This application is based upon and claims the benefit of priority of the prior Japanese Patent Application No. 2018-143628, filed Jul. 31, 2018, the entire contents of which are incorporated herein by reference.
The present invention relates to an electromagnetic relay, and in particular, relates to a sealed-type electromagnetic relay the interior of which is sealed by an adhesive.
Electromagnetic relays in which the contacts are opened and closed by an electromagnet are known. Japanese Unexamined Utility Model Publication No. S61-119237 (JP S61-119237 U) discloses an electromagnetic relay the interior of which is sealed by the application of an adhesive to a gap between a housing, which houses the constituent components of the electromagnetic relay, and a cover.
In sealed-type electromagnetic relays, the cover is a thin molded part made of a resin. Since distortion may occur in the thin cover in some cases, the gap between the case and the cover may not be uniform, and the gap between the case and the cover may be small, depending on the position.
When the gap between the case and the cover becomes small, adhesive may not sufficiently flow into the gap, whereby sealing failure of the electromagnetic relay may occur in some cases.
According to one aspect, the electromagnetic relay comprises a housing, a cover, an adhesive which is interposed and filled in a gap between a side part of the housing and an inner surface of the cover, and a projection which is formed on at least one of the side part and the inner surface.
According to the electromagnetic relay of one aspect, a sealed-type electromagnetic member having no sealing failures can be provided.
The embodiments of an electromagnetic relay (hereinafter, “relay”) will be described below with reference to the attached drawings. The relay includes a housing and a cover, and the interior of the relay is sealed by an adhesive.
The components incorporated in the housing 4 include contact springs, an electromagnet, a hinge spring 8, an armature 10, and a card 12. The contact spring includes a movable spring 14 having terminals 14a and 14b, a fixed break spring 16 having terminals 16a and 16b, and a fixed make spring 18 having terminals 18a and 18b. The electromagnet includes a coil assembly 20, a yoke 22, and an iron core 24. The coil assembly 20 includes terminals 20a and 20b, a coil 20c, and a bobbin 20d on which the coil 20c is wound.
The relay 2 excites the electromagnet when a voltage is applied between the terminals 20a and 20b. The armature 10 is attracted to the iron core 24 due to the excitation of the electromagnet. The card 12 is associated with the armature 10, and the movable spring 14 moves in accordance with the attraction of the armature 10 to iron core 24, whereby the movable spring 14 and the make spring 18 are brought into contact with each other. In a state in which the electromagnet is not excited, the movable spring 14 and the break spring 16 contact each other. The hinge spring 8 is attached to the armature 10 and the yoke 22 so as to elastically bias the armature 10 away from the iron core 24.
Accordingly, the relay 2 opens and closes the contacts. The configuration described above is one example, and arbitrary components and principles can be used. For example, the break-side contact spring may be omitted.
As illustrated in
Projections 34 are formed on the portion of the surface 26a closest to the bottom part 30. An arbitrary number of projections 34 are formed. The side part 26 may not include the recess 26d and the aperture 26e. Furthermore, the entirety of the side part 26 may be formed as a single surface. The side part 28 has the same configuration as the side part 26.
As illustrated in
The cover 6 is formed, for example, as a thin resin part having a thickness of less than 1 mm, and as illustrated in
The degree of warpage depends on the thickness of cover 6 and the lengths of the sides thereof as compared with the same material and molding conditions. For example, the warpage is reduced as the thickness of the cover 6 increases. Furthermore, the warpage is reduced as the side length of the cover 6 decreases. In
The adhesive 38 is arranged on the lower surface side of the relay 2 by, for example, application. For example, the adhesive 38 is made of an epoxy resin, and includes a primary agent and a curing agent.
The cross-hatched portion in
The adhesive 38 is not applied to the protrusion 30b. By providing the protrusion 30b, the amount of adhesive 38 can be reduced while securing sufficient adhesive strength for the adhesive 38 to secure the housing 4 and the cover 6 to each other, whereby a cost reduction in the relay 2 can be realized.
Projections 34 are arranged in the vicinity of the center of the side part 6a at positions facing the surface 36a, and the tips thereof contact the inner surface 36a. Since the projections 34 contact the inner surface 36a, the center portion of the inner surface 36a, which is bent inward, is pushed outward. Since the projections 34 push the inner surface 36a outwardly, warpage of the open end 36 can be at least partially corrected, whereby the gap 40 can be secured across the entirety of the open end 36.
By providing projections 34 on the housing 4, the gap 40 can be secured across the entirety of the open end 36, and thus, a sufficient amount of the adhesive 38 can be applied seamlessly between the surface 26a and the housing 4. Furthermore, when the adhesive 38 is formed from an adhesive including a primary agent and a curing agent, if the gap 40 is secured across the entirety of the open end 36, separation of the primary agent and the curing agent can be prevented, and the adhesive can be appropriately cured. It is preferable that the width of the gap 40 is about 0.1 mm at the narrowest point thereof, and the height of the projection 34 is preferably 0.1 mm.
The projections 34 are formed in arbitrary positions of the side part 26 for contacting and pressing the side part 6a. The projections 34 may be formed in arbitrary positions on the surfaces 26a and 26c. Furthermore, when the entirety of the side part 26 is formed as a single surface, projections 34 may be formed at arbitrary positions of this surface.
Projections 34 are also formed on the side part 28. Furthermore, projections 34 are formed in arbitrary positions for contacting and pushing the side part 6c or 6d.
As illustrated in
As illustrated in
The projection 34 is tapered, and is formed in a square frustum shape as illustrated in
Furthermore, the projection 34 may be formed in the spherical shape illustrated in
Relay 42 according to a second embodiment will be described using
First recesses 56 are formed in the surface 52a in the vicinity of the center of the cover 44 so as to be open on the lower and upper ends of the surface 52a. One end of each first recess 56 is open toward the open end 48 side. An arbitrary number of first recesses 56 are formed.
The entirety of the side part 52 may be formed as a single surface. When the entirety of the side part 52 is formed as a single surface, the first recesses 56 are formed so as to be open on the lower and upper ends of the side part 52.
As illustrated in
Furthermore, when the adhesive 60 is formed from an adhesive including a primary agent and a curing agent, since the adhesive 60 can flow into the first recesses 56 in the vicinity of the warpage of the cover 44, whereby bleeding can be prevented and the adhesive can be appropriately cured.
In
The contact between the side part 44a and the projections 62 depends on the degree of warpage of the cover 44. However, the warpage of the side part 44a can be reduced by supporting the side part 44a with which the projections 62 contact.
The second recess 64 is formed in a position separated from the open end 48 with respect to the first recesses 56. The second recess 64 may be open on both ends of the surface 52a. Alternatively, the second recess 64 may not be open on both ends of the surface 52a, and may be formed so as to be open only on the cover 44 side.
Adhesive 60 is filled in the first recesses 56 and the second recess 64. By filling the adhesive 60 in not only the first recesses 56 but also in the second recess 64, adhesive strength can be further improved.
Note that the first recesses 56 and the second recess 64 may have arbitrary shapes. For example, the first recesses 56 and the second recess 64 may be tapered, or may be curved.
Furthermore, the first recesses 56 and the second recess 64 may be formed at arbitrary positions in the housing 46 so as to increase adhesive strength. For example, a recess may be formed in the side part 54.
The first recesses 56 and the second recess 64 may be formed in the cover 44. When recesses are formed in the side part 44a, the first recesses 56 are open toward the open end 48 side, and the second recess 64 communicates with one end of each first recess 56 and is formed in a position away from the open end 48 with respect to the first recess 56.
The first recesses 56 may be formed in the housing 46 and the second recess 64 may be formed in the cover 44. In this case, the first recesses 56 and the second recess 64 communicate with each other when the cover 44 contacts the housing 46. When the cover 44 and the housing 46 are resin parts, providing the first recesses 56 and the second recess 64 in separate parts facilitates individual injection molding.
The embodiments described above can be appropriately combined. Furthermore, in the drawings described above, identical or corresponding portions have been assigned the same reference numerals. Note that the embodiments described above are exemplary and do not limit the invention.
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The Notification of Reasons for Refusal, and translation thereof, from counterpart Japanese Application No. 2018-143628, dated Apr. 5, 2022, 6 pp. |
The Notification of Reasons for Refusal, and translation thereof, from counterpart Japanese Application No. 2018-143628, dated Aug. 9, 2022, 4 pp. |
Number | Date | Country | |
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20200043687 A1 | Feb 2020 | US |