JP2010010057A - Electromagnetic relay - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a space-saving electromagnetic relay which is excellent in response characteristic. <P>SOLUTION: The electromagnetic relay makes both ends of a movable contactor 63 supported on one end of a drive shaft 61 reciprocated in the axial direction on the basis of the excitation and demagnetization of an electromagnet block 30 touch with and separate from a pair of arranged fixed contact terminals 52, 53. Especially, the electromagnetic relay is provided with a cross-sectioned approximately V-shaped leaf spring 66 inserted into the drive shaft 61 and a coil spring 65 inserted into the drive shaft 61 so as to locate between the movable contactor 63 and the leaf spring 66 and urging the movable contactor 63 to a fixed contact terminals 52, 53 side. Furthermore, when the movable contactor 63 compresses the coil spring 65 by abutting on the fixed contact terminals 52, 53, a lower surface of the movable contactor 63 is pushed to the fixed contact terminal 52, 53 sides at both ends of the leaf spring 66. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to an electromagnetic relay, and more particularly to an electromagnetic relay for a power load.

  Conventionally, as a power load electromagnetic relay, a pair of fixed contacts in which both ends of a movable contact supported by one end of a drive shaft that reciprocates in the axial direction based on excitation and demagnetization of an electromagnetic block are arranged in parallel. There is an electromagnetic switching device that contacts and separates each other (see Patent Document 1).

In particular, in the electromagnetic switching device described above, in order to adjust the spring force to the attractive force curve, for example, as shown in FIG. 26 of Patent Document 1, the leaf spring portion 330c and the coil spring 29 are inserted into the drive shaft 5 and arranged in series. The operation noise is reduced and the contact pressure is increased.
JP 2006-19148 A

  However, in the electromagnetic relay described above, since the leaf spring and the coil spring are arranged in series on the drive shaft, the spring force is not easily transmitted to the movable contact, the response characteristic is low, and a large installation space is required. There is a problem.

  In view of the above problems, an object of the present invention is to provide a space-saving electromagnetic relay that is excellent in response characteristics.

  An electromagnetic relay according to the present invention is provided with both ends of a movable contact supported by one end of a drive shaft that reciprocates in the axial direction based on excitation and demagnetization of an electromagnetic block, in order to solve the above-described problem. An electromagnetic relay that contacts and separates each of the pair of fixed contacts, the leaf spring having a substantially V-shaped cross section inserted through the drive shaft, and the movable contact and the leaf spring being positioned between the leaf spring and the movable spring. A coil spring that is inserted through a drive shaft and biases the movable contact toward the fixed contact. When the movable contact contacts the fixed contact and compresses the coil spring, both ends of the leaf spring are compressed. In this configuration, the lower surface of the movable contact is pressed to the fixed contact side by the portion.

  According to the present invention, since the spring force can be adjusted in multiple stages, the spring characteristics can be easily matched to the attractive force curve of the electromagnet block, so that the design is facilitated and the degree of freedom in design is increased.

  Further, since the coil spring is disposed in the substantially V-shaped leaf spring, space is saved and a small electromagnetic relay can be obtained.

  Furthermore, since the spring load can be easily adjusted by adjusting the height of the leaf spring, an electromagnetic relay with little variation in operating characteristics can be obtained.

  And since the sensitivity of the coil spring in a spring load falls, the malfunction by the variation in the spring force of a coil spring can be eliminated, and there exists an effect that manufacture of a coil spring becomes easy.

As an embodiment of the present invention, a pair of position restricting claws that respectively engage with both side edges of the movable contact may be formed at both ends of the leaf spring.
According to this embodiment, the leaf spring position restricting pawls are engaged with both side edges of the movable contact and accurately press the movable contact, so that an electromagnetic relay with small variation in operating characteristics can be obtained. There is an effect that it is.

An electromagnetic relay for power load, which is an embodiment to which a contact device according to the present invention is applied, will be described with reference to the accompanying drawings of FIGS.
The power load electromagnetic relay according to the first embodiment, as shown in FIGS. 1 to 13, roughly accommodates the drive mechanism unit 20 and the contact mechanism unit 50 integrated vertically in the case 10, The case 10 is covered and covered with a cover 70.

  As shown in FIG. 4, the case 10 has a box shape having a bottom surface that can accommodate a drive mechanism unit 20 to be described later, and a fitting recess 11 (for positioning the drive mechanism unit 20 at the center of the bottom surface). 2 and 3) are provided. The case 10 has a mounting hole 13 and a reinforcing rib 14 projectingly provided on a pedestal part 12 projecting laterally from the lower edge of the outer peripheral corner. However, one of the pedestal portions 12 is not provided with an attachment hole and serves as a mark at the time of attachment. Further, the case 10 is provided with an engagement hole 15 for preventing a cover 70 described later from coming off at the opening edge of the opposite side wall.

  As shown in FIGS. 5 to 7, the drive mechanism unit 20 includes a spool between a first yoke 21 having a substantially U-shaped cross section and a second yoke 22 spanning both ends of the first yoke 21. An electromagnet block 30 in which a coil 32 is wound around 31 is fixed.

  As shown in FIG. 5, the first yoke 21 is provided with an insertion hole 21a for inserting a bottomed cylindrical body 34, which will be described later, in the center of the bottom surface, and the second yoke 22 is fitted to both ends thereof. A notch portion 21b for mating is formed.

  As shown in FIG. 7, the second yoke 22 has a planar shape in which both end portions thereof are respectively engaged with the cutout portions 21b of the first yoke 21 and can be bridged. A hole 22a is provided. Further, the second yoke 22 is provided with counterbore holes 22b provided at the corners of the upper surface thereof, and a gas-filled pipe 23 is airtightly joined to the counterbore holes 22b by brazing.

  As shown in FIGS. 5 and 7, the electromagnet block 30 is formed by winding a coil 32 around a spool 31 having flange portions 31a and 31b at both ends. The relay block 33 provided on the flange portion 31a, The lead wire of the coil 32 is wound around 33 and soldered. Further, lead wires 33a are connected to the relay terminals 33 and 33, respectively. Further, as shown in FIGS. 5 and 6B, a bottomed cylindrical body 34 is inserted into a center hole 31c that penetrates the flange portions 31a and 31b of the spool 31. The upper opening of the bottomed cylindrical body 34 is hermetically joined to the lower surface of the second yoke 22 by laser welding. The bottomed cylindrical body 34 is fitted with an annular auxiliary yoke 35 at the lower end protruding from the insertion hole 21 a of the first yoke 21, and is prevented from coming off by an O-ring 36. The O-ring 36 keeps the annular auxiliary yoke 35 from coming off and performs a sound absorbing and vibration absorbing function.

  According to the present embodiment, the facing area between the outer peripheral surface of the movable iron core 42, which will be described later, and the first yoke 21 and the annular auxiliary yoke 35 is increased, and the magnetic resistance is reduced, so that magnetic efficiency is improved and consumption is increased. There is an advantage that electric power can be reduced.

  As shown in FIG. 6B, a fixed iron core 40, a return coil spring 41, and a movable iron core 42 are sequentially stored in the bottomed cylindrical body 34. The upper end of the fixed iron core 40 is caulked and fixed to the caulking hole 22 a of the second yoke 22. For this reason, the movable iron core 42 is urged downward by the spring force of the return coil spring 41, and a rubber shock-absorbing disc 48 is mounted in a recess provided on the bottom surface thereof. Further, as shown in FIG. 7, the bottomed cylindrical body 34 houses an adhesion preventing metal sheet 49 between its inner bottom surface and the rubber shock absorbing disk 48.

  As shown in FIG. 6B, the movable iron core 42 has a shaft hole having an inner diameter into which a drive shaft 61 to be described later can be inserted, and a connecting pipe 43 made of a non-magnetic material. A ring-shaped magnet 45 and a lower movable iron core 46 are inserted and integrated. A desired magnetic circuit can be formed by shielding the magnetic force of the ring-shaped magnet 45 with the connecting pipe 43.

  As shown in FIG. 9, the contact mechanism unit 50 has a shield member 55 and a movable contact block 60 disposed in a sealed space formed by connecting and integrating a ceramic sealing container 51 on the upper surface of the second yoke 22. It is a thing.

  The sealing container 51 has a pair of substantially T-shaped fixed contact terminals 52 and 53 brazed to the ceiling surface, and a connecting annular skirt portion 54 brazed to the lower opening edge. . Screw holes 52a and 53a are provided on the upper surfaces of the fixed contact terminals 52 and 53, respectively. Then, the annular skirt portion 54 is positioned on the upper surface of the second yoke 22 and integrated by welding with a laser to form the sealed space.

  The shield member 55 is a caulking protrusion that is formed by fitting a metal shielding ring 57 into a shallow box-shaped resin molded product 56 having a through-hole 56 a in the center and projecting from the bottom surface of the box-shaped resin molded product 56. 56b is crimped and integrated. The metal shield ring 57 attracts an arc generated when the contact is opened and closed, and prevents the brazed portion of the sealing container 51 from melting.

  As shown in FIG. 10, the movable contact block 60 includes a plate-shaped first electromagnetic iron piece 62, a movable contact 63, a second electromagnetic iron piece 64 having a substantially U-shaped cross section, a drive shaft 61 having a substantially T-shaped cross section, A coil spring 65 for contact pressure, a leaf spring 66 for contact pressure having a substantially V-shaped cross section, and a washer 67 are sequentially inserted, and an E-ring 68 is engaged and assembled with an annular groove 61a formed on the outer peripheral surface of the drive shaft 61. . In particular, the first electromagnetic iron piece 62, the movable contact 63 and the second electromagnetic iron piece 64 are biased upward via the contact pressure coil spring 64. As a result, a minute gap is formed between the lower surface of the movable contact 63 and both ends of the contact pressure leaf spring 66, and a time lag is generated during operation.

  Further, the leaf spring 66 is formed with a pair of position restricting claws 66 a and 66 a that are respectively latched on both side edges of the movable contact 63 at both ends thereof. For this reason, since the position restricting locking claws 66a of the leaf spring 66 are locked to both side edges of the movable contact 63 and pressed accurately, there is an advantage that an electromagnetic relay with small variation in operating characteristics can be obtained.

  A repulsive force is generated between the fixed contact terminals 52 and 53 and the movable contact 63 due to a large current that flows when both ends of the movable contact 63 come into contact with the fixed contact terminals 52 and 53. However, the first and second electromagnetic iron pieces 62 and 64 of the movable contact block 60 generate a magnetic force that attracts each other based on the large current described above, so that the movable contact 63 opens from the fixed contact terminals 52 and 53. Regulates the action to be separated and prevents contact welding due to arcing.

  As shown in FIG. 11B, the first and second electromagnetic iron pieces 62 and 64 of the movable contact block 60 according to the first embodiment are arranged at both ends of the first electromagnetic iron piece 62 on the upper surfaces of both end portions of the second electromagnetic iron piece 64. It has a structure in which the parts abut. According to this embodiment, when a large current flows through the movable contact 63 at the initial stage when the movable contact 63 contacts the fixed contact terminals 52 and 53, the first electromagnetic iron piece 62 and the second electromagnetic iron piece 64 are The movable contacts 63 are pressed against the fixed contact terminals 52 and 53 by sucking each other. Therefore, there is an advantage that the movable contact 63 is attracted to the fixed contact terminals 52 and 53 without repelling the fixed contact terminals 52 and 53, no arc is generated, and no contact welding occurs.

In addition, the 1st, 2nd electromagnetic iron pieces 62 and 64 are not restricted to the above-mentioned embodiment, The embodiment shown in FIG. 14 may be sufficient. For convenience of explanation, the movable contact 63 and the contact pressure leaf spring 66 are omitted as appropriate in FIGS. 11 and 14.
For example, as shown to FIG. 14A, the structure where the both end surfaces of the 1st electromagnetic iron piece 62 adjoin the inner surface which the 2nd electromagnetic iron piece 64 of a substantially U-shaped cross section opposes may be sufficient (2nd Embodiment). . According to the present embodiment, at the initial stage when the movable contact 63 contacts the fixed contact terminals 52 and 53, both end surfaces of the first electromagnetic iron piece 62 are opposed to the inner side surface of the second electromagnetic iron piece 64. However, when the movable contact 63 comes into contact with the fixed contact terminals 52 and 53 with a predetermined pressure and the operation is completed, the both end surfaces of the first electromagnetic iron piece 62 protrude from the both end surfaces of the second electromagnetic iron piece 64. It becomes. For this reason, at the initial stage when the movable contact 63 abuts against the fixed contact terminals 52 and 53, the magnetic resistance is small and a large attractive force can be generated. As a result, the movable contact 63 can be reliably restricted from being separated from the fixed contact terminal 63, and contact welding can be prevented.

  Moreover, as shown in FIG. 14B, the first and second electromagnetic iron pieces 62 and 64 having a substantially L-shaped cross section may be arranged so as to contact each other (third embodiment). According to the present embodiment, since the first and second electromagnetic iron pieces 62 and 64 have the same shape, the parts can be shared and the parts can be easily managed.

  Furthermore, as shown to FIG. 14C, you may arrange | position so that the right-angled both end surfaces of the 1st, 2nd electromagnetic iron pieces 62 and 64 of a cross-sectional substantially U shape may mutually contact | abut (4th Embodiment). Also in this embodiment, parts can be shared as in the second embodiment described above, and parts management becomes easy.

  And as shown to FIG. 14D, you may arrange | position so that the both end surfaces which the 1st, 2nd electromagnetic iron pieces 62 and 64 of a substantially U-shaped cross section may contact | abut mutually (5th Embodiment). According to the present embodiment, parts management is facilitated, and the tip surfaces 62a and 64a to be sucked are inclined surfaces, so that the facing suction area is large and the suction force is large.

  The contact pressure coil spring 65 and the leaf spring 66 are for applying contact pressure to the movable contact 63. In the present embodiment, by combining the coil spring 65 for contact pressure and the leaf spring 66, there is an advantage that the adjustment of the attractive force characteristic becomes easy and the degree of freedom of design is widened.

  As shown in FIG. 12, the cover 70 has a planar shape that can be fitted into the case 10. The cover 70 is fitted with a holding member 90 made of a substantially U-shaped magnetic material on the inner surface thereof.

  As shown in FIG. 4, the cover 70 is provided with terminal holes 72 and 73 on both sides of an insulating deep groove 71 provided in the center of the ceiling surface. In addition, the cover 70 has receiving portions 74 and 75 projecting laterally from both side surfaces on the short side. Furthermore, insertion slits 76 and 77 into which external connection terminals 95 and 96 can be inserted are provided at the bases of the receiving portions 74 and 75, respectively. The external connection terminals 95 and 96 bent by press working are studded with stud bolts 95a and 96a that can be screwed into connection nuts 97 and 98 on one end side.

  The cover 70 is provided with stepped portions 80, 80 protruding laterally on both side surfaces on the long side, and elastic arm portions 81 for preventing a connector 100 (described later) from coming off on one side surface thereof. It is. The step portion 80 located below the elastic arm portion 81 has a guide wall 82 protruding from the outer edge thereof, and a pair of position restricting claw portions 83 and 83 at the upper end portion thereof. Is protruding.

  As shown in FIG. 12, the holding member 90 has positioning protrusions 91 projecting from the inner surface facing each other at a predetermined pitch, and a positioning claw 92 is cut and raised from its lower edge. . Two sets of two magnets 93 are arranged so as to face each other through the positioning protrusions 91 and the claw portions 92. The magnet 93 pulls an arc generated between the movable contact 63 and the fixed contact terminals 52 and 53 with a magnetic force so that the arc can be easily extinguished.

  The connector 100 attached to the cover 70 is connected to a lead wire 33a connected to the relay terminal 33 as shown in FIG. Then, by placing the connector 100 on the step portion 80 of the cover 70 and sliding the connector 100 along the guide wall 82, the elastic arm portion 81 is locked to the elastic tongue piece 101 of the connector 100 and is prevented from coming off. (FIG. 1B). Further, the position of the lead wire 33a is regulated by engaging with the pair of position regulating claws 83, 83.

A method for assembling the sealed contact device according to the present embodiment will be described.
First, the electromagnet part 30 in which the coil 32 is wound around the spool 31 is placed on the first yoke 21 and positioned. On the other hand, the shield member 55 is positioned at the center of the upper surface of the second yoke 22 in which the fixed iron core 40 is fixed in advance, and the drive shaft 61 of the movable contact block 60 is connected to the through hole 56a of the shield member 55 and the fixed iron core 40. Insert into the shaft hole. Further, the inner peripheral edge portion of the sealing container 51 brazed to the fixed contact terminals 52 and 53 and the annular skirt portion 54 is fitted into the shield ring 57 of the shield member 55. The annular skirt portion 54 is integrated with the upper surface of the second yoke 22 by laser welding while pressing the box-shaped resin molded product 56 at the lower end surface of the opening edge of the sealed container 51.

  Next, the drive shaft 61 protruding from the lower surface of the fixed iron core 40 is inserted into the return coil spring 41 and the shaft hole of the movable iron core 42. The movable iron core 42 is pushed in until it comes into contact with the fixed iron core 40 against the spring force of the return coil spring 41. Further, the drive shaft 61 is pushed in until a predetermined contact pressure is obtained, the movable contact 63 is maintained in contact with the fixed contact terminals 52 and 53 at a predetermined contact pressure, and the movable iron core 42 is in contact with the drive shaft 61. The lower end is integrated by welding. Thereafter, a rubber shock-absorbing disc 48 is mounted in a recess provided on the bottom surface of the movable iron core 42. Next, the bottomed cylinder 34 containing the adhesion preventing metal sheet 49 is placed on the movable iron core 42 and the rubber shock-absorbing disc 48, and the opening edge thereof is laser welded to the lower surface of the second yoke 22. Integrate with welding. Then, after the air in the sealed space is evacuated from the gas sealing pipe 23, an inert gas is injected, and the gas sealing pipe 23 is crimped and sealed.

  Further, the bottomed cylindrical body 34 is inserted into the center hole 31 c of the spool 31, and both end portions of the second yoke 22 are fitted and fixed to the cutout portions 21 b of the first yoke 22. Then, after the annular auxiliary yoke 35 is fitted to the lower end portion of the bottomed cylindrical body 34 protruding from the insertion hole 21 a of the first yoke 21, the O-ring 36 prevents the annular auxiliary yoke 35 from coming off.

  Next, the drive mechanism unit 20 and the contact mechanism unit 50 integrated vertically are inserted into the base 10, and the bottom end of the protruding bottomed cylindrical body 34 is fitted into the recess 11 of the base 10 and positioned. The lead wire 33a is pulled out from the notch 16 (FIG. 4). Then, the engagement claw portion 84 of the cover 70 is engaged and fixed in the engagement hole 15 of the base 10. Next, external connection terminals 95 and 96 are inserted into the insertion slits 76 and 77 of the cover 70 from the side, and screw screws 99a and 99b are screwed into the screw holes 52a and 53a of the fixed contact terminals 52 and 53, respectively. The external connection terminals 95 and 96 are fixed.

  Then, as shown in FIG. 1, the lead wire 33a drawn from the base 10 is bent, and the connector 100 is slid along the guide wall portion 82 provided on the step portion 80, whereby the elastic arm portion 81 is connected to the connector. Locks to the 100 elastic claws 101 to prevent it from coming off. Finally, the lead wire 33a is locked to the elastic claws 83, 83 to restrict the position. Thereby, the electromagnetic relay for power loads concerning this embodiment is obtained.

The operation of the contact device according to this embodiment will be described.
As shown in FIG. 2, when no voltage is applied to the coil 32, the movable iron core 42 is opened from the fixed iron core 40 by the spring force of the return coil spring 41 and the magnetic force of the permanent magnet 45 of the movable iron core 42. Separated. For this reason, both ends of the movable contact 63 are separated from the lower ends of the fixed contact terminals 52 and 53.

  When a voltage is applied to the coil 32, the fixed iron core 40 attracts the movable iron core 42, and the movable iron core 42 is fixed against the spring force of the return coil spring 41 as shown in FIG. Move to the 40 side (first stage S1). For this reason, the drive shaft 61 integral with the movable iron core 42 moves in the axial direction, and both end portions of the movable contact 63 abut against the lower end portions of the fixed contact terminals 52 and 53. At this time, a large current flows through the movable contact 63 and a repulsive force is generated between the movable contact 63 and the fixed contact terminals 52 and 53. However, since the magnetic force is generated simultaneously between the first electromagnetic iron piece 62 and the second electromagnetic iron piece 64 and attracts each other, the movement of the movable contact 63 away from the fixed contact terminals 52 and 53 is restricted. Prevents contact welding due to arcing.

  Further, the movable iron core 42 is attracted to the fixed iron core 40 side, and the movable iron core 42 moves against the spring force of the return coil spring 41 and the contact pressure coil spring 65 to increase the contact pressure (second stage). S2). Next, after the movable contact 63 contacts the lower ends of the fixed contact terminals 52 and 53 with a predetermined pressure against the spring force of the return coil spring 41, the contact pressure coil spring 65, and the contact pressure leaf spring 66 (third) Step S3), the movable iron core 61 is attracted to the fixed iron core 40, and the state is maintained.

  Finally, when the application of voltage to the coil 32 is stopped, the magnetic force is lost, and the movable iron core 42 is separated from the fixed iron core 40 by the spring force of the return coil spring 41. Next, after the movable contact 63 is separated from the fixed contact terminals 52 and 53, the movable iron core 42 returns to the original position. At the time of return, the shock-absorbing disc 48 mounted in the recess on the bottom surface of the movable iron core 42 collides with the adhesion-preventing metal sheet 49. The shock-absorbing disc 48 absorbs and reduces the impact force. To do.

  According to the present embodiment, two types of contact pressure coil springs 65 and leaf springs 66 are combined. For this reason, as shown in FIG. 13, the spring load changes in multiple stages and easily follows the attractive force characteristic curve. Therefore, there is an advantage that the design becomes easy and the degree of freedom of design is widened.

In the present embodiment, the case where the auxiliary yoke 35 is a planar circle has been described, but it may be a planar square.
Further, the case where the annular auxiliary yoke 35 is prevented from coming off by the O-ring 36 has been described.

  Although this embodiment demonstrated the case where it applied to the electromagnetic relay for power loads, it is needless to say that it may apply not only to this but to another electric equipment.

1A and 1B are perspective views showing a first embodiment of a power load electromagnetic relay to which a contact device according to the present invention is applied. It is front sectional drawing of the contact apparatus shown in FIG. It is side surface sectional drawing of the contact apparatus shown in FIG. FIG. 2 is an exploded perspective view of the contact device shown in FIG. 1. It is a principal part disassembled perspective view of the contact apparatus shown in FIG. 6A and 6B are a perspective view and a sectional view of the drive mechanism unit shown in FIG. FIG. 5 is an exploded perspective view of the drive mechanism unit and the contact mechanism unit shown in FIG. 4. FIG. 5 is an exploded perspective view of the drive mechanism unit shown in FIG. 4. FIG. 9 is an exploded perspective view of the contact mechanism unit shown in FIG. 8. FIG. 10 is an exploded perspective view of the movable contact block shown in FIG. 9. 11A is a perspective view of a main part of the movable contact block, and FIG. 11B is an enlarged perspective view of a main part of FIG. 11A. It is a disassembled perspective view of the cover shown in FIG. It is a graph which shows the attractive force characteristic of the contact device concerning 1st Embodiment. 14A, 14B, 14C, and 14D are enlarged perspective views of main parts of the movable contact block showing the second, third, fourth, and fifth embodiments.

Explanation of symbols

10: Base 11: Recess 20: Drive mechanism unit 21: First yoke 21a: Insertion hole 22: Second yoke 23: Gas-filled pipe 30: Electromagnet block 31: Spool 31c: Center hole 32: Coil 33: Relay terminal 33a: Lead wire 34: bottomed cylindrical body 35: annular auxiliary yoke 35a: insertion hole 36: O-ring 40: fixed iron core 41: return coil spring 42: movable iron core 43: connecting pipe 44: upper movable iron core 45: Ring-shaped magnet 46: Downward movable iron core 47: Impact buffer disk 50: Contact mechanism unit 51: Sealing container 52, 53: Fixed contact terminal 54: Annular skirt 60: Moving contact block 61: Drive shaft 62: No. 1 electromagnetic iron piece 63: movable contact element 64: second electromagnetic iron piece 65: coil spring for contact pressure 66: leaf spring for contact pressure 66a: locking claw for position regulation 70: Cover 71: Insulating deep groove 76, 77: Insertion slit 80: Step part 81: Elastic arm part 82: Guide wall 83: Position restricting claw part 90: Holding member 93: Magnet 100: Connector 110: Connector receiver

Claims (2)

An electromagnetic relay in which both ends of a movable contact supported by one end of a drive shaft that reciprocates in the axial direction based on excitation and demagnetization of an electromagnet block are respectively connected to and separated from a pair of fixed contacts arranged side by side. ,
A leaf spring having a substantially V-shaped cross section inserted through the drive shaft;
A coil spring that is inserted through the drive shaft so as to be positioned between the movable contact and the leaf spring, and biases the movable contact toward the fixed contact,
An electromagnetic relay, wherein when the movable contact contacts the fixed contact and compresses the coil spring, the lower surface of the movable contact is pressed toward the fixed contact by both ends of the leaf spring.   2. The electromagnetic relay according to claim 1, wherein a pair of position-regulating locking claws that are respectively locked to both side edges of the movable contact are formed at both ends of the leaf spring.

Images