JP5738209B2 - Electromagnetic relay - Google Patents

Description

  The present invention relates to an electromagnetic relay including an arc extinguishing magnet for extinguishing an arc generated in a contact pair.

  2. Description of the Related Art Conventionally, an electromagnetic relay is known that has a contact pair composed of a pair of a movable contact and a fixed contact, and an electromagnetic coil, and turns on and off the contact pair using the magnetic force of the electromagnetic coil (Patent Document 1 below). reference). An example of a conventional electromagnetic relay is shown in FIGS.

  The conventional electromagnetic relay 9 includes two electromagnetic coils 91 each having a conducting wire wound in a cylindrical shape, a yoke 92 made of a soft magnetic material, two plungers 93, and a plurality of contact pairs 99. Each plunger 93 has a core portion 93a made of a soft magnetic material and a contact portion 93b made of an insulating member. The core portion 93 a is disposed at the center of the electromagnetic coil 91. The yoke 92 is configured by combining a plurality of magnetic members. An in-coil yoke 92 a that is a part of the yoke 92 is provided at the center of the electromagnetic coil 91.

  As shown in FIG. 16, when the electromagnetic coil 91 is energized, a magnetic flux Φ is generated, and the magnetic flux Φ flows through the core portion 93 a of the plunger 93 and the yoke 92. As a result, the core portion 93a is magnetized and attracted to the in-coil yoke 92a. A spring member 97 is provided between the core portion 93a and the in-coil yoke 92a. As shown in FIG. 15, when energization to the electromagnetic coil 91 is stopped, the magnetic flux Φ disappears, and the core portion 93 a is separated from the in-coil yoke 92 a by the pressing force of the spring member 97.

  The contact pair 99 includes a pair of a movable contact 94 and a fixed contact 95. The electromagnetic relay 9 is switched between an on state (see FIG. 16) and an off state (see FIG. 15) by moving the plunger 93 back and forth in the axial direction (Z direction) of the electromagnetic coil 91. In the ON state, the movable contact 94 contacts the fixed contact 95, and a current flows between them. In the off state, the movable contact 94 is separated from the fixed contact 95 and the current is interrupted.

  When the contact pair 99 is switched from the on state to the off state, an arc (not shown) is generated in the contact pair 99. In order to cut off the current quickly, it is necessary to extinguish the arc. Therefore, an arc extinguishing magnet 98 is provided in the vicinity of the contact pair 99. The arc extinguishing magnet 98 is used to apply a magnetic field to the arc, and the arc is extended by the action of Lorentz force to extinguish the arc.

JP 2010-287455 A

  However, in the conventional electromagnetic relay 9, arc-extinguishing magnets 98 are arranged in the vicinity of the individual contact pairs 99 and a magnetic field is directly applied from the arc-extinguishing magnets 98 to the contact pairs 99. A magnet 98 was required. Therefore, there has been a problem that the manufacturing cost of the electromagnetic relay 9 tends to increase.

  This invention is made | formed in view of this background, and it aims at providing the electromagnetic relay which can reduce the number of arc-extinguishing magnets and can reduce manufacturing cost.

A first aspect of the present invention includes a plurality of contact pairs consisting of a pair of the movable contact and the fixed contact,
An electromagnetic coil that generates magnetic flux when energized;
By switching between energization and deenergization of the electromagnetic coil, the magnetic coil moves forward and backward by magnetic force, and an on state in which the movable contact contacts the fixed contact and an off state in which the movable contact is separated from the fixed contact. A plunger configured to switch;
An arc extinguishing magnet for extinguishing an arc generated in each of the plurality of contact pairs when the on state is switched to the off state;
An arc-extinguishing yoke made of a soft magnetic material and guiding magnetic flux generated from the arc-extinguishing magnet to the plurality of contact pairs ;
A coil yoke through which magnetic flux generated by energizing the electromagnetic coil flows,
A plurality of arc extinguishing yokes are provided at predetermined intervals, and a part of the arc extinguishing yokes of the plurality of arc extinguishing yokes is integrated with the coil yoke. It is in the relay (Claim 1).
Further, the second aspect of the present invention is a plurality of contact pairs consisting of a pair of a movable contact and a fixed contact;
An electromagnetic coil that generates magnetic flux when energized;
By switching between energization and deenergization of the electromagnetic coil, the magnetic coil moves forward and backward by magnetic force, and an on state in which the movable contact contacts the fixed contact and an off state in which the movable contact is separated from the fixed contact. A plunger configured to switch;
An arc extinguishing magnet for extinguishing an arc generated in each of the plurality of contact pairs when the on state is switched to the off state;
An arc-extinguishing yoke made of a soft magnetic material and guiding the magnetic flux generated from the arc-extinguishing magnet to the plurality of contact pairs;
The arc extinguishing yoke includes a first arc extinguishing yoke, a second arc extinguishing yoke, and a third arc extinguishing yoke,
The first arc-extinguishing yoke is disposed between the two contact pairs, and the second arc-extinguishing yoke and the position of the two contact pairs are sandwiched in the arrangement direction of the two contact pairs. The third arc-extinguishing yoke is disposed in the electromagnetic relay (Claim 6).

  In the electromagnetic relay, the magnetic flux generated from the arc-extinguishing magnet is guided to a plurality of contact pairs using the arc-extinguishing yoke, and the arc generated in the plurality of contact pairs is extinguished. . In this case, it is not necessary to dispose the arc extinguishing magnets at positions adjacent to the individual contact pairs, so that the number of arc extinguishing magnets can be reduced. Moreover, since the arc extinguishing yoke can be manufactured using a soft magnetic material such as iron, it is less expensive than the arc extinguishing magnet. Therefore, the manufacturing cost of the electromagnetic relay can be reduced.

  As described above, according to the present invention, it is possible to provide an electromagnetic relay that can reduce the number of arc extinguishing magnets and reduce the manufacturing cost.

FIG. 4 is a cross-sectional view of the electromagnetic relay in an off state according to the first embodiment, which is a cross-sectional view taken along the line CC in FIG. 3. Sectional drawing of the electromagnetic relay in an ON state in Example 1. FIG. AA sectional drawing of FIG. BB sectional drawing of FIG. The circuit diagram using the electromagnetic relay of Example 1. FIG. It is sectional drawing of the electromagnetic relay in Example 2, Comprising: It is FF sectional drawing of FIG. FIG. 7 is a cross-sectional view of the electromagnetic relay in an off state according to the second embodiment, which is a cross-sectional view taken along DD in FIG. 6. EE sectional drawing of FIG. Sectional drawing of the electromagnetic relay in an ON state in Example 2. FIG. Sectional drawing of the electromagnetic relay in Example 3. FIG. Sectional drawing of the electromagnetic relay in Example 4. FIG. Sectional drawing of the electromagnetic relay in Example 5. FIG. GG sectional drawing of FIG. Sectional drawing of the electromagnetic relay in Example 6. FIG. Sectional drawing of the electromagnetic relay in an OFF state in a prior art example. Sectional drawing of the electromagnetic relay in an ON state in a prior art example.

  The said electromagnetic relay can be used for the power converter device mounted in an electric vehicle, a hybrid vehicle, etc., for example.

In the first aspect of the present invention, a coil yoke through which a magnetic flux generated by energization of the electromagnetic coil flows is provided, and a plurality of the arc extinguishing yokes are provided at a predetermined interval. Among the arc extinguishing yokes, some of the arc extinguishing yokes are integrated with the coil yoke.
Therefore , some arc-extinguishing yokes of the plurality of arc-extinguishing yokes are integrated with the coil yoke, so that the number of parts of the electromagnetic relay can be reduced. Therefore, it becomes possible to further reduce the manufacturing cost of the electromagnetic relay.

One of the two magnetic poles of the arc-extinguishing magnet is in contact with the coil yoke, and the other magnetic pole is in contact with the arc-extinguishing yoke that is not integrated with the coil yoke. (Claim 2 ).
In this case, since the magnetic pole of the arc extinguishing magnet and the coil yoke are in contact, the magnetic resistance between them can be reduced. In addition, since the other magnetic poles of the arc extinguishing magnet are in contact with the arc extinguishing yoke that is not integrated with the coil yoke, the magnetic resistance between them can be reduced. Therefore, the magnetic flux of the arc extinguishing magnet can be efficiently guided to the contact pair, and the arc generated at the contact pair can be effectively extinguished.

In addition, it is preferable that the direction of the current flowing through the electromagnetic coil is determined so that the arc-extinguishing magnet is attracted to the coil yoke when the electromagnetic coil is energized (Claim 3 ).
When the arc extinguishing magnet and the coil yoke repel each other, the magnetic flux generated from the electromagnetic coil is less likely to flow smoothly through the coil yoke, and the plunger's attractive force tends to decrease. However, if the arc extinguishing magnet is attracted to the coil yoke, the magnetic flux generated from the electromagnetic coil flows smoothly through the coil yoke, and the plunger can be attracted with a strong force.

Further, between the two arc-extinguishing yokes, the contact pair and an arc-extinguishing chamber into which the arc stretched by the magnetic flux enters are interposed, and the two arcing chambers in the vicinity of the contact pair gaps between the arc extinguishing yokes are preferably narrower than the gap between the two arc extinguishing yoke in the arcing chamber (claim 4).
In this case, the magnetic field applied to the contact pair can be made stronger than the magnetic field applied to the arc extinguishing chamber. The arc requires the strongest magnetic field at the initial stage of stretching, and once stretched, the arc can be extinguished even with a relatively weak magnetic field. Therefore, it becomes easier to extinguish the arc by increasing the magnetic field applied to the contact pair.

In addition, it has a switch unit that has two contact pairs and switches on and off of the current flowing through the two contact pairs, and the arc generated in each of the two contact pairs included in the switch unit, Preferably, the arc is extinguished by the magnetic flux guided by the arc extinguishing yoke and extinguished in the same direction (Claim 5 ).
In the electromagnetic relay, it is necessary to secure a space (arc extinguishing chamber) where the extended arc enters. Here, if two arcs are extended in opposite directions, an arc extinguishing chamber to which one arc is guided and an arc extinguishing chamber to which the other arc is guided are arranged on the opposite sides with respect to the switch unit. Therefore, it becomes easy to enlarge an electromagnetic relay. However, if the two arcs are extended in the same direction, the two arc extinguishing chambers can be arranged adjacent to each other, so that the electromagnetic relay can be reduced in size.

Example 1
The Example which concerns on the said electromagnetic relay is described using FIGS. 1-5. As shown in FIGS. 1 to 3, the electromagnetic relay 1 of this example includes a plurality of contact pairs 2 including a pair of a movable contact 21 and a fixed contact 22, and an electromagnetic coil 3. As shown in FIG. 2, the electromagnetic coil 3 generates a magnetic flux Φ by energization. Two plungers 4 are arranged outside the electromagnetic coil 3 in the radial direction. The plunger 4 moves forward and backward by a magnetic force by switching between energization and deenergization of the electromagnetic coil 3. Thereby, the movable contact 21 is configured to switch between an on state (see FIG. 2) in which the movable contact 21 contacts the fixed contact 22 and an off state (see FIG. 1) in which the movable contact 21 is separated from the fixed contact 22.

  The electromagnetic relay 1 includes an arc extinguishing magnet 5 and an arc extinguishing yoke 6 made of a soft magnetic material. When the contact pair 2 is switched from the on state to the off state, an arc is generated in each of the plurality of contact pairs 2. As shown in FIG. 3, the magnetic flux φ generated from the arc-extinguishing magnet 5 is guided to the plurality of contact pairs 2 by the arc-extinguishing yoke 6 so that the arcs generated at the plurality of contact pairs 2 are extinguished. It is configured.

  The movable contact 21 and the fixed contact 22 are each made of a noble metal. As shown in FIG. 1, the movable contact 21 is supported by the movable contact support portion 11, and the fixed contact 22 is supported by the fixed contact support portion 12. The movable contact support part 11 and the fixed contact support part 12 are each made of metal.

  Further, the electromagnetic coil 3, the plunger 4, the arc extinguishing coil 5, and the like are accommodated in the accommodation case 15. The end 19 of the fixed contact support 12 projects from the side wall 151 of the housing case 15 in the arrangement direction (X direction) of the two plungers 4.

  The plunger 4 includes a core portion 41 made of a soft magnetic material and a contact portion 42 made of an insulating resin. In this example, two plungers 4 are moved forward and backward using one electromagnetic coil 3. The two plungers 4 can move forward and backward independently. That is, for example, even when the contact pair 2 is welded and one plunger 4 of the two plungers 4 cannot move forward and backward, the other plunger 4 can move forward and backward.

  In the housing case 15, a coil yoke 7 made of a soft magnetic material is housed. As shown in FIG. 2, the magnetic flux Φ generated by energizing the electromagnetic coil 3 flows through the coil yoke 7. The coil yoke 7 includes a columnar yoke 71, a bottom yoke 72, two suction yokes 73, and a plate yoke 74. The columnar yoke 71 is disposed so as to penetrate the winding central axis of the electromagnetic coil 3. The plate-shaped yoke 74 is connected to one end of the columnar yoke 71 in the axial direction (Z direction) of the electromagnetic coil 3. The bottom yoke 72 is connected to the other end of the columnar yoke 71 in the Z direction. The suction yoke 73 is arranged on the radially outer side of the electromagnetic coil 3 and is in contact with the bottom yoke 72. Between the core portion 41 of the plunger 4 and the suction yoke 73, a plunger pressing member 13 that presses the plunger 4 toward the movable contact support portion 11 in the Z direction is provided.

  As shown in FIG. 2, when the electromagnetic coil 3 is energized, a magnetic flux Φ is generated. This magnetic flux Φ flows through the columnar yoke 71, the plate-shaped yoke 74, the core portion 41, the suction yoke 73, and the bottom yoke 72. As a result, the core portion 41 is magnetized, and the core portion 41 is attracted to the suction yoke 73 against the pressing force of the plunger pressing member 13.

  The core portion 41 and the suction yoke 73 are formed with contact surfaces 410 and 730 that are in contact with each other. The contact surface 410 of the core part 41 is a convex conical surface, and the contact surface 730 of the suction yoke 73 is a concave conical surface.

  A contact pressing member 14 that presses the movable contact support 11 toward the fixed contact support 12 is provided between the upper wall 150 of the housing case 15 and the movable contact support 11. The spring constant of the contact pressing member 14 is smaller than the spring constant of the plunger pressing member 13.

  As shown in FIG. 1, when energization of the electromagnetic coil 3 is stopped, the magnetic flux Φ disappears, and the plunger 4 is pressed toward the movable contact support 11 by the pressing force of the plunger pressing member 13. Therefore, the abutting portion 42 of the plunger 4 abuts on the movable contact support portion 11 and the movable contact support portion 11 is lifted to the upper wall 150 side against the pressing force of the contact pressing member 14. As a result, the movable contact 21 is turned off from the fixed contact 22.

  As shown in FIG. 2, when the electromagnetic coil 3 is energized and the plunger 4 is attracted to the suction yoke 73, the movable contact support portion 11 is pressed toward the fixed contact support portion 12 by the pressing force of the contact pressing member 14. . As a result, the movable contact 21 is brought into an on state in contact with the fixed contact 22.

  As shown in FIGS. 3 and 4, in this example, two fixed contact support portions 12 and one movable contact support portion 11 allow current to flow between the two fixed contact support portions 12 or to be interrupted. The switch part 10 for doing is comprised. When the contact pair 2 is turned on, a current flows between the two fixed contact support portions 12 via the movable contact support portion 11. When the contact pair 2 is turned off, the current is interrupted. In this example, two switch parts 10 (10a, 10b) are provided. Each switch unit 10 is formed with two contact pairs 2.

As shown in FIG. 3, an arc extinguishing yoke 6 made of a soft magnetic material is provided in the vicinity of the contact pair 2. When the contact pair 2 is switched from the on state to the off state, an arc (not shown) is generated between the movable contact 21 and the fixed contact 22. Therefore, the magnetic flux φ of the arc extinguishing magnet 5 is guided to the plurality of contact pairs 2 by the arc extinguishing yoke 6, and the arc is extended by the action of Lorentz force to extinguish the arc. Thereby, the current flowing through the switch unit 10 can be cut off quickly.
In this example, a permanent magnet such as a neodymium magnet is used as the arc extinguishing magnet 5.

  As shown in FIG. 3, the electromagnetic relay 1 of the present example has three arc extinguishing yokes 6 including a first arc extinguishing yoke 6a to a third arc extinguishing yoke 6c. The first arc extinguishing yoke 6 a is in contact with one magnetic pole (N pole) of the arc extinguishing magnet 5. The first arc extinguishing yoke 6a is disposed at substantially the same position as the fixed contact support portion 12 and the fixed contact 22 in the Z direction. Further, as shown in FIG. 4, the first arc extinguishing yoke 6a is formed in a rectangular shape elongated in the X direction when viewed from the Z direction. The first arc extinguishing yoke 6a is located between the two contact pairs 2 included in the switch portions 10a and 10b, respectively. A plunger insertion hole 420 through which the contact portion 42 of the plunger 4 passes is formed in the first arc extinguishing yoke 6a.

  Further, as shown in FIG. 3, the second arc extinguishing yoke 6b and the third arc extinguishing yoke 6c are provided as one of the coil yokes 7 in the width direction (Y direction) orthogonal to both the X direction and the Z direction. It protrudes from the both ends of the plate-like yoke 74, which is a portion, to the upper wall 150 side in the Z direction. The second arc extinguishing yoke 6b and the third arc extinguishing yoke 6c are each formed in a plate shape. The plate-shaped yoke 74, the second arc-extinguishing yoke 6b, and the third arc-extinguishing yoke 6c are formed by bending a single metal plate. The tips 65 of the second arc-extinguishing yoke 6b and the third arc-extinguishing yoke 6c extend from the gap G of the contact pair 2 to the upper wall 150 side. The main surface of the plate-like yoke 74 is orthogonal to the Z direction, and the main surfaces of the second arc extinguishing yoke 6b and the third arc extinguishing yoke 6c are orthogonal to the Y direction, respectively.

  As shown in FIG. 4, between the first arc extinguishing yoke 6a and the second arc extinguishing yoke 6b, one contact pair 2a, 2c of the two switch portions 10a, 10b is interposed. Further, the other contact pair 2b, 2d of the two switch portions 10a, 10b is interposed between the first arc extinguishing yoke 6a and the third arc extinguishing yoke 6c.

  As shown in FIG. 3, the plate-like yoke 74 has a through hole 740 that penetrates in the Z direction. One end of the columnar yoke 71 is fitted in the through hole 740. The end face of the columnar yoke 71 is connected to the magnetic pole (S pole) opposite to the magnetic pole (N pole) of the arc extinguishing magnet 5 connected to the first arc extinguishing yoke 6a.

  As shown in FIG. 4, the magnetic flux φ generated from the arc-extinguishing magnet 5 is divided into four and respectively guided to the contact pairs 2 a to 2 d. Part of the magnetic flux φ is guided from the arc-extinguishing magnet 5 to the contact pair 2a through the first arc-extinguishing yoke 6a, and through the gap G (see FIG. 3) of the contact pair 2a to be used for the second arc-extinguishing. Move to yoke 6b. Thereafter, as shown in FIG. 3, the magnetic flux φ flows through part of the plate-like yoke 74 and the columnar yoke 71 and returns to the arc-extinguishing magnet 5. Thus, by flowing the magnetic flux φ through the contact pair 2a, the arc generated in the gap G of the contact pair 2a is extended and extinguished.

  As shown in FIG. 4, the magnetic flux φ is also guided to the other contact pairs 2 b to 2 d, moves to the second yoke 6 b or the third yoke 6 c, the plate-shaped yoke 74, and the columnar yoke 71, and returns to the arc-extinguishing magnet 5. As described above, the magnetic flux φ generated from the arc-extinguishing magnet 5 flows through different paths, and passes through the four contact pairs 2a to 2d.

  In this example, the magnetic flux φ of the arc extinguishing magnet 5 flows not only in the arc extinguishing yokes 6a to 6c but also in a part of the coil yoke 7 (plate yoke 74 and columnar yoke 71). ing.

  As shown in FIG. 4, an arc extinguishing chamber R into which an extended arc enters is formed between the two switch portions 10a and 10b. The arc generated in each of the two contact pairs 2a and 2b included in one switch unit 10a out of the two switch units 10a and 10b is extended to the other switch unit 10b side in the X direction to extinguish the arc. The chambers R1 and R2 enter and are extinguished. In addition, arcs generated at the two contact pairs 2c and 2d included in the other switch unit 10b are extended to the one switch unit 10a side in the X direction and enter the arc extinguishing chambers R3 and R4 to be extinguished. Arced. An insulating wall portion 18a made of an insulator is formed between two arc extinguishing chambers R1 and R3 adjacent in the X direction. This insulating wall portion 18a prevents the arcs entering the two arc extinguishing chambers R1 and R3 from coming into contact with each other and short-circuiting. An insulating wall portion 18b is also formed between two other arc extinguishing chambers R2 and R4 adjacent in the X direction.

  In this example, as shown in FIG. 2, the direction of the current flowing through the electromagnetic coil 3 so that the arc-extinguishing magnet 5 is attracted to the columnar yoke 71 and the plate-shaped yoke 74 when a current flows through the electromagnetic coil 3. Is stipulated. That is, the magnetic pole of the columnar yoke 71 that contacts the arc-extinguishing magnet 5 is different from the magnetic pole of the arc-extinguishing magnet 5 that contacts the columnar yoke 71 (S pole in this example). ), The direction of the current flowing through the electromagnetic coil 3 is determined.

  In this example, the magnetic pole of the arc-extinguishing magnet 5 that contacts the columnar yoke 71 is the S pole, and the magnetic pole of the columnar yoke 71 that contacts the arc-extinguishing magnet 5 is the N-pole. The direction of 5 may be reversed and the direction of the current flowing through the electromagnetic coil 3 may be reversed. In this case, since the direction of the magnetic field applied to the contact pair 2 by the arc extinguishing magnet 5 is reversed, in order to put the arc into the arc extinguishing chamber R, it is necessary to reverse the direction of the current flowing through the switch unit 10. .

  On the other hand, as shown in FIG. 4, the end portion 19 of the fixed contact support portion 12 protrudes from the housing case 15 in the X direction. Of the two switch portions 10 (10a, 10b), the end portions 19a, 19b of the two fixed contact support portions 12 included in one switch portion 10a protrude in the same direction. Further, the end portions 19c and 19d of the two fixed contact support portions 12 included in the other switch portion 10b protrude on the opposite side to the end portions 19a and 19b of the one switch portion 10a. These end portions 19a to 19d serve as connection terminals for connecting the switch unit 10 to other electronic devices.

  Next, an electric circuit using the electromagnetic relay 1 of this example will be described. As shown in FIG. 5, the electromagnetic relay 1 of this example is used for an inverter 80. The inverter 80 converts the DC power of the DC power source 8 into AC power, and drives the three-phase AC motor 81 using this AC power. One of the two switch units 10a and 10b included in the electromagnetic relay 1 is provided on a positive power line 83 connecting the positive electrode of the DC power supply 8 and the inverter 80, and the other switch unit. 10 b is provided on the negative power line 84 connecting the negative electrode of the DC power supply 8 and the inverter 80. The inverter 80 is connected to or disconnected from the DC power supply 8 by switching the electromagnetic relay 1 between the on state and the off state using the control circuit 82.

  When switching the electromagnetic relay 1 from the on state to the off state, one of the two switch units 10 may be welded. Even in this case, if the other switch unit 10 can be turned off, the direct current I flowing through the inverter 80 can be cut off.

  The effect of this example will be described. As shown in FIG. 3, in this example, the magnetic flux φ generated from the arc-extinguishing magnet 5 is guided to a plurality of contact pairs 2 using the arc-extinguishing yoke 6, and arcs generated at the plurality of contact pairs 2 are extinguished. It is configured to In this case, it is not necessary to arrange the arc-extinguishing magnets 5 at positions adjacent to the individual contact pairs 2, so that the number of arc-extinguishing magnets 5 can be reduced. Further, the arc extinguishing yoke 6 can be manufactured using a soft magnetic material such as iron, and therefore is less expensive than the arc extinguishing magnet 5. Therefore, the manufacturing cost of the electromagnetic relay 1 can be reduced.

As shown in FIG. 3, the electromagnetic relay 1 of this example includes three arc extinguishing yokes 6a to 6c. Of the three arc-extinguishing yokes 6, some arc-extinguishing yokes 6 (second arc-extinguishing yoke 6 b and third arc-extinguishing yoke 6 c) are coil yokes 7 (plate yoke 74). It is integrated.
If it does in this way, the number of parts of the electromagnetic relay 1 can be decreased. As a result, the manufacturing cost of the electromagnetic relay 1 can be further reduced.
Further, when the arc extinguishing yokes 6b and 6c and the coil yoke 7 are integrated, the magnetic resistance between them can be reduced. Therefore, the magnetic flux φ of the arc extinguishing magnet 5 guided to the contact pair 2 can be increased. Thereby, it becomes possible to improve the arc extinguishing performance of the arc. If the arc extinguishing yokes 6b and 6c and the coil yoke 7 are formed separately and a gap is provided between them, the magnetic resistance increases in the gap, and the magnetic flux φ guided to the contact pair 2 decreases. End up. Therefore, the arc extinguishing performance is reduced.

  Further, in this example, as shown in FIG. 3, the arc extinguishing yokes 6b and 6c and the plate-like yoke 74 are formed by bending one metal plate. If it does in this way, since three yokes 6b, 6c, and 74 can be formed only by bending a metal plate, manufacturing cost can be reduced.

As shown in FIG. 3, one of the two magnetic poles (S pole) of the arc extinguishing magnet 5 is in contact with the coil yoke 7 (columnar yoke 71 and plate yoke 74). The other magnetic pole (N pole) is in contact with the arc extinguishing yoke 6 (first arc extinguishing yoke 6 a) that is not integrated with the coil yoke 7.
In this case, since one magnetic pole of the arc extinguishing magnet 5 is in contact with the coil yoke 7, the magnetic resistance between them can be reduced. In addition, since the other magnetic pole of the arc-extinguishing magnet 5 is in contact with the arc-extinguishing yoke 6 (first arc-extinguishing yoke 6a) that is not integrated with the coil yoke 7, the magnetic resistance between them is also reduced. Can be small. Thereby, the magnetic flux φ of the arc extinguishing magnet 5 guided to the contact pair 2 can be increased, and the arc can be extinguished efficiently.
Further, with the above configuration, since a large amount of magnetic flux φ can flow through the arc extinguishing yoke 6 and the coil yoke 7, the amount of the magnetic flux φ leaking outside the yokes 6 and 7 can be reduced. Therefore, the amount of magnetic flux φ leaking to the outside of the electromagnetic relay 1 can be reduced, and even if a component having a magnetic sensor or the like is disposed in the vicinity of the electromagnetic relay 1, the influence on the magnetic sensor can be reduced.
Note that “the one magnetic pole of the arc extinguishing magnet 5 is in contact with the coil yoke 7” means that they are in magnetic contact. That is, in addition to the case where the magnetic pole and the coil yoke 7 are actually in contact with each other, the case where a thin object (thin paper or the like) is interposed within a range in which the magnetic resistance does not increase greatly is included. Further, the meaning of “the other magnetic pole of the arc-extinguishing magnet 5 is in contact with the first arc-extinguishing yoke 6a” is also the same.

Further, as shown in FIG. 2, in this example, the direction of the current flowing through the electromagnetic coil 3 is determined so that the arc-extinguishing magnet 5 is attracted to the coil yoke 7 when the electromagnetic coil 3 is energized. Yes.
When the arc-extinguishing magnet 5 and the coil yoke 7 repel each other, the magnetic flux Φ generated from the electromagnetic coil 3 is less likely to flow smoothly through the coil yoke 7 and the attractive force of the plunger 4 is likely to be reduced. However, if the arc extinguishing magnet 5 is attracted to the coil yoke 7, the magnetic flux Φ generated from the electromagnetic coil 3 can flow smoothly in the coil yoke 7 and attract the plunger 4 with a strong force. It becomes possible.

As shown in FIG. 4, the electromagnetic relay 1 of this example includes a switch unit 10 having two contact pairs 2. The arcs generated at the two contact pairs 2 included in the switch unit 10 are extinguished by extending in the same direction by the magnetic flux φ guided by the arc-extinguishing yoke 6.
If two arcs generated from one switch unit 10 are extended in opposite directions, the arc-extinguishing chamber R to which one arc is guided and the arc-extinguishing chamber R to which the other arc is guided are the switch unit 10. Therefore, the electromagnetic relay 1 can be easily increased in size. However, if two arcs are extended in the same direction as in this example, two arc extinguishing chambers R (R1, R2 and R3, R4) can be arranged adjacent to each other in the Y direction. Therefore, the electromagnetic relay 1 can be reduced in size.

  As described above, according to this example, it is possible to provide an electromagnetic relay capable of reducing the number of arc extinguishing magnets and reducing the manufacturing cost.

(Example 2)
In this example, the number of switch units 10 and plungers 4 and the position of the arc extinguishing magnet 5 are changed. As shown in FIGS. 6 to 8, the electromagnetic relay 1 of this example includes one switch unit 10 and one plunger 4. The plunger 4 is arranged at the winding center of the electromagnetic coil 3.

  As shown in FIGS. 7 and 8, the coil yoke 7 of this example includes a suction yoke 73, a bottom yoke 72, a side wall yoke 75, and a plate-like yoke 74. The suction yoke 73 is disposed at the winding center of the electromagnetic coil 3. The plate-like yoke 74 is disposed on one side of the electromagnetic coil 3 in the Z direction and has a plunger insertion hole 415 through which the plunger 4 passes. The bottom yoke 72 is disposed on the other side of the electromagnetic coil 3 in the Z direction and is in contact with the suction yoke 72. The side wall yoke 75 is erected in the Z direction from the outer peripheral edge of the bottom yoke 72 and is in contact with the plate-like yoke 74.

  As shown in FIG. 9, when the electromagnetic coil 3 is energized, a magnetic flux Φ is generated. This magnetic flux Φ flows through the plate-shaped yoke 74, the side wall yoke 75, the bottom yoke 72, the suction yoke 73, and the core portion 41 of the plunger 4. As a result, the core portion 41 is magnetized and attracted to the suction yoke 73. Further, when energization of the electromagnetic coil 3 is stopped, the magnetic flux Φ disappears, and the plunger 4 is pressed toward the movable contact support portion 11 in the Z direction by the pressing force of the plunger pressing member 13. Thus, by moving the plunger 4 forward and backward, the contact pair 2 is contacted and separated.

  Further, as shown in FIG. 8, the arc extinguishing magnet 5 of this example is provided at a position shifted from the winding center of the electromagnetic coil 3 to the radially outer side of the electromagnetic coil 3. The arc extinguishing magnet 5 is in contact with the first arc extinguishing yoke 6a and the plate-like yoke 74, respectively.

  As shown in FIG. 6, the first arc extinguishing yoke 6 a is interposed between the two fixed contact support portions 12. When viewed from the Z direction, the first arc extinguishing yoke 6a has an elongated rectangular shape in the direction (X direction) in which the fixed contact support portion 12 extends. The switch unit 10 is sandwiched between the second arc-extinguishing yoke 6b and the third arc-extinguishing yoke 6c. The second arc extinguishing yoke 6b and the third arc extinguishing yoke 6c are integrated with a plate-like yoke 74 (see FIG. 7). One of the two contact pairs 2a and 2b is interposed between the first arc-extinguishing yoke 6a and the second arc-extinguishing yoke 6b. The other contact pair 2b is interposed between the first arc extinguishing yoke 6a and the third arc extinguishing yoke 6c.

As shown in FIGS. 6 and 7, the magnetic flux φ generated from the arc extinguishing magnet 5 is guided to the two contact pairs 2a and 2b through the first arc extinguishing yoke 6a, and the gap G of the contact pair 2 is set. It moves to the second arc extinguishing yoke 6b and the third arc extinguishing yoke 6c. The magnetic flux φ flows through the plate-like yoke 74 and returns to the arc extinguishing magnet 5. Thereby, the arc generated in the contact pair 2 is extended and extinguished.
In addition, the same configuration as that of the first embodiment is provided.

The effect of this example will be described. With the above configuration, the arc extinguishing magnet 5 and the arc extinguishing yoke 6 can be provided even when the plunger 4 is arranged at the winding center of the electromagnetic coil 3. Therefore, arcs generated at the plurality of contact pairs 2 can be extinguished using the arc extinguishing magnet 5 and the arc extinguishing yoke 6.
In addition, the same effects as those of the first embodiment are obtained.

(Example 3)
In this example, the shape of the arc extinguishing yoke 6 is changed. As shown in FIG. 10, in this example, convex portions 69 are formed on the second arc extinguishing yoke 6b and the third arc extinguishing yoke 6c in the vicinity of the contact pair 2. Therefore, the interval between the two arc extinguishing yokes 6 (the interval between the first arc extinguishing yoke 6a and the second arc extinguishing yoke 6b, or the first arc extinguishing yoke 6a and the third arc extinguishing yoke 6c, Is narrow in the vicinity of the contact pair 2 and wide in the arc extinguishing chamber R.
In addition, the same configuration as that of the first embodiment is provided.

The effect of this example will be described. In this example, the magnetic field applied to the contact pair 2 can be made stronger than the magnetic field applied to the arc extinguishing chamber R. The arc requires the strongest magnetic field at the initial stage of stretching, and once stretched, the arc can be extinguished even with a relatively weak magnetic field. Therefore, it becomes easier to extinguish the arc by strengthening the magnetic field applied to the contact pair 2.
In addition, the same effects as those of the first embodiment are obtained.

Example 4
In this example, the position of the contact pair 2 is changed. As shown in FIG. 11, in this example, the contact pairs 2 a to 2 d are arranged at a location close to the center of the electromagnetic relay 1 in the X direction (position where the arc extinguishing magnet 5 is arranged), and the X direction of each contact pair 2. An arc extinguishing chamber R was formed outside. Further, the end 19 of the fixed contact support 12 is protruded in the Y direction.

In this example, similarly to the first embodiment, the electromagnetic relay 1 is provided with two switch portions 10a and 10b. In one of the two switch portions 10a and 10b, the current flows through the end portion 19a, the contact pair 2a, the movable contact support portion 11a, the contact pair 2b, and the end portion 19b. In the other switch portion 10b, the current flows through the end portion 19c, the contact pair 2c, the movable contact support portion 11b, the contact pair 2d, and the end portion 19d. Then, the arc generated along with the separation of the contact pairs 2a to 2d is extended outward in the X direction by the magnetic flux φ of the arc extinguishing magnet 5, and is put into the arc extinguishing chamber R to extinguish the arc.
In addition, the configuration is the same as that of the first embodiment.

  The effect of this example will be described. Since the magnetic resistance is small in the vicinity of the arc extinguishing magnet 5, the magnetic flux φ can be increased. Therefore, the magnetic flux φ1 passing through the contact pair 2 can be strengthened by arranging the contact pair 2 at a position close to the arc extinguishing magnet 5 as in this example.

As described above, the arc requires the strongest magnetic field in the first stage of extension, and once extended, it has the property that it can be extinguished even with a relatively weak magnetic field. In this example, since the magnetic field in the contact pair 2 can be increased, the arc can be extinguished more effectively.
In addition, the same effects as those of the first embodiment are obtained.

(Example 5)
In this example, the shape of the arc extinguishing yoke 6 is changed. As shown in FIGS. 12 and 13, in this example, a cutout portion penetrating in the Y direction through the second arc extinguishing yoke 6 b and the third arc extinguishing yoke 6 c at the center in the X direction of the electromagnetic relay 1. 61 was formed. Further, in this example, the contact pairs 2 a to 2 d are formed so as to be positioned slightly outside in the X direction with respect to the side surface 63 of the notch 61. And the arc extinguishing chamber R was formed in the X direction outer side of the contact pairs 2a to 2d.

As shown in FIG. 13, the notch 61 is formed so as to be cut out from the upper edge 62 of the second arc extinguishing yoke 6b and the third arc extinguishing yoke 6c to the vicinity of the plate-like yoke 74, and has a substantially rectangular shape. I am doing.
In addition, the configuration is the same as that of the fourth embodiment.

The effect of this example will be described.
In this example, the notch 61 is formed in the second arc-extinguishing yoke 6 b and the third arc-extinguishing yoke 6 c in the vicinity of the arc-extinguishing magnet 5, so that the magnetic flux φ is the first in the vicinity of the arc-extinguishing magnet 5. It becomes difficult to flow from the first arc-extinguishing yoke 6a to the second arc-extinguishing yoke 6b or the third arc-extinguishing yoke 6c. Therefore, the magnetic flux φ flows from the first arc extinguishing yoke 6a through the contact pairs 2a to 2d to the second arc extinguishing yoke 6b or the third arc extinguishing yoke 6c. Thereby, the magnetic flux φ passing through the contact pairs 2a to 2d can be strengthened, and the arc can be extinguished more effectively.
In addition, the same effects as those of the fourth embodiment are obtained.

(Example 6)
In this example, as shown in FIG. 14, two coils 4a and 4b are provided with electromagnetic coils 3a and 3b, respectively. In this example, the individual plungers 4a and 4b are advanced and retracted by the individual electromagnetic coils 3a and 3b.
In addition, the configuration and operational effects are the same as those of the first embodiment.

DESCRIPTION OF SYMBOLS 1 Electromagnetic relay 2 Contact pair 21 Movable contact 22 Fixed contact 3 Electromagnetic coil 4 Plunger 5 Arc-extinguishing magnet 6 Arc-extinguishing yoke 7 Coil yoke Φ Magnetic flux generated from the electromagnetic coil φ Magnetic flux generated from the arc-extinguishing magnet

Claims (6)

A plurality of contact pairs consisting of pairs of movable contacts and fixed contacts;
An electromagnetic coil that generates magnetic flux when energized;
By switching between energization and deenergization of the electromagnetic coil, the magnetic coil moves forward and backward by magnetic force, and an on state in which the movable contact contacts the fixed contact and an off state in which the movable contact is separated from the fixed contact. A plunger configured to switch;
An arc extinguishing magnet for extinguishing an arc generated in each of the plurality of contact pairs when the on state is switched to the off state;
An arc-extinguishing yoke made of a soft magnetic material and guiding magnetic flux generated from the arc-extinguishing magnet to the plurality of contact pairs ;
A coil yoke through which magnetic flux generated by energizing the electromagnetic coil flows,
A plurality of arc extinguishing yokes are provided at predetermined intervals, and a part of the arc extinguishing yokes of the plurality of arc extinguishing yokes is integrated with the coil yoke. relay. 2. The electromagnetic relay according to claim 1 , wherein one of two magnetic poles of the arc extinguishing magnet is in contact with the coil yoke, and the other magnetic pole is not integrated with the coil yoke. An electromagnetic relay characterized in that it is in contact with a yoke. 3. The electromagnetic relay according to claim 2 , wherein a direction of a current flowing through the electromagnetic coil is determined such that when the electromagnetic coil is energized, the arc-extinguishing magnet is attracted to the coil yoke. An electromagnetic relay characterized by The electromagnetic relay according to any one of claims 1 to 3, between the two above-mentioned arc-extinguishing yoke, said contact pair and, extinguishing the aforementioned arc elongated fall by the flux A gap between the two arc-extinguishing yokes in the vicinity of the contact pair is narrower than a gap between the two arc-extinguishing yokes in the arc extinguishing chamber. Characteristic electromagnetic relay. The electromagnetic relay according to any one of claims 1 to 4, a switch unit for switching on and off of current flowing through the two have the contact pair the two contact pairs, to the switch unit An electromagnetic relay characterized in that the arc generated at each of the two contact pairs included is extended in the same direction by a magnetic flux guided by the arc-extinguishing yoke and extinguished.   A plurality of contact pairs consisting of pairs of movable contacts and fixed contacts;
  An electromagnetic coil that generates magnetic flux when energized;
  By switching between energization and deenergization of the electromagnetic coil, the magnetic coil moves forward and backward by magnetic force, and an on state in which the movable contact contacts the fixed contact and an off state in which the movable contact is separated from the fixed contact. A plunger configured to switch;
  An arc extinguishing magnet for extinguishing an arc generated in each of the plurality of contact pairs when the on state is switched to the off state;
  An arc-extinguishing yoke made of a soft magnetic material and guiding the magnetic flux generated from the arc-extinguishing magnet to the plurality of contact pairs;
  The arc extinguishing yoke includes a first arc extinguishing yoke, a second arc extinguishing yoke, and a third arc extinguishing yoke,
  The first arc-extinguishing yoke is disposed between the two contact pairs, and the second arc-extinguishing yoke and the position of the two contact pairs are sandwiched in the arrangement direction of the two contact pairs. An electromagnetic relay, wherein a third arc extinguishing yoke is arranged.

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