JP3153663B2 - Insulation device between contacts of remote control relay with multiple poles - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an insulation device between contacts of a remote control relay having a plurality of poles.

[0002]

2. Description of the Related Art Conventionally, there has been provided a polarized electromagnet in which a plunger advances and retreats by switching a current supply direction to one coil, and opens and closes a main contact as the plunger advances and retreats.
In addition, by reversing the polarity of the diode, which is a backflow prevention element inserted in the power supply path to the coil as the plunger advances and retreats, energization of the coil is permitted only in the direction in which the plunger is retracted when the plunger projects. There is provided a remote control relay that permits energization of the coil only in a direction in which the plunger is protruded when the user retires. In this type of remote control relay having a plurality of main contacts, all the main contacts are driven by one polarized electromagnet, and thus the main contacts are arranged adjacent to each other.

[0003]

As described above, in a conventional remote control relay having a plurality of main contacts, the main contacts are arranged adjacent to each other. In this case, there is a problem that the insulation distance cannot be increased because the distance between them becomes small, and the withstand voltage is reduced. Therefore, there is a problem that it is difficult to increase the withstand voltage between adjacent main contacts in a small remote control relay.

SUMMARY OF THE INVENTION An object of the present invention is to solve the above-mentioned problems, and to provide an insulation device between contacts of a remote control relay having a plurality of poles, which can be reduced in size while increasing the insulation distance between adjacent main contacts. It is intended to provide.

[0005]

According to the present invention, in order to achieve the above object, a polarized electromagnet provided with a single-winding type coil, in which a plunger advances and retreats in accordance with a direction of energizing the coil, and is provided at a fixed position. An interlocking lever rotatably supported about the axis pin and coupled to the plunger at a position different from the axis pin and rotating around the axis pin as the plunger advances and retreats; a movable contact at one end held by the interlocking lever A plurality of movable contacts, a plurality of fixed contacts separated from and in contact with each movable contact, and a power supply path to the coil selected from two power supply paths that are inserted into the power supply path to the coil and interlock with the movement of the plunger. A remote control relay having a plurality of poles, provided in a case, with a switching contact that performs switching and a backflow prevention element that regulates the direction of a current passing through each power supply path selected by the switching contact in opposite directions. The interlocking lever is provided with a partition plate made of an insulating material for separating the movable contacts, and a partition made of an insulating material located between one set of the movable contact and the fixed contact and the other set is provided in the case. It is set up.

[0006]

According to the above construction, the interlocking lever connected to the plunger of the polarized electromagnet and holding a plurality of movable contacts is provided with a partition plate made of an insulating material for partitioning between adjacent movable contacts. Since a partition made of an insulating material is arranged between one set of contacts and fixed contacts and the other set, a remote control relay having a plurality of main contacts consisting of movable contacts and fixed contacts has a case. Even if the distance between the adjacent poles is reduced by reducing the size, the insulating distance (creeping distance) can be increased by providing a partition plate and a partition wall of an insulating material between the poles, and as a result, the distance between the adjacent poles can be increased. Can be prevented, and a small-sized, high-voltage remote controller relay can be provided.

[0007]

FIG. 1 shows the overall configuration of a remote control relay according to the present invention. The case 10 of the remote control relay is set to one module size (unit size) which is standardized as a common size of a distribution board, and covers a box-shaped body 11 having an open side surface and an opening surface of the body 11. And a cover 12. As shown in FIG. 2, the body 11 and the cover 12
Assembly holes 13, 1 formed in body 11 and cover 12
4, the caulking pin 15 is inserted, and the crimping pin 15 protruding from the side surface of the body 11 opposite to the cover 12 is caulked to be integrally joined. The case 10 has an auxiliary space 16 (see FIG. 5) in which components for enhancing the function can be stored. The peripheral surface of the case 10 corresponding to the auxiliary space 16 is open. Therefore, when not storing a component for high performance, the closing plate 17 is attached so as to close the opening.

A polarized electromagnet 20 is housed in the case 10. As shown in FIG. 5, the polarized electromagnet 20 includes two yokes 21 formed in a substantially U-shape, and the yokes 21 are arranged so as to oppose each other via a gap 22 between the tip end surfaces of the leg pieces. . One magnetic pole of the permanent magnet 23 contacts the central piece of the yoke 21, and an auxiliary yoke 24 is connected to the other magnetic pole of the permanent magnet 23. The auxiliary yoke 24 is disposed so as to surround a coil frame 26 around which the coil 25 is wound, and a plunger 27 is inserted into the coil frame 26 so as to be able to advance and retreat in the axial direction of the coil frame 26. The plunger 27 contacts the yoke 21 or the auxiliary yoke 24 when the plunger 27 moves forward and backward to regulate the moving range of the plunger 27 and form a magnetic circuit.
The two armatures 28 are fixed. The coil 25 is of a single-winding type, and the plunger 27 advances and retreats in accordance with the direction of current supply to the coil 25, and the plunger 27 is held at the stop position by the magnetic force of the permanent magnet 23. That is, at the stop position, a closed magnetic path of a path of the permanent magnet 23, the auxiliary yoke 24, the armature 28, the plunger 27, the armature 28, the yoke 21, and the permanent magnet 23 is formed, and the plunger 27 is held at that position. is there. In the armature 28, the yoke 2
A stationary plate 28a made of a non-magnetic material is fixed to a contact surface with the armature 1 so that the armature 28 can be easily separated from the state attracted to the yoke 21. The polarized electromagnet 20 is disposed between the partition pieces 11f and 11g protruding from a surface of the body 11 facing the cover 12, and a buffer spring 19 made of a leaf spring is provided between the partition piece 11g and the polarized electromagnet 20. By being sandwiched between the polarized electromagnets 20
Is fixed in a form pressed against the partition 11f. Therefore, the polarized electromagnet 20 is fixed by the buffer spring 19, and the vibration accompanying the advance and retreat of the plunger 27 is reduced by the buffer spring 19.

At one end of the plunger 27 in the reciprocating direction,
As shown in FIGS. 1, 3 and 5, an interlocking lever 31 made of a synthetic resin as an insulator is rotatably connected by a shaft pin 32. That is, a part of the plunger 27 is inserted into the concave groove 31b formed in the interlocking lever 31, and the plunger 27 is moved by the shaft pin 32 inserted into the bearing protrusion 31c protruding into the groove 31b. 31c. Further, the interlocking lever 31 is provided with a pair of support pieces 26a protruding from the outer peripheral surface of the coil frame 26 of the polarized electromagnet 20.
Are supported by two shaft pins 33 inserted therethrough. Each shaft pin 33 is inserted into the interlocking lever 31 through the support piece 26a, and the two shaft pins 33 are arranged coaxially. However, the length dimension inside the interlocking lever 31 is set so that the two shaft pins 33 do not contact each other. Is set. Inside the interlocking lever 31, the interlocking lever 31 is located between the two shaft pins 33.
The synthetic resin which is a constituent material of
Is insulated. The shaft pin 32 and the shaft pin 33 are parallel to each other, and when the plunger 27 reciprocates, the interlocking lever 31 swings about the shaft pin 33.

The interlocking lever 31 has a partition plate 31a, and contact holding tables 31d are provided on both left and right sides of the partition plate 31a.
Are formed, and the concave groove 31b is formed in the contact holder 31d. A substantially U-shaped spring receiving projection 31e is formed on both sides of the partition plate 31a so that the surface facing the contact holder 31d is open. The spring receiving projection 31e holds one end of the contact pressure spring 34 formed of a coil spring. The other end of the contact pressure spring 34 elastically contacts the movable contact 40 inserted between the contact holder 31d and the spring receiving projection 31e.

The movable contact 40 has a strip shape. A movable contact 41 is fixed to one end in the longitudinal direction, and a terminal plate 43 is connected to the other end via a connection wire 42 made of a braided copper wire. . A terminal screw 44 with a washer is screwed into the terminal plate 43. A projection 45 serving as a seat for the contact pressure spring 34 is formed at an intermediate portion of the movable contact 40 in the longitudinal direction.
Below 5, a positioning hole 46 is formed. The positioning projection 35 protruding from the interlocking lever 31 is inserted into the positioning hole 46. The interlocking lever 31 is provided with a fulcrum projection 36 having a curved surface on the side of the positioning projection 35 and contacting the movable contact 40, and the movable contact 40 comes into contact with the fulcrum projection 36. I have. A movable electromagnetic iron piece 47 is fixed to an end of the movable contact 40 below the movable contact 41. At the upper end of the interlocking lever 31, as shown in FIG.
The display piece 38 facing 0a is provided integrally, and the characters "ON" and "OFF" are written on the display piece 38. Further, an operation groove 38a is formed in a portion between the characters "ON" and "OFF" on the display piece 38 and is always exposed from the display window 10a to display a tool such as a tip of a driver. The interlocking lever 31 can be manually operated from the outside of the case 10 by being inserted into the window 10a and engaging with the operation groove 38a.

The fixed contact 51 facing the movable contact 41 is
The fixed terminal plate 50 is fixed to one end of a fixed terminal plate 50 formed by bending a conductive sheet metal and fixed to the case 10.
Is exposed outside the case 10. Fixed terminal board 5
Reference numeral 0 denotes a contact piece 52 extending downward from the one end where the fixed contact 51 is provided along the movable contact 40, and a fixed electromagnetic iron piece 53 is fixed to a lower end of the contact piece 52 so as to face the movable electromagnetic iron piece 47. Have been. Further, a terminal screw 55 with a washer is screwed into the terminal piece 54 protruding outward from the case 10. The movable contact 40 and the fixed terminal plate 50 are housed two by two in the case 10, so that the main contact has two poles.

A partition 18 is provided upright at a substantially central portion in the width direction of the case 10 at a position where the movable contact 40 and the fixed terminal plate 50 are housed in the case 10. Body 11
A portion of the lower wall corresponding to the partition 18 is provided with a cover 12.
A stepped portion 11a having a lowered side is formed, and the lower end of the partition 18 is brought into contact with the stepped portion 11a, and the horizontal piece 18a protruding from one side of the lower end of the partition 18 is placed on the lower wall of the body 11. Thereby, the partition 18 is positioned. Here, the lower wall of the body 11 on which the partition 18 is placed forms a step in the longitudinal direction of the body 11 (the left-right direction in FIG. 5).
8a is bent along this lower wall, so that the partition wall 18 is also positioned in the longitudinal direction of the body 11. In addition, the partition wall 18 includes the caulking pin 15
Boss 11e protruding from body 11 at the part where
Are also positioned by being inserted.

Two terminal bases 11b and 11c on which one terminal plate 43 of two poles and a terminal piece 54 are respectively mounted protrude from a surface of the body 11 facing the partition 18. On the surface facing the cover 12, two terminal bases 18b and 18c on which the other terminal plate 43 and the terminal piece 54 of the two poles are respectively mounted are projected. Terminal bases 11b and 18b and terminal bases 11c and 18c
Are arranged in two upper and lower stages as shown in FIG.
The terminal plate 43 connected to the movable contact 41 and the terminal piece 54 connected to the fixed contact 51 are arranged at different height positions. A partition 11d protrudes from a surface of the body 11 facing the partition 18 and a partition 18d protrudes toward the cover 12 at a portion of the partition 18 corresponding to the partition 11d. Further, a partitioning piece 11f with which a part of the partition wall 18 abuts protrudes from a surface of the body 11 facing the cover 12. The terminal plate 43 is fixed by the terminal bases 11b and 18b and the lower surfaces of the partition pieces 11d and 18d, and the terminal piece 54 is fixed by the terminal bases 11b and 18b and the terminal bases 11c and 18d ( (See FIG. 5). Further, the partition piece 11f is connected to the movable contact 41.
The adverse effect on the polarized electromagnet 20 due to the arc generated when the electrode and the fixed contact 51 are opened is reduced.

By the way, in the remote control relay, the coil 2
In order to move the plunger 27 back and forth, it is necessary to reverse the direction of current supply to the coil 25 in order to move the plunger 27 back and forth. Therefore, a switching contact for alternately selecting two types of power supply paths is connected to the coil 25, and a backflow preventing diode is connected to each of the power supply paths selected by the switching contact. The terminals of the diodes opposite to the switching contacts are commonly connected. The diodes are connected in such a way that the currents passing through the respective power supply paths are opposite to each other. If one of the power supply paths allows the current in the direction of the switching contact → coil 25 to pass, the other power supply path In this configuration, a current in the direction from the coil 25 to the switching contact is passed.

Since the energizing direction to the coil 25 is selected by the switching contact as described above, the energizing direction is selected so that the position of the plunger 27 is reversed when the coil 25 is energized. Plunger 2 for switching contact
It is necessary to switch according to the advance and retreat of 7. That is, it is necessary to link the movement of the plunger 27 with the switching contact. Therefore, in the present embodiment, a contact operating piece 37 is protruded from the interlocking lever 31, and the switching operation of the switching contact is performed by the contact operating piece 37.

As shown in FIG. 4, the switching contact includes a contact board 61 mounted on the upper surface of the polarized electromagnet 20. The contact board 61 has two fixed contact plates 62a and 62b, The movable contact plate 6 facing the plates 62a and 62b, respectively.
3a and 63b are fixed. The contact board 61 has a notch 61a at a key point on the periphery, and the coil frame 26 of the polarized electromagnet 20
The fixing claw 26b projecting upward from the outer peripheral surface of the
By engaging with a, positioning with respect to the polarized electromagnet 20 is performed. One end of each of the movable contact plates 63a and 63b is fixed to each leg of a substantially U-shaped contact support plate 64 and is electrically connected to each other.
3b has a spring force in a direction to contact the corresponding fixed contact plates 62a and 62b. The contact operation piece 37 of the interlocking lever 31 is inserted between the movable contact plates 63a and 63b (see FIG. 5). When the interlocking lever 31 swings with the advance and retreat of the plunger 27, the interlocking lever 3 is moved.
1 at both terminal positions, one of the movable contact plates 63a,
63b is separated from the fixed contact plates 62a, 62b.

The fixed contact plates 62a and 62b and the movable contact plates 63a and 63b are electrically connected to a circuit board 65 composed of a printed wiring board attached to the contact board 61. On the circuit board 65, the above-described diode and a reset differentiating circuit are mounted. Further, a pair of coil terminal plates 66 are fixed to the contact board 61, and terminal screws 67 with washers are screwed to the respective coil terminal plates 66. Therefore, the coil 2 receives the external signal input through the coil terminal plate 66 and
When power is supplied to the plunger 5, the plunger 27 advances and retreats according to the direction of power supply. Here, as shown in FIG. 8, both coil terminal plates 66 are disposed at positions shifted vertically. On the upper surface of the contact board 61, fixed contact plates 62a and 62b, movable contact plates 63a and 63b, and a circuit board 65 are partitioned.
Further, a partitioning piece 61b is provided so as to project between the coil terminal plate 66 and another member.

Next, the operation will be described. First, plunger 2
Assuming that the coil 25 is energized in the direction in which the protruding member 7 protrudes, the interlocking lever 31 moves with the shaft pin 3 as the plunger 27 protrudes.
5 rotates clockwise in FIG.
Contacts the fixed contact 51. Here, the movable contact 40 is in contact with the fulcrum projection 36 and is urged clockwise around the fulcrum projection 36 by the contact pressure spring 34.
The contact pressure of the movable contact 41 against the fixed contact 51 is obtained by the contact pressure spring 34. At this time, as shown in FIG. 5, the movable contact plate 63b is separated from the fixed contact plate 62b, and only the direction in which the plunger 27 is retracted as the direction of energizing the coil 25 is permitted. Here, in a state where the movable contact 41 is in contact with the fixed contact 51, the state is maintained by the magnetic force of the permanent magnet 23 even when the energization of the coil 25 is stopped.

Next, when the direction of power supply to the coil 25 is reversed, the plunger 27 retreats and the interlock lever 3
1 rotates counterclockwise in FIG. 5 around the shaft pin 33,
The movable contact 41 is separated from the fixed contact 51, and the main contact is opened. An arc is generated when the main contact is opened, but as shown in FIG.
Is present, the insulation distance between adjacent main contacts is increased, and discharge between adjacent poles is less likely to occur. In addition, since the partition plate 31a of the interlocking lever 31 exists between the adjacent movable contacts 40, the insulation distance between the movable contacts 40 is also increased. That is, the withstand voltage can be increased while the size is reduced. Here, when an extremely large current such as a short-circuit current passes through the main contact when the main contact is closed, an arc is generated when the main contact is opened even if the main contact is slightly opened, and the periphery of the main contact is melted, Since the case 10 may be ruptured due to rapid thermal expansion, the movable electromagnetic iron piece 47 may be used when an excessive current such as a short-circuit current passes.
The movable contact 41 is held so as not to separate from the fixed contact 51 by applying an attractive force by an electromagnetic force between the fixed contact 51 and the fixed electromagnetic iron piece 53.

[0021]

According to the present invention, as described above, the interlocking lever which is connected to the plunger of the polarized electromagnet and holds a plurality of movable contacts is provided with a partition plate made of an insulating material for partitioning between adjacent movable contacts. A remote control having a plurality of main contacts consisting of a movable contact and a fixed contact because a partition made of an insulating material is provided between one set of the movable contact and the fixed contact and another set. In a relay, even if the case is reduced in size and the distance between adjacent poles is reduced, the insulating distance can be increased by providing a partition plate and a partition wall of an insulating material between the poles. This has the advantage that a short circuit can be prevented and a small but high breakdown voltage litho-con relay can be provided.

[Brief description of the drawings]

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

FIG. 2 is an exploded perspective view showing a case used in the embodiment.

FIG. 3 is an exploded perspective view of a main part of the embodiment.

FIG. 4 is an exploded perspective view of a main part of the embodiment.

FIG. 5 is a partially cutaway side view of the embodiment with a cover removed.

FIG. 6 is a plan view of the embodiment.

FIG. 7 is a front view of the embodiment.

FIG. 8 is a rear view of the embodiment.

FIG. 9 is a sectional view of a main part of the embodiment.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 10 Case 18 Partition wall 20 Polarized electromagnet 25 Coil 27 Plunger 31 Interlocking lever 31a Partition plate 33 Axis pin 40 Movable contact 41 Movable contact 51 Fixed contact 62a Fixed contact plate 62b Fixed contact plate 63a Movable contact plate 63b Movable contact plate

──────────────────────────────────────────────────続 き Continued on front page (58) Field surveyed (Int.Cl. ⁷ , DB name) H01H 45/00-51/36

Claims (1)

(57) [Claims] 1. A polarized electromagnet having a single-winding type coil in which a plunger advances and retreats in accordance with an energizing direction to the coil, and a position different from the shaft pin which is rotatably supported around a shaft pin provided at a fixed position. An interlocking lever which is connected to the plunger and rotates around an axis pin in accordance with the reciprocation of the plunger; a plurality of movable contacts which are held by the interlocking lever and have a movable contact at one end; A plurality of fixed contacts, a switching contact inserted into a power supply path to the coil and selecting a power supply path to the coil from two power supply paths in conjunction with advance and retreat of the plunger, and passing through each power supply path selected by the switching contact Remote control relay having a plurality of poles in a case and a backflow prevention element for regulating the directions of currents flowing in opposite directions, interlocking a partition plate made of an insulating material for partitioning between adjacent movable contacts. A remote control relay having a plurality of poles, wherein a partition made of an insulating material is provided in the case and is provided between the one set of the movable contact and the fixed contact and the other set. Insulation equipment.