KR890001193B1 - Electromagnetic relay - Google Patents

Abstract

The electromagnetic relay converts the contact point of a switch by a moving block which is moved by the exciting or nonexciting currents of a electronic coil. This does not generate the moving forces of a main apparatus by the moving part, acquires the stable magnetic characteristics, provides the small type electromagnetic relay, provides the high frequency relay which has a better high frequency characteristics, and has the high security.

Description

Electronic relay

1 is an exploded perspective view showing a conventional electromagnetic relay.

FIG. 1 (a) is an enlarged view of FIG.

2 is a partial cross-sectional plan view of the conventional apparatus.

3 is a three-dimensional magnetic equivalent circuit diagram of the conventional apparatus.

4 is a front view of a high frequency relay composed of the conventional electromagnetic relay.

5 is a bottom view of the high frequency relay.

6 is a graph showing the amount of leakage between the poles of the high frequency relay.

7 is an internal plan view showing an electromagnetic relay according to an embodiment of the present invention.

8 is a plan view of the state in which the connection member is removed.

9 is a cross-sectional view taken along the line A-A of FIG.

Fig. 10 is a schematic perspective view showing the main parts of the device of the second embodiment.

11 is a three-dimensional magnetic equivalent circuit diagram.

12 is a front view showing an embodiment in which the electromagnetic relay according to the present invention is applied to a high frequency relay.

FIG. 13 is a bottom view of the high frequency relay shown in FIG.

14 is a graph showing the high frequency characteristics of the high frequency relay to which the electromagnetic relay according to the present invention is applied in comparison with the conventional apparatus.

15 is an exploded perspective view showing another embodiment in the case where the electromagnetic relay according to the present invention is applied to a high frequency relay.

Figure 16 is an enlarged perspective view of the main part of the apparatus of the third embodiment;

17 is a cross-sectional view of the fixed block.

18 is a plan view of a third embodiment apparatus.

FIG. 19 is a cross-sectional view taken along the line VV of FIG. 18. FIG.

* Explanation of symbols for main parts of the drawings

(1): Electronic coil (2): Spool

(3): Iron core (4): Protruding end

(5): stimulation (6): yoke

(9): Iron piece (10): Permanent magnet

(11): frame (12): movable block

(13): movable piece (14): slit

(15): Base (16): Common Terminal

(17): contact a (18): contact b

(41): high frequency relay (42): case

(43): Base (44): Contact Terminal

(45): coil terminal (51): electromagnetic coil

(56): Wark Gap (58): Base

The present invention is a woman of an electronic coil. The present invention relates to an electromagnetic relay of a type for switching a switch contact by applying a movable contact to a movable block moved by an element.

Conventional electromagnetic relays are known, for example, as shown in FIGS. 1 and 2. In the drawing, the iron core 3 is inserted into the spool 2 wound around the electromagnetic coil 1 by protruding one end 4.

The yoke 6 is provided with a locking portion 7 which is fixed to the other end 8 of the iron core 3, and the protruding end 4 of the iron core 3 between a pair of opposing magnetic poles 5 and 5. It is supported by the spool (2) by sandwiching it.

The movable block 12 includes iron pieces 9 and 9 inserted into a warp gap formed between the protruding end 4 and the quantum poles 5 and 5 of the iron core 3 and these iron pieces 9 and 9. It is composed of a frame member 11 that surrounds the permanent magnet (10) and the iron pieces (9) (9) to be inserted between the holding the permanent magnet 10 side. Two slits 14 and 14 are formed of the frame member 11.

On the other hand, the movable contact pieces 13 and 13 are arrange | positioned at the base 15 which fixes the spool 2. One end of these movable contacts 13 and 13 is fixed to the common terminals 16 and 16, and the other end thereof is inserted between the a contact 17 and the b contact 18 which are switch contacts as free ends. The free ends of the movable contacts 13 and 13 are inserted into the slits 14 and 14 of the movable block 12. In this state, the main body of the electromagnetic relay is entirely covered with the case 19 from the top.

In such an electromagnetic relay, when the excitation polarity of the electromagnetic coil 1 is switched, the movable block 12 reciprocates in the horizontal direction, and the free ends of the movable contact 13 are a contact 17 and b contact 18. ) To operate.

The electromagnetic relay configured as described above has a mechanical stability against the motion of the movable block because the movable block 12 reciprocates from one side of the apparatus to the width direction of the apparatus.

3 is a magnetic equivalent circuit of the electromagnetic relay described above. R ₁ -R ₄ is the side of the protruding end 4 of the iron core 3 in the work gap, the contact magnetic resistance of the yoke stimulus 5, the iron piece 9 and the locking portion of the yoke of the iron core 8. When (7) is caking fixed, there is a drawback that the magnetic resistance of R ₀ enters in the passage of the magnetic flux in series, and the magnetic characteristics fluctuate depending on the state of the cucking fixation, so that a stable switch operation cannot be obtained.

In order to remove the mechanically unstable elements of the electromagnetic relay, two of the electromagnetic relays shown in FIGS. 1 and 2 are combined with the movable blocks located outside, and the left and right movable blocks are connected with an appropriate connecting member. Is considered.

In this configuration, since the left and right movable blocks simultaneously move in the same direction, the line on which the force acts becomes the center line of the device, and no rotational force is generated. However, with this configuration, the defect that the magnetic characteristics fluctuate due to an increase in the magnetoresistance of the curving fixation is increased to two parts of the curling fixation. In addition, the work of combining two electromagnetic relays increases, as well as the disadvantage that the length of the device as a whole becomes long by combining.

On the other hand, when constituting a high frequency relay with this kind of electromagnetic relay, miniaturization is also possible to be mounted on a printed board. Problems here are high frequency characteristics and airtightness.

Regarding the airtightness, high part precision and assembly precision are required, but since it is small, it is not easy to manufacture, and insufficient airtightness cannot be obtained yet.

In addition, regarding the high frequency characteristics, since the contact terminals are arranged very close to each other, it is necessary to provide a shield against high frequency signals. As a shield structure conventionally implemented, there are some shown in FIG. 4 and FIG. In the drawing, the high frequency relay 41 is composed of a case 42 accommodating the main body of the electromagnetic relay and a base 43 covering the opening of the case 42. A plurality of terminals such as a contact terminal 44, a coil terminal 45, an earth terminal 46, and the like are closely arranged on the base 43. As shown in FIG. 5, Cu-Ni plating is performed on the inner and outer surfaces of the base 43 except for the contact terminals 44 and the coil terminals. The plated portion on the inner surface, the plated portion on the outer surface, the plated portion on the outer surface and the earth terminal 46 are electrically connected.

That is, the contact terminal 44 is surrounded in the earth region to reduce the leakage of the high frequency signal.

However, such a high frequency relay is mounted on a printed board by soldering each terminal to a board, and electrical connection is made by surface contact between the plated surface of the base and the earth pattern of the printed board. At this time, the flux at the time of solder may intrude between contact surfaces, and it is generally difficult to remove such an intrusion flux. This residual flux not only reduces the contact area between the plated surface of the base and the earth pattern of the printed board, but also corrodes the terminal with time, causes contact failure, and reduces high frequency characteristics. The deterioration of this high frequency characteristic is shown in FIG.

In Fig. 6, curve I shows the high frequency characteristics when the high frequency relay is mounted on the printed board in a good state, and the leakage of the high frequency signal is -74 Hz at 900 MHz. On the other hand, curve (II) shows the high frequency characteristic in the connected state by the earth terminal 46 only when the above described contact failure occurs, and the leakage amount of the high frequency signal is -61 Hz at 900 MHz. (I) It is clearly deteriorated.

It is an object of the present invention to provide an electromagnetic relay in which a rotational force is not generated in the apparatus main body by the movement of the movable portion.

Another object of the present invention is to provide an electromagnetic relay capable of obtaining stable magnetic properties.

Still another object of the present invention is to provide an electronic relay that can be miniaturized.

Still another object of the present invention is to provide an electromagnetic relay capable of constructing a high frequency relay having good high frequency characteristics.

Still another object of the present invention is to provide an electromagnetic relay capable of constructing a high frequency relay having high airtightness.

Hereinafter, with reference to the drawings will be described in detail.

7 to 11 show an electromagnetic relay according to the first embodiment of the present invention. In the drawing, a plate-shaped iron core 53 is inserted into the center of the spool 52 on which the electromagnetic coil 51 is wound, and both ends of the iron core 53 protrude outward from both end faces of the spool 52. Both ends of the electromagnetic coil 51 are connected to the coil terminal 78.

Yoke 54 is disposed on the lower surface shaft of the spool 52, and the warp gap 56 is provided at both ends 55 and 55 of both projections of the iron core 53 at both ends of the yoke 54. And (56) are formed to connect opposite magnetic poles (57) and (57). The spool 52 and the yoke 54 are integrally connected and fixed to the base 58.

Movable blocks 59 and 59 disposed at both of the gap gaps 56 and 56 at the both ends of the copper core 53 are iron pieces 61 inserted between the gap gaps 56 and 56. ), (61) and the permanent magnet 62 sandwiched between these iron pieces (61), (61). The polarities of the permanent magnets 62 and 62 are set to be reverse polarities with each other. These movable blocks 59 and 59 are fixed to both end surfaces of the connecting member 60.

The base 58 is formed with rectangular seals 65 and 65 sealed by the shield members 63 and 64 on both sides in the width direction of the spool 52. In the center of each chamber 65, a common contact 67 connected to a common terminal 66, and a contact 70 connected to a contact terminal, a b contact terminal 69, and a contact b at both sides of the bath, respectively. 71) is excreted.

In the shield member 63, the ground contacts 74a, 74b are formed to face the side where the contacts 67, 70, and 71 are fitted, and the ground contacts 74a, 74b are collectively. To the grand terminal 75.

The contact surfaces 72a, 72b are provided at the supporting surfaces 73 on both side surfaces of the connecting member 60 in the width direction. Is supported by the contact piece 72a between the contact point 70 and the common contact 67 and the grand terminal 74a, and the contact piece 42b is positioned at a position opposite to this. And b are disposed between the contact point 71 and the ground terminal 74b, respectively.

In addition, leaf springs 77a and 77b are fitted between the side surface of the connecting member 60 and the raised portions 76 on both sides of the base 58, and one end of each of the leaf springs 77a and 77b is connected. It is fixed to the side part of the member 60, and the other end abuts on the side surface of the both side raise part 46 of the base 58. As shown in FIG.

The electromagnetic relay thus constructed can be used as a single-state type or a latching type relay. In the case of use as a single-tate type, for example, the force of the leaf spring 77b of one side is weaker than that of the other leaf spring 77a. It is set so that the contact piece 72a may contact.

In addition, when used as a latching type, the force of the two plate springs 77a and 77b is appropriately adjusted so that the contact piece 72a is connected to the ground terminal 74a and the a contact terminal in the absence of the permanent magnet 62. The permanent magnets 62 and 62 are not allowed to contact the ground terminal 74b, the common terminal 67, and the b contact 72, respectively. In this attached state, the connecting member 60 moves in either of the width directions by the magnetic force of the permanent magnets 62 and 62, and the state is maintained in the element state. That is, for example, the contact piece 72b is in contact with the common terminal 67 and the b contact terminal 71, and the contact piece 72a is kept in contact with the ground terminal 74a.

11 is a three-dimensional magnetic equivalent circuit, and R _a1 to R _a4 and R _b1 to R _b4 represent the warp gaps 56. The magnetoresistance of the magnetic core 53, the iron core 61, and the magnetic pole 57 of the yoke 54 in FIG.

In the electromagnetic relay configured in this manner, the leaf springs 77a and 77b are configured as described above, and the electromagnetic coil 51 is excited to form the polarity of the iron core 53 in the left end of the drawing, with the S pole and the right end being N. To the pole. Then, the movable block 59 on the left side of the figure moves upward in the figure by the repulsion of the same pole and the suction of the other pole. In addition, the movable block 59 on the right side in the figure moves upward in the same manner, and as a result, the connecting member 60 moves upward in parallel, so that the common contact 67 is replaced by the b contact 71. In addition, when the electromagnetic coil 51 is demagnetized, the connecting member 60 is returned to its original state by the force of the leaf springs 77a and 77b (in the case of the single state type). Alternatively, the connecting member 60 maintains the moved state (in the case of latching type).

In the case of the latching type, when the element is excited in the opposite direction to the state shown in the figure, the device is in the other holding state.

In this manner, the electromagnetic relay can move the movable blocks 59 and 59 in the same direction in parallel, and the line of action of the force can obtain dynamic stability against the movement of the movable blocks 59 and 59. . In addition, since the iron core 53 and the yoke 54 do not need to be combined, the fluctuation factor of the magnetic characteristic is eliminated, and the magnetic characteristic is stable. In addition, since one electronic coil can be comprised mainly, miniaturization is possible.

Next, Figs. 12 and 13 show one embodiment of a high frequency relay constituted by the electromagnetic relay according to the present invention.

This high frequency relay 91 is composed of a case 92 and a base 93. The case 92 has a main body of the electromagnetic relay as described above. The base 93 is provided with a contact terminal 94, a coil terminal 95, and an AAS terminal 96 inserted into the printed board 100 along one side of the case 92. In this embodiment, two rows are provided along both sides of the case 92.

It should be noted that the contact terminal 94 has both sides of the terminal arrangement direction fitted with the AAS terminals 86, and the protrusions 97 are provided on the inner side of the base 93, and both AS terminals 96 are provided. The contact terminal 94 is surrounded by the reference numeral 96 and the protrusion 97. That is, the earth terminal 86 and the protrusion 97 are electrically connected by a high frequency shield layer formed by Cu—Ni plating performed on the inner and outer surfaces of the base 93, whereby the contact terminals 4 are formed. ) Is isolated by a high frequency chuck. In addition, since the protrusions 97 are provided, when the high frequency relay 91 is mounted on the printed circuit board 10, the base 93 is lifted from the printed circuit board 100 by the amount of the protrusions 9 so that the base 93 and Flux mixed between the printed circuit boards 100 can be easily removed. Therefore, the bad influence by a flux can be reduced. At this time, the contact terminal 94 exposed between the base 93 and the printed circuit board 100 by the protrusion 97 is surrounded by the earth terminal 96 and the protrusion 97, so that the high frequency characteristics are deteriorated. Disappear.

In addition, although the protrusion part 97 may be an arc shape like the two earth terminals 96 and 96, in view of the ease of sealing work, it is rectangular in this embodiment. It goes without saying that no plating for insulation is performed around the contact terminal 94 and the coil terminal 95. Curve IV shown in FIG. 14 shows the characteristics of the high frequency relay 91 configured as described above. In addition, curves (I) and (II) indicate the characteristics of the conventional high frequency relay.

As is apparent from this figure, the high frequency relay according to the above embodiment has a leakage amount of -79 kHz at 900 MHz, which is better than the characteristics (I) and (II) of the conventional high frequency relay.

Next, the earth terminal 96 and the protrusion 97 may be specifically configured by various methods as follows.

First, the earth terminal 96 is press-fitted into the base 93 in the same manner as the other terminals 95 and 95, and the protrusions 97 are integrally installed when the base 93 is formed. When forming 93, it is integrally provided and plating is performed on both surfaces of the base 93, and electrical connection of the AS terminal 96,96 and the protrusion 97 is performed.

2 shows that the protrusion 97 is integrally formed on the base 93 as described above, and the ground terminals 96 and 96 are formed in the lead frame and inserted into the base 93 to form the base ( 93) Apply plating.

3 shows a metal shield box provided with the earth terminal 96 and the protrusion 97 in the case 92 and press-fits the earth terminal 96 and the protrusion 97 with the base 93. do.

4 shows the protruding portion 97 integrally formed on the base 93, and the protruding end of the earth terminal 96 press-fitted into the base 93 is re-assembled, so that each of the notched earth terminals is removed from the base 93. It electrically connects with the metal plate press-contacted to it, and the electrical connection of the metal plate and the protrusion part 97 is performed by a plating layer. According to the high frequency relay configured in this way, the fragrance mixed between the base and the printed board can be easily removed, and contact failure and corrosion of the terminal can be prevented. In addition, since the contact terminal is surrounded by the protruding portion and the earth terminal, leakage of the high frequency signal can be prevented, and the leakage of the high frequency signal between the two poles due to the miniaturization of the high frequency relay can be reduced, and the high frequency characteristics can be obtained in good condition. Is as described above.

Finally, another embodiment of a high frequency relay is shown in FIGS. 15-19. The high frequency relay according to this embodiment is such that high airtightness can be obtained in addition to the improvement of the high frequency characteristics. This high frequency relay is composed of a fixed block 110, an electromagnet portion 120, a movable block 130, two return springs 140, 145 and a case 150.

The fixed block 110 has fixed terminals 119a, 119b, and 119c on the back surface of the base 112 formed by integrally forming a rectangular long hole 113 with an enemy resin through an earth ground substrate 115. And the terminal block 118 connected by the connecting portions 118e and 118f is fixed.

The contact end portions 119a, 119b, and 119c of the fixed terminals 119a, 119b, and 119c are located in the long hole 113, and each contact portion 119a is disposed on the inner wall of the long hole 113. Aas contacts 112a, 112b,..., Facing 119b, 119c. 112f is properly installed.

The ground substrate 115 is a copper plate and has cutout portions 117a to prevent falling into a plane. Connecting portions 115a, 115b having 117b; 115e, the ground terminals 116a, 116b are located on the back side thereof. (116f) is in season. The base 112 is plated with a conductive foil on the rear surface thereof, and the insertion holes 113a, 113b, and 113c communicating with the above-mentioned long holes 113 at positions facing the long holes 113. And the connecting portions 115a and 115b of the AAS substrate 115. Guide groove 113a into which 115e is press-fitted,... It holds (113e). In addition, the base 112 communicates the insertion holes 113a, 113b, and 113c with each other, and at the same time, cutouts 113e and 113f corresponding to the connection portions 118e and 118f of the terminal block 118 described above. ) It goes without saying that the conductive foil and the fixed terminals 119a, 119b and 119c are insulated from each other.

Next, a method of assembling the fixed block 110 will be described. That is, the guide groove 113a,... Connection portion 115a to 113e. 115e is press-fitted, the earth substrate 115 is bonded to the base 112, and the terminal block 118 is press-fitted into the insertion holes 113a, 113b, 113c of the base 112. At this time, the side wall 118a of the terminal block 118. 118b is the connecting portion 115a. Since 115d is strongly pressed against the inner surface of the insertion hole, high airtightness can be ensured. Then, the insertion holes 113a, 113b, 113c, the connecting portion 115a,... As 115d electrically connects the base 112 and the ground substrate 115 via the conductive foil, the high frequency characteristic is improved by increasing the contact area. In addition, excellent high-frequency characteristics can be obtained by increasing the contact area in the joining of the ground substrate 115 and the back surface of the base 112. Furthermore, the earth terminal 116a is formed between the fixed terminals 119a, 119b, and 119c. 116d and the connecting portion 115a. Since 115d is provided, leakage of a high frequency signal is prevented and the high frequency characteristic is further improved.

The electromagnet portion 120 inserts the I-shaped iron core 121 into the eastern part of the spool 122 and winds the coil 127 and simultaneously combines the spool 122 and the yoke 129 as the base 112. It is mounted to the concave inlet 114. The spool 122 intrudes the protruding piece 129a of the hole 123a and the yoke 129 of the supporting part 123 and abuts the side part 123b inside the protruding piece 129b. It is coupled with the yoke 129. In addition, the coil terminals 128 and 128 are attached to the supporting portions 123 and 123 and protrude below the base 112.

The movable block 130 is movable iron pieces 136a, 136b and the permanent magnets 137, 137 inserted into the frame portions 132, 132 of the movable table 131 integrally formed of an enemy resin. And the insulators 138 and 138 having the movable contact pieces 139a and 139b are inserted into and fixed to the holes 133 and 133. The movable table 131 is installed such that the movable iron pieces 136a and 136b face each other with a predetermined gap in the spool 122 of the iron core 121 and face the plate spring 140. As 145, it is hold | maintained so that reciprocation may be carried out in parallel with arrow (A), (A ') direction. The polarities of the permanent magnets 137 and 137 are reverse polarity with each other as in the first embodiment.

The leaf spring 140 inserts the protrusion 141 of the center portion into the groove portion 112a of the base 112 and the two side portions 142 and 143 into the groove portions 134 and 134 of the movable table 131. Is inserted into The leaf spring 145 is regrettable to the small protrusions 135 and 135 having cutouts 146 and 146 formed on the movable table 131, and the end portions 147 and 147 are connected to the base 112. In the grooves 112a and 112b.

That is, in the absence of the excitation of the electromagnetic coil 127, the movable block 130 is a magnetic force of the permanent magnets 137 and 137, and both the magnetic pole surfaces of the iron core 121 and the movable iron block 130 are arrows. Move in the direction (A '), and both ends of the movable contact piece 139a contact the engaging portions 119b' and 119c ', and both ends of the movable contact piece 139b are ground contacts 112a' and 112c. Touch ').

Here, when the electromagnetic coil 127 is excited, a suction force acts between the magnetic pole surfaces of the iron core 121 and the movable iron pieces 136a and 136a so that the movable block 130 moves in the direction of the arrow A. FIG. Earth contact which moves, the both ends of the movable contact piece 139b contact the contact parts 119a ', 119b', and the both ends of the movable contact piece 139a are provided in the inner side wall of the base 112 ( 112d ') and 112f.

That is, in this embodiment, the movable block 130 is moved in the direction of the arrow A by the excitation element with respect to the electromagnetic coil 127, returns to the direction of the arrow A ', and the contact portions 119a', ( 119 b ') and (119b') and (119c ') are switched.

On the other hand, since the leaf springs 145 are cut out 146 and 146 from the small protrusions 135 and 135 of the movable table 131, even if a difference in the spring force occurs in the left and right portions, the leaf springs ( 145 itself is stretched by the gap between the notch 146 and the small protrusion 135, so that the difference in the spring force is absorbed, and the reciprocating movement with the parallelism of the movable block 130 is possible.

Moreover, it goes without saying that it is not necessary to provide the guide groove in the insertion hole on the back surface of the base.

As described above, according to the high-frequency relay according to this embodiment, the terminal block is fixed to the base by interposing the connection part of the earth board in the crimped state between the insertion hole provided in the base and the terminal block. The connection part and the insertion hole in which the conductive thin film is provided are in surface contact, and the high frequency characteristic improves with the increase of a contact area. Furthermore, since the terminal block is fixed to the insertion hole of the base by the connection part of the earth substrate, high airtightness can be obtained.

Claims (15)

An electromagnet device once accommodated in the case of the opening; An electromagnetic relay comprising a base which covers an opening of the case and has a plurality of external connection terminals disposed along one side of the case. The electromagnet apparatus according to claim 1, further comprising: a spool to which the electromagnetic coil is wound; An iron core which projects through both ends of the spool and is inserted; A yoke having opposite magnetic poles by forming a warp gap on both sides sandwiching each projecting end of the iron core; A permanent magnet, a pair of movable blocks provided at the anode of the permanent magnet, having a pair of iron pieces inserted into the warp gap, and disposed on each protruding end side of the iron core; And a biasing means for absent of the pair of movable blocks against the magnetic force of the permanent magnet. 3. An electromagnetic relay according to claim 2, wherein a latching type or a single state type relay can be configured by the action of the biasing means. 3. The electromagnetic relay according to claim 2, wherein the permanent magnets of each of the pair of movable blocks are disposed so as to be reverse polarity to each other. 3. The electromagnetic relay as claimed in claim 2, wherein the pair of movable blocks are integrally connected. The electromagnetic relay as claimed in claim 2, wherein the pair of movable blocks are connected by a separate connecting member. A plurality of external connection terminals provided in the base is composed of a coil terminal, a contact terminal and an earth terminal; The contact terminal is surrounded by the earth terminal disposed in close proximity to both sides along one side of the case so as to sandwich it, and a protrusion protruding from the contact terminal to the inner base surface such as to connect both earth terminals; And the protruding end faces of the two earth terminals and the protrusion are electrically connected. 8. The electromagnetic relay according to claim 7, wherein the electrical connection between the two earth terminals and the projecting end face of the protrusion is made by a plating layer formed on the base. 8. The electromagnetic relay according to claim 7, wherein the two earth terminals are connected by a connecting piece embedded in the base, and the electrical connection between the earth terminal and the projecting end surface of the protrusion is made by a plating layer formed of a base. . 8. The earth ground terminal according to claim 7, wherein the two earth terminals are electrically connected by a connecting body pressed against the base surface, and the electrical connection between the earth terminal and the protruding end surface of the protrusion is made by a plating layer formed of a base. Electromagnetic relay. 8. The electromagnetic relay as set forth in claim 7, wherein both earth terminals and the protrusion are part of a sealed box provided in the case. The contact terminal according to claim 1, wherein the contact terminal of the plurality of external connection terminals is fixed to the terminal block; An earth terminal of the plurality of external connection terminals is formed integrally with the earth plate; And the terminal block and the earth plate are fixed to the base. The electromagnetic relay according to claim 12, wherein an insertion hole is provided in the base, and the connection portion of the earth plate and the terminal block are press-fitted to the insertion hole. 13. The electromagnetic relay according to claim 12, wherein the electrical connection between the base and the earth plate is made by a conductive thin film layer formed on the inner side of the press hole. 13. The electromagnetic relay according to claim 12, wherein the earth plate and the terminal block are fixed to the base in a form in which the earth terminal is inserted into the contact terminal.

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