KR101671814B1 - Cantilever type relay device with movable core having plunger - Google Patents

Abstract

A movable contact spring having at least one movable contact; A stationary contact assembly having at least one stationary contact disposed at a position opposite to the movable contacts; And a driving force transmitting means for connecting the core and the movable contact spring to transmit the oscillation of the core due to the turn-on or turn-off of the coil current to the movable contact spring, Wherein the core includes a head portion, a body portion for supporting the head portion, and a neck portion positioned between the head portion and the body portion, wherein the driving force transmitting means includes a space for accommodating the head portion of the core Wherein a first face of the box is connected to the movable contact spring and a second face opposite to the first face is provided with a guide slit for receiving and guiding the neck of the core, And a core-moving type cantilever-type relay device is provided.

Description

[0001] The present invention relates to a cantilever type relay device having a plunger,

The present invention relates to a core-moving type cantilever-type relay device, and more particularly, to a core-moving type cantilever type relay device having a structure in which fixed contacts and movable contacts arranged in a cantilever manner are opened and closed by driving a movable core.

A relay device is a switching mechanism that operates when an input signal reaches a certain value to open and close another electric circuit. The relay device is classified into a contact type relay, a thermal relay, a pressure type relay, and an optical relay depending on the operation mode.

In addition, contact type relays which are widely used in various industrial fields such as automobiles, industrial automation control devices and the like can be roughly divided into ladder type relays and cantilever type relays.

The ladder-type relay is a relay in which at least one pair of movable contacts move linearly with respect to the fixed contact to open and close the contact, and the contact is driven by a large magnetic force, so that it is widely used for load control of a large current. A technique related to a ladder type relay is disclosed in, for example, Korean Patent Laid-Open Publication No. 2010-0125806.

Korean Patent Laid-Open Publication No. 2010-0125806 includes a fixed contact, a movable contact which is disposed so as to be contactable with and detachable from the fixed contact, and an electric actuator for driving the movable contact. The electric actuator generates magnetic force A movable core disposed in proximity to and spaced from the fixed core; a movable core disposed around the movable core and having a lower hardness than the movable core to mitigate impact when the movable core moves; And a cushioning portion for causing the cushioning portion to contact the cushioning portion.

However, since the ladder-type relay is required to be energized by contacting all of the movable contacts at the same time with the fixed contacts, the contact failure rate is high, and at least three contact pieces are arranged in the relay, which makes the apparatus complicated and difficult to miniaturize.

The cantilever-type relay is a relay in which one movable contact is pivoted to an arc shape with respect to the stationary contact to open and close the contact, which is advantageous in that it can be manufactured in a simpler form than a ladder type relay. A technique related to the cantilever-type relay is disclosed, for example, in Japanese Utility Model Publication No. Hei 5-27942.

Japanese Unexamined Utility Model Publication No. 5-27942 discloses a cantilever type electromagnetic relay having an elastic body between a movable contact spring and an armature to reduce an operation sound caused by vibration of an armature.

However, since the conventional cantilever-type relay as described above is structured such that the core is fixed in the bobbin in which the coil is wound and the armature is moved relative to the core to open and close the contact, it is known to be unsuitable for controlling a load of a large current requiring a large magnetic force have.

On the other hand, it is important that the relay having the movable core reliably transmits the movement of the movable core toward the movable contact. To this end, it is preferable to provide driving force transmitting means between the movable core and the movable contact. A related art is disclosed in, for example, Korean Patent Laid-Open Publication No. 2014-0001388.

Korean Patent Laid-Open Publication No. 2014-0001388 discloses a relay including a ladder-type fixed contact and a movable contact, and a support provided between the movable contact and the drive shaft for bringing the fixed contact into contact with the movable contact .

However, when the ladder-type relay has a high contact failure ratio in structure and it is difficult to miniaturize the ladder-type relay, it is not possible to achieve the object simply by the structure in which the drive shaft passes through the support portion. New technological means should be provided to prevent occurrence.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a core moving type cantilever type relay device which is designed in consideration of the above problems and has a structure capable of enhancing the driving efficiency of the movable contact and improving the mobility of the core.

It is another object of the present invention to provide a core moving type cantilever type relay device having a structure capable of preventing a contact failure between a fixed contact and a movable contact.

According to an aspect of the present invention, there is provided a movable contact spring comprising: a movable contact spring having at least one movable contact; A stationary contact assembly having at least one stationary contact disposed at a position opposite to the movable contacts; And a driving force transmitting means for connecting the core and the movable contact spring to transmit the oscillation of the core due to the turn-on or turn-off of the coil current to the movable contact spring, Wherein the core includes a head portion, a body portion for supporting the head portion, and a neck portion positioned between the head portion and the body portion, wherein the driving force transmitting means includes a space for accommodating the head portion of the core Wherein a first face of the box is connected to the movable contact spring and a second face opposite to the first face is provided with a guide slit for receiving and guiding the neck of the core, The present invention provides a core moving type cantilever type relay device.

The guide slit has a first slit having a margin width for giving a predetermined gap to the neck portion to elastically buffer the left and right swinging of the core in a state of receiving the neck portion of the core and the first slit communicates with the first slit And a second slit that is narrow and elongated at a width substantially equal to the diameter of the neck portion.

And a protrusion for forming a predetermined gap between the first surface and the head portion of the core is disposed inside the first surface.

The protrusions are preferably hemispherical.

The projection may be disposed at the center of the first surface so that the projection is positioned at the center of the head portion of the core.

The box is preferably an open box having at least one side open.

The box may include a first open side and a second open side in which two sides connecting the first side and the second side are open.

The box may be formed with a separation gap so as to reach an edge tangent to the first open side surface of the first surface and an edge tangent to the second open side surface.

The first surface and the movable contact spring may be connected through riveting.

And a tool insertion hole for inserting the tool for riveting is formed on the second surface.

And an opening portion for receiving the head portion of the core is formed on at least one of the remaining closed side faces connecting the first face and the second face.

According to the present invention, efficient operation of the core and the movable contact spring can be achieved by the arrangement structure in which the fixed terminal terminal and the movable terminal terminal are positioned so as to form the predetermined contact gap, and the actuator is positioned therebetween.

In addition, when the core is lowered, the movable contact spring descending with the movement of the core is over traveled by the plunger so that overlapping occurs between the movable contact and the fixed contact, thereby preventing the occurrence of contact failure in abrasion of the contact.

BRIEF DESCRIPTION OF THE DRAWINGS The accompanying drawings, which are incorporated in and constitute a part of the specification, illustrate preferred embodiments of the invention and, together with the description of the invention given below, serve to further the understanding of the technical idea of the invention. And should not be construed as limiting.
1 is a perspective view showing a main configuration of a core-moving type cantilever type relay device according to a preferred embodiment of the present invention,
Fig. 2 is an exploded perspective view of Fig. 1,
FIG. 3 is a partial cross-sectional view of FIG. 1,
FIG. 4 is a partial cross-sectional view showing a state in which the fixed contact and the movable contact are in contact with each other by driving the actuator in FIG. 3;
FIG. 5 is a partial cross-sectional view showing a state where the fixed contact and the movable contact are separated from each other in FIG. 4;
FIG. 6 is a partial cross-sectional view showing a configuration in which a core guide portion is added in FIG. 5,
FIG. 7 is a bottom view showing a configuration of a plunger provided in a core moving type cantilever type relay device according to a preferred embodiment of the present invention;
8 is a side view of Fig. 7,
FIG. 9 is a side view showing a coupling relationship between the plunger and the core,
10 is a side view showing the operation of the plunger and the core.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Prior to this, terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary terms, and the inventor should appropriately interpret the concepts of the terms appropriately It should be interpreted in accordance with the meaning and concept consistent with the technical idea of the present invention based on the principle that it can be defined. Therefore, the embodiments described in this specification and the configurations shown in the drawings are merely the most preferred embodiments of the present invention and do not represent all the technical ideas of the present invention. Therefore, It is to be understood that equivalents and modifications are possible.

FIG. 1 is a perspective view showing a main structure of a core-moving type cantilever type relay device according to a preferred embodiment of the present invention, and FIG. 2 is an exploded perspective view of FIG.

1 and 2, a core moving type cantilever type relay device according to a preferred embodiment of the present invention includes a movable contact spring 100 having a movable contact 103, An actuator 110 and a stationary terminal assembly 120 having a stationary terminal terminal 120 and a movable terminal terminal 130 as well as a stationary contact 121 facing the movable contact 103. In the present invention, the fixed terminal terminal 120 is disposed at a relatively low position relative to the movable terminal terminal 130, and the actuator 110 is disposed between the fixed terminal terminal 120 and the movable terminal terminal 130 .

The movable contact spring 100, the fixed terminal assembly and the actuator 110 are supported and fixed by a predetermined base plate 140 and are accommodated in a housing having a predetermined shape to be coupled with the base plate 140 do. For the sake of understanding, the illustration of the housing in Fig. 1 has been omitted. Considering the arrangement structure of the movable contact spring 100, the fixed terminal assembly, the actuator 110, and the like, the housing is preferably formed in a T shape as a whole in view of miniaturization of the product.

The movable contact spring (100) has at least one movable contact (103). More specifically, the movable contact spring 100 has at least one movable contact 103 disposed at one end thereof and the other end substantially supported by the base plate 140, And the elastic contact plate 121 contacts and contacts the fixed contact 121 and the movable contact 103 in response to a swing motion generated around the other end of the movable contact.

3, the movable contact spring 100 is a conductive plate extending from the one end to the other end, and includes a fixed portion 101a, 102a and at least two fixed portions 101a, 102a which are separated from the fixed portions 101a, And more than two movable spring portions 101b and 102b. A movable contact 103 is disposed at one end of each of the two or more movable spring portions 101b and 102b. The movable contact 103 is fixed to the movable spring portions 101b and 102b by fixing means such as a rivet 104, for example.

The movable contact spring 100 is constructed by overlapping the first conductor plate 101 and the second conductor plate 102. The first conductor plate 101 and the second conductor plate 102 are formed with a first stretchable portion 101c and a second stretchable portion 102c curved in directions opposite to each other. The first stretchable and contractible portion 101c and the second stretchable and contractible portion 102c are spaced apart from each other at a predetermined interval between the one end and the other end. Here, it is preferable that the core 113 is located at the center between the first stretchable portion 101c and the second stretchable portion 102c. As described above, the bending force and the bending force acting on the movable contact spring 100 are remarkably reduced by the first stretchable portion 101c and the second stretchable and contractible portion 102c spaced apart from each other around the core 113 . Specifically, this structure has the effect of reducing the bending force and the bending force by four times as compared with the cantilevers without the first stretchable portion 101c and the second stretchable portion 102c.

The first conductor plate 101 and the second conductor plate 102 are each a thin plate extending from one end to the other end and have fixing portions 101a and 102a fixed to a fixed connection portion 191 to be described later, 101a, 102a, and at least two movable spring portions 101b, 102b which are separated from the movable spring portions 101a, 102b. The first stretchable portion 101c and the second stretchable portion 102c are formed separately in the at least two movable spring portions 101b, 102b.

The first stretchable and contractible portion 101c and the second stretchable and contractible portion 102c each preferably have a circular arch shape.

The movable contact spring 100 is operated to swing around the fixed portions 101a and 102a by the driving force of the actuator 110 and the restoring forces of the movable spring portions 101b and 102b and the core restoring means. That is, the movable contact spring 100 swings as shown in FIG. 4 by driving the actuator 110 to contact the fixed contact 121 and the movable contact 103, and the driving force of the actuator 110 is released The movable contact 103 is swung back to its original position by the restoring force of the movable spring portions 101b and 102b and the core restoring means to thereby widen the fixed contact 121 and the movable contact 103. [

The actuator 110 provides a driving force to the movable contact spring 100 so that the fixed contact 121 and the movable contact 103 can be brought into contact with each other so that the movable contact 103 and the fixed contact 121 can be energized . 5, the actuator 110 includes a bobbin 111 having a hollow therein, a coil 112 wound around the bobbin 111, and a core (not shown) swung by a current flowing in the coil 112 113 and a coil case 114 for receiving the bobbin 111. [

The core 113 is an operating rod that moves upward and downward in the bobbin 111 by electromagnetic interaction with the coil 112. The core 113 includes a head portion 113c and a body portion 113a for supporting the head portion 113c And a neck portion 113b positioned between the head portion 113c and the body portion 113a.

As shown in FIG. 6, it is preferable that a core guide portion 116 made of a non-magnetic material is coated on the hollow inner surface of the bobbin 111. According to such a configuration, it is possible to reduce the phenomenon that the movement of the core 113 is disturbed by the magnetized coil case 114 and the coil cap 115.

When the current flowing through the coil 112 of the actuator 110 is turned off, the core 113 is provided with the restoring force, which is restored to its original position by the core restoring means together with the movable contact spring 100. The core restoring means provides the effect of reducing the phenomenon that the movement of the core 113 is disturbed by the magnetized coil case 114 and the coil cap 115 in the same manner as the core guide portion 116. [

The core recovery means includes a coil spring 150 wound around the head 113c of the core 113 and a leaf spring 151 disposed at the lower end of the tail of the core 113, By increasing the speed, it is possible to more effectively prevent the arc-induced damage to the contacts.

The coil spring 150 is wound between the head portion 113c of the core 113 and the body portion 113a to provide an elastic restoring force.

The plate spring 151 includes a thin plate-shaped body portion and a contact spring portion extending from the body portion at a central portion of the body portion.

The core recovery means includes a core pin 152 for transmitting the spring restoring force of the leaf spring 151 through the body portion 113a of the core 113. [ The core pin 152 is preferably formed in a round column shape.

The diameter of the receiving hole is larger than the diameter of the core pin 152. The diameter of the receiving hole is larger than the diameter of the core pin 152. In the core pin 152, A stopper ring having a diameter larger than that of the receiving hole is coupled to prevent the coil spring 152 from falling into the coil case 114.

The fixed terminal assembly has at least one fixed contact 121 disposed at a position opposite to the movable contact 103 provided in the movable contact spring 100. The fixed terminal assembly includes a fixed terminal terminal 120 and a movable terminal terminal 130.

The stationary terminal terminal 120 has a first surface on which at least one stationary contact 121 is disposed and a second surface that is bent perpendicularly to the first surface and fixed to the base plate 140, "It consists of a body that is shaped like a letter.

The movable terminal terminal 130 has a first surface which is overlapped with the other end of the movable contact spring 100 and a second surface which is bent perpendicularly to the first surface to be fixed to the base plate 140 It is made up of a "a" shaped body. Although not shown in the drawing, a embossing emboss for fixing the other end of the movable contact spring 100 is provided below the first surface.

3, the upper portion of the fixed terminal terminal 120 is disposed at a relatively low position relative to the upper portion of the movable terminal terminal 130 so that a predetermined contact gap can be formed. At this time, it is preferable that the actuator 110 is located at the center between the fixed terminal terminal 120 and the movable terminal terminal 130.

The movable contact spring 100 is prevented from being excessively vibrated due to the moment of inertia when the movable contact 103 is lifted from the fixed contact 121 by the spring restoring force as the driving force of the actuator 110 is turned off A vibration suppressing means for suppressing the vibration of the movable contact spring 100 is provided.

The vibration suppressing means includes an oscillation absorbing plate 160 extending from the one end of the movable spring portions 101b and 102b to a length longer than a contact point of the fixed contact 121 and the movable contact 103, And an upper magnet member 162 disposed at a predetermined upper region of the absorption plate 160 to capture the vibration absorption plate 160 by a magnetic force.

The vibration absorbing plate 160 is preferably a separate metal plate connected to one end of each of the movable spring portions 101b and 102b. The vibration absorbing plate 160 is connected to the movable spring portions 101b and 102b by the movable contact 103 in a contact tightening manner.

It is preferable that the magnetic force of the upper magnet member 162 is smaller than the driving force of the actuator 110 so as not to interfere with the contact between the movable contact 103 and the fixed contact 121.

Side contact magnets 170 and 171 are provided on both sides of the contact point for extinguishing an arc generated when the movable contact 103 and the fixed contact 121 are opened. The side surface magnet members 170 and 171 on both sides are arranged so as to face each other with different polarities and the stationary contact point 121 and the movable contact point 103 are preferably disposed between the side magnet members 170 and 171 respectively. According to this configuration, the arc generated between the movable contact 103 and the fixed contact 121 is canceled by the magnetic force of the magnetic field formed between the side magnet pieces 170 and 171 and biased in the direction of the force according to the Fleming's left-hand rule . When two or more contact points are located between the side magnet members 170 and 171, the directions of the arcs generated at the contact points are equal to each other.

The upper magnet member 162 and the side magnet members 170 and 171 are coupled to each other to form a magnet assembly. The magnet assembly is fixedly coupled to the first surface of the fixed terminal terminal 120.

The upper magnet member 162 is preferably spaced apart from the vibration absorbing plate 160 so as to maintain a predetermined contact gap between the movable contact 103 and the fixed contact 121.

It is preferable that the upper magnet member 162 is disposed in an area not covering the contact point and the upper magnet member 162 and the side magnet members 170 and 171 are both made of permanent magnets. In order to stably maintain such an arrangement structure, it is preferable that the upper magnet member 162 and the side magnet members 170 and 171 are installed together in one magnet frame 161.

A driving force transmitting means for connecting the core 113 and the movable contact spring 100 to transmit the oscillation of the core 113 to the movable contact spring 100 according to the turn- A plunger 180 is provided.

7 and 8, the plunger 180 is a box-shaped tool having therein a space for receiving the head portion 113c of the core 113. The plunger 180 has a first surface 181 And a guide slit 183 for receiving and guiding the neck portion 113b of the core 113 is formed on a second surface 182 opposed to the first surface 181. [ ) Are formed on the substrate.

The guide slit 183 has a margin for giving a predetermined gap to the neck portion 113b in order to elastically buffer the left and right swings of the core 113 in a state of receiving the neck portion 113b of the core 113 And a second slit 183b communicating with the first slit 183a and extending narrower and longer than the diameter of the neck portion 113b.

9, the first surface 181 and the second surface 182 of the plunger 180 maintain the gaps of G1 and G2 relative to the head portion 113c of the core 113, Can be prevented. 10 (a) and 10 (b), when the core 113 moves upward and downward, a distance loss is generated by the gap. This distance loss is minimized, A protrusion 184 is provided at the center of the plunger 180 for immediate reaction of the movable contact spring 100 during exercise.

The protrusion 184 has a hemispherical emboss structure disposed inside the first surface 181 to form a constant gap between the first surface 181 and the head portion 113c of the core 113. [ The protrusion 184 is disposed at the center of the first surface 181 so as to be positioned at the center of the head portion 113c of the core 113. [

The box comprises an open box having at least one side open. The open box includes a first open side 185 and a second open side 185 'with two open sides connecting the first side 181 and the second side 182. The open box is formed with a separation gap 186 so as to reach an edge tangent to the first open side 185 of the first surface 181 and to an edge tangent to the second open side 185 '.

The first surface 181 and the movable contact spring 100 are connected through riveting using a rivet fastening hole 187. [ The second surface 182 is formed with a tool insertion hole 188 for inserting a tool for riveting. An opening 189 for receiving the head portion 113c of the core 113 is formed on one of the remaining closed side faces connecting the first face 181 and the second face 182. [

The stopper 190 blocks the excessive over swing of the movable contact spring 100 when the movable contact 103 is opened from the fixed contact 121 by the restoring force as the driving force of the actuator 110 is turned off .

The stopper 190 is disposed so as to cover the movable contact spring 100 in a state that the stopper 190 extends from the other end to the one end and forms a certain gap with the movable contact spring 100. The stopper 190 has a fixed connection portion 191 connected to the movable contact spring 100 and fixed to the base plate 140 and a fixed gap 191 extending from the fixed connection portion 191, And a claw portion 192 covering the movable contact spring 100 while forming the movable contact spring 100. At this time, it is preferable that the end of the stopper 190 and the movable contact spring 100 are in contact with each other through the damper 200.

The fixed connection portion 191 is integrally formed with the first surface of the movable terminal terminal 130 and is coupled to the other end of the movable contact spring 100. Alternatively, the fixed connection portion 191 may be formed of a separate plate and attached to the first surface of the movable terminal terminal 130.

When the current flowing through the coil 112 of the actuator 110 is turned on, the core 113 is lowered and the movable contact spring 112 is rotated. The fixed contact 121 and the movable contact 103 are brought into contact with each other and energized as the movable contact 100 swings downward.

Here, the fixed terminal terminal 120 is disposed at a relatively low position relative to the movable terminal terminal 130 so as to form a predetermined contact gap, and the actuator 110 is disposed between the fixed terminal terminal 120 and the movable terminal terminal 130, the core 113 and the movable contact spring 100 can be efficiently driven. The core 113 is provided with a core guide portion 116 for guiding the sliding thereof and a core pin 152 for transmitting elastic restoring force to the core 113, It is possible to perform the up-and-down motion smoothly.

The movable contact spring 100 swings about the end fixed to the base plate 140 by the descent of the core 113 and moves between the first stretchable portion 101c and the second stretchable portion The bending force can be reduced by the expansion and contraction action of the elastic members 102a and 102c.

The downward movement of the core 113 is transmitted to the movable contact spring 100 via the plunger 180. [ The plunger 180 is a driving force transmitting means for allowing the movable contact spring 100 to descend together with the core 113 so that the movable contact spring 100 is over traveled to be fixed to the movable contact 103 By causing overlapping between the contact points 121, it is possible to prevent a contact failure from occurring when the contact is worn.

In particular, since the plunger 180 has the structure of the open box, deformation such as bending or sagging does not occur when the core 113 is lowered. The first face 181 and the second face 182 of the plunger 180 can be prevented from interference by maintaining the gaps G1 and G2 with respect to the head portion 113c of the core 113, respectively. In addition, since the protrusion 184 is provided at the center of the plunger 180, the movable contact spring 100 can be instantly reacted when the core 113 moves.

The core 113 is elastically supported by the core restoring means including the coil spring 150 and the leaf spring 151 in a state where the lowering of the core 113 is completed.

On the other hand, when the current flowing through the coil 112 of the actuator 110 is turned off, the core 113 rises due to the elastic restoring force of the core restoring means and the movable contact spring 100 swings upward, The movable contact 121 and the movable contact 103 are widened to release the energized state.

The movable contact spring 100 is swung upward and restored to its original position and the damper 200 provided on the upper surface of the movable contact spring 100 contacts the stopper 190 to absorb the noise and to prevent excessive over swing.

In addition, since the vibration absorbing plate 160 provided at the end portion of the movable contact spring 100 is attached to the upper magnet member 162, the movable contact spring 100 vibrates excessively due to the moment of inertia, And rapid contact opening and closing can be achieved.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not to be limited to the details thereof and that various changes and modifications will be apparent to those skilled in the art. And various modifications and variations are possible within the scope of the appended claims.

100: movable contact spring 101: first conductive plate
102: second conductor plate 101a, 102a:
101b, 102b: movable spring portion 101c: first elastic portion
102c: second stretchable member 103: movable contact
110: Actuator 111: Bobbin
112: coil 113: core
114: coil case 115: coil cap
120: fixed terminal terminal 130: movable terminal terminal
121: fixed contact point 140: base plate
150: coil spring 151: leaf spring
160: vibration absorbing plate 162: upper magnet member
170: side magnet member 180: plunger
184: projection 190: stopper
200: damper

Claims (11)

A movable contact spring having at least one movable contact; A stationary contact assembly having at least one stationary contact disposed at a position opposite to the movable contacts; And a driving force transmitting means for connecting the core and the movable contact spring to transmit the oscillation of the core due to the turn-on or turn-off of the coil current to the movable contact spring, In the apparatus,
Wherein the core includes a head portion, a body portion for supporting the head portion, and a neck portion positioned between the head portion and the body portion,
Wherein the driving force transmitting means is a box-shaped tool having a space for accommodating a head portion of the core therein, the first surface of the box being connected to the movable contact spring, the second surface facing the first surface, Wherein a guide slit is formed in the surface for receiving and guiding the neck of the core,
Wherein a protrusion for forming a predetermined gap between the first surface and the head portion of the core is disposed inside the first surface. The method according to claim 1,
The guide slit has a first slit having a margin width for giving a predetermined gap to the neck portion to elastically buffer the left and right swinging of the core in a state of receiving the neck portion of the core and the first slit communicates with the first slit And a second slit that is narrow and long in the same width as the diameter of the neck portion. delete The method according to claim 1,
Wherein the projections are hemispherical. 5. The method of claim 4,
Wherein the projections are disposed at the center of the first surface so that the projections can be positioned at the center of the head portion of the core. 3. The method according to claim 1 or 2,
Wherein the box is an open box having at least one side open. The method according to claim 6,
Wherein the box includes a first open side and a second open side, the two open sides connecting the first side and the second side being open. 8. The method of claim 7,
Wherein the box has a separating gap formed so as to reach an edge tangent to the first open side of the first surface to an edge tangent to the second open side. 3. The method according to claim 1 or 2,
Wherein the first surface and the movable contact spring are connected through riveting. 10. The method of claim 9,
And a tool insertion hole for inserting a tool for riveting is formed on the second surface. 8. The method of claim 7,
And an opening for accommodating the head portion of the core is formed on at least one of the remaining closed side surfaces connecting the first surface and the second surface.

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