JP2020200938A - Electromagnetic coil and valve device - Google Patents

Abstract

To prevent slipping-off and loss of a spacer member in an electromagnetic coil using the spacer member for electrically connecting an operation part of a valve body and a casing of the electromagnetic coil.SOLUTION: An electromagnetic coil is constituted by a mold coil 13 having an operation part through hole 13A through which an operation part 3 of a valve body 20 is inserted, and a casing 11. A spacer fitting hole 13B is formed in an end of the operation part through hole 13A of the mold coil 13. A spacer member 4 is fitted in the spacer fitting hole 13B. The spacer member 4 is provided between an attractor 33 of the operation part 3 and a base 11a of the casing 11. The attractor 33 and the base 11a are magnetically connected by the spacer member 4. The slipping-off of the spacer member 4 can be prevented by an abutment part 131 between the operation part through hole 13A and the spacer fitting hole 13B.SELECTED DRAWING: Figure 1

Description

The present invention relates to an electromagnetic coil that operates a plunger or the like in the operating portion of the valve device, and a valve device including the electromagnetic coil.

Conventionally, as an electromagnetic coil and valve device of this type, for example, there is one disclosed in Japanese Patent Application Laid-Open No. 59-86477 (Patent Document 1). This conventional valve device is a solenoid valve, in which a plunger facing the attractor is inserted into the plunger tube via a plunger spring, and a solenoid (coil) is arranged on the outer periphery of the plunger tube. Then, the plunger is driven by the electromagnetic force of the solenoid to operate the valve body. That is, the plunger tube, the suction element, and the plunger form a tubular operating portion that operates the valve body on the valve body side, and the solenoid and its outer case form an electromagnetic coil. The operating portion is inserted and arranged in the center of the electromagnetic coil.

Jikkai Sho 59-86477

As described above, the solenoid valve (valve gear) has a structure in which the operating part of the valve body is inserted into the electromagnetic coil, but many solenoid valves allow the electromagnetic coil to be attached to and detached from the operating part. It has become. Then, according to the specifications of the solenoid valve, the solenoid coil attached to the operating portion can be appropriately changed without changing the valve main body portion.

However, if the valve body portion (acting portion) is not changed, there may be a difference between the length of the operating portion and the length of the electromagnetic coil. For example, when the length of the electromagnetic coil is longer than the length of the operating portion (when it is larger), in order to magnetically connect the operating portion (attractor) of the valve body and the outer box of the electromagnetic coil, for example, Patent Document 1 It is conceivable to use a spacer member made of a magnetic material as shown in FIG. 2 and to provide this spacer member between the attractor of the operating portion and the outer box of the electromagnetic coil. However, in such a case, when the electromagnetic coil is replaced, the spacer member may fall out of the electromagnetic coil and the spacer member may be lost.

The present invention is an electromagnetic coil that uses a spacer member that magnetically connects the operating portion (attractor) of the valve body and the outer box of the electromagnetic coil, and an electromagnetic coil that can prevent the spacer member from falling off or being lost. An object of the present invention is to provide a valve device using an electromagnetic coil.

The electromagnetic coil according to claim 1 has an actuating portion in which a plunger is inserted into a tubular plunger case and an aspirator is fixed to an end portion of the plunger case, and is interlocked with the plunger of the actuating portion. An electromagnetic coil mounted on a valve body for operating a valve body, wherein a mold coil having an actuating portion insertion hole through which the actuating portion is inserted is formed, and the molded coil is opposed to the actuating portion insertion hole of the mold coil. The mold is provided with an outer box having a substrate portion to be formed, and a spacer member for magnetically connecting the suction element and the substrate portion between the attractor of the operating portion and the substrate portion of the outer box. It is characterized by having a retaining structure for preventing the spacer member from coming off from the operating portion insertion hole of the coil to the side opposite to the substrate portion.

At this time, it is preferable that at least a part of the spacer member has an outer diameter larger than the inner diameter of the operating portion insertion hole, and the portion having this large outer diameter constitutes a part of the retaining structure.

Further, in the state before being attached to the operating portion, the part forming a part of the retaining structure of the spacer member is formed between the substrate portion of the outer box and the operating portion insertion hole. It is preferable that the working portion insertion hole is loosely fitted so as to be movable in the axial direction.

Further, the spacer member has an outer box side coupling surface that contacts the substrate portion of the outer box and an attractor side coupling surface that contacts the attractor, and the attractor side coupling surface is of the attractor. It is preferable that the outer box side coupling surface is configured to be in contact with the entire surface of the surface facing the attractor side coupling surface and to be in contact with the substrate portion in a wider area than the entire surface of the outer box side coupling surface.

At this time, a spacer fitting hole having an inner diameter larger than that of the actuating portion insertion hole is provided on the substrate side of the actuating portion insertion hole, and the spacer member is fitted into the spacer fitting hole to insert the actuating portion. It is preferable that the retaining structure is formed by contacting the outer periphery of the end portion of the spacer member with the stepped portion between the hole and the spacer fitting hole.

Further, a collar portion having a diameter larger than the inner diameter of the actuating portion insertion hole is formed on the outer periphery of the spacer member, and the flange portion comes into contact with the opening peripheral portion on the substrate portion side of the actuating portion insertion hole, whereby the collar portion comes out. It is preferable that a stop structure is configured.

Further, the substrate portion side of the actuating portion insertion hole has a spacer fitting hole having a tapered surface whose diameter increases as the distance from the actuating portion insertion hole increases, and the spacer member is the spacer fitting hole. It is preferable that the outer peripheral surface of the spacer member and the tapered surface are brought into contact with each other to form the retaining structure.

The valve device of the present invention is characterized in that the electromagnetic coil according to any one of claims 1 to 6 is provided with respect to the operating portion of the valve main body portion.

According to the electromagnetic coil of the present invention, the retaining structure prevents the spacer member from coming off from the insertion hole of the operating portion of the mold coil to the side opposite to the substrate portion, so that the spacer member can be prevented from falling off or being lost. ..

Further, according to the valve device of the present invention, it is possible to prevent the spacer member from falling off or being lost when the electromagnetic coil is attached or detached.

It is a vertical sectional view at the time of de-energization of the valve device of 1st Embodiment of this invention. FIG. 5 is an enlarged cross-sectional view of a main part showing a state before attachment of the electromagnetic coil to the valve main body in the first embodiment. It is an enlarged sectional view of the main part which shows the state after attachment to the operating part of the electromagnetic coil in 1st Embodiment. FIG. 5 is an enlarged cross-sectional view of a main part showing a state before attachment of the electromagnetic coil to the valve body according to the second embodiment of the present invention. It is an enlarged sectional view of the main part which shows the state after attachment to the operating part of the electromagnetic coil in 2nd Embodiment. It is an enlarged sectional view of the main part which shows the state after attachment to the actuating part of the electromagnetic coil in 3rd Embodiment of this invention. It is an enlarged sectional view of the main part which shows the state after attachment to the operating part of the electromagnetic coil in 4th Embodiment of this invention. It is an enlarged sectional view of the main part which shows the state after attachment to the operating part of the electromagnetic coil in 5th Embodiment of this invention. It is an enlarged sectional view of the main part which shows the state after attachment to the actuating part of the electromagnetic coil in 6th Embodiment of this invention.

Next, an embodiment of the electromagnetic coil and valve device of the present invention will be described with reference to the drawings. The valve device of each of the following embodiments is an example of a pilot solenoid valve. FIG. 1 is a vertical cross-sectional view of the valve device of the first embodiment when the valve device is not energized. The concept of "up and down" in the following description corresponds to the top and bottom in the drawing of FIG. The valve device of the first embodiment is composed of an electromagnetic coil 10 and a valve body 20. The reference numeral “L” in the figure is an axis that is the center of the plunger tube 31 and the operating portion insertion hole 13A, which will be described later.

The electromagnetic coil 10 includes an outer box 11, a fixing plate 12, a mold coil 13, and a spacer member 4. The fixed plate 12 is formed by insert molding with the mold resin 13a of the mold coil 13, and the mold coil 13 is formed. It is provided integrally with. The outer box 11, the fixing plate 12, and the spacer member 4 are each made of a magnetic material. The outer box 11 has a substrate portion 11a fitted to the end of the mold coil 13 on the opposite side of the fixing plate 12, and a pair of side plate portions 11b extending in the same direction from the substrate portion 11a in parallel with the axis L. It is integrally formed with (shown by a broken line) and is configured in a "U" shape. Further, the substrate portion 11a is located so as to intersect the operating portion insertion hole 13A of the motor coil 13, which will be described later.
The pair of side plate portions 11b are located on the side circumference of the mold coil 13, and the fixing plate 12 is sandwiched between the ends opposite to the substrate portion 11a, and the fixing plate 12 (and the mold coil 13) is crimped or the like. Is fixed.

The mold coil 13 is obtained by winding a cylindrical coil 13c around a bobbin 13b and integrally molding these with a mold resin 13a. Further, the bobbin 13b has a substantially cylindrical hole in the center, whereby the operating portion insertion hole 13A and the spacer fitting hole 13B having the axis L as the center line are formed in the mold coil 13. .. The spacer fitting hole 13B communicates with the operating portion insertion hole 13A and opens on the substrate portion 11a side of the outer box 11, and the inner diameter of the spacer fitting hole 13B is larger than the inner diameter of the operating portion insertion hole 13A. There is. A columnar spacer member 4 is fitted in the spacer fitting hole 13B, and a suction element 33 and a plunger tube 31 of the operation part 3 described later are inserted into the operation part insertion hole 13A, and the suction child 33 is inserted. A spacer member 4 is interposed between the outer box 11 and the substrate portion 11a of the outer box 11. The electromagnetic coil 10 is fixed to the attractor 33 of the operating portion 3 by a screw N via a screw hole 11c of the substrate portion 11a and a central hole 14a of the spacer member 4. Details of the spacer member 4 will be described later.

The valve body portion 20 has a valve housing 21 and an operating portion 3 provided on the valve housing 21, and the valve housing 21 is composed of a metal joint portion 21A and a cylinder portion 21B. The joint portion 21A has a central axis about a high-pressure primary side joint 21a into which a fluid such as a refrigerant flows in, a secondary side joint 21b in which a fluid flows out, and an axis L orthogonal to the primary side joint 21a and the secondary side joint 21b. It has a holder portion 21c and the like. The cylinder portion 21B is fixed coaxially with the holder portion 21c by screwing into the holder portion 21c.

Further, in the joint portion 21A, a partition wall 21d is formed between the primary side joint 21a and the secondary side joint 21b, and a main valve seat 21e is formed on the holder portion 21c side of the partition wall 21d. A main valve port 21f having a circular opening is formed in the main valve seat 21e, and a thin circular valve chamber 21g is formed around the main valve seat 21e. Further, the cylinder portion 21B extends from the holder portion 21c to the operating portion 3 side, and a cylindrical guide hole 21h is formed inside the cylinder portion 21c, and the piston valve 22 is inserted into the guide hole 21h. Has been done. A strainer 21i is arranged in the primary side joint 21a. The strainer 21i is attached to the plug 21j, and is attached to the end of the primary side joint 21a together with the plug 21j.

The outer shape of the piston valve 22 is substantially cylindrical, and the metal piston portion 22a covering the outside and the resin seal portion 22b arranged inside the piston valve 22 are mutually press-fitted to press the upper portion of the piston portion 22a. It is integrally formed by bending and crimping inward. The piston valve 22 is arranged so as to face the main valve port 21f, and a truncated cone-shaped valve opening spring 22c is compressed and arranged between the bottom of the valve chamber 21g and the piston valve 22. The piston valve 22 is urged in a direction away from the main valve seat 21e (valve opening direction) by the spring force of the valve opening spring 22c. Then, the seal portion 22b closes the main valve port 21f when the piston valve 22 is seated on the main valve seat 21e.

Further, a pilot port 22d and a conduction path 22e are formed in the center of the seal portion 22b, and the pilot port 22d is conducted to the secondary side joint 21b via the conduction path 22e and the main valve port 21f. A clearance is provided between the piston valve 22 and the guide hole 21h of the cylinder portion 21B, and the fluid on the primary side joint 21a side can flow into the back space of the piston valve 22 through this clearance.

The actuating portion 3 is attracted by a cylindrical plunger tube 31 centered on the axis L, a plunger 32 made of a magnetic material inserted in the plunger tube 31, and a magnetic material fixed to the upper end of the plunger tube 31. It includes a child 33 and a plunger spring 34 disposed between the plunger 32 and the suction element 33.

The plunger tube 31 is fitted to the cylinder portion 21B coaxially with the guide hole 21h, and the plunger tube 31 and the periphery of the end portion of the cylinder portion 21B are fixed by brazing or the like. Further, the plunger 32 is slidably arranged in the plunger tube 31 in the axis L direction (vertical direction). A conical pilot valve 32a is formed at the lower end of the plunger 32, and the pilot valve 32a opens and closes the pilot port 22d of the piston valve 22.

With the above configuration, the valve device of the embodiment is provided in the refrigeration cycle system, the high-pressure refrigerant of the primary side joint 21a flows in, and the refrigerant flows out from the secondary side joint 21b. When the electromagnetic coil 10 is not energized (when it is not energized), the state shown in FIG. 1 is obtained, and the plunger 32 is separated from the attractor 33 by the urging force of the plunger spring 34 and the weight of the plunger 32. At this time, the pilot valve 32a closes the pilot port 22d. Further, the piston valve 22 descends together with the plunger 32 (pilot valve 32a) to close the main valve port 21f, and the refrigerant passage is cut off. At this time, the back space of the piston valve 22 becomes high pressure, and the valve closed state by the piston valve 22 is surely maintained.

When the electromagnetic coil 10 is energized, an attractive force is generated between the suction element 33 and the plunger 32 to raise the plunger 32, and the pilot valve 32a is separated from the pilot port 22d. As a result, the back space of the piston valve 22 is conducted to the secondary side joint 21b to reduce the pressure. As a result, the piston valve 22 is separated from the main valve port 22f by the rising force generated by the pressure difference between the back space of the piston valve 22 and the primary side joint 21a and the spring force of the valve opening spring 22c, and the piston valve 22 is in a valve open state. Flows from the primary side joint 21a to the secondary side joint 21b.

FIG. 2 is an enlarged cross-sectional view of a main part showing a state before the electromagnetic coil 10 is attached to the valve body 20 in the first embodiment, and FIG. 3 is an operating portion 3 (valve body 20) of the electromagnetic coil 10 in the first embodiment. ) Is an enlarged cross-sectional view of a main part showing a state after attachment. As shown in FIG. 2, the outer diameter of the spacer member 5 is larger than the inner diameter of the operating portion insertion hole 13A. The stepped portion between the operating portion insertion hole 13A and the spacer fitting hole 13B is a contact portion 131 forming an annular flat surface, and in the state before the electromagnetic coil 10 is attached to the operating portion 3, The outer peripheral portion 41 of the lower end surface of the spacer member 4 can come into contact with the contact portion 131. That is, the distance from the contact portion 131 to the inner surface of the substrate portion 11a of the outer box 11 is larger than the height of the spacer member 4 (the length in the axis L direction), and the outer peripheral portion 41 hits the contact portion 131. In the state of being in contact with each other, there is a gap between the inner surface of the substrate portion 11a and the upper surface of the spacer member 4.

As described above, in the state before the electromagnetic coil 10 is attached to the operating portion 3, the spacer member 4 has the axis L of the operating portion insertion hole 13A between the substrate portion 11a of the outer box 11 and the operating portion insertion hole 13A. It is loosely fitted so that it can move in the direction. Therefore, for example, even if a force is applied to the spacer member 4 from the substrate portion 11a side of the outer box 11, the spacer member 4 does not press the contact portion 131 (bobbin 13b), and the bobbin 13b is damaged. Can be prevented.

Then, when the spacer member 4 comes into contact with the contact portion 131, the spacer member 4 is not inserted into the operating portion insertion hole 13A, and the spacer member 4 and the substrate portion 11a from the operating portion insertion hole 13A Is prevented from coming out to the other side. As described above, the outer peripheral portion 41 and the contact portion 131 of the spacer member 4 have a “retaining structure”. Further, when the electromagnetic coil 10 is attached to the valve body 20 as shown in FIG. 3, the attractor 33 is in contact with the lower surface of the spacer member 4 and the upper surface of the spacer member 4 is in contact with the inner surface of the substrate portion 11a. Will be done. As a result, the spacer member 4 magnetically connects the substrate portion 11a and the attractor 33. Here, the spacer member 4 has an outer box side coupling surface 4A that contacts the substrate portion 11a of the outer box 11 and an attractor side coupling surface 4B that contacts the attractor 33. Further, the attractor-side coupling surface 4B contacts the entire surface of the spacer-side flat surface 33A of the attractor 33 facing the attractor-side coupling surface 4B. Further, the outer box side coupling surface 4A is in contact with the substrate portion 11a in an area wider than the entire surface of the spacer side plane 33A (opposing surface) of the suction element 33. With such a structure, since the outer box side coupling surface 4A of the spacer member 4 is wide, the magnetic path area between the spacer member 4 and the outer box 11 (board portion 11a) can be widened, and the magnetic efficiency can be improved. improves.

FIG. 4 is an enlarged cross-sectional view of a main part showing a state before the electromagnetic coil 10 is attached to the valve body 20 in the second embodiment, and FIG. 5 is an operating portion 3 (valve body 20) of the electromagnetic coil 10 in the second embodiment. ) Is an enlarged cross-sectional view of a main part showing a state after attachment. In the following second to sixth embodiments, the difference from the first embodiment is mainly the "retaining structure", and the structure around the spacer member will be described. Other configurations are the same as those of the first embodiment, and the same reference numerals as those of FIGS. 1 to 3 are added to the members similar to those of the first embodiment in the drawings of each embodiment, and duplicate description will be omitted as appropriate. , The description of the first embodiment will be appropriately incorporated.

In the second embodiment of FIG. 5, the spacer fitting hole 13B of the first embodiment is eliminated, and the operating portion insertion hole 13A is extended to the substrate portion 11a side of the outer box 11. Further, in the spacer member 5, a flange portion 51 is formed on the outer periphery of the end portion of the outer box 11 facing the substrate portion 11a, and a part (almost all) of the spacer member 5 is inserted into the operating portion insertion hole 13A. There is. Further, a mortar-shaped tapered portion 132 is formed around the opening of the operating portion insertion hole 13A on the substrate portion 11a side, and the flange portion 51 of the spacer member 5 is arranged so as to face the tapered portion 132. The outer diameter of the flange portion 51 is larger than the inner diameter of the operating portion insertion hole 13A.

As described above, in the state before the electromagnetic coil 10 is attached to the operating portion 3, the flange portion 51 of the spacer member 5 is located between the substrate portion 11a of the outer box 11 and the operating portion insertion hole 13A (or the tapered portion 132). Therefore, it is loosely fitted so as to be movable in the axis L direction of the operating portion insertion hole 13A. Therefore, for example, even if a force is applied to the spacer member 5 from the substrate portion 11a side of the outer box 11, the flange portion 51 of the spacer member 5 does not press the tapered portion 132 (bobbin 13b), and the bobbin 13b Damage etc. can be prevented.

Further, with the above configuration, the flange portion 51 of the spacer member 5 can be brought into contact with the tapered portion 132 (aperture peripheral portion). Therefore, even in the state before the electromagnetic coil 10 is attached to the operating portion 3, the spacer member 5 is prevented from coming off from the operating portion insertion hole 13A to the side opposite to the substrate portion 11a. As described above, the flange portion 51 and the tapered portion 132 of the spacer member 5 have a “retaining structure”. Further, when the electromagnetic coil 10 is attached to the valve body 20 as shown in FIG. 5, the attractor 33 is in contact with the lower surface of the spacer member 5, and the upper surface of the spacer member 5 is in contact with the inner surface of the substrate portion 11a. Will be done. As a result, the spacer member 5 magnetically connects the substrate portion 11a and the attractor 33. Also in this second embodiment, the spacer member 5 has an outer case side coupling surface 5A in contact with the substrate portion 11a and an attractor side coupling surface 5B in contact with the attractor 33, and the attractor side coupling surface 5B is this. It contacts the entire surface of the spacer-side flat surface 33A of the attractor 33 facing the attractor-side coupling surface 5B. Further, the outer box side coupling surface 5A is in contact with the substrate portion 11a in an area wider than the entire surface of the spacer side plane 33A (opposing surface) of the suction element 33. Therefore, since the outer box side coupling surface 5A of the spacer member 5 is wide, the magnetic path area between the spacer member 5 and the outer box 11 (board portion 11a) can be widened, and the magnetic efficiency is improved.

FIG. 6 is an enlarged cross-sectional view of a main part showing a state after the electromagnetic coil 10 is attached to the operating portion 3 (valve main body portion 20) in the third embodiment. In the third embodiment, the shape of the spacer fitting hole 13B of the first embodiment is deformed so that the diameter of the spacer fitting hole 13A increases as the distance from the actuating portion insertion hole 13A increases toward the substrate portion 11a of the actuating portion insertion hole 13A. A truncated cone-shaped spacer fitting hole 13C having a tapered surface is formed. Further, the spacer member 6 has a truncated cone shape that matches the spacer fitting hole 13C. That is, the outer diameter of the outer circumference 61 of the spacer member 6 is larger than the inner diameter of the operating portion insertion hole 13A toward the substrate portion 11a.

As described above, in the state before the electromagnetic coil 10 is attached to the operating portion 3, the outer peripheral 61 of the spacer member 6 has the substrate portion 11a of the outer box 11 and the operating portion insertion hole 13A (or the spacer fitting hole 13C). Between them, they are loosely fitted so as to be movable in the axis L direction of the operating portion insertion hole 13A. Therefore, for example, even if a force is applied to the spacer member 6 from the substrate portion 11a side of the outer box 11, the spacer member 6 does not press the spacer fitting hole 13C (bobbin 13b), and the bobbin 13b is damaged. Can be prevented.

Further, with the above configuration, the outer peripheral 61 of the spacer member 6 can come into contact with the inner surface of the spacer fitting hole 13C. Therefore, even in the state before the electromagnetic coil 10 is attached to the operating portion 3, the spacer member 6 is prevented from coming off from the operating portion insertion hole 13A to the side opposite to the substrate portion 11a. As described above, the outer peripheral 61 of the spacer member 6 and the truncated cone-shaped spacer fitting hole 13C have a “retaining structure”. Further, in the state where the electromagnetic coil 10 is attached to the operating portion 3 as shown in FIG. 6, the attractor 33 is brought into contact with the lower surface of the spacer member 6 and the upper surface of the spacer member 6 is brought into contact with the inner surface of the substrate portion 11a. To. As a result, the spacer member 6 magnetically connects the substrate portion 11a and the attractor 33. Also in this third embodiment, the spacer member 6 has an outer case side coupling surface 6A in contact with the substrate portion 11a and an attractor side coupling surface 6B in contact with the attractor 33, and the attractor side coupling surface 6B is this. It contacts the entire surface of the spacer-side flat surface 33A of the attractor 33 facing the attractor-side coupling surface 6B. Further, the outer case side coupling surface 6A is in contact with the substrate portion 11a in an area wider than the entire surface of the spacer side flat surface 33A (opposing surface) of the suction element 33. Therefore, since the outer box side coupling surface 6A of the spacer member 6 is wide, the magnetic path area between the spacer member 6 and the outer box 11 (board portion 11a) can be widened, and the magnetic efficiency is improved.

FIG. 7 is an enlarged cross-sectional view of a main part showing a state after the electromagnetic coil 10 is attached to the operating portion 3 (valve main body portion 20) in the fourth embodiment. In the fourth embodiment, the depth of the spacer fitting hole 13B of the first embodiment is made shallow to form a spacer fitting hole 13D having an inner diameter larger than the inner diameter of the working portion insertion hole 13A, and the spacer fitting hole 13A and the working portion insertion hole 13A are formed. The portion of the step with the spacer fitting hole 13D is a contact portion 133 forming an annular flat surface. Further, in the spacer member 7, a flange portion 71 having an outer diameter larger than the inner diameter of the operating portion insertion hole 13A is formed on the outer periphery of the end portion of the outer box 11 facing the substrate portion 11a, and the flange portion 71 and the spacer member 7 are formed. The shape is such that a stepped portion 7a that matches the spacer fitting hole 13D and the operating portion insertion hole 13A is provided between the portion where the flange portion 71 is not formed.

Further, as shown in FIG. 7, as can be seen from the fact that a gap is formed between the contact portion 133 and the step portion 7a of the spacer member 7, before the electromagnetic coil 10 is attached to the operating portion 3. In this state, the flange portion 71 of the spacer member 7 is loosely fitted between the substrate portion 11a of the outer box 11 and the contact portion 133 so as to be movable in the axial L direction of the operating portion insertion hole 13A. Therefore, for example, even if a force is applied to the spacer member 7 from the substrate portion 11a side of the outer box 11, the spacer member 7 does not press the contact portion 133 (bobbin 13b), and the bobbin 13b is damaged. Can be prevented.

As a result, even in a state where a part of the spacer member 7 is inserted into the operating portion insertion hole 13A and before the electromagnetic coil 10 is attached to the operating portion 3, the step portion 7a of the spacer member 7 is in contact portion 133. It is possible to contact with. Therefore, even in the state before the electromagnetic coil 10 is attached to the operating portion 3, the spacer member 7 is prevented from coming off from the operating portion insertion hole 13A to the side opposite to the substrate portion 11a. As described above, the step portion 7a of the spacer member 7 and the contact portion 133 have a “retaining structure”. Further, when the electromagnetic coil 10 is attached to the operating portion 3 as shown in FIG. 7, the attractor 33 is brought into contact with the lower surface of the spacer member 7 and the upper surface of the spacer member 7 is brought into contact with the inner surface of the substrate portion 11a. To. As a result, the spacer member 7 magnetically connects the substrate portion 11a and the attractor 33. Also in the fourth embodiment, the spacer member 7 has an outer case side coupling surface 7A in contact with the substrate portion 11a and an attractor side coupling surface 7B in contact with the attractor 33, and the attractor side coupling surface 7B is this. It contacts the entire surface of the spacer side flat surface 33A of the suction element 33 facing the suction element side coupling surface 7B. Further, the outer case side coupling surface 7A is in contact with the substrate portion 11a in an area wider than the entire surface of the spacer side flat surface 33A (opposing surface) of the suction element 33. Therefore, since the outer box side coupling surface 7A of the spacer member 7 is wide, the magnetic path area between the spacer member 7 and the outer box 11 (board portion 11a) can be widened, and the magnetic efficiency is improved.

FIG. 8 is an enlarged cross-sectional view of a main part showing a state after the electromagnetic coil 10 is attached to the operating portion 3 (valve main body portion 20) in the fifth embodiment. In the fifth embodiment, the length of the spacer member 8 is longer than that of the spacer member 4 in the first embodiment, and the recess 111 is provided in the substrate portion 11a'of the outer box 11 by that amount.

As in the first embodiment, the outer peripheral diameter of the spacer member 8 is larger than the inner diameter of the operating portion insertion hole 13A, and the spacer member is in a state before the electromagnetic coil 10 is attached to the operating portion 3. The outer peripheral portion 81 of the lower end surface of No. 8 can come into contact with the contact portion 131. Further, as shown in FIG. 8, as can be seen from the fact that a gap is formed between the contact portion 131 and the outer peripheral portion 81 of the lower end surface of the spacer member 8, the moving portion 3 of the electromagnetic coil 10 is reached. In the state before mounting, the outer peripheral portion 81 of the lower end surface of the spacer member 8 is the axis of the operating portion insertion hole 13A between the substrate portion 11a of the outer box 11 and the operating portion insertion hole 13A (contact portion 131). It is loosely fitted so as to be movable in the L direction. Therefore, for example, even if a force is applied to the spacer member 8 from the substrate portion 11a side of the outer box 11, the spacer member 8 does not press the contact portion 133 (bobbin 13b), and the bobbin 13b is damaged. Can be prevented.

Then, when the spacer member 8 comes into contact with the contact portion 131, the spacer member 8 is not inserted into the operating portion insertion hole 13A, and the substrate portion 11a ′ from the operating portion insertion hole 13A of the spacer member 8 The exit to the opposite side is prevented. As described above, the outer peripheral portion 81 and the contact portion 131 of the spacer member 8 have a “retaining structure”. Further, when the electromagnetic coil 10 is attached to the operating portion 3 as shown in FIG. 8, the attractor 33 is brought into contact with the lower surface of the spacer member 8, and the upper surface of the spacer member 8 is the inner surface of the recess 111 of the substrate portion 11a'. Is in contact with. As a result, the spacer member 8 magnetically connects the substrate portion 11a and the attractor 33. Also in the fifth embodiment, the spacer member 8 has an outer case side coupling surface 8A in contact with the substrate portion 11a and an attractor side coupling surface 8B in contact with the attractor 33, and the attractor side coupling surface 8B is this. It contacts the entire surface of the spacer-side flat surface 33A of the attractor 33 facing the attractor-side coupling surface 8B. Further, the outer box side coupling surface 8A is in contact with the substrate portion 11a in an area wider than the entire surface of the spacer side plane 33A (opposing surface) of the suction element 33. Therefore, since the outer box side coupling surface 8A of the spacer member 8 is wide, the magnetic path area between the spacer member 8 and the outer box 11 (board portion 11a) can be widened, and the magnetic efficiency is improved.

FIG. 9 is an enlarged cross-sectional view of a main part showing a state after the electromagnetic coil 10 is attached to the operating portion 3 (valve main body portion 20) in the sixth embodiment. In this sixth embodiment, the spacer fitting hole 13B of the first embodiment is eliminated. Further, in the spacer member 9, a flange portion 91 is formed on the outer periphery of the end portion of the outer box 11 facing the substrate portion 11a, and a part (almost all) of the spacer member 9 is inserted into the operating portion insertion hole 13A. The collar portion 91 is arranged between the bobbin 13b'and the substrate portion 11a so that the collar portion 91 faces the opening peripheral portion 134 on the substrate portion 11a side of the operating portion insertion hole 13A. That is, the opening peripheral portion 134 constitutes a contact portion with respect to the flange portion 91. The outer diameter of the flange portion 91 is larger than the inner diameter of the operating portion insertion hole 13A.

Further, as shown in FIG. 9, as can be seen from the fact that a gap is formed between the opening peripheral portion 134 (contact portion) of the operating portion insertion hole 13A and the flange portion 91 of the spacer member 9. In the state before the electromagnetic coil 10 is attached to the operating portion 3, the flange portion 91 of the spacer member 9 has an operating portion insertion hole between the substrate portion 11a of the outer box 11 and the opening peripheral portion 134 (contact portion). It is loosely fitted so as to be movable in the L direction of the axis of 13A. Therefore, for example, even if a force is applied to the spacer member 9 from the substrate portion 11a side of the outer box 11, the spacer member 9 does not press the opening peripheral portion 134 (bobbin 13b), and the bobbin 13b is damaged. Can be prevented.

Further, with the above configuration, the flange portion 91 of the spacer member 9 can be brought into contact with the opening peripheral portion 134 (contact portion) of the operating portion insertion hole 13A. As a result, even before the electromagnetic coil 10 is attached to the operating portion 3, the spacer member 9 is prevented from coming off from the operating portion insertion hole 13A to the side opposite to the substrate portion 11a. As described above, the flange portion 91 and the opening peripheral portion 134 of the spacer member 9 have a “retaining structure”. Further, in the state where the electromagnetic coil 10 is attached to the operating portion 3 as shown in FIG. 9, the attractor 33 is brought into contact with the lower surface of the spacer member 9 and the upper surface of the spacer member 9 is brought into contact with the inner surface of the substrate portion 11a. To. As a result, the spacer member 9 magnetically connects the substrate portion 11a and the attractor 33. Also in the sixth embodiment, the spacer member 9 has an outer case side coupling surface 9A in contact with the substrate portion 11a and an attractor side coupling surface 9B in contact with the attractor 33, and the attractor side coupling surface 9B is this. It contacts the entire surface of the spacer-side flat surface 33A of the attractor 33 facing the attractor-side coupling surface 9B. Further, the outer box side coupling surface 9A is in contact with the substrate portion 11a in an area wider than the entire surface of the spacer side flat surface 33A (opposing surface) of the suction element 33. Therefore, since the outer box side coupling surface 9A of the spacer member 9 is wide, the magnetic path area between the spacer member 9 and the outer box 11 (board portion 11a) can be widened, and the magnetic efficiency is improved.

As described above, according to the present invention, since the spacer member does not come out from the operating portion insertion hole, it is possible to prevent the spacer member from being lost due to falling off. In addition, a large electromagnetic coil can be attached to a small valve body while sharing the valve body. For example, the electromagnetic coil for DC drive is larger than the electromagnetic coil for AC drive. Therefore, by using a spacer member made of a magnetic material as in the present invention, the valve body can be used for both AC drive and DC drive. The parts can be shared.

Not limited to each of the above embodiments, the retaining structure may be any structure in which the spacer member is locked in the operating portion insertion hole. For example, in the present embodiment, the spacer member is substantially cylindrical, but may be a prism such as a triangular prism or a quadrangular prism. Further, the collar portions 51, 71, 91 do not have to be formed on the entire circumference, and may be formed on a part of the periphery.

The electromagnetic coil of the present invention has an actuating portion in which a plunger is inserted into a tubular plunger case and an attractor is fixed to an end portion of the plunger case, and is interlocked with the plunger of the actuating portion. It is applied to a valve device in which an electromagnetic coil is mounted on the valve body that operates the valve body. In each of the above embodiments, the case where the valve device is a solenoid valve having one primary side joint and one secondary side joint has been described as an example, but for example, selectively for a plurality of secondary side joints. It may be a valve device such as a flow path switching valve through which a fluid flows.

Although the embodiments of the present invention have been described in detail with reference to the drawings, the specific configuration is not limited to these embodiments, and the design changes, etc. within the range not deviating from the gist of the present invention, etc. Even if there is, it is included in the present invention.

10 Electromagnetic coil 11 Outer box 11a Board part 12 Fixing plate 13 Molded coil 13A Acting part insertion hole 13B Spacer fitting hole 13C Spacer fitting hole 13D Spacer fitting hole 13a Mold resin 13b Bobbin 13c Coil 131 Contact part (retaining structure) )
20 Valve body 21 Valve housing 21A Joint 21B Cylinder 21a Primary side joint 21b Secondary side joint 21c Holder part 22 Piston valve 3 Acting part 31 Plunger tube 32 Plunger 32a Pilot valve 33 Suction element 33A Spacer side plane 34 Plunger spring 4 Spacer member 41 Outer circumference (retaining structure)
4A Outer box side joint surface 4B Attractor side joint surface 5 Spacer member 51 collar (retaining structure)
5A Outer box side coupling surface 5B Attractor side coupling surface 132 Tapered part (opening circumference, retaining structure)
13C spacer fitting hole (retaining structure)
6 Spacer member 61 outer circumference (retaining structure)
6A Outer box side coupling surface 6B Attractor side coupling surface 13D Spacer fitting hole 133 Contact part (retaining structure)
7 Spacer member 71 Collar 7A Outer box side coupling surface 7B Attractor side coupling surface 7a Stepped portion (retaining structure)
11a'Substrate 111 Recess 8 Spacer member 81 Outer circumference (retaining structure)
8A Outer box side coupling surface 8B Attractor side coupling surface 13b'Bobbin 134 Opening circumference (retaining structure)
9 Spacer member 91 collar (retaining structure)
9A Outer box side coupling surface 9B Attractor side coupling surface L axis

Claims (8)

A valve body that has an actuating portion in which a plunger is inserted into a tubular plunger case and a suction element is fixed to an end of the plunger case, and operates the valve body in conjunction with the plunger of the actuating portion. It is an electromagnetic coil attached to the part,
A mold coil having an actuating portion insertion hole through which the actuating portion is inserted, an outer box having a substrate portion facing the actuating portion insertion hole of the mold coil, and an attractor of the actuating portion and the outer box. A spacer member for magnetically connecting the attractor and the substrate portion with the substrate portion is provided.
An electromagnetic coil comprising a retaining structure for preventing the spacer member from coming off from the operating portion insertion hole of the mold coil to the side opposite to the substrate portion. The claim is characterized in that at least a part of the spacer member has an outer diameter larger than the inner diameter of the operating portion insertion hole, and the portion having the larger outer diameter constitutes a part of the retaining structure. The electromagnetic coil according to 1. In the state before attachment to the operating portion, the part forming a part of the retaining structure of the spacer member is actuated between the substrate portion of the outer box and the operating portion insertion hole. The electromagnetic coil according to claim 2, wherein the electromagnetic coil is loosely fitted so as to be movable in the axial direction of the partial insertion hole. The spacer member has an outer box side coupling surface that contacts the substrate portion of the outer box and an attractor side coupling surface that contacts the attractor, and the attractor side coupling surface is the suction of the attractor. The claim is characterized in that the outer case side coupling surface is configured to be in contact with the entire surface of the surface facing the child side coupling surface and to be in contact with the substrate portion in a wider area than the entire surface of the outer box side coupling surface. The electromagnetic coil according to any one of 1 to 3. A spacer fitting hole having an inner diameter larger than that of the working portion insertion hole is provided on the substrate side of the working portion insertion hole, and the spacer member is fitted into the spacer fitting hole. The invention according to any one of claims 1 to 4, wherein the retaining structure is formed by contacting the end portion of the spacer member with the step portion with the spacer fitting hole. Electromagnetic coil. A collar portion having a diameter larger than that of the operating portion insertion hole is formed on the outer periphery of the spacer member, and the flange portion comes into contact with the opening peripheral portion on the substrate portion side of the operating portion insertion hole to form the retaining structure. The electromagnetic coil according to any one of claims 1 to 4, wherein the electromagnetic coil is provided. The substrate portion side of the actuating portion insertion hole has a spacer fitting hole having a tapered surface whose diameter increases as the distance from the actuating portion insertion hole increases, and the spacer member fits into the spacer fitting hole. The electromagnetic coil according to any one of claims 1 to 4, wherein the retaining structure is formed by abutting the outer peripheral surface of the spacer member with the tapered surface. A valve device comprising the electromagnetic coil according to any one of claims 1 to 7 with respect to the operating portion of the valve body.

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