JP3385242B2 - Electromagnetic relay - Google Patents

Description

Description: BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method of oscillating an armature.
Control the electromagnet to disconnect the signal transmission path.
It relates to a replaceable electromagnetic relay. FIG. 9 is a sectional view showing a conventional electromagnetic relay.
It is. As shown in FIG. 9, a conventional electromagnetic relay 10
1 is an armature 1 by an electromagnet 138 and a permanent magnet 132
An electromagnet as a magnetic force generator for performing a seesaw operation of 36
The lock 130 and the respective contact leaf springs to be described later
24, the seesaw movement of the armature 136
Contact spring blower that presses the end of each contact spring
And a contact provided at an end of each contact leaf spring.
Each fixed terminal (to be described later) to be brought into contact with the ground layer 115, 1
16 and the like. electromagnetic
The stone block 130 and the contact spring block 120
The case 140 is housed inside the
A relay board 110 is fitted in the portion. The electromagnet block 130 of the electromagnetic relay 101
Are formed as magnetic poles 131a and 131b, respectively.
The substantially U-shaped iron core 131 to be used and the insulator are integrally molded
The coil 133 is wound around the groove of the spool 134 thus formed.
An electromagnet 138 configured by rotating the core 13
1 and a permanent magnet 132 disposed substantially at the center of the magnetic material.
And the support 136c provided at the center is permanent
It is magnetized by the magnet 132 and is
An armature swung like a seesaw with respect to the magnet 138
136. [0005] The armature 136 presses each contact spring.
Studs 137a and 138b are provided respectively.
It has arms 136a and 136b as pressing parts. Further
At the center of the armature 136, the end of the arm 136a is attached.
Hinge spring (not shown) for contacting the magnetic pole 131a
Is provided. The magnetic force of the electromagnet 138 is a hinge spring.
From the sum of the restoring force of the magnet and the magnetic force of the permanent magnet 132
Is also set large. Therefore, the armature 136 is
When the magnet 138 is in the non-excited state, the hinge spring is restored.
Force and the magnetic force of the permanent magnet 132
The end is in contact with the magnetic pole 131a, and the electromagnet 138 is excited.
In the state, the arm 136 is moved by the magnetic force of the electromagnet 138.
The end of b is in contact with the magnetic pole 131b. FIG. 10 shows a conventional electromagnetic relay shown in FIG.
It is a perspective plan view which shows the contact spring block of FIG. [0007] As shown in FIG.
The contact spring block 120 is a manufacturer as a signal contact spring.
Contact leaf spring 121 and ground contact leaf spring 123,
Contact with a break contact leaf spring 122 as a contact spring
Each of the leaf springs 123 ′ is
And each movable spring portion configured by
And a spring fixing portion 124 for fixing and supporting the spring portion.
I have. Each contact leaf spring 121, 12 of each movable spring portion
2 and one end of each air contact leaf spring 123, 123 '
The part and each spring connection part 150 are connected to the spring fixing part 124.
Fixed. Also, make contact leaf spring 121 and
Ground contact leaf spring 123, break contact leaf spring 122 and
And the ground contact leaf spring 123 'are parallel to each other.
Is fixed to the spring fixing part 124 in a state where
In addition, the spring fixing portion 124 is connected to the relay board 110 (see FIG. 9).
)). The free end of the make contact leaf spring 121 is T-shaped.
And two tips 1 at its tip.
21a and 121a 'are provided. Similarly,
The free end of the break contact leaf spring 122 is also formed in a T-shape.
And two break contacts 122a,
122a 'is provided. Also, air contact leaf springs
At the free ends of 123 and 123 ', the ground contact 12
3a and 123a 'are provided. Each movable spring
The part is constituted by a conductive member. FIG. 11 shows a conventional electromagnetic relay shown in FIG.
FIG. 4 is a plan view showing the relay board of FIG. As shown in FIG.
In addition, the relay board 110 of the electromagnetic relay 101 has a ground on its surface.
An air layer 115 is formed and a ground layer 116 is formed on the back surface.
Formed on each side end of the relay board 110,
Make contact terminals 111, 111 ', ground contact terminal 11
3 'and coil terminal 114, break fixed terminal 11
2, 112 ', ground contact terminal 113 and coil terminal 1
14 'are provided. Each make contact terminal 111, 111 'is
Fixing the make, which is a signal fixed contact, on the surface of the laser board 110
Contact points 111a and 111a 'are provided, and an external real
Make solder connection used for mounting on mounting board (not shown)
Pads 111b and 111b 'are provided. This and
Similarly, each break contact terminal 112, 112 '
-Break fixing, which is a signal fixing contact, on the surface of the substrate 110
Contact points 112a and 112a 'are provided, and break on the back
Solder connection pads 112b and 112b 'are provided.
You. In addition, the air contact terminals 113 and 113 ′ are also relays.
Ground fixed contacts 113a, 113a 'are provided on the surface of the substrate 110.
Are provided, and ground solder connection pads 113b and 11
3b 'is provided. Furthermore, each coil contact terminal 1
14 and 114 ′ are also fixed on the surface of the relay board 110 by a coil.
Constant contacts 114a and 114a 'are provided, and a coil
Solder connection pads 114b and 114b 'are provided.
You. The make-fixed contact 1 of the make connection terminal 111 ′
11a 'and the break fixed contact 112a'.
The constant contacts 112a 'are connected to each other. Also,
The fixed contact of each terminal and the solder pad should be
Are connected to each other by the
The constant contact constitutes a terminal of the signal transmission path. Here, FIG. 10 and FIG. 11 are referred to.
Make contact 121a of make contact leaf spring 121,
121a ', each break contact of the break contact leaf spring 122
The points 122a, 122a 'and the ground contact leaf spring 123,
Each of the air contact points 123a and 123a 'of 123'
Corresponding make fixed contacts 111, 111 ', break
Fixed contacts 112a and 112a 'and ground fixed contacts 11
3a and 113a '. FIG. 12 shows the armature and contact point shown in FIG.
FIG. 3 is a perspective plan view showing a sash block. When the electromagnet 138 (see FIG. 9) is
Sometimes, the end of the arm 136a of the armature 136 is
31a, and is magnetized on the right side with respect to the spring fixing portion 124.
Contact leaf spring 122 fixed to ground and ground contact
A leaf spring 123 is provided on the arm 136b of the armature 136.
Pressed by the stud 137b (see FIG. 9).
You. On the other hand, when the electromagnet 138 is in the excited state,
The end of the arm 136b of the 136 is magnetized to the magnetic pole 131b.
And is fixed to the spring fixing portion 124 on the left side in the figure.
Contact leaf spring 121 and ground contact leaf spring 123 '
Are studs provided on the arm 136a of the armature 136.
137a (see FIG. 9). Thus, according to the operation of the electromagnet 138,
To the fixed contacts 112a, 112a ', and 113a.
Closing operation of each contact 122a, 122a ', 123a
And each fixed contact 111a, 111a ', 113a'
Of the contacts 121a, 121a ', 123a'
The operation is performed alternately, and the desired
The connection state is selected. [0016] However, as described above,
In the conventional electromagnetic relay described, for example, as shown in FIG.
Break contacts 122a, 122a 'and ground contact
A point 123a corresponds to each fixed terminal of the relay board 110 (see FIG. 11).
When the armature 136 is closed,
Direction center line and each contact 123a, 122a, 122a '.
The distances are D21, D22 and D22 ', respectively, and each contact 123
a, 122a, 122a '.
Assuming that F21, F22 and F22 ', respectively, the following equation (1) is obtained.
stand. F22 × D22 + F22 ′ × D22 ′> F21 × D21 (1) Therefore, each of the contacts 123a, 122a, 122a ′ is
When closed to the fixed terminal, the length of the armature 136
Torque is generated around the center line in the hand direction, and the armature 136
I will be twisted. Then, the seesaw operation of the armature 136 becomes
Is disturbed and adversely affects the closing / opening characteristics of the electromagnetic relay.
There was a problem of giving. Also, in the conventional electromagnetic relay described above,
When the electromagnet 138 is in the non-excited state,
The contact 122 is such that each of the contacts 122a and 122a 'is a fixed contact 1
It is closed at 12a and 112a 'and becomes a part of the transmission line.
On the other hand, the ground contact point connected to the break contact spring 122
The ground contact 123a 'of the wire 123' is connected anywhere.
And open state. Therefore, the break contact 122
a, 122a ′, when viewed from the input end of the transmission path,
The impedance of the contact spring 123 '
Input impedance because it is connected in parallel
And the high-frequency characteristics of the transmission line deteriorate.
There was a problem. Accordingly, the present invention provides a transmission line impedance
It is possible to suppress the drop and improve the high frequency characteristics of the transmission line.
It is an object of the present invention to provide an electromagnetic relay that can be used. [0020] To achieve the above object,
Therefore, the electromagnetic relay of the present invention constitutes a terminal of a signal transmission path.
Fixed contacts connected to earth and fixed earth contacts
A relay board provided with
And a plurality of movable spring portions fixedly supported by the spring fixing portion.
Therefore, a signal connection for connecting the respective signal fixed contacts to each other is provided.
A point is provided at one end and the other end is fixed to the spring
A signal contact spring fixedly supported on one side of the portion,
A ground contact that is connected to a ground contact is provided at one end
And the other end is fixed to the other side of the spring fixing portion.
A supported ground contact spring, and the other of the signal contact springs
A spring connecting an end and the other end of the ground contact spring
A plurality of movable spring portions constituted by a connection portion, and a magnetic body
Formed of a material, centered on the vicinity of the spring fixing portion.
Armature arranged to swing like a seesaw
And two magnetic poles at which both ends of the armature are magnetized.
A magnetic force generating portion provided with a pole, and one of the armatures
Magnetizing one end of the magnetic force generating portion to one magnetic pole of the magnetic force generating portion.
The other of the movable spring portions,
Each contact spring fixedly supported on one side is connected to the relay board.
To close each contact and each fixed contact.
Operation and the other end of the armature
By magnetizing the other magnetic pole of the raw part, each movable
Fixedly supported on one side of the spring fixing portion of the spring portion
Pressed each contact spring against the relay board
The operation of closing each of the contacts and each of the fixed contacts is exchanged.
In an electromagnetic relay operated mutually, a small number of the relay boards are used.
At least the surface has a geosphere connected to the earth
And each of the movable spring portions is located above the
And the width of the spring connection is equal to the width of the signal contact.
And the width of the ground contact spring is smaller than that of the spring.
It is characterized by that. The electromagnetic relay of the present invention configured as described above.
According to the container, the static electricity generated between the movable spring part and the stratum
The capacity is small, and the spring connection
In order to increase the impedance,
The reduction of force impedance is suppressed,
Deterioration of sex is suppressed. Next, an embodiment of the present invention will be described.
This will be described with reference to the drawings. (First Embodiment) FIG.
It is sectional drawing which shows 1st Embodiment of a relay. As shown in FIG. 1, the electromagnetic relay of this embodiment
The device 1 comprises an armature 36 by an electromagnet 38 and a permanent magnet 32.
As a magnetic generator that swings the robot like a seesaw
The stone block 30 and each of the contact leaf springs described later are
24, the seesaw operation of the armature 36
Contact spring blower whose ends are pressed by contact springs
And a contact provided at an end of each contact leaf spring.
Each fixed terminal (to be described later) to be brought into contact with the ground layers 15, 16
And the like are provided. Electromagnetic blow
The lock 30 and the contact spring block 20 are inside the case 40.
And a relay base is provided in the lower opening of the case 40.
The plate 10 is fitted. Relay board 10 and case 40
Of the case 40 is bonded with an adhesive.
Are hermetically sealed. Here, the magnetic core of the electromagnet block 30
Iron core 31, coil 33 and spool 34
Electromagnet 38 and permanent magnet 32, and arm as a pressing portion
36a, 36b and studs 37a, 37b, support
36c, an armature 36 having a hinge spring (not shown)
Are the same as those of the conventional electromagnetic relay 101 shown in FIG.
Therefore, detailed description is omitted. FIG. 2 shows the contact points of the electromagnetic relay shown in FIG.
It is a perspective plan view which shows a sash block. As shown in FIG. 2, the contact point of the electromagnetic relay 1
The block 20 is a conventional electromagnetic relay 1 shown in FIG.
01, as with the contact spring block 120 of FIG.
Make contact leaf spring 21 and ground air contact leaf spring 23,
And a break contact leaf spring 22 as a signal contact spring.
Each of the ground contact leaf springs 23 ′ is
Each movable member made of a conductive member
Spring part and spring fixing part 2 for fixing and supporting each movable spring part
And 4. The make contact leaf spring 21
Have make contacts 21a, 21a 'at one end and
The rake contact leaf spring 22 has a break contact 22 at one end.
a, 22a ', and each air contact leaf spring 23, 23
Have earth contact 23a, 23a 'at one end
You. In this embodiment, the air contact leaf springs 23, 23 '
It is configured in a partially bent state. In this embodiment, each contact leaf spring is
The spring fixing portion 24 is connected to the other end of each contact leaf spring and the spring.
Nail connection part 50 is embedded inside spring fixing part 24
And are integrally configured. Furthermore, the width of the spring connection 50
Are formed narrower than the width of each contact leaf spring. FIG. 3 shows a relay of the electromagnetic relay shown in FIG.
It is a top view showing a substrate. As shown in FIG. 3, the relay of the electromagnetic relay 1
The board 10 is the same as the conventional electromagnetic relay 101 shown in FIG.
As in the case of the relay board 110, the ground layer 15 is formed on the surface.
And an earth layer 16 is formed on the back surface.
The make contact terminals 11 and 1 are provided on each side end of the laser board 10.
1 'and the ground contact terminal 13' and the break contact terminal 1
2, 12 'and the ground contact terminal 13 are provided respectively.
Have been. However, in the present embodiment, the coil terminals 14
Is provided at the lower end of the relay board 10, and the coil terminal 1
4 'is provided at the upper end of the relay board 10. Each contact terminal and each coil terminal are connected to a lead
Lead frame formed by stamping out part of the frame
The surface of the relay board 10 is bent by bending the
Side has fixed contacts and the back side has solder pads.
Fixed contacts and solder pads are passed through the inside of the board.
Are configured to be connected to each other by
You. Each solder pad is mounted on an external mounting board (not shown)
Used for In addition, the surface of each fixed contact
A lock is applied or a precious metal is welded.
The make-fixed contact 11a 'of the make connection terminal 11'
And the break fixed contact 12 of the break fixed contact 12a '
a ′ are connected to each other. Also, ground contact terminals
13, 13 'ground fixed contacts 13a, 13a'
Each is connected to the ground layer 15. The ground layer 15 on the front side of the relay board 10
Fixed contacts for each terminal are provided from one lead frame.
Formed by stamping out the parts to be pressed
Is done. Same for the ground layer 16 on the back side of the relay board 10
Then, from one lead frame, solder pads of each terminal
By punching the provided part by pressing
Formed. The lead substrate 10 in the present embodiment is
Each terminal configured as described above and each air layer are insulating members
It is composed by insert molding
You. Referring now to FIG. 2 and FIG.
Make contact 21a, 21a 'of the spring contact leaf spring 21;
Each break contact 22a, 22 of the break contact leaf spring 22
a ′ and each air contact 2 of the ground contact leaf springs 23, 23 ′
3a and 23a 'are corresponding signal fixed contacts, respectively.
Fixed contacts 11a, 11a 'and signal fixed contacts
Fixed contacts 12a, 12a 'and ground
They are arranged so as to face the fixed contacts 13a and 13a '.
You. Next, the operation of the electromagnetic relay 1 described above.
Will be described. FIG. 4 shows a state where the electromagnetic relay of this embodiment is not operated.
FIG. 5 is a sectional view of the electromagnetic relay according to the present embodiment.
It is sectional drawing at the time. When the electromagnet 38 is in the non-excited state, FIG.
As shown in FIG. 7, the magnetic force of the permanent magnet 32 and the
Due to the restoring force, one arm 36a of the armature 36 is
1a. At this time, the break contact leaf spring 22
And the ground contact leaf spring 23 (see FIG. 2)
The stud 37b provided on the other arm 36b of the
And the break contact of the break contact spring 22
22a, 22a 'and ground contact 2 of ground contact spring 23
3a are the fixed contacts 12a, 12a of the relay board 10.
a ', 13a (see FIG. 3). Meanwhile, make
The make contacts 21a and 21a 'of the contact leaf spring 21 are open.
Ground contact connected to the make contact leaf spring 21
Since the ground contact 23a of the point leaf spring 23 is closed,
Make contact spring 21 is grounded. Also open
Above the fixed make contacts 11a and 11a '
The grounded make contact leaf springs 21 and
And the ground layer 15 provided on the front and back surfaces of the relay board 10,
16 is shielded from the
Signal leakage has been suppressed. When the electromagnet 38 is in the excited state, FIG.
As shown, the armature 36 magnetized on the magnetic pole 31a has
Direction to cancel the magnetic flux of the permanent magnet 32 passing through the arm 36a
Then, a magnetic flux of the electromagnet 38 is generated. Therefore, armature 3
The magnetic force between the arm 36a and the magnetic pole 31a disappears.
On the other hand, the other arm 36 b of the armature 36
And the magnetic flux of the permanent magnet 32 are added to increase the magnetic force
Therefore, the armature 36 is inverted and the arm 36b is
b. At this time, the break contact leaf spring 22
Between the break contacts 22a and 22a 'and the ground contact leaf spring 23;
While the ground contact 23a is open, the make contact leaf spring
The arm 21 of the armature 36
Pressed down by stud 37a provided on 36a
Break contacts 22a, 22a 'and ground contact 2
3 'is closed. It should be noted that the electromagnet 38 is again turned off.
And the magnetic flux of the electromagnet 38 passing through the armature 36 disappears.
The armature 36 is moved by the restoring force of a hinge spring (not shown).
To return to the initial state (see FIG. 4). Thus the hinge spring
, The electromagnet 38 is de-energized.
And the arm 36a of the armature 36 immediately contacts the magnetic pole 31a.
Promptly set the electromagnetic relay 1 to the initial state.
Becomes possible. FIG. 6 shows the armature and contact spring shown in FIG.
It is a perspective plan view showing a block. For example, the break contacts 22a, 22a 'and
And the ground contact 23a is connected to each fixed terminal of the relay board 10 (FIG.
3), the longitudinal direction of the armature 36 is closed.
Distance between the directional center line and each of the contacts 23a, 22a, 22a '
Are D1, D2, and D2 ', respectively, and the contacts 23a, 22
a, 22a '(ie, the pressing force)
F1, F2, F2 '
Then, the following equation (2) holds. F2 × D2 + F2 ′ × D2 ′ = F1 × D1 Equation (2) As described above, in the electromagnetic relay 1 of the present embodiment, the ground contact is provided.
A part of the leaf spring 23 is formed in a bent state,
The longitudinal direction of the armature 36 due to the repulsive force of each contact spring
So that the torques acting around the center line cancel each other out
The contacts 22a, 22a ', and 23a are disposed at the respective positions.
Therefore, each contact 23a, 22a, 22a 'is
Armature 36 may be twisted when closed
Is prevented, so that the seesaw operation of the armature 36 is hindered.
To improve the closing / opening operation characteristics of the electromagnetic relay 1.
Can be up. The ground contact leaf spring 23 'is also partially bent.
The make contact leaf spring 21 is configured as shown in FIG.
Make contacts 21a, 21a 'and ground contact leaf spring 2
When the 3 ′ earth contact 23a ′ is closed,
As described above, it acts around the longitudinal center line of the armature 36.
Contact points 21a, 21a so that the respective torques cancel each other.
1a 'and 23a' are arranged. Therefore, each contact
23a ', 21a, 21a' are closed to each fixed terminal
Armature 36 is prevented from twisting when
You. As described above, for example, the electromagnet 38
Is in the non-excited state, the break contact leaf spring 22
Short-circuit the break fixed contacts 12a and 12a 'to make the transmission line
Function as a part of the
The continued ground contact leaf spring 23 'is connected to anywhere.
Not open. Therefore, from the input end of the transmission path
When viewed, the break contact leaf spring 22 and the ground contact leaf spring
23 'is connected in parallel to the transmission line.
And the input impedance of the transmission line drops.
It will be. Break contact leaf spring 22 and ground
The impedance Zin [Ω] of the air contact leaf spring 23 ′ is
A ground layer 15 provided on the surface of the laser substrate 10;
15, each of the contact leaf springs 22, 23 'and
And Zin = 1 / jωC (when L <λg / 4) ... Expression (4) However, L is grounded from the transmission path of the contact leaf spring.
Length [mm] to the tip of the contact, C is each contact leaf spring 2
Occurs between 2, 23 'and the ground layer 15 of the relay board 10.
Capacitance [F], ω is angular velocity [rad / s], λg
Is the wavelength [mm]. However, the electromagnetic relay 1 of the present embodiment
, The break contact leaf spring 22 and the ground contact leaf spring
The width of the connecting portion 50 with the contact leaf springs 22 and 2
Because it is thinner than the width of 3 ', the movable spring part and the ground
It is possible to reduce the capacitance generated between the layer 15
Wear. As described above, the connecting portion 50 has the movable spring
In order to increase the impedance,
The reduction of force impedance is suppressed,
The deterioration of the performance can be suppressed. FIG. 7 shows a modification of the electromagnetic relay shown in FIG.
It is sectional drawing which shows an example. However, the electromagnetic relay shown in FIG.
1 'is the same as the electromagnetic relay 1 shown in FIG.
The same components are denoted by the same reference numerals,
Is omitted. As shown in FIG. 7, the electromagnetic relay of the present modification is
1 ', the back surface of the armature 36' and the support portion 36c
On the opposite side, the spring fixing portion 24 'is fixed
I have. Therefore, in this modification, the spring fixing portion 24 'is fixed to the spring fixing portion 24'.
The fixed movable spring portion is swung together with the armature 36 ',
The contact of each contact leaf spring is pressed against the relay board 10. What
Note that the armature 36 'in this modification is provided with each contact leaf spring.
There is no stud provided for pressing. Therefore, the contact spring block 20 is
An electrode fixed to the armature 36 ', not on the substrate 10,
Also in the magnetic relay 1 ', the electric power described with reference to FIG.
The same operation and effect as those of the magnetic relay 1 can be obtained.
You. FIG. 8 shows a contact spring block shown in FIG.
And a modification of the armature shown in FIG. 1 and the like.
FIG. As shown in FIG. 8, the contact spring block of this modification is
The lock is the same as the contact spring block 20 shown in FIG.
The make contact leaf spring 71 as a signal contact spring and the ground
Contact leaf spring 73 and break as signal contact spring
The contact leaf spring 72 and the ground contact leaf spring 73 '
Each movable spring connected and connected by the connecting portion 60
And a spring fixing portion 74 for fixedly supporting each movable spring portion thereof
It is composed of In the present embodiment, each air contact plate
The main body of the spring is positioned with respect to the longitudinal center line of the armature 36.
It is inclined at a certain angle. The make contact leaf spring
71 has make contacts 71a, 71a 'at one end.
The break contact leaf spring 72 has a break contact at one end.
Air contact leaf springs 73, 7 having points 72a, 72a '
3 has a ground contact 73a, 73a 'at one end, respectively.
Have. Also in this modification, each movable spring portion
And the spring fixing portion 74 are integrally formed. Spring fixed
Inside the part 74, the make contact leaf spring 71 and the ground contact
Spring 73, break contact leaf spring 72 and ground contact leaf spring 7
3 ′ are connected by spring connection portions 60, respectively.
I have. The width of the spring connection part 60 is larger than the width of each contact leaf spring.
It is formed thin. Also in this modification, each contact 72a, 72
a ', 73a is the rebound of each contact spring when it is closed.
Acts around the longitudinal center line of the armature 86 by force
The arrangement is such that the torques cancel each other. example
For example, break contacts 72a, 72a 'and ground contact 73a
Is closed to each fixed terminal (see FIG. 3) of the relay board 10.
The center line of the armature 86 in the longitudinal direction and each contact point
The distances to 73a, 72a and 72a 'are D11 and D, respectively.
12, D12 ', and are applied to the respective contacts 73a, 72a, 72a'.
The obtained contact pressures are F11, F12 and F12 ', respectively.
Then, the following equation (5) holds. F12 × D12 + F12 ′ × D12 ′ = F11 × D11 (Equation (5)) Therefore, each contact 72a, 72a ′, 73a is connected to each fixed end.
Armature 86 may be twisted when closed
Is prevented, so that the seesaw operation of the armature 86 is hindered.
Improves the closing and opening operation characteristics of the electromagnetic relay
Can be done. The contacts 71a, 71a, 7
The same applies when 3a 'is closed to each fixed terminal.
Thus, the armature 86 is prevented from being twisted. Also in this modification, each contact leaf spring
The width of the connecting portion 60 for connecting each other is equal to the width of each contact leaf spring.
The movable spring part and the ground layer 15
Can be reduced. This
As shown in FIG.
In order to increase the
The decrease in impedance is suppressed, and the high-frequency characteristics of the transmission line are inferior.
Can be suppressed. As described above, the electromagnetic relay of the present invention
The device has a geosphere formed on at least the surface of the relay board.
And each movable spring portion is disposed above the stratum,
Part width is smaller than the width of the signal contact spring and the ground contact spring.
Is provided between the movable spring part and the stratum.
The generated capacitance is small, and the spring connection is
Transmission line to increase the impedance of
Of the input impedance at the transmission line
Can be suppressed from deteriorating.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a sectional view showing a first embodiment of the electromagnetic relay of the present invention. FIG. 2 is a perspective plan view showing a contact spring block of the electromagnetic relay shown in FIG. 1; FIG. 3 is a plan view showing a relay board of the electromagnetic relay shown in FIG. 1; FIG. 4 is a cross-sectional view of the electromagnetic relay of the present embodiment when not operating. FIG. 5 is a cross-sectional view of the electromagnetic relay of the present embodiment during operation. FIG. 6 is a perspective plan view showing the armature and the contact spring block shown in FIG. 1 and the like. FIG. 7 is a sectional view showing a modification of the electromagnetic relay shown in FIG. FIG. 8 shows a modification of the contact spring block shown in FIG.
FIG. 9 is a perspective plan view showing a modification of the armature shown in FIG. 1 and the like. FIG. 9 is a sectional view showing a conventional electromagnetic relay. FIG. 10 is a perspective plan view showing a contact spring block of the conventional electromagnetic relay shown in FIG. FIG. 11 is a plan view showing a relay board of the conventional electromagnetic relay shown in FIG. 12 is a perspective plan view showing the armature and the contact spring block shown in FIG. 9 and the like. DESCRIPTION OF SYMBOLS 1, 1 'Electromagnetic relay 10 Relay board 11, 11' Make contact terminal 11a, 11a 'Make fixed contact 11b, 11b' Make solder pad 12, 12 'Break contact terminal 12a, 12a' Break fixed contact 12b , 12b 'Break solder pad 13, 13' Ground contact terminal 13a, 13a 'Ground fixed contact 13b, 13b' Ground solder pad 14, 14 'Coil terminal 14a, 14a' Coil fixed contact 14b, 14b 'Coil solder pad 15, 16 Ground layer 20 Contact spring block 21, 71 Make contact leaf spring 21a, 21a ', 71a, 71a' Make contact 22, 72 Break contact leaf spring 22a, 22a ', 72a, 72a' Break contact 23, 23 ' 73, 73a 'ground-contact springs 23a, 23a', 73a, 73a 'ground-contact 24, 24', 74 Fixed part 30 Electromagnetic block 31 Iron core 31a, 31b Magnetic pole 32 Permanent magnet 33 Coil 34 Spool 36, 36 'Armature 36a, 36b Arm part 36c Support part 37a, 37b Stud 38 Electromagnet 40 Case 50, 60 Spring connection part

Claims (1)

(57) [Claims 1] A relay board provided with a plurality of signal fixed contacts constituting terminals of a signal transmission path and a ground fixed contact connected to the ground, A plurality of movable spring portions made of a conductive member and fixedly supported by a spring fixing portion, wherein a signal contact for connecting the signal fixing contacts is provided at one end, and the other end is provided. A signal contact spring fixedly supported on one side surface of the spring fixing portion and a ground contact connected to the ground fixing contact are provided at one end, and the other end is the other of the spring fixing portion. A plurality of movable spring portions each comprising: a ground contact spring fixedly supported on a side surface of the spring; and a spring connection portion connecting the other end of the signal contact spring and the other end of the ground contact spring. And a sheet made of a magnetic material and centered around the spring fixing portion. An armature disposed so as to be swung like ー, and a magnetic force generating portion provided with two magnetic poles at which both ends of the armature are magnetized, one of the armatures Each contact spring fixedly supported on the other side surface of the spring fixing portion of the movable spring portions with respect to the relay board by magnetizing one end of the magnetic force generating portion to one magnetic pole of the magnetic force generating portion. The operation of closing each of the contacts and each of the fixed contacts by pressing, and magnetizing the other end of the armature to the other magnetic pole of the magnetic force generating unit, thereby forming And an operation of pressing each contact spring fixedly supported on one side surface of the spring fixing portion against the relay board to close each contact and each fixed contact is performed alternately. , At least the surface of the relay board is grounded A connected ground layer is formed, and each of the movable spring portions is disposed above the ground layer, and the width of the spring connection portion is the width of the signal contact spring and the width of the ground contact spring. An electromagnetic relay characterized by being provided narrower than the electromagnetic relay.