JP2023003206A - Contact structure - Google Patents

Abstract

To reduce the repulsive force generated between two terminals that can contact and separate from each other while suppressing the amount of heat generated at the time of energization.SOLUTION: A contact structure includes a first terminal having a first contact, and a second terminal having a second contact, and at least one of the first terminal and the second terminal moves to bring the first contact and the second contact into contact with each other. A contact portion of the first contact and the second contact is provided at a position such that the entire current path is short with respect to the cross section of the contacts perpendicular to the current path.SELECTED DRAWING: Figure 2

Description

The present invention relates to contact structures.

In Patent Document 1 below, by linearly moving the mover in a direction approaching each of the two fixed terminals, each of the two contact portions of the mover is brought into contact with each of the two fixed terminals. A relay device is disclosed that is configured to allow current flow between two fixed terminals.

JP 2012-199136 A

However, in the technique disclosed in Patent Document 1, since the mover is not in a straight line connecting the two contact portions, the current path of the mover becomes long, which may increase the amount of heat generated when energized.

FIG. 15 is a diagram showing the configuration of a contact portion according to the prior art. As shown in FIG. 15, according to the prior art, both the movable contact 12 of the movable terminal 10 and the fixed contact 22 of the fixed terminal 20 have an overall dome shape. In the prior art, the central portion (top portion) of the movable contact 12 and the central portion (top portion) of the fixed contact 22 are configured to point-contact. Therefore, as shown in FIG. 15, in the fixed contact 22, the short-circuit current I concentrates toward the center (top), and in the movable contact 12, the short-circuit current I flows from the center (top). is diffused, currents flow in directions opposite to each other in the fixed contact 22 and the movable contact 12 (see the dotted line in the figure). there is

In order to solve the above-described problems, a contact structure according to one embodiment includes a first terminal having a first contact, a second terminal having a second contact, and a contact between the first terminal and the second contact. A contact structure in which a first contact and a second contact are brought into contact by operating at least one of the terminals, wherein the contact portion between the first contact and the second contact is perpendicular to the current path It is positioned so that the overall current path is short with respect to the cross section of the contact.

According to the contact structure according to one embodiment, it is possible to reduce the repulsive force generated between the two terminals that are separable and contactable from each other while suppressing the amount of heat generated at the time of energization.

Sectional drawing which shows the structure of the electromagnetic relay which concerns on one Embodiment Partially enlarged side view showing the configuration of the contact portion in the electromagnetic relay according to one embodiment A partially enlarged side view showing a first modification of the configuration of the contact portion in the electromagnetic relay according to one embodiment. A plan view showing a configuration of a first movable contact according to a first modified example. Partially enlarged side view showing a second modification of the configuration of the contact portion in the electromagnetic relay according to one embodiment Front view showing the configuration of the first movable contact according to the second modification Partially enlarged side view showing a third modification of the configuration of the contact portion in the electromagnetic relay according to one embodiment A plan view showing a configuration of a first movable contact according to a third modification A partially enlarged side view showing a fourth modified example of the configuration of the contact portion in the electromagnetic relay according to one embodiment. A plan view showing a configuration of a first movable contact according to a fourth modification Partially enlarged perspective view showing a fifth modification of the configuration of the contact portion in the electromagnetic relay according to one embodiment Partially enlarged perspective view showing the configuration of the first fixed contact according to the fifth modification The perspective view which shows the magnetic flux which arises by short-circuit current in the electromagnetic relay which concerns on one Embodiment. Sectional drawing which shows the magnetic flux which arises by the short circuit current I in the electromagnetic relay which concerns on one Embodiment A diagram showing a configuration of a contact portion according to conventional technology

An embodiment of the present invention will be described below with reference to the drawings.

(Configuration of electromagnetic relay 100)
FIG. 1 is a cross-sectional view showing the configuration of an electromagnetic relay 100 according to one embodiment. An electromagnetic relay 100 shown in FIG. 1 is used, for example, in various vehicles (eg, hybrid vehicles, electric vehicles, etc.) to disconnect and connect current paths for sending battery current to motors and the like.

As shown in FIG. 1 , electromagnetic relay 100 includes case 110 , electromagnet 120 , movable terminal 130 , first fixed terminal 141 , second fixed terminal 143 and spring 150 .

Case 110 is a box-shaped member formed using an insulating material. The interior of the case 110 is separated into an upper space 112 and a lower space 113 by a horizontal partition 111 .

Electromagnet 120 is arranged in lower space 113 of case 110 . Electromagnet 120 has excitation coil 121 and core 122 .

The excitation coil 121 is formed in a cylindrical shape by winding an electric wire (for example, a copper wire) in multiple layers. The excitation coil 121 generates magnetic lines of force inside the excitation coil 121 by being energized.

The core 122 is a rod-shaped member made of a magnetic material (for example, iron) and linearly extending in the vertical direction (Z-axis direction). The core 122 is arranged inside the exciting coil 121 so as to be movable in the vertical direction (the Z-axis direction). A magnetic force is generated in the core 122 by the lines of magnetic force generated by the excitation coil 121 . An upper portion of the core 122 is disposed in the upper space 112 through the partition wall portion 111 . A movable terminal 130 is fixed to the upper end of the core 122 .

The movable terminal 130 is provided in the upper space 112 of the case 110 . The movable terminal 130 is formed using a conductive metal material and has a horizontal flat plate shape extending linearly in the left-right direction (X-axis direction). The movable terminal 130 is fixed to the upper end of the core 122 at its central portion in the left-right direction (X-axis direction). This allows the movable terminal 130 to move vertically (in the Z-axis direction) together with the core 122 . The movable terminal 130 has a first movable contact 131 on the upper surface and the left (X-axis negative side) end, and has a second movable contact 132 on the upper surface and the right (X-axis positive side) end. The first movable contact 131 and the second movable contact 132 are formed using a conductive metal material and have a generally horizontal flat plate shape.

The first fixed terminal 141 is arranged above the first movable contact 131 on the left side (X-axis negative side) of the upper space 112 of the case 110 . The first fixed terminal 141 is formed using a conductive metal material, and has a columnar shape extending linearly in the vertical direction (the Z-axis direction). The first fixed terminal 141 has a first fixed contact 142 on its bottom surface. The first fixed contact 142 is formed using a conductive metal material and has a generally horizontal flat plate shape. The first fixed contact 142 faces the first movable contact 131 . The upper portion of the first fixed terminal 141 penetrates the upper wall portion 114 of the case 110 and protrudes above the upper wall portion 114 (positive Z-axis direction).

The second fixed terminal 143 is arranged above the second movable contact 132 on the right side (X-axis positive side) of the upper space 112 of the case 110 . The second fixed terminal 143 is made of a conductive metal material and has a columnar shape extending linearly in the vertical direction (Z-axis direction). The second fixed terminal 143 has a second fixed contact 144 on its bottom surface. The second fixed contact 144 is formed using a conductive metal material and has a substantially horizontal flat plate shape. The second fixed contact 144 faces the second movable contact 132 . The upper portion of the second fixed terminal 143 penetrates the upper wall portion 114 of the case 110 and protrudes above the upper wall portion 114 (in the positive Z-axis direction).

Spring 150 is arranged to surround core 122 between movable terminal 130 and partition wall portion 111 . The spring 150 is formed in a helical shape using a metal wire and can expand and contract in the vertical direction (Z-axis direction). The upper end of spring 150 is fixed to the bottom surface of movable terminal 130 . A lower end portion of the spring 150 is fixed to the bottom surface of the partition wall portion 111 . Thereby, the spring 150 can expand and contract in the vertical direction (Z-axis direction) as the movable terminal 130 moves in the vertical direction (Z-axis direction).

(Operation of electromagnetic relay 100)
By energizing the exciting coil 121 of the electromagnet 120 , the electromagnetic relay 100 according to one embodiment can generate magnetic lines of force inside the exciting coil 121 and generate magnetic force in the core 122 . The magnetic force generated in core 122 generates an attraction force between movable terminal 130 fixed to core 122 and first fixed terminal 141 and second fixed terminal 143 . Movable terminal 130 moves upward (in the Z-axis positive direction) together with core 122 due to this attraction force, thereby moving first movable contact 131 and second movable contact 132 to first fixed contact 142 and second fixed contact, respectively. 144 can be contacted. As a result, in the electromagnetic relay 100 according to one embodiment, the current path from the first fixed terminal 141 to the second fixed terminal 143 via the movable terminal 130 is in a connected state.

Further, the electromagnetic relay 100 according to one embodiment can eliminate the magnetic force generated in the core 122 and the adsorption force generated in the movable terminal 130 by canceling the energization of the exciting coil 121 of the electromagnet 120 . can. As a result, the electromagnetic relay 100 according to one embodiment moves the core 122 downward (Z-axis negative direction) by the biasing force of the spring 150, and each of the first movable contact 131 and the second movable contact 132 is moved. It can be spaced apart from each of the first fixed contact 142 and the second fixed contact 144 . As a result, in the electromagnetic relay 100 according to one embodiment, the current path from the first fixed terminal 141 to the second fixed terminal 143 via the movable terminal 130 is disconnected.

(Structure of contact part)
FIG. 2 is a partially enlarged side view showing the configuration of contact portions in the electromagnetic relay 100 according to one embodiment.

As shown in FIG. 2, the first fixed contact 142 has a right (positive X-axis) end, that is, an end near the second fixed contact 144, downward (negative Z-axis direction). It has a protruding dome-shaped convex portion 142A.

In addition, as shown in FIG. 2, the first movable contact 131 extends upward (in the positive Z-axis direction) at the end on the right side (positive side of the X-axis), that is, at the end on the side closer to the second movable contact 132 . It has a dome-shaped protrusion 131A that protrudes toward it.

The convex portion 142A and the convex portion 131A are provided to face each other. Moreover, both the convex portion 142A and the convex portion 131A have curved surfaces.

2, when the exciting coil 121 of the electromagnet 120 is energized and the movable terminal 130 moves upward (positive direction of the Z-axis), the electromagnetic relay 100 according to the embodiment moves the first The top of the projection 131A of the first movable contact 131 makes point contact with the top of the projection 142A of the fixed contact 142 .

As a result, in the electromagnetic relay 100 according to one embodiment, the short-circuit current I that flows from the first fixed terminal 141 to the movable terminal 130, as shown in FIG. ), flows to the convex portion 131A provided at the right end of the first movable contact 131 through the contact portion between the convex portion 142A and the convex portion 131A, and flows to the movable terminal 130 through the convex portion 131A. Then, the short-circuit current I flows through the movable terminal 130 toward the right direction (positive direction of the X-axis) where the second fixed terminal 143 is located.

That is, in the electromagnetic relay 100 according to one embodiment, the short-circuit current I is applied to the first movable contact 131 so that the projection 131A provided at the right end of the first movable contact 131 is downward (Z-axis negative direction). only pass through. For this reason, in the electromagnetic relay 100 according to one embodiment, currents in opposite directions do not flow through the first fixed contact 142 and the first movable contact 131 , so that the first fixed contact 142 and the first movable contact 131 It is possible to suppress the occurrence of a repulsive force between

Further, in the electromagnetic relay 100 according to one embodiment, the point contact portion between the convex portion 142A of the first fixed contact 142 and the convex portion 131A of the first movable contact 131 is the point contact portion of the first fixed contact 142 and the first movable contact 131 Since it is provided at the right end, the current path of the short-circuit current I flowing from the first fixed terminal 141 to the second fixed terminal 143 via the movable terminal 130 can be minimized.

Although illustration is omitted, in the electromagnetic relay 100 according to one embodiment, the configuration of the contact portion between the second fixed contact 144 and the second movable contact 132 is the same as that between the first fixed contact 142 and the first movable contact 131. It is bilaterally symmetrical with respect to the structure of the contact portion. That is, the second fixed contact 144 has a dome-shaped protrusion (similar to the protrusion 142A) that protrudes downward (in the Z-axis negative direction) at the left (X-axis negative side) end. In addition, the second movable contact 132 has a dome-shaped convex portion (similar to the convex portion 131A) that protrudes upward (positive direction of the Z axis) at the right end (positive side of the X axis).

Accordingly, in the electromagnetic relay 100 according to one embodiment, when the exciting coil 121 of the electromagnet 120 is energized and the movable terminal 130 moves upward (positive direction of the Z-axis), the projection of the second fixed contact 144 The top of the projection of the second movable contact 132 makes point contact with the top.

As a result, in the electromagnetic relay 100 according to one embodiment, the short-circuit current I flows from the movable terminal 130 to the second fixed terminal through the point contact portion between the convex portion of the second fixed contact 144 and the convex portion of the second movable contact 132 . Flow to 143.

That is, in the electromagnetic relay 100 according to one embodiment, the short-circuit current I is generated in the second movable contact 132 upward (in the positive direction of the Z-axis) through the projection provided at the left end of the second movable contact 132. just pass through. For this reason, in the electromagnetic relay 100 according to one embodiment, currents do not flow in opposite directions to the second fixed contact 144 and the second movable contact 132 . It is possible to suppress the occurrence of a repulsive force between

Also, in the electromagnetic relay 100 according to one embodiment, the point contact portion between the convex portion of the second fixed contact 144 and the convex portion of the second movable contact 132 is the left end portion of the second fixed contact 144 and the second movable contact 132 . , the current path of the short-circuit current I flowing from the first fixed terminal 141 to the second fixed terminal 143 via the movable terminal 130 can be minimized.

(First Modification of Configuration of Contact Portion)
Next, with reference to FIGS. 3 and 4, a first modification of the configuration of the contact portion will be described. FIG. 3 is a partially enlarged side view showing a first modified example of the configuration of the contact portion in the electromagnetic relay 100 according to one embodiment. FIG. 4 is a plan view showing the configuration of the first movable contact 131 according to the first modified example.

First Modification As shown in FIGS. 3 and 4, both the first fixed contact 142 and the first movable contact 131 according to the modification have planar surfaces.

Further, as shown in FIGS. 3 and 4, the first movable contact 131 according to the first modification is arranged at the right (X-axis positive side) end, that is, the end near the second movable contact 132. , and rib-like protrusions 131A that protrude upward (in the positive direction of the Z-axis). The convex portion 131A is provided along the right end portion of the first movable contact 131 so as to extend linearly in the front-rear direction (Y-axis direction), and has a dome-shaped cross section that protrudes upward. have a shape.

As a result, the electromagnetic relay 100 according to the first modification, as shown in FIG. The top of the projection 131A of the first movable contact 131 is in line contact with the surface of the first fixed contact 142 .

As a result, in the electromagnetic relay 100 according to the first modified example, the short-circuit current I flowing from the first fixed terminal 141 to the movable terminal 130 is collected at the right end of the first fixed contact 142 in the same manner as in the configuration shown in FIG. , through the line contact portion between the surface of the first fixed contact 142 provided at the right end and the top of the protrusion 131A, flow to the protrusion 131A provided at the right end of the first movable contact 131, and flow into the protrusion 131A. It flows to the movable terminal 130 through the portion 131A. Then, the short-circuit current I flows through the movable terminal 130 toward the right direction (positive direction of the X-axis) where the second fixed terminal 143 is located.

That is, in the electromagnetic relay 100 according to the first modification, the short-circuit current I in the first movable contact 131 moves downward (Z-axis negative direction ). Therefore, in the electromagnetic relay 100 according to the first modified example, currents do not flow in the opposite directions to the first fixed contact 142 and the first movable contact 131, so that the first fixed contact 142 and the first movable contact 131 can be suppressed.

Further, in the electromagnetic relay 100 according to the first modification, the line contact portion between the surface of the first fixed contact 142 and the convex portion 131A of the first movable contact 131 is arranged at the right ends of the first fixed contact 142 and the first movable contact 131. Since it is provided in the portion, the current path of the short-circuit current I flowing from the first fixed terminal 141 to the second fixed terminal 143 via the movable terminal 130 can be minimized. Therefore, the electromagnetic relay 100 according to the first modification can suppress the amount of heat generated when energized.

In particular, since the electromagnetic relay 100 according to the first modified example is configured to make line contact by the linear convex portion 131A extending in the front-rear direction (Y-axis direction), the contact between the first fixed contact 142 and the first movable contact 131 is reduced. can be dispersed in the front-rear direction (Y-axis direction). Therefore, the electromagnetic relay 100 according to the second modified example can suppress the generation of repulsive force between the first fixed contact 142 and the first movable contact 131 .

Although illustration is omitted, in the electromagnetic relay 100 according to the first modification, the configuration of the contact portion between the second fixed contact 144 and the second movable contact 132 is the first fixed contact 142 and the first movable contact 131. is symmetrical with respect to the configuration of the contact portion of That is, the second movable contact 132 has a dome-shaped convex portion (similar to the convex portion 131A) that protrudes upward (positive direction of the Z axis) at the left end (negative side of the X axis). As a result, the contact portion between the second fixed contact 144 and the second movable contact 132 acts similarly to the contact portion between the first fixed contact 142 and the first movable contact 131. It is possible to suppress the occurrence of a repulsive force with the second movable contact 132 .

(Second Modification of Configuration of Contact Portion)
Next, with reference to FIGS. 5 and 6, a second modification of the configuration of the contact portion will be described. FIG. 5 is a partially enlarged side view showing a second modification of the configuration of the contact portion in the electromagnetic relay 100 according to one embodiment. FIG. 6 is a front view showing the configuration of the first movable contact 131 according to the second modified example.

As shown in FIGS. 5 and 6, both the first fixed contact 142 and the first movable contact 131 according to the second modification have planar surfaces.

Further, as shown in FIGS. 5 and 6, the first movable contact 131 according to the second modification is located at the right (X-axis positive side) end, that is, the end near the second movable contact 132. , and a plurality of dome-shaped projections 131A projecting upward (in the positive direction of the Z-axis). The plurality of protrusions 131A are arranged linearly in the front-rear direction (Y-axis direction) along the right end of the first movable contact 131 .

As a result, the electromagnetic relay 100 according to the second modification, as shown in FIG. The apex of each of the plurality of protrusions 131A of the first movable contact 131 makes multi-point contact with the surface of the 1 fixed contact 142 .

As a result, in the electromagnetic relay 100 according to the second modification, the short-circuit current I flowing from the first fixed terminal 141 to the movable terminal 130 is collected at the right end of the first fixed contact 142, as in the configuration shown in FIG. , through the multi-point contact portion between the surface of the first fixed contact 142 provided at the right end and the plurality of protrusions 131A, to the plurality of protrusions 131A provided at the right end of the first movable contact 131. , flows to the movable terminal 130 through the plurality of protrusions 131A. Then, the short-circuit current I flows through the movable terminal 130 toward the right direction (positive direction of the X-axis) where the second fixed terminal 143 is located.

That is, in the electromagnetic relay 100 according to the second modification, the short-circuit current I in the first movable contact 131 moves downward (Z-axis negative direction). For this reason, in the electromagnetic relay 100 according to the second modification, currents in opposite directions do not flow through the first fixed contact 142 and the first movable contact 131, so that the first fixed contact 142 and the first movable contact 131 can be suppressed.

Further, in the electromagnetic relay 100 according to the second modification, the multi-point contact portion between the surface of the first fixed contact 142 and the convex portion 131A of the first movable contact 131 is replaced by the first fixed contact 142 and the first movable contact 131. Since it is provided at the right end, the current path of the short-circuit current I flowing from the first fixed terminal 141 to the second fixed terminal 143 via the movable terminal 130 can be minimized. Therefore, the electromagnetic relay 100 according to the second modification can suppress the amount of heat generated when energized.

In particular, since the electromagnetic relay 100 according to the second modification is configured to make multi-point contact by the plurality of convex portions 131A arranged linearly in the front-rear direction (Y-axis direction), the first fixed contact 142 and the first movable contact 142 The current flowing between the contacts 131 can be dispersed in the front-rear direction (Y-axis direction). Therefore, the electromagnetic relay 100 according to the second modified example can suppress the generation of repulsive force between the first fixed contact 142 and the first movable contact 131 .

Here, since the repulsive force is proportional to the square of the current, for example, when the first movable contact 131 is provided with two plurality of protrusions 131A, the repulsive force of each of the two first movable contacts 131 is 4 1/2 (1/2 squared), and the total repulsive force of the two first movable contacts 131 can be reduced to 1/2.

Although illustration is omitted, in the electromagnetic relay 100 according to the second modification, the configuration of the contact portion between the second fixed contact 144 and the second movable contact 132 is the first fixed contact 142 and the first movable contact 131. is symmetrical with respect to the configuration of the contact portion of That is, the second movable contact 132 has a plurality of dome-shaped protrusions (similar to the protrusion 131A) that protrude upward (in the positive direction of the Z axis) at the left end (negative side of the X axis). As a result, the contact portion between the second fixed contact 144 and the second movable contact 132 acts similarly to the contact portion between the first fixed contact 142 and the first movable contact 131. It is possible to suppress the occurrence of a repulsive force with the second movable contact 132 .

(Third modification of the configuration of the contact portion)
Next, with reference to FIGS. 7 and 8, a third modification of the configuration of the contact portion will be described. FIG. 7 is a partially enlarged side view showing a third modified example of the configuration of the contact portion in the electromagnetic relay 100 according to one embodiment. FIG. 8 is a plan view showing the configuration of the first movable contact 131 according to the third modification.

As shown in FIGS. 7 and 8, both the first fixed contact 142 and the first movable contact 131 according to the third modification have planar surfaces.

Further, as shown in FIGS. 7 and 8, the first movable contact 131 according to the third modification is arranged at the right (X-axis positive side) end, that is, the end near the second movable contact 132. , and rib-like protrusions 131A that protrude upward (in the positive direction of the Z-axis). The convex portion 131A is provided along the right end portion of the first movable contact 131 so as to extend linearly in the front-rear direction (Y-axis direction), and has a dome-shaped cross section that protrudes upward. have a shape. However, as shown in FIG. 7, the convex portion 131A of the third modified example is slightly offset to the right side (X-axis positive side) of the right end portion of the first fixed contact 142 .

7, when the exciting coil 121 of the electromagnet 120 is energized and the movable terminal 130 moves upward (positive direction of the Z-axis), the electromagnetic relay 100 according to the third modification The curved surface portion of the convex portion 131A of the first movable contact 131 is in line contact with the right end portion (lower right corner portion) of the first fixed contact 142 .

As a result, in the electromagnetic relay 100 according to the third modification, the short-circuit current I flowing from the first fixed terminal 141 to the movable terminal 130 is collected at the right end of the first fixed contact 142, as in the configuration shown in FIG. , through the line contact portion between the lower right corner of the first fixed contact 142 provided at the right end and the curved surface portion of the protrusion 131A, flow to the protrusion 131A provided at the right end of the first movable contact 131. , flows to the movable terminal 130 through the projection 131A. Then, the short-circuit current I flows through the movable terminal 130 toward the right direction (positive direction of the X-axis) where the second fixed terminal 143 is located.

That is, in the electromagnetic relay 100 according to the third modification, the short-circuit current I in the first movable contact 131 moves downward (Z-axis negative direction ). For this reason, in the electromagnetic relay 100 according to the third modification, currents do not flow in the opposite directions to the first fixed contact 142 and the first movable contact 131. Therefore, the first fixed contact 142 and the first movable contact 131 can be suppressed.

Further, in the electromagnetic relay 100 according to the third modification, the line contact portion between the lower right corner portion of the first fixed contact 142 and the convex portion 131A of the first movable contact 131 is connected to the first fixed contact 142 and the first movable contact 131. , the current path of the short-circuit current I flowing from the first fixed terminal 141 to the second fixed terminal 143 via the movable terminal 130 can be minimized. Therefore, the electromagnetic relay 100 according to the third modification can suppress the amount of heat generated when energized.

In particular, since the electromagnetic relay 100 according to the third modification is configured such that linear contact is achieved by the linear convex portion 131A extending in the front-rear direction (Y-axis direction), the contact between the first fixed contact 142 and the first movable contact 131 is reduced. can be dispersed in the front-rear direction (Y-axis direction). Therefore, the electromagnetic relay 100 according to the third modification can suppress the generation of repulsive force between the first fixed contact 142 and the first movable contact 131 .

Although illustration is omitted, in the electromagnetic relay 100 according to the third modification, the configuration of the contact portion between the second fixed contact 144 and the second movable contact 132 is the first fixed contact 142 and the first movable contact 131. is symmetrical with respect to the configuration of the contact portion of That is, the second movable contact 132 has a rib-like projection (similar to the projection 131A) projecting upward (positive direction of the Z-axis) at the left end (negative side of the X-axis). As a result, the contact portion between the second fixed contact 144 and the second movable contact 132 acts similarly to the contact portion between the first fixed contact 142 and the first movable contact 131. It is possible to suppress the occurrence of a repulsive force with the second movable contact 132 .

(Fourth modification of the configuration of the contact portion)
Next, with reference to FIGS. 9 and 10, a fourth modification of the configuration of the contact portion will be described. FIG. 9 is a partially enlarged side view showing a fourth modified example of the configuration of the contact portion in the electromagnetic relay 100 according to one embodiment. FIG. 10 is a plan view showing the configuration of a first movable contact 131 according to a fourth modification.

As shown in FIGS. 9 and 10, both the first fixed contact 142 and the first movable contact 131 according to the fourth modification have planar surfaces.

Further, as shown in FIGS. 9 and 10, the first movable contact 131 according to the fourth modification is arranged at the right (X-axis positive side) end, that is, the end near the second movable contact 132. , and rib-like protrusions 131A that protrude upward (in the positive direction of the Z-axis). The convex portion 131A is provided along the right end portion of the first movable contact 131 so as to extend linearly in the front-rear direction (Y-axis direction), and has a trapezoidal cross section that is convex upward. have a shape. However, as shown in FIG. 9, the convex portion 131A of the fourth modification is slightly offset to the right (X-axis positive side) of the right end portion of the first fixed contact 142 .

As a result, as shown in FIG. 9, the electromagnetic relay 100 according to the fourth modification is configured such that when the exciting coil 121 of the electromagnet 120 is energized and the movable terminal 130 moves upward (positive direction of the Z-axis), the The left slanted portion of the projection 131A of the first movable contact 131 is in line contact with the right end (lower right corner) of the first fixed contact 142 .

As a result, in the electromagnetic relay 100 according to the fourth modification, the short-circuit current I flowing from the first fixed terminal 141 to the movable terminal 130 is collected at the right end of the first fixed contact 142, as in the configuration shown in FIG. , the projection 131A provided at the right end of the first movable contact 131 through a line contact portion between the lower right corner of the first fixed contact 142 provided at the right end and the left slope portion of the projection 131A. It flows to the movable terminal 130 through the convex portion 131A. Then, the short-circuit current I flows through the movable terminal 130 toward the right direction (positive direction of the X-axis) where the second fixed terminal 143 is located.

That is, in the electromagnetic relay 100 according to the fourth modification, the short-circuit current I in the first movable contact 131 moves downward (Z-axis negative direction ). Therefore, in the electromagnetic relay 100 according to the fourth modification, currents in opposite directions do not flow through the first fixed contact 142 and the first movable contact 131, so that the first fixed contact 142 and the first movable contact 131 can be suppressed.

Further, in the electromagnetic relay 100 according to the fourth modification, the line contact portion between the lower right corner portion of the first fixed contact 142 and the left slope portion of the convex portion 131A of the first movable contact 131 is arranged between the first fixed contact 142 and the second 1 movable contact 131, the current path of the short-circuit current I flowing from the first fixed terminal 141 to the second fixed terminal 143 via the movable terminal 130 can be minimized. Therefore, the electromagnetic relay 100 according to the fourth modification can suppress the amount of heat generated when energized.

In particular, since the electromagnetic relay 100 according to the fourth modification is configured to make line contact by the linear projections 131A extending in the front-rear direction (Y-axis direction), the contact between the first fixed contact 142 and the first movable contact 131 is reduced. can be dispersed in the front-rear direction (Y-axis direction). Therefore, the electromagnetic relay 100 according to the fourth modification can suppress the generation of repulsive force between the first fixed contact 142 and the first movable contact 131 .

Although illustration is omitted, in the electromagnetic relay 100 according to the fourth modification, the configuration of the contact portion between the second fixed contact 144 and the second movable contact 132 is the first fixed contact 142 and the first movable contact 131. is symmetrical with respect to the configuration of the contact portion of That is, the second movable contact 132 has a rib-like projection (similar to the projection 131A) projecting upward (positive direction of the Z-axis) at the left end (negative side of the X-axis). As a result, the contact portion between the second fixed contact 144 and the second movable contact 132 acts similarly to the contact portion between the first fixed contact 142 and the first movable contact 131. It is possible to suppress the occurrence of a repulsive force with the second movable contact 132 .

In addition, in the first to fourth modifications, the first movable contact 131 is provided with the convex portion 131A. may be provided.

(Fifth modification of the configuration of the contact portion)
Next, with reference to FIGS. 11 and 12, a fifth modification of the configuration of the contact portion will be described. FIG. 11 is a partially enlarged perspective view showing a fifth modified example of the configuration of the contact portion in the electromagnetic relay 100 according to one embodiment. FIG. 12 is a partially enlarged perspective view showing the configuration of a first fixed contact 142 according to a fifth modification.

As shown in FIGS. 11 and 12, the first movable contact 131 according to the fifth modification generally has a hemispherical shape convex upward (in the positive Z-axis direction).

Further, as shown in FIGS. 11 and 12, a first fixed contact 142 according to the fifth modification is provided at the right end portion of the lower end surface of the first fixed terminal 141 so as to protrude downward. The first fixed contact 142 has a cylindrical shape with a concave portion 142B conically recessed upward from the bottom surface, divided into two parts by the YZ plane, and the left side (the negative side of the X axis) is removed. As a result, the first fixed contact 142 has a semi-cylindrical shape and a semi-conical concave portion 142B.

13, when the exciting coil 121 of the electromagnet 120 is energized and the movable terminal 130 moves upward (positive direction of the Z-axis), the electromagnetic relay 100 according to the fifth modification The inner peripheral surface of the semi-conical concave portion 142B of the first fixed contact 142 and the right side (positive side of the X axis) of the spherical surface of the first movable contact 131 are in line contact in an arc shape.

As a result, in the electromagnetic relay 100 according to the fifth modification, the short-circuit current I flowing from the first fixed terminal 141 to the movable terminal 130 is collected at the right end portion of the first fixed contact 142 in the same manner as in the configuration shown in FIG. , through an arc-shaped line contact portion between the concave portion 142B of the first fixed contact 142 provided at the right end portion and the right side (positive side of the X axis) of the spherical surface of the first movable contact 131, to the movable terminal 130. flow. Then, the short-circuit current I flows through the movable terminal 130 toward the right direction (positive direction of the X-axis) where the second fixed terminal 143 is located.

That is, in the electromagnetic relay 100 according to the fifth modification, the short-circuit current I only passes through the right end portion of the first movable contact 131 downward (Z-axis negative direction) in the first movable contact 131 . Therefore, in the electromagnetic relay 100 according to the fifth modification, currents in opposite directions do not flow through the first fixed contact 142 and the first movable contact 131, so that the first fixed contact 142 and the first movable contact 131 can be suppressed.

Further, in the electromagnetic relay 100 according to the fifth modification, since the arc-shaped line contact portion between the first fixed contact 142 and the first movable contact 131 is provided at the right end portion of the first movable contact 131, the first fixed terminal The current path of the short-circuit current I flowing from 141 to the second fixed terminal 143 via the movable terminal 130 can be minimized. Therefore, the electromagnetic relay 100 according to the fifth modification can suppress the amount of heat generated when energized.

In particular, the electromagnetic relay 100 according to the fifth modification is configured such that the first fixed contact 142 and the first movable contact 131 are in line contact with each other in an arc. can be distributed circumferentially. Therefore, the electromagnetic relay 100 according to the fifth modification can suppress the generation of repulsive force between the first fixed contact 142 and the first movable contact 131 .

Further, since the electromagnetic relay 100 according to the fifth modification is configured such that the first fixed contact 142 and the first movable contact 131 are in line contact in an arc shape, the contact portion may be displaced by 1 due to the tilt of the contacts or positional deviation due to processing accuracy. It is possible to suppress the formation of a point, thereby improving the robustness against the tilt of the contact and the displacement due to the processing accuracy.

Although illustration is omitted, in the electromagnetic relay 100 according to the fifth modification, the configuration of the contact portion between the second fixed contact 144 and the second movable contact 132 is the first fixed contact 142 and the first movable contact 131. is symmetrical with respect to the configuration of the contact portion of That is, the second movable contact 132 as a whole has a hemispherical shape convex upward (positive direction of the Z-axis). The second fixed contact 144 is provided on the left end of the lower end surface of the second fixed terminal 143 so as to protrude downward, and has a semi-cylindrical shape and a semi-conical recess (recess 142B). and symmetrical shape). As a result, the contact portion between the second fixed contact 144 and the second movable contact 132 acts similarly to the contact portion between the first fixed contact 142 and the first movable contact 131. It is possible to suppress the occurrence of a repulsive force with the second movable contact 132 .

In the fifth modification, the second fixed contact 144 has the same shape as the first movable contact 131 (the first movable contact 131 shown in FIGS. 13 and 14 is inverted upside down), and the first movable contact 131 may have the same shape as the second fixed contact 144 (the second fixed contact 144 shown in FIGS. 13 and 14 is inverted upside down).

(Effect of suppressing electromagnetic repulsion)
FIG. 13 is a perspective view showing magnetic flux generated by the short-circuit current I in the electromagnetic relay 100 according to one embodiment. FIG. 14 is a cross-sectional view showing magnetic flux generated by the short-circuit current I in the electromagnetic relay 100 according to one embodiment.

As shown in FIGS. 13 and 14 , at the movable terminal 130 , the backward (Y-axis negative direction) magnetic flux M formed by the short-circuit current I and the rightward (X-axis positive direction) short circuit flowing through the movable terminal 130 The current I acts to generate an electromagnetic repulsive force as Lorentz force in the downward direction (Z-axis negative direction).

In particular, as shown in FIGS. 13 and 14, in the inner region surrounded by the fixed terminals 141 and 143 and the movable terminal 130, the magnetic flux M in the rearward direction (the Y-axis negative direction) overlaps and becomes large. An electromagnetic repulsive force of 130 is likely to occur. Furthermore, since the current density increases in the vicinity of the contact, the magnetic flux M in the rearward direction (Y-axis negative direction) also increases, which is a factor that strengthens the electromagnetic repulsive force of the movable terminal 130 .

As described above, the electromagnetic relay 100 according to one embodiment has the contact portion P1 (point contact portion, multi-point contact portion, or line contact portion) between the first fixed contact 142 and the first movable contact 131 provided at the right end. In addition, a contact portion P2 (point contact portion, multi-point contact portion, or line contact portion) between the second fixed contact 144 and the second movable contact 132 is provided at the left end. For this reason, in the electromagnetic relay 100 according to one embodiment, the boundary between the forward (Y-axis positive direction) magnetic flux M and the backward (Y-axis negative direction) magnetic flux M at the contact portion P1 and the contact portion P2 (Fig. 14 ) can be shifted inwardly at the movable terminal 130 . As a result, the electromagnetic relay 100 according to one embodiment can suppress the magnetic flux in the rearward direction (Y-axis negative direction) distributed in the movable terminal 130 , thereby suppressing the electromagnetic repulsive force of the movable terminal 130 . can.

Although the preferred embodiments of the present invention have been described in detail above, the present invention is not limited to these embodiments, and various modifications or Change is possible.

For example, the present invention is not limited to electromagnetic relays, and includes at least "a first terminal having a first contact, a second terminal having a second contact, and at least one of the first terminal and the second terminal." It can be applied to the following devices as long as it has a contact structure in which the first contact and the second contact are brought into contact by the operation of one of them.

For example, in the present invention, each of the first terminal and the second terminal is a movable contact, and by moving the first terminal and the second terminal toward each other, the first contact and the second terminal move toward each other. It can also be applied to an electromagnetic relay or a device other than an electromagnetic relay having a contact structure in which two contacts are in contact with each other.

Moreover, in the present invention, the fixed contact is not limited to being a separate member from the fixed terminal, and may be integrally formed with the fixed terminal. Moreover, in the present invention, the movable contact is not limited to being a separate member from the movable terminal, and may be integrally formed with the movable terminal.

100 electromagnetic relay 110 case 111 partition 112 upper space 113 lower space 114 upper wall 120 electromagnet 121 exciting coil 122 core 130 movable terminal 131 first movable contact 131A convex portion 132 second movable contact 141 first fixed terminal 142 first fixed Contact 142A Convex portion 142B Concave portion 143 Second fixed terminal 144 Second fixed contact 150 Spring

Claims (2)

a first terminal having a first contact;
a second terminal having a second contact;
A contact structure in which the first contact and the second contact are brought into contact by operating at least one of the first terminal and the second terminal,
A contact structure, wherein a contact portion between the first contact and the second contact is provided at a position such that the entire current path is short with respect to a cross section of the contact perpendicular to the current path. an exciting coil;
a core driven by energization of the exciting coil;
a fixed terminal having a fixed contact;
a movable terminal that operates together with the core and has a movable contact that contacts the fixed contact during the operation;
with
An electromagnetic relay, wherein the contact portions of the movable contact and the fixed contact are provided at positions such that the entire current path is short with respect to a cross section of the contact perpendicular to the current path.

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