JPH07105816A - Electromagnetic relay - Google Patents

Abstract

PURPOSE:To provide a stable contact pressure, assemble an electromagnetic relay without deforming a hinge part, and retain both flexibility of the hinge part and toughness of a fixed part and a terminal compatible with each other without specific bending process. CONSTITUTION:An electromagnetic relay 40 is composed of a base block 50, an electromagnet block 60, and a card block 80. In the electromagnet block 60, a common terminal 67 having a flat part 67b in the upper end side is previously fixed and a movable contact spring 85 which has a plate spring part 86, a hinge part 87, and a small piece part 88 and is unitedly formed from a flexible and conductive material is fixed in an armature 81 in the card block 80 side in the condition it is overlaid on a fixed plate 90. The small piece part 88 of the card block 80 is fixed in the flat part 67b of the common terminal 67 of the electromagnet block 60 by welding, so that both blocks are united.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a small electromagnetic relay.

[0002]

2. Description of the Related Art An electromagnetic relay rotates an armature by an electromagnetic force generated by energizing a coil of an electromagnet, and a movable contact that rotates together with the armature is brought into contact with or separated from a fixed contact to make the movable contact and the fixed contact. It is configured to electrically connect or disconnect between and.

FIG. 1 shows such a conventional electromagnetic relay.
An electromagnetic relay 1 having a configuration shown in 0 has been proposed. This electromagnetic relay 1 includes a base block 10 and an electromagnet block 2.
0 and the card block 30, the electromagnet block 20 is fixed on the base block 10, and the card block 30 is further fixed on the base block 10 to be integrated.

On a plate-shaped base body 11 made of an insulating material of the base block 10, contact terminals 12 and 13 fixed so as to vertically penetrate through the front and rear sides of the base body are provided on both sides. Fixed contacts 12a and 13a are provided at the upper ends of the respective contact terminals 12 and 13 and are horizontally bent so that the upper surfaces are exposed to the upper surface side of the base body. Further, the base main body 11 has two fixed contacts 12 on the front side.
a and 12a, two fixed contacts 13 on the side and on the rear side
A coil terminal hole 14 for press-fitting the coil terminal of the electromagnet block 20 is provided at each side of a and 13a, and the common terminal of the card block 30 is press-fitted at each position between the fixed contacts 12a and 13a. A common terminal hole 15 is provided for this purpose.

The electromagnetic block 20 includes a coil bobbin 21 made of an insulator, a core 22 fixed to the center of the coil bobbin 21, coils 23 and 24 separately wound around the coil bobbin 21, and both front and rear sides of the coil bobbin 21. The four coil terminals 25 fixed to the
4 and a permanent magnet 26 for biasing the armature to rotate in one direction. A card receiver 21a, which is cut out in a semicircular shape, is formed on both sides of the center of the coil bobbin 21.

This electromagnetic block 20 includes coil terminals 2
5 is fixed onto the base block 10 with the coil terminal hole 14 of the base block 10 fitted from above.

The card block 30 is made of synthetic resin so as to cover the outer periphery of the armature 31 formed in the shape of a Japanese letter frame, and the middle portion of the vertical frame portions 31a and 31b on both sides of the armature 31, 32, and two movable contact springs 3 formed of a conductive material having flexibility to a predetermined length.
5 and 35, and two common terminals 37 and 37 respectively fixed to each movable contact spring 35 by welding.

The armature 31 is formed such that the length from the middle frame portion 31c to the front frame portion 31d is slightly shorter than the length from the rear frame portion 31e. Further, a U-shaped leg portion 32a and two welding shafts 32b are provided in a protruding manner on the lower surface side of each card 32, and each movable contact spring 35 has two welding shafts 3a.
Insertion holes 36, 36 for inserting 2b are provided.

At the upper end of the terminal portion 37a of each common terminal 37, as shown in FIG. 11, a hinge portion 37b which is freely deformable in the twisting direction is horizontally extended, and a movable contact spring is provided at the tip of the hinge portion 37b. Fixing portion 37c formed shorter than 35
Has been extended. The movable contact spring 3 is attached to the fixed portion 37c.
5 are provided with two through holes 38 that match the two through holes 36, and each movable contact spring 35 has a fixed portion 37.
The central portion is welded in a state where it overlaps with c and their insertion holes match each other, and is integrated with the common terminal 37. The welding shaft 32b of the card 32 of the armature 31 is inserted into a continuous insertion hole of the movable contact spring 35 and the common terminal 37 which are integrated by welding, and the tip of the welding shaft 32b is melted to form an integrated card block as a whole. 10 are formed.

The common terminal 37 is formed of a plate material in which the hinge portion 37b can be twisted and deformed by a weak electromagnetic force, and the terminal portion 37a and the fixed portion 37c are bent so as to obtain strong rigidity.

In the card block thus integrated, the lower end of the U-shaped leg portion 32a is attached to the electromagnet block 20.
The common terminal 3 of each common terminal 3a.
7 is pressed onto the common terminal hole 15 of the base block 10 and is supported on the base block. At this time, the armature 31 has the coils 23, 24 of the electromagnetic block 20.
The hinge portion 37b of the common terminal 37 at a position surrounding the
Each movable contact spring 3 is supported so as to be rotatable in the twisting direction.
Both ends of 5 are positioned so as to be able to contact the fixed contacts 12a and 13a on the base block 10 within the rotation range of the armature 31.

In the electromagnetic relay thus constructed, when the coils 23 and 24 are not energized, the magnetic path F ₀ of the permanent magnet 26 causes the magnetic path to be short, as shown in FIG. Since the one front frame portion 31d side is attracted to the front end 22a side of the core 22, each movable contact spring 35, 3
The front end side of 5 contacts the front fixed contacts 12a and 12a, respectively.

Then, as shown in FIG. 12 (b), the coils 23, 24 are so arranged that a magnetic force F _{1 in the} opposite direction to the magnetic force F ₀ of the permanent magnet 26 generated in the front part of the core 22 is generated in the entire core.
When the armature 31 is energized, the magnetic force acting on the front side of the armature 31 becomes the difference between the magnetic force of the permanent magnet 26 and the magnetic force generated by the coils 23, 24, while the magnetic force acting on the rear side of the armature is permanent. The magnetic force of the magnet 26 and the coil 23,
Since it is the sum of the magnetic force generated by 24, the armature 3
1 then rotates in the direction in which the frame portion 31e side is attracted to the rear end 22b side of the core 22.

Therefore, the front end sides of the movable contact springs 35, 35 separate from the front fixed contact 12a on the base block 10, and the electrical connection between each common terminal 37 and the fixed contact 12 is cut off. The rear ends of the movable contact springs 35, 35 are fixed contacts 13 on the rear side of the base block 10.
The common terminals 37 and the fixed contacts 13 are electrically connected to each other by contacting a and 13a.

When the armature 31 rotates, the fixed portion 37c, which is more rigid than the movable contact spring 35, forcibly separates the contacts that were in contact with the movable contact spring 35. Phenomenon) is prevented.

[0016]

However, the electromagnetic relay having such a structure has the following problems. (1) Fixed part 37 of movable contact spring 35 and common terminal 37
Since c and c are welded in advance and then fixed to the card, unevenness due to welding marks occurs on the upper surface side of the movable contact spring, and when fixed to the card, the parallelism to the armature varies, and the movable contact spring The contact pressure between the fixed contact and the fixed contact varies widely.

(2) The careless external force applied to the common terminal protruding from the card block or the terminal pressure input when fixing the card block to the base block is directly applied to the hinge portion, and the hinge portion is deformed. .

(3) In order to maintain the flexibility of the hinge portion and to give strong rigidity to the fixing portion and the terminal portion, a bending process is required. Due to variations in the accuracy of the bending process and deformation during processing, However, if the common terminal is made of a plate material that has high rigidity without bending and conversely there is a tendency for the rotation abnormality and contact pressure variation to occur. The magnetic force must also be increased accordingly, resulting in an increase in the size of the coil and an increase in current consumption.

The present invention solves these problems, obtains a stable contact pressure, and assembles without deforming the hinge portion. Further, the flexibility of the hinge portion and the rigidity of the fixing portion are specially bent. It is an object of the present invention to provide an electromagnetic relay that can be made compatible without processing.

[0020]

In order to solve the above problems, an electromagnetic relay according to the present invention includes a base body, a fixed contact fixed to the upper surface of the base body, and an electrical connection to the fixed contact. A base block integrally formed with the contact terminal, a coil bobbin, a core fixed to the center of the coil bobbin, and a coil wound around the outer periphery of the core,
An electromagnet block fixed to the coil bobbin and integrally formed with a common terminal having a flat portion on one end side and projecting the other end side to the outside of the coil bobbin, and an electromagnet block fixed on the base block; Integrally formed of a certain conductive material,
Movable having a hinge part that is freely deformable in a twisting direction, a leaf spring part that extends from one end of the hinge part in a direction orthogonal to the hinge part, and a small piece part that extends to the other end side of the hinge part. The contact spring is formed to be shorter than the leaf spring portion of the movable contact spring, and the leaf spring portion is superposed on one surface of the leaf spring portion at a position intersecting with the hinge portion of the movable contact spring in a length direction. A fixed plate, an armature, and a card that is provided on one surface side of the armature and that crimp-fixes an intermediate portion of the overlapping portion of the movable contact spring and the fixed plate to the one surface side of the armature, A small piece of the movable contact spring is welded and fixed to a flat portion of the common terminal of the electromagnet block, receives the electromagnetic force of the electromagnet block, and rotates in a direction in which the hinge is twisted. End of the plate spring portion is constituted by the said supported position approaching and moving away from the fixed contact card block on the base block I.

[0021]

As described above, in the electromagnetic relay of the present invention, the common terminal having the flat portion on one end side is previously fixed to the electromagnet block side, and the hinge portion, the leaf spring portion, and the leaf spring portion are attached to the armature on the card block side. A movable contact spring integrally formed with a flexible conductive material having a small piece portion is fixed in a state of being superposed on a fixed plate, and the small piece portion of this card block is fixed to the common terminal of the electromagnet block. Both blocks are integrally formed by welding and fixing to the flat portion.

[0022]

DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described below with reference to the drawings. 1 to 6 show the structure of an electromagnetic relay 40 of one embodiment. The electromagnetic relay 40 includes a base block 50, an electromagnet block 60 and a card block 80.
It consists of and.

The base body 51 of the base block 50 is
It is made of synthetic resin in a substantially rectangular shape, and contact points 52, 52 are provided on both sides of the front part of the upper surface, which are formed one step higher than the center part, and on both sides of the rear part, the same height as that of the front contact part 52. Contact blocks 53, 53 are provided. Each contact block 52,
On the side of 53, coil terminal holes 54 penetrating from the upper surface to the lower surface are provided, respectively. Also, the front contact block 5
The common terminal holes 55 are provided between the second contact block 53 and the rear contact block 53.

Four front and rear contact blocks 52, 52, 53, 53
The contact terminals 56, 56 and the contact terminals 57, 57 are fixed to each other by insert molding. The contact terminals 56 and 57 are connected to the contact blocks 52 and 53 from the upper end thereof.
Fixed contact part 5 that is bent horizontally so that it closely contacts the upper surface of the
6a and 57a, and terminal portions 56b and 57b protruding to the lower surface side of the base body 51.

Coil bobbin 61 of electromagnet block 60
As shown in FIG. 2, the core support portion 62 has a substantially rectangular tube shape with both ends and the upper surface side of the central portion open, and the core support portion 62.
Has a coil terminal support portion 63 projecting laterally from the front end and the rear end thereof and a common terminal support portion 64 projecting laterally from the middle portion of the core support portion 62, as viewed from above. It is shaped like a king.

Inside the core supporting portion 62, a vertically extending king-shaped core 65 is fixed so as to expose the upper surfaces of both ends 65a and 65b and the central portion 65c, and each coil terminal supporting portion is fixed. The upper ends of the coil terminals 66 extending downward are fixed to the respective 63.

The side surface 64 of each common terminal support 64
The common terminal 67 is fixed to a. A flat portion 67b, which is wider and flatter than the terminal portion 67a, is provided at the upper end of the terminal portion 67a of each common terminal 67.
Each common terminal 67 is fixed to the coil bobbin 61 in a state where one surface of the flat portion 67b is in close contact with the side surface of the common terminal support portion 64. The core 65 and the coil terminal 6
6 and the common terminal 67 are previously fixed to the coil bobbin 61 by insert molding.

As shown in FIG. 1, coils 68 and 69 are separately wound around the outer periphery of the core supporting portion 62.
The winding of each coil 68, 69 is connected to the coil terminal 66 on the lower surface side of the coil bobbin 61. The coil 6
A permanent magnet 70 is attracted to the central portion 65c of the core 65, the upper surface side of which is exposed between 8 and 69.

The armature 81 of the card block 80 is made of a magnetic material such as iron, and the front and rear ends of the vertical frame portions 81a and 81b on both sides are connected by a front frame portion 81c and a rear frame portion 81d, respectively. The middle portions of the frame portions 81a and 81b are connected to each other by a middle frame portion 81e to form a letter V shape. The length from the middle frame part 81e to the front frame part 81c is formed slightly shorter than the length from the middle frame part 81e to the rear frame part 81d, and the middle frame part 81e has the front frame part 81e.
c, provided at a position slightly higher than the rear frame portion 81d.

Cards 82, 82 molded of synthetic resin are provided at the connecting portion between the vertical frame portion 81a and the middle frame portion 81e of the armature 81 and the connecting portion between the vertical frame portion 81b and the middle frame portion 81e.
Is provided.

The inside of the center of the lower surface of the card 82 is shown in FIG.
As shown in, a leg portion 83 protruding in a U shape is provided,
On both outer sides of the leg portion 83, a cylindrical caulking shaft 84,
84 is projected.

A movable contact spring 85 and a fixed plate 90 are fixed to each other on two caulking shafts 84 protrudingly provided on the lower surface of each card 82 in a state of being superposed on each other.

The movable contact spring 85 is integrally formed of a thin plate having a high flexibility and a high conductivity (for example, a phosphor bronze plate), and has a predetermined length between the leaf spring portion 86 and the leaf spring portion 86. Has a hinge portion 87 extending slenderly from the side to the side thereof, and a wide small piece portion 88 bent downward from the tip of the hinge portion 87.

Both ends of the leaf spring portion 86 are bifurcated, and contact pieces 86a are provided on the lower surface thereof. In addition, the card 8
Two through holes 86b for inserting the two caulking shafts 84, 84 provided in No. 2 are provided at positions symmetrical with respect to the hinge portion 87.

In addition, at the center of the small piece portion 88, a welding piece 88a whose outer peripheral portion except the lower portion is separated from the outer edge of the small piece portion 88.
Is provided.

On the other hand, the fixed plate 90 is a metal plate having a rigidity higher than that of the movable contact spring 85, and the plate spring portion 8 of the movable contact spring 85 is used.
6 has a width substantially the same as that of 6 and a length shorter than that of the movable contact spring 86, and is formed in a substantially rectangular shape.
A depressed portion 90a that is slightly depressed is provided in the width direction. The fixed plate 90 is provided with through holes 90b, which coincide with the two through holes 86b of the movable contact spring 85, at positions symmetrical with respect to the recess 90a.

Movable contact spring 8 for armature 81
5 and the fixing plate 90 are fixed to each other as shown in FIG.
Two caulking shafts 84 projecting from the card 82 are inserted into the two through holes 86b of the leaf spring portion 86, and further, two through holes 90b of the fixing plate 90 are inserted into the caulking shaft 84, so that the movable contact spring 85 and the fixed plate 90 are overlapped with each other, and the caulking shaft 84 protruding from the lower surface of the fixed plate 90,
The tip of 84 is crushed while being melted by an ultrasonic caulking device or the like. By this caulking fixing, the intermediate portion of the movable contact spring 85 is brought into close contact with the lower surface of the card 82 as shown in FIG. 4B, and the movable contact spring 85 and the fixed plate 90 are parallel to the armature 81 with high accuracy. Supported by.

In the card block 80 thus integrated, as shown in FIG. 1, the middle frame portion 81e of the armature 81 is inserted with a gap between the coils 68 and 69 of the electromagnet block 60. Placed from above.
At this time, the lower end of the leg portion 83 of the card block 80 has an upper surface 64 b of the common terminal support portion 64 of the electromagnet block 60.
The dimensions of each portion are predetermined so that the small piece portion 88 of the movable contact spring 85 substantially overlaps the flat portion 67b of the common terminal 67 as shown in FIG. Further, at this time, since the length of the front portion of the armature 81 is shorter than the length of the rear portion thereof, the armature 81 is not
As described above, due to the action of the permanent magnet 70, the front frame portion 81c is attracted to the front end 65a of the core 65.

Here, the rear frame portion 81d of the armature 81
After pushing the upper end of the core 65 toward the rear end 65b of the core 65 and then releasing the pushing, check whether the armature 81 is rotated by the action of the permanent magnet 70 and smoothly returns to the original state. You can

After completion of this check, each movable contact spring 8
5, the welding piece 88a of the small piece portion 88 of 5 is pressed against the flat portion 67b of each common terminal 67 as shown in FIG.
0 and the electromagnet block 60 are integrated. Since the outer peripheral portion of the welding piece 88a is separated from the outer edge of the small piece portion 88 except for a part, reliable welding can be performed in a state where the welding piece 88a is closely adhered to the flat portion of the common terminal without a gap,
Moreover, this pressing force is not directly applied to the hinge portion 87.

In the electromagnet block 60 integrated with the card block 80 in this manner, the coil terminals 66 and the common terminals 67 are press-fitted into the coil terminal holes 54 and the common terminal holes 55 of the base block 50 from above. 7 (a), the leaf spring portion 86 of each movable contact spring 85
Is fixed at a position where the front end of the two contacts the two front fixed contact portions 56a.

At this time, since the electromagnet block 60 and the card block 80 are already integrated, if the power source B is connected between the coil terminals 66 as shown in FIG. The card block 80 can be rotated in the direction in which the fixed contact portion 57a and the fixed contact portion 57a come into contact with each other. By energizing and de-energizing such a coil, the gap between the both ends of the leaf spring portion 86 of the movable contact spring 85 and the fixed contact portions 56a and 57a of the base block 50 and the contact pressure during contact are uniform. The press-fitting depth can be adjusted so that

Also, the force of this press-fitting is due to the electromagnet block 6
Each terminal including the common terminal 67 is firmly fixed to the coil bobbin 61 of the electromagnet block 60, and the rigidity of the terminal itself is sufficiently high, so that the hinge portion 87 of the movable leaf spring 85 is deformed. Therefore, the depth of press fitting can be adjusted without worrying about the deformation of the hinge portion.

In this way, after the blocks are integrated, the outer case (not shown) is attached and the lower surface of the base block 50 is hermetically sealed to complete one electromagnetic relay.

In the electromagnetic relay thus constructed, when the coil terminals are energized, the electromagnetic force generated by the electromagnet block 60 causes the armature 81 to rotate,
The front end of the leaf spring portion 86 of each movable contact spring 85 and the fixed contact portion 56a on the front side are separated from each other, and the rear end of the leaf spring portion 86 and the fixed contact portion 57a on the rear side are brought into contact with each other at an appropriate contact pressure, The common terminal 67 and the contact terminal 57 are electrically connected.
Then, when the energization is released, the armature 81 is rotated in the opposite direction by the action of the permanent magnet 70 to return to the original state (see FIG. 7).

As shown in FIG. 8, the movable contact spring 8
When the leaf spring portion 86 of No. 5 is separated from the fixed contact portion 57a, the leaf spring portion 86 is forcibly pushed up in the direction in which the contacts are separated from each other by the fixing plate 90 having higher rigidity, so that the welding between the contacts (stick Phenomenon is surely prevented.

[0047]

[Other Embodiments] In the above embodiment, the small piece of the movable contact spring is provided so as to bend downward from the end of the hinge portion, and the flat portion of the common terminal is substantially vertical so as to overlap with the small piece. Although it is formed, this is not a limitation of the present invention, and it may be formed so as to overlap each other. For example, as in the movable contact spring 85 ′ shown in FIG. The flat portion 67b of the common terminal 67 'may be provided horizontally while extending horizontally from the end. In this case, welding and fixing between the two may be performed from above.

Further, in the above embodiment, the movable contact spring and the fixed plate are supported on the lower surface side of the armature, but the present invention is similarly applied to the electromagnetic relay supporting the movable contact spring on the upper surface side of the armature. it can.

Further, although the present invention is applied to the two-circuit, two-contact type electromagnetic relay in the above-mentioned embodiment, this does not limit the present invention, and the one-contact type or three-circuit or more electromagnetic relay is used. Can be similarly applied to.

Further, in the above embodiment, the coil terminal and the common terminal of the electromagnet block are press-fitted into the base block to integrate the two. However, not only the fixing method by such terminal press-fitting, but also other The present invention can be similarly applied to an electromagnetic relay in which an electromagnet block and a base block are integrated by a fixing method.

[0051]

As described above, the electromagnetic relay of the present invention is provided with the leaf spring portion, the hinge portion and the small piece portion on the movable contact spring side, and the fixed plate is superposed on the leaf spring portion of the movable contact spring. In this state, the card block is fixed to the armature and the flat part is provided on the common terminal that is fixed in advance on the electromagnet block side.The small piece on the card block side is welded to the flat part of the common terminal on the electromagnet block side. Since the card block is supported by the electromagnet block, the following effects can be obtained.

(1) Since the welding stop between the movable contact spring and the fixed plate is not required, unevenness due to welding marks on the upper surface of the leaf spring does not occur, and the parallelism of the movable contact spring with respect to the armature is eliminated. Is eliminated, and the contact pressure between the movable contact spring and the fixed contact is also eliminated.

(2) Since the common terminal is previously fixed to the electromagnet block, the hinge portion of the movable contact spring is not deformed by the external force applied to this terminal.

(3) Since the fixing plate and the common terminal are independent of each other with respect to the hinge, the fixing plate and the common terminal have high rigidity and the hinge portion without special bending work or strengthening of magnetic force. It is possible to achieve both high flexibility and high flexibility.

[Brief description of drawings]

FIG. 1 is an exploded perspective view showing the configuration of an embodiment.

FIG. 2 is a perspective view showing a configuration of a main part of one embodiment.

FIG. 3 is a perspective view of a main part of one embodiment as seen from a lower surface side.

FIG. 4 is a schematic side view for explaining a process of assembling the card block according to the embodiment.

FIG. 5 is an enlarged side view of the main part of the embodiment.

6 is a sectional view taken along line AA of FIG.

FIG. 7 is a schematic side view showing a relationship between a movable contact spring and a fixed contact portion when a terminal is press-fitted.

FIG. 8 is a schematic side view for explaining the action of the fixing plate.

FIG. 9 is a perspective view showing a main part of another embodiment of the present invention.

FIG. 10 is an exploded perspective view of a conventional electromagnetic relay.

11 is a perspective view showing a configuration of a main part of FIG.

FIG. 12 is a schematic side view for explaining the operation of the electromagnetic relay.

[Explanation of symbols]

 40 electromagnetic relay 50 base block 51 base body 56, 57 contact terminals 56a, 57a fixed contact part 60 electromagnet block 61 coil bobbin 65 core 66 coil terminal 67 common terminal 67b flat part 68, 69 coil 70 permanent magnet 80 card block 81 armature 82 card 83 Legs 84 Caulking Shaft 85 Movable Contact Spring 86 Leaf Spring 87 Hinge 88 Small Piece 88a Welding 90 Fixing Plate

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[Procedure amendment]

[Submission date] November 5, 1993

[Procedure Amendment 1]

[Document name to be corrected] Drawing

[Correction target item name] All drawings

[Correction method] Change

[Correction content]

[Figure 1]

[Fig. 2]

[Figure 3]

[Figure 4]

[Figure 5]

[Figure 6]

[Figure 8]

[Figure 9]

[Figure 7]

[Figure 10]

FIG. 11

[Fig. 12]

Claims (1)

[Claims] 1. A base block integrally formed with a base body, a fixed contact fixed to an upper surface of the base body, and a contact terminal electrically connected to the fixed contact, a coil bobbin, and the coil bobbin. A core fixed to the center of the coil, a coil wound around the outer periphery of the core, and a common terminal fixed to the coil bobbin and having a flat portion on one end side and projecting the other end side to the outside of the coil bobbin. And an electromagnet block fixed on the base block, and a hinge part that is integrally formed of a flexible conductive material and is deformable in a twisting direction, from one end of the hinge part to the hinge part. A movable contact spring having a leaf spring portion extending in a direction orthogonal to each other and a small piece portion extended to the other end side of the hinge portion, and the movable contact spring formed to be shorter than the leaf spring portion of the movable contact spring. Spring A fixed plate that is superposed on one surface of the leaf spring portion at a position intersecting with the hinge portion so as to match the length direction of the leaf spring portion, an armature, and the movable contact spring provided on one surface side of the armature. An intermediate portion of the overlapping portion with the fixed plate is integrally formed with a card for crimping and fixing to one surface side of the armature, and a small piece portion of the movable contact spring is welded and fixed to a flat portion of the common terminal of the electromagnet block. Receiving the electromagnetic force of the electromagnet block to rotate the hinge part in a twisting direction, and by the rotation, the end of the leaf spring part is supported at a position contacting and separating from the fixed contact on the base block. Relay with a card block.