JP7148953B2 - Molded coil and electrically driven valve - Google Patents

Description

The present invention relates to molded coils and electrically actuated valves.

A solenoid valve adjusts the degree of opening of the valve using a magnetic force generated by energizing a coil. Such an electromagnetic valve has a molded coil in which a coil and terminals connected to the coil are molded with resin, and a cylindrical housing that accommodates the molded coil. It fixes the molded coil and the housing.

JP-A-2003-142313

A conventional solenoid valve is manufactured by molding a coil and terminals with resin, integrally molding a coil mold part covering the outer periphery of the coil and a connector part including terminals, producing a molded coil, and manufacturing the molded coil. The mold coil and the housing are integrated by housing them in a housing and crimping the ends of the housing. That is, the housing was retrofitted to the molded coil.

In addition, since the caulking receiving portion of the molded coil is formed in a flat annular shape, when the solenoid valve is subjected to vibration for a long period of time, such as when mounted in the engine compartment of an automobile, the molded coil and housing may There is a risk of rotation or the housing falling off from the molded coil.

The above problem applies not only to electromagnetic valves but also to electrically driven valves, such as motor operated valves, which are driven by a driving force generated by energizing a coil.

SUMMARY OF THE INVENTION An object of the present invention is to provide a molded coil and an electrically driven valve that can prevent the housing from rotating and falling off.

The molded coil of the present invention has a cylindrical body, a bobbin having flanges provided at both ends of the cylindrical body, a coil unit having a coil mounted on the cylindrical body, and a cylindrical shape. a housing for accommodating the coil unit; a plate having a cutout and fitted into an opening at one end of the housing; and a resin member formed by molding a part of the coil and the terminal. a first notch portion that has a thickness and is wider on the other end side than on the other end side, and the resin member is provided between the housing and the coil, A coil mold portion covering the coil and a first resin portion protruding outside the coil mold portion and filling the first cutout portion are provided.

The housing is provided with a second notch portion extending from the plate-side end portion to the other end portion, and the resin member is provided so as to protrude outside the coil mold portion to form the second notch portion. You may make it have the 2nd resin part which fills a part.

The housing has an opening that is slightly smaller than the plate and has elasticity, and a plurality of third notches are provided in the circumferential direction at the end of the housing on the plate side. , a plurality of protrusions having the same shape as the third notch are provided on the outer edge, the opening of the housing is pushed wide so that the plate fits into the opening, and the protrusion is formed in the third notch. may be embedded.

The plate is provided with a hole for injecting the resin of the resin member into the housing, and the housing and the plate are made of a magnetic material. A magnetic path, which is a path for the generated magnetic field, may be formed, and the hole may be provided inside the outer edge of the plate.

A convex portion is provided on the end surface of the flange portion on the plate side, and the convex portion includes a base portion provided on the end surface and a projection provided on the base portion that is slightly smaller than the base portion. The plate is provided with a positioning hole into which the projection is fitted, the plate is arranged on the base portion with the projection fitted into the positioning hole, and is aligned with the end surface of the flange portion. An interval may be provided between them.

The resin member may have a terminal mold portion covering a portion of the terminal, and a connector portion surrounding a portion of the terminal exposed from the terminal mold portion.

In the resin member, the terminal mold portion, the connector portion, the coil mold portion, the first resin portion, and the second resin portion may be seamlessly and integrally formed of resin. .

An electrically driven valve according to the present invention includes any of the molded coils described above and a valve body driven by a driving force generated by energizing the coil.

According to the present invention, it is possible to obtain a molded coil and an electrically driven valve that can prevent the housing from rotating and falling off.

1 is a front view of an electromagnetic valve that is an example of an electrically driven valve according to an embodiment; FIG. 1 is a front view of a molded coil according to an embodiment; FIG. It is a rear view of the molded coil according to the embodiment. 1 is a side view of a molded coil according to an embodiment; FIG. FIG. 2 is a cross-sectional view of the molded coil according to the embodiment taken along the line AA. It is a rear view of a bobbin. Fig. 2 is a perspective view of a housing; Fig. 2 is a plan view of a plate; It is a figure for demonstrating the process of assembly of a bobbin and a plate. It is a figure for demonstrating the process of assembly of a coil and a terminal. It is a figure for demonstrating the process of assembly of a housing. FIG. 4 is a perspective view of a molded coil before resin molding;

(embodiment)
EMBODIMENT OF THE INVENTION Hereinafter, embodiment of the electrically driven valve which concerns on this invention is described in detail, referring drawings.

(Constitution)
FIG. 1 is a front view of an electromagnetic valve that is an example of an electrically driven valve according to an embodiment. The solenoid valve 1 includes a molded coil 2 and a valve portion 3, and the valve of the valve portion 3 is driven by a magnetic force generated by energizing the coil included in the molded coil 2, thereby adjusting the opening degree of the valve. be. This solenoid valve 1 is used, for example, as a compressor control valve.

FIG. 2 is a front view of the molded coil 2 according to the embodiment. FIG. 3 is a rear view of the molded coil 2 according to the embodiment. FIG. 4 is a side view of the molded coil 2 according to the embodiment. FIG. 5 is a cross-sectional view of the molded coil 2 according to the embodiment taken along the line AA.

The molded coil 2 includes a bobbin 4, a coil 5, a housing 6, a plate 7, terminals 8, and a resin member 9, as shown in FIGS.

6 is a rear view of the bobbin 4. FIG. The bobbin 4 is made of resin, for example. The resin is, for example, polyphenylene sulfide (PPS). The bobbin 4 has a cylindrical body portion 41, a flange portion 42, a convex portion 43, and an insertion portion 44 for the terminal 8, as shown in FIGS. The tubular trunk portion 41 has a cylindrical shape and is a portion to which the coil 5 is mounted. The flange portions 42 are provided at both ends of the cylindrical body portion 41, and are annular portions protruding in a direction perpendicular to the extending direction of the cylindrical body portion 41 with the ends of the cylindrical body portion 41 as base ends. is.

The convex portion 43 is provided on the end surface 421 of one flange portion 42 and protrudes in the axial direction of the cylindrical body portion 41 . The protrusions 43 are provided at two locations here. The convex portion 43 is composed of a base portion 431 provided on the end surface 421 and a projection 432 provided on the base portion 431 . The projection 432 has a smaller diameter than the base portion 431 . Two insertion portions 44 are provided on an end face 421 of the flange portion 42 on the plate 7 side so as to rise from the end face 421, and the terminal 8 is attached to the bobbin 4 by inserting the terminal 8 (FIGS. See Figure 12).

The coil 5 is formed in a cylindrical shape by winding a conductive wire made of copper, for example, around the cylindrical body portion 41. By winding the conductive wire around the cylindrical body portion 41 to form the coil 5, the coil 5 and a bobbin 4 constitute a coil unit. The conductors are, for example, enamelled copper wires.

FIG. 7 is a perspective view of the housing. The housing 6 is made of a magnetic material, has a cylindrical shape, and accommodates the coil unit. Here, the housing 6 has a cylindrical shape and is one size larger in diameter than the coil unit. That is, as shown in FIG. 5, a space is provided between the inner surface of the housing 6 containing the coil unit and the coil 5 .

As shown in FIG. 7 , the housing 6 is provided with a first notch 61 , a second notch 62 and a plurality of third notches 63 . The first cutout portion 61 is cut out from one end portion 60a to have a length in the axial direction of the housing 6, and is cut wider toward the other end portion 60b than toward the one end portion 60a. He becomes Here, as shown in FIGS. 2 and 7, the first notch portion 61 is cut out in a convex shape. That is, it has a shape combining a quadrangle whose one side is the opening edge of the opening 65 and a wider quadrangle having the same side as the quadrangle and provided on the other end portion 60b side. The “width” referred to here is the length of the housing 6 in the circumferential direction.

As shown in FIG. 7, the second notch 62 extends from one end 60a to the other end 60b. Here, it extends linearly in the axial direction of the housing 6 and reaches from one end 60a to the other end 60b. In other words, the housing 6 viewed from above is C-shaped. A plurality of third notch portions 63 are provided in the end portion 60a in the circumferential direction. Here, the third cutouts 63 are substantially rectangular and provided at four locations.

Further, the housing 6 is provided with a stepped portion 64 inside the opening edge forming the opening 65 on the end portion 60a side. The stepped portion 64 is provided in an annular shape by extending in the circumferential direction except for the first notch portion 61 and the second notch portion 62 . In other words, the stepped portion 64 is formed by cutting the inner peripheral side of the opening edge of the opening 65 in the circumferential direction. , an annular step 641 extending in the circumferential direction, and an inner peripheral surface 642 rising from the step 641 toward the end portion 60a. The inner diameter of the housing 6 is smaller than the diameter of the area surrounded by the inner peripheral surface 642 by the step 641 .

The housing 6 has an opening 65 slightly smaller than the plate 7 . Moreover, the housing 6 has elasticity and can push the opening 65 open. For example, two axial sides defining the second notch 62 can be pushed apart with a finger or the like.

8 is a plan view of the plate 7. FIG. Plate 7 is a yoke made of magnetic material. As shown in FIG. 8, plate 7 is generally annular. That is, the plate 7 has a substantially disk-like plate 71 and a central hole 72 . Plate 7 is fitted into opening 65 of housing 6 . In other words, the plate 71 has the same or substantially the same diameter as the inner diameter of the housing 6 . Here, the plate body 71 is fitted into the opening 65 of the housing 6 so that the outer edge of the plate body 71 contacts the inner peripheral surface 642 of the stepped portion 64, and the plate body 71 is placed on the stepped portion 641 of the stepped portion 64 so that the plate body 71 is mounted on the stepped portion 641. One side of the body 71 is flush with the end 60a of the housing 6. As shown in FIG.

A central hole 72 is provided in the center of the plate 7 . Its size is the same as or slightly smaller than the diameter of the tubular body 41 (see FIG. 5). Also, the plate 7 is provided with a small notch 73 and a large notch 74 . A small notch 73 and a large notch 74 are provided facing each other with the center hole 72 interposed therebetween. In addition, the large cutout 74 has a relatively large cutout area compared to the small cutout 73 . The insertion portion 44 penetrates the notch 74 .

A positioning hole 75 and a resin injection hole 76 are provided in the plate 7 . Here, two positioning holes 75 are provided in the plate 71 so as to face each other with the center hole 72 interposed therebetween. The positioning hole 75 is a through hole into which the projection 432 of the projection 43 is fitted. Two resin injection holes 76 are provided inside the outer edge of the plate 7 . This resin injection hole 76 is a hole for injecting the resin of the resin member 9 . Further, the plate 7 is provided with a plurality of projections 77 on its outer edge. The protrusions 77 are arranged in the circumferential direction of the plate 71 and protrude in the radial direction. The protrusion 77 has the same shape as the third cutout portion 63 of the housing 6 and is fitted into the third cutout portion 63 (see FIGS. 2 to 4 and 12).

The terminal 8 is made of a conductive member and electrically connected to the coil 5 . That is, a pair of terminals 8 are provided, one terminal 8 is inserted into one insertion portion 44 , and the other terminal 8 is inserted into the other insertion portion 44 . The terminal 8 is provided with a projection for entwining the conductor wire forming the coil 5 and a protruding piece for electrically connecting to the conductor wire by crimping. Both ends of the conductor wire constituting the coil 5 from which the coating is removed are pulled out to the terminal 8 side through the large notch 74, and the end of one conductor wire serves as a projection of one terminal 8 or a protruding piece for crimping the conductor wire. The terminal 8 and the coil 5 are electrically connected by entangling and crimping the protruding piece, and by entwining the end of the other conductor wire with the projection and protruding piece of the other terminal 8 and crimping the protruding piece. be done.

As shown in FIG. 12, the terminal 8 has a double L-shaped configuration. That is, it extends in the direction in which the central axis of the housing 6 extends, bends toward the central axis in the middle, further extends in the direction in which the central axis extends, and bends in the central axis direction in the middle. As shown in FIG. 5 , the tip of the terminal 8 is exposed from the resin member 9 and the other portion is embedded in the resin member 9 .

The resin member 9 is made of a resin such as nylon, and as shown in FIG. , are integrally constructed. In other words, the resin member 9 is formed by resin injection molding, and the parts 91 to 95 are seamlessly formed of a common resin.

The terminal mold portion 91 is provided above the flange portion 42 of the bobbin 4 on the side of the plate 7 and partially covers the terminal 8 . Here, not only part of the terminal 8 but also the plate 7 are embedded in the terminal mold portion 91 . The terminal mold portion 91 extends in the axial direction of the bobbin 4 or the housing 6 , has one upper end connected to the connector portion 92 , and the other end connected to the coil mold portion 93 .

The connector portion 92 has a tubular shape extending perpendicularly to the terminal mold portion 91 , and is electrically connected to the terminal 8 by fitting a connection terminal of an external power source to the coil 5 . In other words, the connector portion 92 is configured such that the tip of the terminal 8 that is not embedded in the terminal mold portion 91 is exposed and surrounded by resin. However, the connector portion 92 is provided with an opening 92a into which a mating connector is inserted. The outer surface of the connector portion 92 is provided with a protrusion 92b that engages with a locking piece of the mating connector. The protrusion 92b is also formed during injection molding of the resin member 9, and is seamlessly formed with the connector portion 92 and the resin.

The coil mold portion 93 is formed following the terminal mold portion 91 , is provided between the housing 6 and the coil 5 , and covers the coil 5 . The coil mold portion 93 has a tubular shape (here, a cylindrical shape).

The first resin portion 94 protrudes outside the coil mold portion 93 and fills the first notch portion 61 . That is, the first resin portion 94 has the same shape as the first notch portion 61 . Here, the first resin portion 94 has a convex shape (see FIG. 2). The thickness of the first resin portion 94 is the same as the thickness of the housing 6 . The term “thickness” used herein refers to the radial length of the housing 6 .

The second resin portion 95 protrudes outside the coil mold portion 93 and fills the second notch portion 62 . That is, the second resin portion 95 has the same shape as the second notch portion 62 . Here, the second resin portion 95 has a strip shape. The thickness of the second resin portion 95 is the same as the thickness of the housing 6 . The term “thickness” used herein refers to the radial length of the housing 6 .

The valve portion 3 includes an aspirator, a plunger, a valve body and an orifice (not shown). The attractor is made of a magnetic material and is inserted and fixed inside the molded coil 2 . For example, a suction element is inserted from the opening 66 of the other end 60b of the housing 6 shown in FIG. The plunger is, for example, a hollow rod-shaped body made of a magnetic material, and is slidably arranged in the inner space of the cylindrical body 41, and the valve body is fixed to the tip of the plunger. That is, one end of the plunger is located on the side of the aspirator, and the valve is fixed to the other end.

The valve body tapers, for example, toward the orifice, and has different waist circumferences depending on the height from the tip. When the coil 5 is energized, the attractor and the plunger are excited, and the plunger is attracted to the attractor side, thereby separating the valve body from the orifice and adjusting the opening of the orifice. Further, when the coil 5 is de-energized, the valve body is brought into contact with the orifice by the urging force of a spring provided between the attractor and the plunger, for example, so that the orifice is closed.

A method of manufacturing the molded coil 2 will be described with reference to FIGS. 9 to 12. FIG. 12, illustration of the coil 5 is omitted. First, the plate 7 is attached to the bobbin 4 as shown in FIG. That is, the plate 7 is positioned with respect to the bobbin 4 by fitting the projections 432 of the projections 43 into the positioning holes 75 of the plate 7 . At this time, the base portion 431 functions as a spacer, and a gap is formed between the plate 7 and the end surface 421 of the flange portion 42 .

Next, as shown in FIG. 10 , the terminals 8 are inserted into the insertion portions 44 to form the coils 5 . Specifically, one end portion 51 of the conductor wire is entwined with one terminal 8 for electrical connection, the conductor wire is wound around the cylindrical body portion 41 via the flange portion 42, and the other end portion 52 at the end of the winding is wound. It is electrically connected to the other terminal 8 by winding it through the flange portion 42 . A coil unit is thus formed. Then, as shown in FIG. 11, the coil unit is accommodated inside the housing 6, and the projection 77 is fitted into the third notch 63 to fix the housing 6 to the plate 7. As shown in FIG. Here, since the opening 65 of the housing 6 is slightly smaller than the plate 7 and has elasticity, the outer edge of the plate 7 is brought into contact with the inner peripheral surface 642 of the stepped portion 64 by expanding the opening 65 and fitting the plate 7 thereon. , the one-sided outer side of the plate 7 rests on the stepped portion 641 of the stepped portion 64, and the housing 6 and the coil unit are integrated. Thus, a magnetic circuit can be formed by the plate 7 and the housing 6 made of a magnetic material. A gap is provided between the inner peripheral surface of the housing 6 and the coil 5 and the flange portion 42, and the insertion portion 44 penetrates through the notch 74. Around the insertion portion 44, A gap is provided as shown in FIG. The inside and outside of the housing 6 with the plate 7 interposed therebetween communicate with each other through the small notch 73 and the first notch 61 .

As described above, after the housing 6 and the coil unit are integrated, they are set in a mold, filled with resin in the mold, and solidified to form the resin member 9 . Here, as indicated by a thick arrow in FIG. 4, a resin injection port is provided in the rear portion of the insertion portion 44, and a portion of the terminal 8 is molded to form a terminal mold portion 91 and a connector portion. form 92; Further, the injected resin flows into the gap between the coil 5 and the housing 6, the first notch 61 and the second notch 62 through the gap around the insertion part 44 and the positioning hole 75, and the coil A mold portion 93, a first resin portion 94, and a second resin portion 95 are formed. At this time, the second cutout portion 62 extending from the end portion 60a to the other end portion 60b serves as a flow path for the resin, and the resin flows toward the flange portion 42 opposite to the flange portion 42 to which the plate 7 is attached. be filled.

(action/effect)
(1) The molded coil 2 of this embodiment has a cylindrical body 41, a bobbin 4 having flanges 42 provided at both ends of the cylindrical body 41, and a coil 5 attached to the cylindrical body 41. A coil unit, a housing 6 having a cylindrical shape and housing the coil unit, a plate 7 having a notch 74 and fitted into an opening 65 at one end of the housing 6, and a notch in a flange portion 42 on the plate 7 side. 74, the terminal 8 is electrically connected to the coil 5, and the resin member 9 is formed by molding a part of the coil 5 and the terminal 8. A first notch portion 61 is provided which is cut out from the end portion 60a to have a length in the axial direction of the housing 6 and which is cut wider toward the other end portion 60b than toward the end portion 60a. , the resin member 9 is provided between the housing 6 and the coil 5 to cover the coil 5, and the resin member 9 is provided so as to protrude outside the coil mold portion 93 and fill the first notch portion 61. and a first resin portion 94.

As a result, even if the housing 6 tries to fall off in the axial direction, the first resin portion 94 is caught by the side of the housing 6 forming the wide portion of the first notch portion 61, so that the housing 6 does not fall off in the axial direction. can be prevented. In addition, since the first cutout portion 61 has a length in the axial direction of the housing 6, the first resin portion 94 is caught by the axial side of the housing 6 forming the first cutout portion 61, thereby Rotation around the axis of 6 can be prevented.

(2) The housing 6 is provided with a second notch portion 62 extending from the end portion 60a on the plate 7 side to the other end portion 60b, and the resin member 9 is provided so as to protrude outside the coil mold portion 93, A second resin portion 95 is formed by filling the second notch portion 62 .

Thereby, it is possible to prevent the housing 6 from rotating around the axis. In addition, the second notch 62 serves as a flow path for the resin when the resin member 9 is injection-molded, and the resin can easily flow into the gap between the housing 6 and the coil 5 . As a result, the production time of the resin member 9 and thus the molded coil 2 can be shortened.

(3) The housing 6 has an opening 65 slightly smaller than the plate 7 and has elasticity. A plurality of protrusions 77 having the same shape as the third notch 63 are provided on the outer edge of the plate 7, and the opening 65 of the housing 6 is pushed and expanded to fit the plate 7 into the opening 65, thereby forming the third notch. A protrusion 77 is fitted into the cutout portion 63. - 特許庁

As a result, since the housing 6 is fixed to the plate 7, not only the coil unit, the terminals 8 and the plate 7, but also the housing 6 can be used as an insert of the mold for molding the resin member 9. That is, it is possible to prevent the housing 6 from moving within the mold due to the resin pressure during injection molding of the resin member 9 .

(4) The plate 7 is provided with a resin injection hole 76 for injecting the resin of the resin member 9 into the housing 6. The housing 6 and the plate 7 are made of a magnetic material and are in contact with the housing 6 of the plate 7. A magnetic path for the magnetic field generated by the coil 5 is formed on the outer edge, and the resin injection hole 76 is provided inside the outer edge of the plate 7 .

As a result, the housing 6 can be fixed to the plate 7 without the resin injection hole 76, which is a resin injection hole, interfering with the magnetic path.

(5) A convex portion 43 is provided on the end surface 421 of the flange portion 42 on the plate 7 side. The plate 7 is provided with a positioning hole 75 to be fitted into the projection 432, the plate 7 is fitted with the projection 432 in the positioning hole 75, and is arranged on the base 431, A space is provided between the flange portion 42 and the end face 421 .

As a result, the plate 7 and the coil unit can be positioned by fitting the protrusion 432 into the positioning hole 75, and the base portion 431 serves as a spacer between the plate 7 and the flange portion 42, creating a gap. Since the resin can flow in this gap when molding the resin member 9, the space between the coil 5 and the housing 6, the second notch 62, and the first notch 61 are easily filled with the resin. time can be shortened. In particular, the resin flowing from the resin injection hole 76 can easily enter between the coil 5 and the housing 6 .

(Other embodiments)
The present invention is not limited to the above embodiments, but also includes other embodiments shown below. In addition, the present invention also includes forms in which all or any of the above embodiments and other embodiments described below are combined. Further, various omissions, replacements, and modifications can be made to these embodiments without departing from the scope of the invention, and the modifications are also included in the present invention. In the following other embodiments, portions different from the above embodiment will be explained, and the same portions as those in the above embodiment will be assigned the same reference numerals and description thereof will be omitted.

In the above embodiment, the electrically driven valve is explained as the electromagnetic valve 1, but it is not limited to this. For example, the electrically driven valve may be an electrically operated valve. That is, the motor-operated valve includes a molded coil 2 and a valve body driven by a driving force generated by energizing the coil 5 .

In the above embodiment, the shape of the first notch 61 is convex, but it may be L-shaped, J-shaped, or trapezoidal. Moreover, although the shape of the second notch portion 62 is a straight line extending in the direction parallel to the axis of the housing 6 so as to reach the other end portion 60b from the end portion 60a, it is not limited to this. For example, the second notch portion 62 may be configured by notching in a straight line from the end portion 60a to the other end portion 60b, or in a direction intersecting the circumferential direction of the housing 6. It may be configured by notching.

In the above embodiment, the protrusion 43 is provided on the flange portion 42 of the bobbin 4 and the positioning hole 75 is provided on the plate 7, but the arrangement may be reversed. That is, a projection may be provided on the surface of the plate 7 on the flange portion 42 side, and a positioning hole may be provided on the end surface of the flange portion 42 .

1 Solenoid valve 2 Molded coil 3 Valve portion 4 Bobbin 41 Cylindrical body portion 42 Flange portion 421 End surface 43 Convex portion 431 Base portion 432 Projection 44 Insertion portion 5 Coil 51 One end portion 52 of conducting wire constituting coil Conducting wire constituting coil Other end 6 Housing 60a One end 60b of housing Other end 61 First notch 62 Second notch 63 Third notch 64 Step 641 Step 642 Inner peripheral surface 65 Opening 66 Opening 7 Plate 71 Plate 72 Center hole 73 Small notch 74 Large notch 75 Positioning hole 76 Resin injection hole 77 Projection 8 Terminal 9 Resin member 91 Terminal mold portion 91a Recess 92 Connector portion 92a Opening 92b Projection 93 Coil mold portion 94 First The resin portion 95 of the second resin portion

Claims (8)

a coil unit having a cylindrical body, a bobbin having flanges provided at both ends of the cylindrical body, and a coil mounted on the cylindrical body;
a housing that has a cylindrical shape and accommodates the coil unit;
a plate having a notch and fitted into the opening at one end of the housing;
a terminal provided upright through the notch in the flange portion on the plate side and electrically connected to the coil;
a resin member obtained by molding a part of the coil and the terminal;
with
The housing includes:
A first cutout portion is provided which is cut out from the end portion on the plate side, has a length in the axial direction of the housing, and is cut out wider toward the other end side than the end portion side. ,
The resin member is
a coil mold portion provided between the housing and the coil and covering the coil;
a first resin portion protruding outside the coil mold portion and filling the first notch portion;
having
A molded coil characterized by The housing is provided with a second notch extending from the plate-side end to the other end,
The resin member is
Having a second resin portion protruding outside the coil mold portion and filling the second notch portion;
The molded coil according to claim 1, characterized by: the housing has the opening slightly smaller than the plate and has elasticity;
A plurality of third notches are provided in the circumferential direction at the end of the housing on the plate side,
The plate is provided with a plurality of protrusions having the same shape as the third notch on the outer edge,
the opening of the housing is pushed and widened to fit the plate into the opening, and the protrusion is fitted into the third notch;
The molded coil according to claim 1, characterized by: The plate is provided with a hole for injecting the resin of the resin member into the housing,
The housing and the plate are made of a magnetic material, and form a magnetic path that is a path for the magnetic field generated by the coil at the outer edge of the plate that contacts the housing,
The hole is provided inside the outer edge of the plate;
The molded coil according to any one of claims 1 to 3, characterized by: A convex portion is provided on the end face of the flange portion on the plate side,
The convex portion includes a base portion provided on the end surface and a protrusion provided on the base portion that is one size smaller than the base portion,
The plate is provided with a positioning hole to be fitted into the protrusion,
The plate has the protrusion fitted in the positioning hole, is arranged on the base portion, and is spaced from the end surface of the flange portion;
The molded coil according to any one of claims 1 to 4, characterized by: The resin member is
a terminal mold portion covering a portion of the terminal;
a connector portion surrounding the exposed portion of the terminal from the terminal mold portion;
having
The molded coil according to any one of claims 1 to 5, characterized by: The housing is provided with a second notch extending from the plate-side end to the other end,
The resin member has a second resin portion filling the second notch portion, and includes the terminal mold portion, the connector portion, the coil mold portion, the first resin portion, and the second resin portion. that the resin part of the
The molded coil according to claim 6 , characterized by: a molded coil according to any one of claims 1 to 7;
a valve body driven by a driving force generated by energizing the coil;
having
An electrically actuated valve characterized by:

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