming the portion 92, the first suction region 85 and the second suction region 101 can be formed.

  Then, when the outer dimension of the plunger general portion 71 of the plunger 31 is Dp and the outer dimension of the convex portion 72 is Dp1, Dp1 / Dp is set to be 0.57 or more and 069 or less, When the inner diameter of the core 23 in the core general portion 81 is Dc and the inner diameter of the small diameter portion 92 is Dc1, Dc1 / Dc is set to be 0.57 or more and 0.70 or less, and When the protrusion amount from the plunger general portion 71 of the plunger 31 to the tip of the convex portion 72 is Lp and the depth dimension from the tip of the core 23 to the small diameter portion 92 is Lc, Lp / Lc is 0.27. By setting so as to be 0.33 or less, the flat region of the suction characteristic of the plunger 31 by the core 23 can be expanded.

  Here, FIG. 3 is a diagram showing magnetic field analysis calculation results when the dimensions of the respective parts are set to the above-described values, and the magnetic field analysis calculation results in the conventional structure are also shown by broken lines.

  As can be seen from this figure, it is possible to increase the suction force which has been reduced as the stroke amount increases after the suction of the plunger 31 by the core 23 is started and the movement is started. It was confirmed that the area could be expanded.

  Thereby, the attraction | suction characteristic of the said plunger 31 by the said core 23 can be brought close to an ideal characteristic.

It is explanatory drawing which shows one embodiment of this invention. It is explanatory drawing which shows the relationship in each place of the embodiment. It is a figure which shows the magnetic field analysis calculation result of the embodiment. It is explanatory drawing which shows the conventional solenoid valve.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Solenoid valve 21 Yoke 23 Core 31 Plunger 33 Inner side surface 71 Plunger general part 72 Convex part 81 Core general part 82 Outer side surface 85 1st suction area 91 Projection part 92 Small diameter part 101 2nd suction area

Claims (1)

In the solenoid valve in which the opposing part of the outer side surface of the plunger and the inner side surface of the core constitute the magnetic delivery part when the plunger is operated,
A protrusion having a smaller diameter than the general portion protrudes from the front end of the plunger to form a step on the outer surface of the plunger, and a protrusion that protrudes inwardly is provided at the base end of the core. Forming a small-diameter portion that allows the insertion of the convex portion inside, forming a step on the inner side surface of the core , the magnetic delivery portion has a multi-stage structure,
A first region where the outer surface of the plunger and the inner surface of the core come close to or in sliding contact with each other when the plunger is sucked into the core; and after the plunger is sucked into the core and moved While setting the second region where the outer side surface and the inner side surface of the core start proximity or sliding contact ,
When the external dimension of the general part of the plunger is Dp and the external dimension of the convex part is Dp1, Dp1 / Dp is set to be 0.57 or more and 069 or less,
Dc1 / Dc is set to be 0.57 or more and 0.70 or less when the inner diameter dimension of the general part of the core is Dc and the inner diameter dimension of the small diameter part is Dc1,
Lp / Lc is not less than 0.27 and not more than 0.33 when the projection amount from the general portion of the plunger to the tip of the convex portion is Lp and the depth dimension from the tip of the core to the small diameter portion is Lc. A solenoid valve characterized by being set as follows .

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