Electromagnetic relays
The electromagnetic relay's innovative housing design with hermetic sealing and Lorentz force suppression addresses assembly complexity and cost issues, ensuring airtightness and cost-effectiveness.
Patent Information
- Authority / Receiving Office
- JP · JP
- Patent Type
- Applications
- Current Assignee / Owner
- EM DEVICES CORP
- Filing Date
- 2024-11-27
- Publication Date
- 2026-06-08
AI Technical Summary
The assembly structure of electromagnetic relays with contact mechanisms that suppress electromagnetic repulsion is complex, leading to increased manufacturing costs and reduced airtightness, particularly when handling large currents.
The electromagnetic relay design includes a contact mechanism housed in a bucket-shaped housing case with a lid, where stators pass through holes in the case and lid, ensuring hermetic sealing and simplifying assembly, while using Lorentz force to suppress electromagnetic repulsion.
This design simplifies assembly, reduces manufacturing costs, and maintains airtightness by hermetically sealing two sides of the relay, effectively suppressing electromagnetic repulsion during high current flow.
Smart Images

Figure 2026092969000001_ABST
Abstract
Description
Technical Field
[0004] , , , ,
[0001] The present disclosure relates to an electromagnetic relay.
Background Art
[0002] Electromagnetic relays having a contact mechanism are widely used in fields such as communication equipment, automotive electrical components, and electrical appliances. Patent Document 1 discloses a technique related to a contact mechanism capable of suppressing an electromagnetic repulsive force acting in a direction to open the mover when energized. Patent Document 2 discloses a technique related to a contact mechanism capable of reducing the height of a contact device while suppressing an electromagnetic repulsive force generated between a mover and a stator.
Prior Art Documents
Patent Documents
[0003]
Patent Document 1
Patent Document 2
Summary of the Invention
Problems to be Solved by the Invention
[0004] When a large current is passed, an electromagnetic repulsive force acts on the contact mechanism, resulting in a decrease in contact pressure and potentially leading to problems with the electromagnetic relay. As a countermeasure, for example, the structure of the contact mechanism shown in FIG. 2 is effective. However, the structure of the contact mechanism in which the paths leading to the outside of the electromagnetic relay of the two stators are in the reverse direction is difficult to assemble into the electromagnetic relay compared to the structure of the contact mechanism in which the two stators are in the same direction toward the outside of the electromagnetic relay. Therefore, such a structure of the contact mechanism is particularly difficult to ensure the airtightness introduced into each part connecting the inside and outside of the electromagnetic relay for the purpose of preventing a decrease in contact stability due to dust, and there is a risk of increasing the manufacturing cost of the electromagnetic relay.
[0005] In view of the above issues, the purpose of this disclosure is to reduce manufacturing costs by simplifying the assembly structure of an electromagnetic relay equipped with a contact mechanism capable of suppressing electromagnetic repulsion when a large current is applied. [Means for solving the problem]
[0006] An electromagnetic relay according to one aspect of the present disclosure comprises a contact mechanism having a movable element having a first movable contact and a second movable contact provided on both ends in the first direction of a first surface of a conductive plate extending in a first direction; a first stator having a first fixed contact provided to connect to the first movable contact; and a second stator having a second fixed contact provided to connect to the second movable contact; and a case housing the contact mechanism, the case comprising a bucket-shaped housing case housing the contact mechanism in a recess formed in the first direction, and a lid covering the opening of the housing case, wherein the first stator is arranged to pass through a first hole formed in the bottom surface of the recess of the housing case, and the second stator is arranged to pass through a second hole formed in the lid. [Effects of the Invention]
[0007] This disclosure simplifies the assembly structure of an electromagnetic relay equipped with a contact mechanism capable of suppressing electromagnetic repulsion when high current is flowing, thereby reducing manufacturing costs. [Brief explanation of the drawing]
[0008] [Figure 1] This is a perspective view showing an example configuration of an electromagnetic relay according to Embodiment 1. [Figure 2] This is a front view showing an example of the configuration of the contact mechanism according to Embodiment 1. [Figure 3] This is a perspective view showing an example of the configuration of the contact mechanism and case according to Embodiment 1. [Figure 4] This is a perspective view showing an example configuration of an electromagnetic relay according to Embodiment 1. [Figure 5] This is a perspective view showing an example configuration of an electromagnetic relay according to Embodiment 1. [Figure 6] It is a perspective view showing a configuration example of the electromagnetic relay according to Embodiment 1. [Figure 7] It is a side view showing a configuration example of the electromagnetic relay according to Embodiment 2. [Figure 8] It is a cross-sectional view taken along the cutting line VII-VII of FIG. 7. [Figure 9] It is an enlarged view of the range enclosed by the solid-line square in FIG. 8. [Figure 10] It is an enlarged view of the range enclosed by the solid-line square in FIG. 8. [Figure 11] It is an enlarged view of the range enclosed by the solid-line square in FIG. 8. [Figure 12] It is a front view showing a configuration example of the contact mechanism according to Embodiment 3. [Figure 13] It is a perspective view showing a configuration example of the contact mechanism according to Embodiment 3. [Figure 14] It is a side view showing a configuration example of the electromagnetic relay according to Embodiment 3. [Figure 15] It is a cross-sectional perspective view taken along the cutting line XIV-XIV of FIG. 14. [Figure 16] It is a side view showing a configuration example of the electromagnetic relay with the lid removed according to Embodiment 3. [Figure 17] It is a front view showing a configuration example of the contact mechanism and the electromagnetic mechanism according to Embodiment 4. [Figure 18] It is a cross-sectional view taken along the cutting line XVII-XVII of FIG. 17 in the non-energized state. [Figure 19] It is a cross-sectional view taken along the cutting line XVII-XVII of FIG. 17 in the energized state. [Figure 20] It is a perspective view showing a configuration example of the contact mechanism and the electromagnetic mechanism according to Embodiment 5. [Figure 21] It is a front view of the electromagnetic relay according to Embodiment 5. [Figure 22] It is a cross-sectional view taken along the cutting line XXI-XXI of FIG. 21. [Figure 23] It is a side view showing a configuration example of the electromagnetic relay according to Embodiment 6. [Figure 24]It is a perspective view showing a configuration example of an electromagnetic relay according to Embodiment 7. [Figure 25] It is a cross-sectional view showing a configuration example of an electromagnetic relay according to Embodiment 8. [Figure 26] It is a cross-sectional view showing a configuration example of an electromagnetic relay according to Embodiment 8. [Figure 27] It is a cross-sectional view showing a configuration example of an electromagnetic relay according to Embodiment 8. [Figure 28] It is a perspective view showing a configuration example of a contact mechanism according to Embodiment 9. [Figure 29] It is a bottom view showing a configuration example of a contact mechanism according to Embodiment 9. [Figure 30] It is a side view showing a configuration example of the contact mechanism in a non-energized state according to Embodiment 9. [Figure 31] It is a diagram showing the direction of current flowing through the contact mechanism and the direction of the magnetic field according to Embodiment 9.
Embodiments for Carrying Out the Invention
[0009] <Embodiment 1> Hereinafter, embodiments will be described with reference to the drawings. FIG. 1 is a perspective view showing a configuration example of an electromagnetic relay according to Embodiment 1. As shown in FIG. 1, the electromagnetic relay 1 according to the present embodiment includes a contact mechanism 10, an electromagnetic mechanism 20, a case 30, and a sealing resin 40.
[0010] FIG. 2 is a front view showing a configuration example of the contact mechanism according to Embodiment 1. As shown in FIG. 2, the contact mechanism 10 includes a first stator 11, a second stator 12, and a mover 13.
[0011] The movable element 13 includes a conductive plate 130 extending in the x-axis direction (first direction), and a first movable contact 131 and a second movable contact 132, respectively, provided on both ends of the first surface (the surface on the z-axis positive side) of the conductive plate 130 in the x-axis direction. The first movable contact 131 and the second movable contact 132 of the movable element 13 are formed by providing convex-shaped members on the first surface of both ends of the conductive plate 130 in the x-axis direction. Each member constituting the movable element 13 is made of a conductive material such as a metal material. The first movable contact 131 and the second movable contact 132 may be formed integrally with the conductive plate 130.
[0012] The first stator 11 includes a conductive plate 110 extending in the x-axis direction and a first fixed contact 111 provided to be connectable to the first movable contact 131 of the movable element 13. The first fixed contact 111 of the first stator 11 is formed by providing a convex-shaped member on the negative z-axis side of the conductive plate 110. Each member constituting the first stator 11 is made of a conductive material such as a metal. The first fixed contact 111 may be formed integrally with the conductive plate 110.
[0013] The second stator 12 includes a conductive plate 120 extending in the x-axis direction and a second fixed contact 121 that is connectable to the second movable contact 132 of the movable element 13. The second fixed contact 121 of the second stator 12 is formed by providing a convex-shaped member on the negative z-axis side of the conductive plate 120. Each member constituting the second stator 12 is made of a conductive material such as a metal. The second fixed contact 121 may be formed integrally with the conductive plate 120.
[0014] The contact mechanism 10 switches between energized and de-energized states by displacing the movable element 13 in the z-axis direction (second direction). Specifically, when the movable element 13 is displaced to the negative side in the z-axis direction, the first movable contact 131 and the first fixed contact 111 become disconnected, and the second movable contact 132 and the second fixed contact 121 become disconnected, so the first stator 11 and the second stator 12 become de-energized. On the other hand, when the movable element 13 is displaced to the positive side in the z-axis direction, the first movable contact 131 and the first fixed contact 111 become connected, and the second movable contact 132 and the second fixed contact 121 become connected, so the first stator 11 and the second stator 12 become energized via the movable element 13. Figure 2 illustrates the case when the contact mechanism 10 is de-energized.
[0015] In the contact mechanism 10, the first stator 11, the second stator 12, and the movable element 13 are configured to extend in the x-axis direction. That is, when the contact mechanism 10 is energized, the direction of current flow in the first stator 11, the second stator 12, and the movable element 13 is the same. When current flows through the contact mechanism 10, a magnetic field is generated in the y-axis direction (third direction) on the movable element 13. More specifically, when a current flows in the contact mechanism 10 toward the positive x-axis direction, the first stator 11 and the second stator 12 generate a magnetic field on the movable element 13 toward the positive y-axis direction. On the other hand, when a current flows in the contact mechanism 10 toward the negative x-axis direction, the first stator 11 and the second stator 12 generate a magnetic field on the movable element 13 toward the negative y-axis direction.
[0016] When the contact mechanism 10 is energized, a Lorentz force is generated in the movable element 13 (conductive plate 130) in the direction that maintains the energized state (positive z-axis direction) due to the magnetic field generated by the first stator 11 and the second stator 12. Therefore, by using the Lorentz force acting in the positive z-axis direction, the electromagnetic repulsive force (force acting in the negative z-axis direction) acting between the movable element 13 and the first stator 11 and the second stator 12 when energized can be effectively suppressed.
[0017] As shown in Figure 1, the electromagnetic mechanism 20 is located on the negative side of the z-axis direction of the contact mechanism 10. The electromagnetic mechanism 20 can displace the movable element 13 in the z-axis direction. More specifically, when the electromagnetic mechanism 20 is off, the movable element 13 is stationary at the negative side of the z-axis direction. In this state, the first movable contact 131 and the first fixed contact 111 are disconnected, and the second movable contact 132 and the second fixed contact 121 are disconnected, so the first stator 11 and the second stator 12 are not energized.
[0018] On the other hand, when the electromagnetic mechanism 20 is on, the movable element 13 is displaced to the positive side in the z-axis direction. In this state, the first movable contact 131 and the first fixed contact 111 are connected, and the second movable contact 132 and the second fixed contact 121 are connected, so the first stator 11 and the second stator 12 are energized via the movable element 13.
[0019] Thus, the electromagnetic relay 1 uses the electromagnetic mechanism 20 to switch between connecting and disconnecting the first movable contact 131 and the first fixed contact 111, and connecting and disconnecting the second movable contact 132 and the second fixed contact 121. Therefore, the electromagnetic relay 1 can switch between conducting and not conducting the first stator 11 and the second stator 12.
[0020] The case 30 houses the contact mechanism 10 and the electromagnetic mechanism 20. Figure 3 is a perspective view showing an example of the configuration of the contact mechanism and case according to Embodiment 1. As shown in Figure 3, the case 30 comprises a bucket-shaped housing case 31 having a recess 311 formed in the x-axis direction, and a lid 32 covering the opening of the housing case 31.
[0021] As shown in Figure 3, a mounting structure 35 may be formed on at least one of the housing case 31 or the lid 32. The mounting structure 35 is used to fix and position the electromagnetic relay 1 relative to other components. For example, as shown in Figure 3, the mounting structure 35 has a shape that protrudes vertically from the surface of the housing case 31 or the lid 32 and has a hole through which a male screw can pass. The electromagnetic relay 1 is then fixed and positioned relative to other components by the mounting structure 35 and the male screw.
[0022] The contact mechanism 10 is housed in a recess 311 of the housing case 31. The first stator 11 is positioned to pass through a first hole 312 formed in the bottom surface (the negative x-axis side) of the recess 311 of the housing case 31. The first stator 11 and the first hole 312 are hermetically sealed. The second stator 12 is positioned to pass through a second hole 321 formed in the lid 32. The second stator 12 and the second hole 321 are hermetically sealed. In other words, the electromagnetic relay 1 can be manufactured efficiently because hermetically sealed connection is completed by hermetically sealing two sides in the x-axis direction relative to the case 30. Therefore, an electromagnetic relay that can ensure hermetically sealed connections while keeping manufacturing costs down can be realized.
[0023] Furthermore, at least one of the cross-sectional shapes of the first stator 11 at the position where it penetrates the first hole 312 and the second stator 12 at the position where it penetrates the second hole 321 may be rectangular in shape, with at least one corner having curvature. This reduces stress concentration at the corners of the first hole 312 and the second hole 321, and suppresses the reduction in airtightness due to cracking of the sealing resin 40, which will be described later.
[0024] As shown in Figure 1, the sealing resin 40 comprises a first sealing resin 41 and a second sealing resin 42. Figures 4 to 6 are perspective views showing an example of the configuration of an electromagnetic relay according to Embodiment 1. As shown in Figure 4, the first stator 11 and the first hole 312 are hermetically sealed using the first sealing resin 41. Also, as shown in Figure 5, the second stator 12 and the second hole 321 are hermetically sealed using the second sealing resin 42.
[0025] Furthermore, to further improve airtight sealing, the storage case 31 and the lid 32 may be airtightly joined to each other by thermal melting. For example, the storage case 31 and the lid 32 shown in Figure 6 each have a welding rib 34 protruding in the positive x-axis direction near the boundary between the storage case 31 and the lid 32. By heating and melting the welding rib 34 and then cooling and hardening it, the storage case 31 and the lid 32 are airtightly joined to each other.
[0026] As described above, the electromagnetic relay 1 according to this embodiment has a structure in which the contact mechanism 10 is housed in a housing case 31 that opens in the x-axis direction, and the opening of the housing case 31 is closed with a lid 32. When resin sealing is performed with this structure, the negative x-axis side of the electromagnetic relay 1 having the first stator 11 and the first hole 312, and the positive x-axis side of the electromagnetic relay 1 having the second stator 12 and the second hole 321 are hermetically sealed by the sealing resin 40. In other words, since the electromagnetic relay 1 is hermetically sealed by sealing two sides in the x-axis direction to the case 30, it is efficient to manufacture. Therefore, it is possible to ensure airtightness while keeping manufacturing costs down.
[0027] The disclosure described above makes it possible to provide an electromagnetic relay that can ensure airtightness while keeping manufacturing costs down.
[0028] <Embodiment 2> Next, an electromagnetic relay according to Embodiment 2 will be described. Figure 7 is a side view showing an example of the configuration of an electromagnetic relay according to Embodiment 2. Figure 8 is a cross-sectional view taken along the cutting line VII-VII in Figure 7. Figures 9 to 11 are enlarged views of the area enclosed by the solid rectangle in Figure 8. As shown in Figure 7, the electromagnetic relay 1a according to this embodiment comprises a contact mechanism 10a, an electromagnetic mechanism 20a, a case 30a, and a sealing resin 40a. The contact mechanism 10a comprises a first stator 11a, a second stator 12a, and a movable element 13a. The case 30a comprises a housing case 31a and a lid 32a.
[0029] In this specification, corresponding components are indicated by the same number. For example, the "contact mechanism 10" shown in Figure 1 and the "contact mechanism 10a" shown in Figure 8 are both represented by the same number "10," indicating that they are corresponding components. In this specification, the addition of "a" to reference numeral 11 indicates that it is the "first stator 11a" of the contact mechanism 10a shown in Figure 8. In other words, the "first stator 11a" in Embodiment 2 corresponds to the "first stator 11" in Embodiment 1, and redundant explanations are omitted in this specification as appropriate. The same applies to each component described below.
[0030] Case 30a according to Embodiment 2 differs from case 30 according to Embodiment 1 in that a first fitting portion 313 is formed in the housing case 31a and a second fitting portion 322 is formed in the lid 32a (see Figure 9). The other configurations are the same as those of the electromagnetic relay 1 described in Embodiment 1, so a redundant explanation will be omitted.
[0031] As shown in Figure 9, the storage case 31a has a convex first fitting portion 313 on at least one side facing the opening. The lid 32a has a concave second fitting portion 322 at a position corresponding to the first fitting portion 313 of the storage case 31a. When the first fitting portion 313 of the storage case 31a is inserted into the second fitting portion 322 of the lid 32a, the first fitting portion 313 of the storage case 31a is fitted with the second fitting portion 322 of the lid 32a, and the lid 32a is fixed to the storage case 31a. This improves the sealing strength between the storage case 31a and the lid 32a.
[0032] As shown in Figure 10, the first fitting portion 313 may be fitted with the second fitting portion 322 by press-fitting. This further improves the sealing strength between the housing case 31a and the lid 32a. Furthermore, the number of first fitting portions 313 is not limited to one, and there may be multiple. In the case of multiple first fitting portions, the first fitting portions 313 may be formed on two opposing long sides of the opening side of the housing case 31a (i.e., two long sides extending in the z-axis direction).
[0033] After the first fitting portion 313 is fitted with the second fitting portion 322, a second sealing resin 42a, which is a resin material, may be provided between the storage case 31a and the lid 32a. This ensures that the storage case 31a and the lid 32a are airtightly sealed, further improving the sealing strength between the storage case 31a and the lid 32a.
[0034] As shown in Figure 11, after the first fitting portion 313 is fitted with the second fitting portion 322, the first fitting portion 313 and the second fitting portion 322 may be further heat-crimped to form a heat-crimped portion 33. In this way, the first fitting portion 313 of the housing case 31a is fitted with the second fitting portion 322 of the lid 32a and heat-crimped, and a second sealing resin 42a, which is a resin material, is provided between the housing case 31a and the lid 32a, thereby further improving the sealing strength between the housing case 31a and the lid 32a.
[0035] In this embodiment, this configuration improves the sealing strength between the storage case 31a and the lid 32a. Furthermore, when the storage case 31a attempts to bulge outward due to internal pressure expansion at high temperatures, the first fitting portion 313 is restrained by the lid 32a, thereby reducing the bulging of the storage case 31a and suppressing a decrease in the airtightness inside the case 30a. Note that the first fitting portion 313 of the storage case 31a may be concave, and the second fitting portion 322 of the lid 32a may be convex.
[0036] <Embodiment 3> Next, an electromagnetic relay according to Embodiment 3 will be described. First, the contact mechanism according to Embodiment 3 will be described with reference to Figures 12 and 13. Figures 12 and 13 are a front view and a perspective view, respectively, showing an example configuration of the contact mechanism according to Embodiment 3. As shown in Figures 12 and 13, the contact mechanism 10b according to this embodiment comprises a first stator 11b, a second stator 12b, a movable element 13b, a first permanent magnet 14, and a second permanent magnet 15.
[0037] The contact mechanism 10b according to Embodiment 3 differs from the contact mechanism 10 according to Embodiment 1 in that it includes a first permanent magnet 14 and a second permanent magnet 15 for arc extinguishing. The other configurations are the same as those of the contact mechanism 10 described in Embodiment 1, so a redundant explanation will be omitted.
[0038] As shown in Figure 12, the first permanent magnet 14 for arc extinguishing is located on the outside of the first movable contact 131b and the first fixed contact 111b in the x-axis direction (i.e., on the negative x-axis side). The second permanent magnet 15 for arc extinguishing is located on the outside of the second movable contact 132b and the second fixed contact 121b in the x-axis direction (i.e., on the positive x-axis side).
[0039] Furthermore, the first permanent magnet 14 and the second permanent magnet 15 are configured such that the magnetic field extends in the x-axis direction. For example, the first permanent magnet 14 is configured such that the negative x-axis side of its face is the north pole, and the positive x-axis side of its face is the south pole. Similarly, the second permanent magnet 15 is configured such that the negative x-axis side of its face is the south pole, and the positive x-axis side of its face is the north pole. Note that the north and south poles may be reversed.
[0040] As described above, in this embodiment, a first permanent magnet 14 is provided to generate a magnetic field in the x-axis direction near the first movable contact 131b and the first fixed contact 111b. Similarly, in this embodiment, a second permanent magnet 15 is provided to generate a magnetic field in the x-axis direction near the second movable contact 132b and the second fixed contact 121b. Therefore, the arcs generated when the first movable contact 131b and the first fixed contact 111b change from a connected state to a disconnected state, and the arcs generated when the second movable contact 132b and the second fixed contact 121b change from a connected state to a disconnected state, can be extinguished.
[0041] In other words, in this embodiment, arcs generated near the first movable contact 131b and the first fixed contact 111b can be demagnetized by stretching them in the y-axis direction using the magnetic field of the first permanent magnet 14. Similarly, arcs generated near the second movable contact 132b and the second fixed contact 121b can be demagnetized by stretching them in the y-axis direction using the magnetic field of the second permanent magnet 15. The direction in which the arc stretches is either the positive or negative side of the y-axis direction, and the direction in which the arc stretches is determined according to the direction of the current flowing through the contact mechanism 10b and the direction of the magnetic fields of the first permanent magnet 14 and the second permanent magnet 15.
[0042] The contact mechanism 10b according to this embodiment may further include a yoke 16. As shown in Figure 13, the first permanent magnet 14 and the second permanent magnet 15 are provided with a yoke 16 to strengthen the magnetic field for arc extinguishing. Specifically, as shown in Figure 13, the yoke 16 has a U-shape in which a plate-shaped member extending in the z-axis direction and a plate-shaped member extending in the x-axis direction are connected at a right angle. The first permanent magnet 14 is attached to the plate-shaped member of the yoke 16 that extends in the z-axis direction and is on the negative x-axis side. The second permanent magnet 15 is attached to the plate-shaped member of the yoke 16 that extends in the z-axis direction and is on the positive x-axis side. The yoke 16 may be formed by bending a single metal plate into a U-shape.
[0043] Next, an electromagnetic relay according to Embodiment 3 will be described with reference to Figures 14 and 15. Figures 14 and 15 are a side view and a cross-sectional perspective view, respectively, showing an example configuration of the electromagnetic relay according to Embodiment 3. As shown in Figures 14 and 15, the electromagnetic relay 1b according to this embodiment comprises the contact mechanism 10b, electromagnetic mechanism 20b, case 30b, and sealing resin 40b described above.
[0044] Case 30b according to Embodiment 3 differs from Case 30 according to Embodiments 1 and 2 in that a third hole 314 (see Figure 15) is formed in the housing case 31b and a fourth hole 323 is formed in the lid 32b. The other configurations are the same as those of the electromagnetic relays 1 and 1a described in Embodiments 1 and 2, so a redundant explanation will be omitted.
[0045] As shown in Figure 15, the third hole 314 is formed in a position corresponding to the first permanent magnet 14 on the bottom surface of the recess 311b of the housing case 31b. The first permanent magnet 14 is bonded to the housing case 31b by a resin material introduced through the third hole 314. As shown in Figures 14 and 15, the fourth hole 323 is formed in a position corresponding to the second permanent magnet 15 on the lid 32b. The second permanent magnet 15 is bonded to the lid 32b by a resin material introduced through the fourth hole 323. The shapes of the third hole 314 and the fourth hole 323 are not particularly limited, for example, they can be circular or square.
[0046] In this embodiment, the first permanent magnet 14 and the second permanent magnet 15 are bonded to the case 30b by a resin material introduced through the third hole 314 and the fourth hole 323 opened in the case 30b. This configuration suppresses the displacement of the first permanent magnet 14 and the second permanent magnet 15 relative to the contact mechanism 10b due to vibration or shock, and allows for more effective arc extinguishing.
[0047] Figure 16 is a side view showing an example of the configuration of an electromagnetic relay with the cover removed, according to Embodiment 3. As shown in Figure 16, when the contact mechanism 10b is housed in the case 30b, the contact mechanism 10b may be arranged eccentrically to the opposite side from the direction in which the arc extends from the center position z1 in the y-axis direction of the opening of the housing case 31b (the negative side in the y-axis direction in Figure 16).
[0048] In other words, when the opening of the housing case 31b is viewed from above, the opening is rectangular. If the direction in which the longer side of the rectangular opening extends is the z-axis direction and the direction in which the shorter side extends is the y-axis direction, the first permanent magnet 14 and the second permanent magnet 15 are arranged in the housing case 31b such that the arc extends towards the negative side in the y-axis direction. Furthermore, the contact mechanism 10b is arranged in the housing case 31b such that it is eccentrically positioned from the center position z1 in the y-axis direction of the opening of the housing case 31b to the opposite side of the direction in which the arc extends. This configuration allows for a larger space to extinguish the arc. Therefore, the arc can be extinguished more effectively.
[0049] <Embodiment 4> Next, an electromagnetic relay according to Embodiment 4 will be described. First, the electromagnetic mechanism according to Embodiment 4 will be described with reference to Figures 17 to 19. Figure 17 is a front view showing an example of the configuration of the contact mechanism and electromagnetic mechanism according to Embodiment 4. Figure 18 is a cross-sectional view taken along the cutting line XVII-XVII in Figure 17 when the device is not energized. Figure 19 is a cross-sectional view taken along the cutting line XVII-XVII in Figure 17 when the device is energized. As shown in Figure 17, the electromagnetic relay 1c according to this embodiment comprises a contact mechanism 10c, an electromagnetic mechanism 20c, a case 30c (not shown), and a sealing resin 40c (not shown).
[0050] As shown in Figure 17, the contact mechanism 10c according to this embodiment comprises a first stator 11c, a second stator 12c, a movable element 13c, and a movable plate 17. The contact mechanism 10c according to Embodiment 4 differs from the contact mechanism 10 according to Embodiment 1 in that it includes a movable plate 17. The other configurations are the same as those of the contact mechanism 10 described in Embodiment 1, so redundant explanations are omitted.
[0051] As shown in Figures 17 to 19, the movable plate 17 comprises a plate-shaped member 170 and a plate-shaped member 171. As shown in Figures 18 and 19, the plate-shaped member 170 is connected to the second surface (the negative side in the z-axis direction) of the conductive plate 130c provided on the movable element 13c. The plate-shaped member 170 is provided to extend in the negative side in the y-axis direction. The negative end of the plate-shaped member 170 in the y-axis direction is connected to the plate-shaped member 171. The plate-shaped member 171 is provided to extend in the negative side in the z-axis direction. The movable plate 17 can be constructed using a metal material. The plate-shaped members 170 and 171 that constitute the movable plate 17 may be formed integrally. In other words, the movable plate 17 may be formed by bending a single metal plate into an L-shape.
[0052] As shown in Figures 17 and 18, the electromagnetic mechanism 20c according to Embodiment 4 comprises an electromagnetic mechanism body 21, a yoke 22, and a movable iron piece 23. As shown in Figure 18, a plate-shaped member 171 of the movable plate 17 is fixed to the movable iron piece 23. The movable iron piece 23 is connected to the yoke 22 near the connection point between the movable iron piece 23 and the plate-shaped member 171. Therefore, as shown in Figures 18 and 19, when the movable iron piece 23 rotates around the connection point with the yoke 22 as the center of rotation, the movable plate 17 also rotates, and the movable element 13c is displaced in the y-axis and z-axis directions.
[0053] Specifically, when the electromagnetic mechanism body 21 is off, as shown in Figure 18, the movable iron piece 23 is not attracted to the electromagnetic mechanism body 21, so the movable element 13c remains stationary at a position on the negative side of the z-axis. In this state, the first movable contact 131c and the first fixed contact 111c are disconnected, and the second movable contact 132c (not shown) and the second fixed contact 121c (not shown) are disconnected, so the first stator 11c and the second stator 12c are not energized.
[0054] On the other hand, when the electromagnetic mechanism body 21 is ON, as shown in Figure 19, the movable iron piece 23 is attracted to the electromagnetic mechanism body 21, so the movable element 13c is displaced to the positive side in the z-axis direction. In this state, the first movable contact 131c and the first fixed contact 111c are connected, and the second movable contact 132c (not shown) and the second fixed contact 121c (not shown) are connected, so the first stator 11c and the second stator 12c are energized via the movable element 13c.
[0055] As described above, the electromagnetic relay 1c according to this embodiment includes an electromagnetic mechanism 20c that can displace the movable element 13c in the z-axis direction. The electromagnetic mechanism 20c is used to switch between connecting and disconnecting the first movable contact 131c and the first fixed contact 111c, and connecting and disconnecting the second movable contact 132c and the second fixed contact 121c. Therefore, the electromagnetic relay 1c can switch between conducting and not conducting the first stator 11c and the second stator 12c.
[0056] Furthermore, in this embodiment, when switching the conductivity and non-conductivity of the first stator 11c and the second stator 12c, the electromagnetic relay 1c displaces the movable element 13c not only in the z-axis direction but also in the y-axis direction. As a result of the displacement of the movable element 13c in the y-axis direction, the surface of the first movable contact 131c and the surface of the first fixed contact 111c rub against each other, and similarly, the surface of the second movable contact 132c and the surface of the second fixed contact 121c rub against each other. This removes contaminating films and foreign matter adhering to the surfaces of the first movable contact 131c, the first fixed contact 111c, the second movable contact 132c, and the second fixed contact 121c. Therefore, it is possible to suppress the increase in electrical resistance and the obstruction of conductivity between contacts caused by contaminating films and foreign matter. Furthermore, the displacement of the movable element 13c in the y-axis direction reduces the rebound (i.e., bounce) of the first movable contact 131c and the second movable contact 132c in the z-axis direction during connection between contacts, which affects electrical durability.
[0057] <Embodiment 5> Next, an electromagnetic relay according to Embodiment 5 will be described. Figure 20 is a perspective view showing an example of the configuration of the contact mechanism and electromagnetic mechanism according to Embodiment 5. Figure 21 is a front view of the electromagnetic relay according to Embodiment 5. Figure 22 is a cross-sectional view taken along the cutting line XXI-XXI in Figure 21. As shown in Figures 20 to 22, the electromagnetic relay 1d comprises a contact mechanism 10d, an electromagnetic mechanism 20d, a case 30d, a sealing resin 40d, and a base 50.
[0058] As shown in Figure 22, the electromagnetic relay 1d according to this embodiment differs from the electromagnetic relay 1c according to Embodiment 4 in that it includes a base 50. Note that, apart from the configuration including the base 50, it is the same as the electromagnetic relay 1c described in Embodiment 4, so a redundant explanation will be omitted.
[0059] As shown in Figure 20, the yoke 22 supporting the first stator 11d, the second stator 12d, and the movable element 13d, as well as the first permanent magnet 14 and the second permanent magnet 15, are fixed to the base 50. The base 50 is, for example, frame-shaped or box-shaped, and is configured to have an opening in the direction in which the arc extends (in the case of Figure 22, the negative y-axis direction). With this configuration, the base 50 can suppress obstruction of the arc, and the space for arc extinguishing can be made larger. Therefore, the arc can be extinguished more effectively.
[0060] <Embodiment 6> Next, an electromagnetic relay according to Embodiment 6 will be described. Figure 23 is a side view showing an example of the configuration of an electromagnetic relay according to Embodiment 6. As shown in Figure 23, the electromagnetic relay 1e according to this embodiment comprises a contact mechanism 10e, an electromagnetic mechanism 20e, a case 30e, and a sealing resin 40e.
[0061] Furthermore, as shown in Figure 23, the electromagnetic relay 1e according to this embodiment has a terminal 24 for supplying drive current to the electromagnetic mechanism body 21.
[0062] The terminal 24 is positioned to extend from the electromagnetic mechanism body 21 in the x-axis direction. The terminal 24 passes through the fifth hole 324 formed in the cover 32e. The fifth hole 324 may be provided on the bottom surface of the recess of the housing case 31e.
[0063] In case 30e, the holes that need to be resin-sealed are the first hole 312, the second hole 321, and the fifth hole 324. The first hole 312 is on the negative x-axis side, the second hole 321 is on the positive x-axis side, and the fifth hole 324 is on one of the two x-axis sides. Therefore, sealing the two x-axis sides completes the airtight bond, resulting in good manufacturing efficiency.
[0064] <Embodiment 7> Next, an electromagnetic relay according to Embodiment 7 will be described. Figure 24 is a perspective view showing an example of the configuration of an electromagnetic relay according to Embodiment 7. As shown in Figure 24, the electromagnetic relay 1f according to this embodiment comprises a contact mechanism 10f, an electromagnetic mechanism 20f (not shown), a case 30f, and a sealing resin 40f.
[0065] As shown in Figure 24, the electromagnetic relay 1f according to this embodiment differs from the electromagnetic relay 1 according to Embodiment 1 in that the housing case 31f is equipped with ventilation holes 315. The other configurations are the same as those of the electromagnetic relay 1f described in Embodiment 1, so a redundant explanation will be omitted.
[0066] The ventilation holes 315 formed in the housing case 31f release at least one of the pressure generated when the first stator 11f and the first hole 312f are airtight sealed using the first sealing resin 41f, and the pressure generated when the second stator 12f and the second hole 321f are airtight sealed using the second sealing resin 42f.
[0067] If the ventilation holes 315 are not formed, the high pressure inside the case 30f when the first sealing resin 41f and the second sealing resin 42f are heat-cured will try to escape to the outside of the case 30f through the first sealing resin 41f and the second sealing resin 42f. In this case, the first sealing resin 41f and the second sealing resin 42f may harden with holes, for example, and there is a risk that airtight sealing cannot be ensured. Therefore, the electromagnetic relay 1f according to this embodiment ensures airtight sealing of the first sealing resin 41f and the second sealing resin 42f by releasing the high pressure inside the case 30f to the outside of the case 30f through the ventilation holes 315. Note that the ventilation holes 315 may be formed not only in the housing case 31f but also in the lid 32f.
[0068] The vent holes 315 are sealed after the first sealing resin 41f and the second sealing resin 42f have been heat-cured, that is, after the first stator 11f and the first hole 312f, and the second stator 12f and the second hole 321f have been airtightly sealed. The sealing of the vent holes 315 is not particularly limited to methods other than sealing the vent holes 315 by melting them with heat, such as filling them with a resin material.
[0069] <Embodiment 8> Next, an electromagnetic relay according to Embodiment 8 will be described. Figures 25 to 27 are cross-sectional views showing an example of the configuration of an electromagnetic relay according to Embodiment 8. As shown in Figure 25, the electromagnetic relay 1g according to this embodiment comprises a contact mechanism 10g, an electromagnetic mechanism 20g (not shown), a case 30g, and a sealing resin 40g (not shown).
[0070] As shown in Figure 25, the contact mechanism 10g according to this embodiment differs from the contact mechanism 10g according to Embodiment 1 in that screw structures 112 and 122 are formed on the first stator 11g and the second stator 12g. The other configurations are the same as those of the contact mechanism 10 described in Embodiment 1, so a redundant explanation will be omitted.
[0071] As shown in Figure 25, the threaded structures 112 and 122 are formed on the conductive plate 110g of the first stator 11g and the conductive plate 120g of the second stator 12g. More specifically, the threaded structures 112 and 122 are formed on the portions of the conductive plates 110g and 120g that are not housed in the case 30g, with the rotation axis direction being the z-axis direction. Furthermore, since the threaded structures 112 and 122 are formed to fit within the plate thickness of the conductive plates 110g and 120g, it is possible to process and form the threaded structures 112 and 122 before housing the first stator 11g and the second stator 12g in the case 30g, thereby increasing the degree of freedom in the manufacturing process.
[0072] The conductive plates 110g and 120g are fixed to a predetermined member by the screw structures 112 and 122, and are electrically connected. The predetermined member is, for example, a terminal connected to an electrical component in a circuit into which the contact mechanism 10g is incorporated. The conductive plates 110g and 120g are fixed to the predetermined member by reverse-threaded bolts in addition to the screw structures 112 and 122. The screw structures 112 and 122 firmly fix the conductive plates 110g and 120g to the predetermined member, thereby improving the stability of the electrical connection.
[0073] Alternatively, instead of forming the screw structures 112 and 122 on the conductive plates 110g and 120g as shown in Figure 25, the screw structures may be formed by fixing screw members 113 and 123, which are components equipped with the screw structures 112 and 122, to the conductive plates 110g and 120g, as shown in Figures 26 and 27. Since the screw structures 112 and 122 shown in Figure 25 are female threads, the screw structure of a given component is limited to a male thread. On the other hand, the screw structures 112 and 122 shown in Figure 26 are male threads, and the screw structures 112 and 122 shown in Figure 27 are female threads. Therefore, in the case of the screw members 113 and 123 shown in Figures 26 and 27, the screw structure of a given component can be either a male or female thread.
[0074] Here, when fixing the conductive plates 110g and 120g to a predetermined member, in the case of the screw structures 112 and 122 shown in Figures 25 and 27, the user does not need to prepare nuts separately, and in the case of Figure 26, the user does not need to prepare bolts.
[0075] <Embodiment 9> Next, an electromagnetic relay according to Embodiment 9 will be described. Figures 28 to 30 are perspective views, bottom views, and side views, respectively, showing examples of the configuration of the contact mechanism according to Embodiment 9. As shown in Figures 28 to 30, the contact mechanism 10h according to this embodiment comprises a first stator 11h, a second stator 12h, and a movable element 13h.
[0076] The contact mechanism 10h according to this embodiment differs from the contact mechanism 10 according to Embodiment 1 in that the second stator 12h has an excitation section 124. The other configurations are the same as those described in Embodiment 1, so redundant explanations will be omitted.
[0077] The second stator 12h has a second fixed contact 121h that is connectable to the second movable contact 132h of the movable element 13h, and an excitation unit 124. The excitation unit 124 of the second stator 12h is configured to generate a magnetic field in the y-axis direction when the contact mechanism 10h is energized (see Figure 31). Specifically, as shown in Figure 30, the excitation unit 124 has an annular structure in which a first conductive member 125 and a third conductive member 127 extending in the x-axis direction and a second conductive member 126 and a fourth conductive member 128 extending in the z-axis direction are connected in the order of the first conductive member 125, the second conductive member 126, the third conductive member 127, and the fourth conductive member 128. The fourth conductive member 128 is connected to a conductive member (fifth conductive member) 129, and the second fixed contact 121h is provided on the negative z-axis side surface of the conductive member 129. In other words, the second fixed contact 121h is located on the side of the fourth conductive member 128 among the first to fourth conductive members 125 to 128 that constitute the excitation unit 124. Therefore, when the contact mechanism 10h is energized, current flows through the excitation unit 124, and the current flows through the first conductive member 125, the second conductive member 126, the third conductive member 127, and the fourth conductive member 128 in that order (see Figure 31).
[0078] When the contact mechanism 10h is energized, current flows through the excitation unit 124, and as shown in Figure 31, a magnetic field is generated inside the excitation unit 124 that is directed towards the negative side in the y-axis direction. Also, as shown in Figure 31, the excitation unit 124 is positioned so as to overlap with the movable element 13h (conductive plate 130h) when viewed from the y-axis direction. Therefore, as shown in Figure 31, when the contact mechanism 10h is energized, a Lorentz force is generated on the movable element 13h (conductive plate 130h) in the direction that maintains the energized state (positive side in the z-axis direction) due to the magnetic field generated by the excitation unit 124. Thus, by using the Lorentz force acting in the positive side in the z-axis direction, the electromagnetic repulsive force (force acting in the negative side in the z-axis direction) acting between the movable element 13h and the first stator 11h and the second stator 12h when energized can be effectively suppressed.
[0079] Furthermore, in this embodiment, as shown in Figures 29 and 30, the first conductive member 125 and the third conductive member 127 are configured to overlap with the movable element 13h (conductive plate 130h) when viewed from the z-axis direction. In other words, as shown in Figure 30, the excitation unit 124 is configured to have a U-shaped cross-section when viewed from the x-axis direction.
[0080] As shown in Figure 31, when the contact mechanism 10h is energized, the direction of the current flowing through the conductive plate 130h of the movable element 13h and the direction of the current flowing through the first conductive member 125 are the same, while the direction of the current flowing through the conductive plate 130h of the movable element 13h and the direction of the current flowing through the third conductive member 127 are opposite. Therefore, when the contact mechanism 10h is energized, an attractive force due to the Lorentz force is generated between the first conductive member 125 and the conductive plate 130h of the movable element 13h. Also, a repulsive force due to the Lorentz force is generated between the third conductive member 127 and the conductive plate 130h of the movable element 13h. Therefore, when energized, a Lorentz force acts on the conductive plate 130h of the movable element 13h in the positive z-axis direction, so the electromagnetic repulsive force (force acting in the negative z-axis direction) acting between the movable element 13h and the first stator 11h and the second stator 12h can be effectively suppressed. In this embodiment, the same effect can be obtained even if the direction of the current flowing through the contact mechanism 10h is opposite to the direction of the current shown in Figure 31.
[0081] It should be noted that the present invention is not limited to the embodiments described above, and can be modified as appropriate without departing from the spirit of the invention. Furthermore, each embodiment may be combined with others.
[0082] Although the present invention has been described above in accordance with the above embodiments, the present invention is not limited to the configuration of the above embodiments, and of course includes various modifications, alterations, and combinations that can be made by a person skilled in the art within the scope of the claims of the present patent application. [Explanation of Symbols]
[0083] 1 Electromagnetic relay 10 Contact mechanism 11 1st stator 12 Second stator 13 Mover 14. First permanent magnet 15. Second permanent magnet 16 York 17 Movable plate 20 Electromagnetic mechanism 21 Electromagnetic mechanism body 22 yoke 23 Movable Iron Piece 24 terminals 30 cases 31 storage cases 32 Lid 33. Heat crimping section 34 Welded Ribs 35 Installation structure 40 Sealing resin 41 First sealing resin 42 Second sealing resin 50 base 110 conductive plate 111 1st fixed contact 112 Threaded structure 113 Threaded component 120 conductive plate 121 2nd fixed contact 122 Threaded structure 123 Threaded component 124 Excitation section 125 First conductive member 126 Second conductive member 127 Third conductive member 128 Fourth conductive member 129 Fifth conductive member 130 conductive plate 131 1st movable contact 132 2nd movable contact 170, 171 Plate-shaped member 311 Recess 312 1st hole 313 First mating section 314 3rd hole 315 Ventilation holes 321 2nd hole 322 Second fitting section 323 4th hole 324 5th hole
Claims
1. A contact mechanism comprising: a movable element having a first movable contact and a second movable contact provided on both ends in the first direction of a conductive plate extending in a first direction; a first stator having a first fixed contact provided to connect to the first movable contact; and a second stator having a second fixed contact provided to connect to the second movable contact; A case housing the aforementioned contact mechanism, The case comprises a bucket-shaped housing case that houses the contact mechanism in a recess formed in the first direction, and a lid that covers the opening of the housing case. The first stator is positioned to penetrate the first hole formed in the bottom surface of the recess of the housing case, The second stator is positioned to penetrate the second hole formed in the cover. Electromagnetic relay.
2. At least one of the storage case or the lid has a mounting structure formed therein. The electromagnetic relay according to claim 1.
3. The first stator and the first hole are hermetically sealed using a sealing resin. The second stator and the second hole are hermetically sealed using a sealing resin. The electromagnetic relay according to claim 1 or 2.
4. The aforementioned storage case and the aforementioned lid are airtightly joined to each other by thermal fusion. The electromagnetic relay according to claim 1 or 2.
5. A first fitting portion is formed on at least one side of the housing case on the opening side, A second fitting portion is formed on the lid at a position corresponding to the first fitting portion of the housing case. The lid is fixed to the storage case by the first fitting portion of the storage case fitting with the second fitting portion of the lid. The electromagnetic relay according to claim 1 or 2.
6. The first fitting portion of the storage case is fitted with the second fitting portion of the lid and heat-crimped, and a resin material is provided between the storage case and the lid, thereby creating an airtight seal between the storage case and the lid. The electromagnetic relay according to claim 5.
7. The first fitting portion of the storage case fits with the second fitting portion of the lid, and a resin material is provided between the storage case and the lid, thereby creating an airtight seal between the storage case and the lid. The electromagnetic relay according to claim 5.
8. The first fitting portion is formed on two opposing long sides of the opening side of the aforementioned storage case. The electromagnetic relay according to claim 5.
9. A first permanent magnet for arc extinguishing is provided on the outer side of the first movable contact and the first fixed contact in the first direction. A second permanent magnet for arc extinguishing is provided on the outer side of the second movable contact and the second fixed contact in the first direction. The electromagnetic relay according to claim 1 or 2.
10. The first and second permanent magnets are provided with yokes for strengthening the magnetic field used to extinguish the arc. The electromagnetic relay according to claim 9.
11. A third hole is formed in the bottom surface of the recess of the housing case at a position corresponding to the first permanent magnet, and the first permanent magnet is bonded to the housing case by a resin material introduced through the third hole. A fourth hole is formed in the lid at a position corresponding to the second permanent magnet, and the second permanent magnet is bonded to the lid by a resin material introduced through the fourth hole. The electromagnetic relay according to claim 9.
12. When the opening of the aforementioned storage case is viewed from above, the opening is rectangular in shape. When the direction in which the longer side of the rectangular opening extends is designated as the second direction, and the direction in which the shorter side extends is designated as the third direction, the first and second permanent magnets are arranged such that the arcs generated near the first movable contact and the first fixed contact, and near the second movable contact and the second fixed contact, extend in the third direction. The contact mechanism is arranged such that it is eccentric to the opposite side from the direction in which the arc extends from the center position in the third direction of the opening of the housing case. The electromagnetic relay according to claim 9.
13. When the opening of the aforementioned storage case is viewed from above, the opening is rectangular in shape. When the direction in which the longer side of the rectangular opening extends is designated as the second direction, and the direction in which the shorter side extends is designated as the third direction, the movable element is configured to be displaceable in the second and third directions. The electromagnetic relay according to claim 1 or 2.
14. At least one of the cross-sectional shapes of the first stator at the position where it penetrates the first hole and the cross-sectional shape of the second stator at the position where it penetrates the second hole is rectangular in shape, with at least one corner having curvature. The electromagnetic relay according to claim 1 or 2.
15. The first stator, the second stator, the yoke supporting the movable element, the first permanent magnet, and the second permanent magnet are fixed to a base, and the base is configured to have openings in the direction in which the arcs generated near the first movable contact and the first fixed contact, and near the second movable contact and the second fixed contact extend. The electromagnetic relay according to claim 9.
16. The movable element is further provided with an electromagnetic mechanism that can be displaced. The terminal that supplies the drive current to the electromagnetic mechanism is arranged to extend in the first direction and is configured to penetrate the bottom surface of the recess of the housing case or the fifth hole formed in the lid. The electromagnetic relay according to claim 1 or 2.
17. The housing case or the lid is provided with ventilation holes to release at least one of the pressure generated when the first stator and the first hole are airtightly sealed with sealing resin, and the pressure generated when the second stator and the second hole are airtightly sealed with sealing resin. The ventilation holes are sealed after the first stator and the first hole, and the second stator and the second hole are hermetically sealed. The electromagnetic relay according to claim 1 or 2.
18. The first stator and the second stator are formed with a screw structure capable of fixing a predetermined member. The electromagnetic relay according to claim 1 or 2.
19. The screw structure is formed by fixing the member having the screw structure to the first stator and the second stator. The electromagnetic relay according to claim 18.