JP2017139194A - Electromagnetic relay - Google Patents

Abstract

An electromagnetic relay capable of suppressing abnormal noise is provided. An electromagnetic relay includes a fixed contact, a movable contact, a mover, a coil, an armature, and a transmission spring. The movable contact 14 moves between a closed position in contact with the fixed contact 13 and an open position away from the fixed contact 13. The movable element 15 is provided with a movable contact 14 at a first end 153 in one direction, and moves the movable contact 14 between a closed position and an opened position with a second end 154 opposite to the first end 153 as a fulcrum. Let The armature 6 drives the mover 15 by magnetic flux generated by energization of the coil 2. The transmission spring 8 is provided between the armature 6 and the mover 15 and transmits a force between the armature 6 and the mover 15. The transmission spring 8 contacts the armature 6 in an elastically deformed state when the movable contact 14 is in the open position. [Selection] Figure 1

Description

  The present invention generally relates to an electromagnetic relay, and more particularly to an electromagnetic relay that opens and closes a contact using a magnetic attractive force generated by energization of a coil.

  Conventionally, relays (electromagnetic relays) such as latching relays are known and disclosed in, for example, Patent Document 1. In the relay described in Patent Document 1, when the coil is excited, the armature rotates due to the magnetic attraction generated between the stator attracting portion and the armature attracting piece, and the armature driving piece is contacted. By pressing the spring (mover), the movable contact contacts the fixed contact and the contact closes. In the relay described in Patent Document 1, when the coil is excited in the reverse direction, the armature returns to the original state, the movable contact is separated from the fixed contact, and the contact is opened.

JP 2006-278057 A

  However, the conventional example has a problem that when the contact is opened and the mover returns to the original state, the mover vibrates and abnormal noise (reverberation) may occur.

  This invention is made | formed in view of said point, and it aims at providing the electromagnetic relay which can suppress abnormal noise.

  An electromagnetic relay according to a first aspect of the present invention includes a fixed contact, a closed position that contacts the fixed contact, a movable contact that moves between an open position away from the fixed contact, and a first end in one direction. The movable contact is provided, and a movable element for moving the movable contact between the closed position and the open position with a second end opposite to the first end as a fulcrum, a coil, and the coil An armature that drives the mover by magnetic flux generated by energization, and a transmission spring that is provided between the armature and the mover and transmits a force between the armature and the mover. The transmission spring is in contact with the armature in an elastically deformed state when the movable contact is in the open position.

  In the electromagnetic relay according to the second aspect of the present invention, in the first aspect, it is preferable that the transmission spring is attached to the movable element.

  In the electromagnetic relay according to a third aspect of the present invention, in the second aspect, it is preferable that the transmission spring is attached to the first end of the movable element.

  The electromagnetic relay of the 4th form of this invention is further equipped with the bobbin by which the electric wire which comprises the said coil is wound in any one of the 1st-3rd form, and the return spring attached to the said armature. The return spring is configured to return the armature from a first state in which the contactor closes the movable element to a second state in which the armature opens the movable element by an elastic force. Preferably, the bobbin further includes a limiting wall that comes into contact with the return spring in an elastically deformed state when the armature is in the second state.

  In the present invention, since the transmission spring functions as a damper, the mover can be decelerated to suppress the vibration of the mover. For this reason, this invention can converge the vibration of a needle | mover at an early stage, and can suppress the noise which may be generated by the vibration of a needle | mover.

FIG. 1 is a cross-sectional view of an electromagnetic relay according to an embodiment of the present invention. FIG. 2A is a cross-sectional view showing a part of the electromagnetic relay same as above and showing an ON state of the contact device. FIG. 2B is a cross-sectional view showing a part of the electromagnetic relay same as above and showing an OFF state of the contact device. FIG. 3 is an exploded perspective view of the electromagnetic relay. FIG. 4 is a perspective view of a part of the armature in the electromagnetic relay same as above. FIG. 5A is a perspective view of a transmission spring in the electromagnetic relay. FIG. 5B is a perspective view of a mover to which a transmission spring is attached in the electromagnetic relay same as above. FIG. 6A is a cross-sectional view showing a part of the electromagnetic relay same as above and showing an ON state of the contact device. FIG. 6B is a cross-sectional view showing a part of the electromagnetic relay same as above and showing an OFF state of the contact device.

  As shown in FIGS. 1 to 3, the electromagnetic relay 100 according to the embodiment of the present invention includes a fixed contact 13, a movable contact 14, a mover 15, a coil 2, an armature 6, and a transmission spring 8. It has. The movable contact 14 moves between a closed position in contact with the fixed contact 13 and an open position away from the fixed contact 13. The movable element 15 is provided with a movable contact 14 at a first end 153 in one direction, and moves the movable contact 14 between a closed position and an opened position with a second end 154 opposite to the first end 153 as a fulcrum. Let The armature 6 drives the mover 15 by magnetic flux generated by energization of the coil 2.

  The transmission spring 8 is provided between the armature 6 and the mover 15 and transmits a force between the armature 6 and the mover 15. The transmission spring 8 contacts the armature 6 in an elastically deformed state when the movable contact 14 is in the open position.

  Hereinafter, the electromagnetic relay 100 according to the present embodiment will be described in detail. However, the configuration described below is only an example of the present invention, and the present invention is not limited to the following embodiment, and the technical idea according to the present invention is not deviated from this embodiment. Various changes can be made in accordance with the design or the like as long as they are not.

  In the following description, in FIG. 1, the direction in which the fixed contact 13 and the movable contact 14 are arranged will be referred to as the up-down direction, and the movable contact 14 side as viewed from the fixed contact 13 will be referred to as the upper side. Further, in the following, in FIG. 1, the direction in which the first terminal plate 11 and the second terminal plate 12 (described later) are arranged in the left-right direction, and the second terminal plate 12 side as viewed from the first terminal plate 11 is on the right side. The reverse is described as the left side.

  1 and 3 show arrows indicating these directions (up, down, left, and right). These arrows are merely described for the purpose of assisting the explanation, and the substance is Not accompanied. Further, the definition of the direction is not intended to limit the usage pattern of the electromagnetic relay 100 of the present embodiment.

  In the present embodiment, the case where the electromagnetic relay 100 is mounted on an automobile having an idling stop function is taken as an example. In this embodiment, the electromagnetic relay 100 is connected and used so as to insert a contact device A1 (described later) into a DC power supply path from a traveling battery to a load (for example, an LED lamp or an inverter). For example, For this reason, in the electromagnetic relay 100 of this embodiment, the supply state of the DC power from the battery to the load can be switched by opening and closing the contact device A1.

  The electromagnetic relay 100 of this embodiment is a so-called hinge type relay. As shown in FIGS. 1 and 3, the electromagnetic relay 100 of the present embodiment includes a contact device A1, a drive device B1, and a case C1.

  As shown in FIGS. 1 and 3, the contact device A <b> 1 includes a pair of terminal plates 1, a pair of fixed contacts 13, a pair of movable contacts 14, and a movable element 15. Hereinafter, the left terminal board 1 of the pair of terminal boards 1 is referred to as a “first terminal board 11”, and the right terminal board 1 is referred to as a “second terminal board 12”.

  The first terminal board 11 is formed in a flat plate shape that is long in the left-right direction from a conductive material (for example, copper (Cu)). As shown in FIG. 3, a pair of mounting holes 111 penetrating in the thickness direction (up and down direction) is provided in the middle portion of the first terminal board 11 in the longitudinal direction (left and right direction). The shaft portions 131 of the pair of fixed contacts 13 are inserted into the pair of mounting holes 111, respectively. The pair of fixed contacts 13 are attached to the first terminal plate 11 by caulking each shaft portion 131 to the first terminal plate 11. The pair of fixed contacts 13 may be configured integrally with the first terminal board 11.

  The second terminal board 12 is formed in a flat plate shape that is long in the left-right direction from a conductive material (for example, copper (Cu)). A pair of fixing holes 121 penetrating in the thickness direction (vertical direction) is provided in an intermediate portion in the longitudinal direction (left-right direction) of the second terminal board 12. The pair of fixing holes 121 are used to fix the mover 15 to the second terminal plate 12.

  The first terminal plate 11 and the second terminal plate 12 have a first terminal portion 112 and a second terminal portion 122, respectively. The first terminal portion 112 is formed in a rectangular plate shape, and protrudes upward from one end (left end) in the longitudinal direction of the first terminal plate 11. The second terminal portion 122 is formed in a rectangular plate shape, and protrudes upward from one end (right end) in the longitudinal direction of the second terminal plate 12. The first terminal portion 112 and the second terminal portion 122 are provided with a first terminal hole 113 and a second terminal hole 123 into which screws or the like are inserted, respectively. The 1st terminal part 112 and the 2nd terminal part 122 are electrically connected to the electric circuit which connects a battery and load, for example by screwing.

  The mover 15 is formed in a plate shape that is long in the left-right direction from a conductive material. In the present embodiment, the mover 15 is configured by overlapping a plurality of (here, three) leaf springs along the vertical direction. A first end (left end) 153 in the longitudinal direction of the mover 15 is provided with a pair of attachment holes 152 penetrating in the thickness direction (vertical direction). The shaft portions 141 of the pair of movable contacts 14 are inserted into the pair of mounting holes 152, respectively. A pair of movable contacts 14 are attached to the movable element 15 by caulking each shaft portion 141 to the movable element 15. That is, a pair of movable contacts 14 is provided at a first end (left end) 153 in one direction (longitudinal direction) of the mover 15. The pair of movable contacts 14 may be integrated with the movable element 15.

  A second end (right end) 154 in the longitudinal direction of the mover 15 is provided with a pair of fixing holes 151 penetrating in the thickness direction (vertical direction). The second end 154 of the mover 15 is fixed to the second terminal plate 12. Specifically, the pair of fixed holes 151 of the mover 15 are overlapped with the pair of fixed holes 121 of the second terminal plate 12, and pins are inserted into the fixed holes 151, 121 for caulking, thereby moving the mover. 15 is fixed to the second terminal board 12.

  The mover 15 is bent on the second end (right end) 154 side in the longitudinal direction so that the first end (left end) 153 in the longitudinal direction faces the first terminal board 11 with a gap in the vertical direction. It is configured. Therefore, the pair of movable contacts 14 of the mover 15 faces the pair of fixed contacts 13 of the first terminal board 11 in the vertical direction.

  The mover 15 is driven by the driving device B1 so that the pair of movable contacts 14 are set to a closed position and an open position with a second end (right end) 154 opposite to the first end (left end) 153 as a fulcrum. Move between. Here, the closed position is a position where the pair of movable contacts 14 contacts the pair of fixed contacts 13 (see FIG. 2A). The open position is a position where the pair of movable contacts 14 are separated from the pair of fixed contacts 13 (see FIG. 2B).

  When the pair of movable contacts 14 are in the closed position, that is, in the ON state of the contact device A1, the first terminal plate 11 and the second terminal plate 12 are short-circuited via the movable element 15. Therefore, when the contact device A1 is in the ON state, the first terminal plate 11 and the second terminal plate 12 are electrically connected, and DC power is supplied from the battery to the load. When the pair of movable contacts 14 are in the open position, that is, in the OFF state of the contact device A1, the space between the first terminal plate 11 and the second terminal plate 12 is opened, so that no DC power is supplied from the battery to the load. .

  As shown in FIGS. 1 and 3, the drive device B <b> 1 includes a coil 2, a bobbin 3, a stator 4, a yoke 5, an armature 6, a return spring 7, and a transmission spring 8. Yes. The stator 4, the yoke 5, and the armature 6 are all made of a magnetic material.

  The coil 2 is configured by winding an electric wire (for example, a copper wire) around the outer peripheral surface of the bobbin 3. The coil 2 includes a pair of coil terminals 21 to which the first end and the second end of the electric wire are electrically connected. The coil 2 is energized by being supplied with current through a pair of coil terminals 21 and generates magnetic flux. The bobbin 3 is formed in a cylindrical shape from a material having electrical insulation properties such as a synthetic resin material. The bobbin 3 is disposed such that its axial direction coincides with the left-right direction.

  The stator 4 is an iron core formed in a cylindrical shape that is long in the left-right direction. The stator 4 is inserted into the hollow portion 31 of the bobbin 3 such that both ends in the longitudinal direction (left-right direction) are exposed from the bobbin 3. The first end (right end) in the longitudinal direction of the stator 4 is larger in diameter than the intermediate portion and faces the armature 6. Hereinafter, the first end of the stator 4 is referred to as a “suction part 41”. The second end (left end) in the longitudinal direction of the stator 4 has a diameter smaller than that of the intermediate portion, and is fixed to a first plate 51 (described later) of the yoke 5.

  The yoke 5 together with the stator 4 and the armature 6 forms a magnetic path through which the magnetic flux generated when the coil 2 is energized passes. The yoke 5 is formed such that its cross section is L-shaped by bending an intermediate portion of a rectangular plate that is long in the left-right direction. The yoke 5 has a first plate 51 and a second plate 52. Both the first plate 51 and the second plate 52 are formed in a rectangular plate shape. The first plate 51 is provided on one end side (left side) of the coil 2 in the axial direction (left-right direction). The first plate 51 is provided with an insertion hole 511 penetrating in the thickness direction (left-right direction). The second end of the stator 4 is inserted into the insertion hole 511. The second plate 52 is provided below the coil 2.

  The armature 6 is formed so that its cross section is L-shaped by bending an intermediate portion 63 of a rectangular plate that is long in the left-right direction. The armature 6 has a first plate 61 and a second plate 62. Both the first plate 61 and the second plate 62 are formed in a rectangular plate shape. The dimension in the width direction of the first plate 61 is smaller than the dimension in the width direction of the second plate 62. Here, the width direction is a direction substantially orthogonal to both the vertical direction and the horizontal direction.

  As shown in FIGS. 1 and 4, the first plate 61 of the armature 6 includes a protrusion 611. The protrusion 611 protrudes downward from one surface (lower surface) of the first plate 61 facing the mover 15. Further, the protrusion 611 is formed integrally with the first plate 61. One surface of the protrusion 611 facing the movable element 15 is formed in a spherical shape.

  The armature 6 has a first position where the second plate 62 contacts the suction portion 41 of the stator 4 and a second position where the second plate 62 moves away from the suction portion 41 of the stator 4 with the intermediate portion 63 as a fulcrum. It is comprised so that rotation is possible. When the armature 6 is in the first position, the first plate 61 of the armature 6 pushes the mover 15 via the transmission spring 8. When the armature 6 is in the second position, the first plate 61 of the armature 6 is pressed from the mover 15 via the transmission spring 8. That is, it can be said that the armature 6 is configured to be rotatable between a first state where the mover 15 is in the closed position and a second state where the mover 15 is in the open position.

  The return spring 7 is formed from a metal leaf spring so that its cross section is L-shaped. The return spring 7 is configured by integrally forming a pair of first pieces 71 and second pieces 72. The pair of first pieces 71 are both fixed to the second plate 52 of the yoke 5. The second piece 72 is fixed to the second plate 62 of the armature 6. The return spring 7 is configured to bend when the armature 6 is in the first position. The return spring 7 causes the armature 6 to be applied with a force in a direction to move the armature 6 from the first position to the second position by returning to the original state.

  That is, the return spring 7 is configured to cause the armature 6 to act on the armature 6 in a direction to move the armature 6 from the first position to the second position by an elastic force. In other words, the return spring 7 is configured to act on the armature 6 with a force in a direction to move the armature 6 from the first state to the second state by an elastic force.

  The transmission spring 8 is provided between the armature 6 and the mover 15 and transmits a force between the armature 6 and the mover 15. That is, in the present embodiment, force is transmitted from the armature 6 to the mover 15 via the transmission spring 8, and force is transmitted from the mover 15 to the armature 6 via the transmission spring 8.

  As shown in FIGS. 5A and 5B, the transmission spring 8 is formed in a U shape in plan view from a plate spring made of metal such as stainless steel (SUS). The transmission spring 8 is configured by integrally forming a pair of attachment pieces 81 and a connecting piece 82. Each of the pair of attachment pieces 81 and connection pieces 82 is formed in a rectangular shape.

  Each of the pair of attachment pieces 81 is provided with a hole 811 penetrating in the thickness direction (vertical direction). In the present embodiment, the pair of attachment pieces 81 are attached to the mover 15 by inserting and caulking the shaft portions 141 of the pair of movable contacts 14 into the holes 811. Note that the pair of attachment pieces 81 may not be attached together with the pair of movable contacts 14. That is, the transmission spring 8 may be attached to a part of the movable element 15 that is different from the part to which the pair of movable contacts 14 are attached.

  The connecting piece 82 connects the ends in the longitudinal direction of the pair of attachment pieces 81. Here, the connecting piece 82 is bent upward along a connecting portion 83 with each of the pair of attachment pieces 81. Therefore, the connecting piece 82 can be bent with the connecting portion 83 as a fulcrum. The connecting piece 82 faces the first plate 61 of the armature 6 with the pair of attachment pieces 81 attached to the mover 15. The connecting piece 82 is in contact with the protrusion 611 of the armature 6.

  The case C1 is made of, for example, an electrically insulating material such as ceramic or synthetic resin, or stainless steel (SUS). The case C1 is configured by joining the base C11 and the cover C12 by, for example, welding, brazing, adhesion using a thermosetting resin adhesive, or the like. Case C1 accommodates contact device A1 and drive device B1. As shown in FIG. 1, in the contact device A1, the first terminal portion 112 of the first terminal plate 11 and the second terminal portion 122 of the second terminal plate 12 are exposed from the case C1. Further, as shown in FIG. 1, a part of each of the pair of coil terminals 21 in the driving device B1 is exposed from the case C1.

  Hereinafter, operation | movement of the electromagnetic relay 100 of this embodiment is demonstrated using FIG. 2A and FIG. 2B. In the following description, the state of the mover 15 in the OFF state of the contact device A1 is referred to as “original state”. When the coil 2 is energized in the OFF state of the contact device A1, the coil 2 generates a magnetic flux. Then, a magnetic attraction force is generated between the second plate 62 of the armature 6 and the attraction portion 41 of the stator 4, so that the second plate 62 is attracted to the attraction portion 41 against the elastic force of the return spring 7. It is done. As a result, the armature 6 rotates counterclockwise and moves from the second position to the first position.

  As the armature 6 moves to the first position, the first plate 61 (here, the protrusion 611) of the armature 6 pushes the connecting piece 82 of the transmission spring 8. Then, the transmission spring 8 transmits a force from the armature 6 to the mover 15. The mover 15 receives the force from the transmission spring 8 and is pushed downward to rotate counterclockwise with the second end (right end) 154 as a fulcrum. And a pair of movable contact 14 moves to the closed position which contacts a pair of fixed contact 13 (refer FIG. 2A). Therefore, the contact device A1 is turned on, and the first terminal plate 11 and the second terminal plate 12 are electrically connected.

  Next, when the energization of the coil 2 is released, the coil 2 does not generate a magnetic flux. Then, the magnetic attraction force between the second plate 62 of the armature 6 and the attraction portion 41 of the stator 4 is also lost. The armature 6 rotates clockwise by the elastic force of the return spring 7 and moves from the first position to the second position.

  As the armature 6 moves to the second position, the force with which the first plate 61 of the armature 6 pushes the mover 15 via the transmission spring 8 is weakened. For this reason, the mover 15 rotates clockwise with the second end (right end) 154 as a fulcrum by its own elastic force. Then, the pair of movable contacts 14 moves to an open position away from the pair of fixed contacts 13 (see FIG. 2B).

  When the armature 6 returns to the second position and the movement of the armature 6 is completed, the armature 6 is fixed at the second position. For this reason, the connecting piece 82 of the transmission spring 8 is elastically deformed by being sandwiched between the first plate 61 of the armature 6 and the movable element 15. That is, the transmission spring 8 contacts the armature 6 (here, the protrusion 611) in an elastically deformed state with the pair of movable contacts 14 in the open position.

  Then, the elastic force which the connection piece 82 of the transmission spring 8 tries to return to the original state acts on the movable element 15, so that the movable element 15 is decelerated. For this reason, the vibration of the mover 15 is suppressed by the transmission spring 8 and converges, and the movement of the mover 15 is completed.

  As described above, the electromagnetic relay 100 according to the present embodiment includes the transmission spring 8 that is provided between the armature 6 and the mover 15 and transmits a force between the armature 6 and the mover 15. . The transmission spring 8 is in contact with the armature 6 in an elastically deformed state with the pair of movable contacts 14 in the open position. That is, in the electromagnetic relay 100 of the present embodiment, when the contact device A1 shifts from the on state to the off state, the transmission spring 8 functions as a damper, so that the mover 15 is decelerated to vibrate the mover 15. Can be suppressed. For this reason, the electromagnetic relay 100 of this embodiment can converge the vibration of the needle | mover 15 at an early stage, when contact apparatus A1 transfers to an OFF state from an ON state. As a result, the electromagnetic relay 100 of the present embodiment can suppress abnormal noise (reverberation) that can be generated by vibration of the mover 15.

  Moreover, in the electromagnetic relay 100 of this embodiment, the relative positional relationship between the armature 6 and the mover 15 is easily stabilized by the transmission spring 8. For this reason, the electromagnetic relay 100 of this embodiment can improve the tolerance with respect to the vibration and impact of contact device A1 compared with the structure which is not provided with the transmission spring 8, and stabilizes the operating characteristic of contact device A1. You can plan. Furthermore, when the electromagnetic relay 100 according to the present embodiment is mounted on an electric vehicle, for example, vibration during traveling of the electric vehicle is difficult to be transmitted to the armature 6 and the mover 15 by the transmission spring 8. Abnormal noise due to vibration of the mover 15 is unlikely to occur.

  In the electromagnetic relay 100 of this embodiment, the transmission spring 8 is attached to the mover 15. Further, the transmission spring 8 may be attached to the armature 6 instead of the mover 15. In this case, the connecting piece 82 of the transmission spring 8 is attached to the first plate 61 of the armature 6. Further, the transmission spring 8 may be attached to either the mover 15 or the armature 6. In this case, the pair of attachment pieces 81 of the transmission spring 8 are attached to the mover 15, and the connection piece 82 is attached to the first plate 61 of the armature 6.

  Further, in the electromagnetic relay 100 of the present embodiment, the transmission spring 8 is attached to the first end (left end) 153 of the mover 15. That is, the transmission spring 8 is attached to the first end (left end) 153 having the largest deflection width among the movers 15 that rotate with the second end (right end) 154 as a fulcrum. In this configuration, the vibration of the first end 153 of the mover 15 can be suppressed, so that the vibration of the mover 15 can be more effectively accelerated compared to the case where the transmission spring 8 is attached in the middle of the mover 15. Can be converged. In particular, the transmission spring 8 is preferably attached to a region between the tip and the portion where the movable contact 14 is attached, in the first end 153 of the mover 15. Whether or not to adopt the above configuration is arbitrary.

  Here, in the electromagnetic relay 100 of the present embodiment, the armature 6 is in the second position (second state) in addition to the configuration that suppresses the vibration of the movable element 15 when the pair of movable contacts 14 are in the open position. The structure which suppresses the vibration of the armature 6 sometimes is further provided. Hereinafter, a configuration for suppressing the vibration of the armature 6 will be described.

  As a configuration for suppressing the vibration of the armature 6, the return spring 7 includes an extension piece 73 and a protrusion 74 as shown in FIGS. 6A and 6B. The extension piece 73 is formed integrally with the second piece 72 and protrudes upward from one end in the longitudinal direction (vertical direction) of the second piece 72. The protrusion 74 protrudes rightward from the extension piece 73. Further, the protrusion 74 is formed integrally with the extension piece 73.

  Further, as a configuration for suppressing the vibration of the armature 6, the bobbin 3 includes a limiting wall 32 as shown in FIGS. 6A and 6B. The limiting wall 32 is formed integrally with the bobbin 3 and protrudes rightward from one end (right end) in the longitudinal direction of the bobbin 3. The limiting wall 32 is formed so as to cover the extension piece 73 of the return spring 7. Further, the protrusion 74 of the return spring 7 faces the inner wall 321 of the limiting wall 32. One surface of the protrusion 74 facing the inner wall 321 is formed in a spherical shape.

  Hereinafter, operation | movement of the electromagnetic relay 100 of this embodiment is demonstrated using FIG. 6A and FIG. 6B. In the ON state of the contact device A1, the armature 6 is in the first position (first state). In the ON state of the contact device A 1, the second piece 72 of the return spring 7 is attracted to the suction portion 41 of the stator 4 together with the second plate 62 of the armature 6. Therefore, the extension piece 73 formed integrally with the second piece 72 is located away from the inner wall 321 of the restriction wall 32 as shown in FIG. 6A.

  Next, when the energization of the coil 2 is released, the contact device A1 shifts from the on state to the off state. Then, the armature 6 moves from the first position (first state) to the second position (second state). At this time, the second piece 72 of the return spring 7 rotates clockwise together with the second plate 62 of the armature 6. Accordingly, the extension piece 73 formed integrally with the second piece 72 also rotates clockwise. Then, as shown in FIG. 6B, the extension piece 73 is elastically deformed by the protrusion 74 coming into contact with the inner wall 321 of the restriction wall 32. That is, when the armature 6 is in the second position (second state), the return spring 7 (here, the extension piece 73) contacts the limiting wall 32 (here, the inner wall 321) in an elastically deformed state.

  Then, the elastic force that the return spring 7 (extension piece 73) tries to return to the original state acts on the armature 6 to decelerate the armature 6. For this reason, the vibration of the armature 6 is suppressed by the return spring 7 and converges, and the movement of the armature 6 is completed.

  As described above, the electromagnetic relay 100 according to this embodiment further includes the bobbin 3 around which the electric wire constituting the coil 2 is wound, and the return spring 7 attached to the armature 6. The return spring 7 is adapted to move the armature 6 by the elastic force from the first state in which the armature 6 places the mover 15 in the closed position to the second state in which the armature 6 places the mover 15 in the open position. A force is applied to the armature 6. The bobbin 3 further includes a limiting wall 32 that contacts the return spring 7 in an elastically deformed state when the armature 6 is in the second state.

  For this reason, in the electromagnetic relay 100 of the present embodiment, when the contact device A1 shifts from the on state to the off state, the return spring 7 functions as a damper, so that the armature 6 is decelerated to vibrate the armature 6. Can be suppressed. For this reason, the electromagnetic relay 100 of this embodiment can converge the vibration of the armature 6 early when the contact device A1 shifts from the on state to the off state. As a result, the electromagnetic relay 100 of the present embodiment can suppress abnormal noise (reverberation) that can be generated by the vibration of the armature 6. Moreover, in the electromagnetic relay 100 of this embodiment, since the limiting wall 32 is formed integrally with the bobbin 3, it is not necessary to add a new part in order to suppress the vibration of the armature 6.

  In the present embodiment, the limiting wall 32 is formed so as to cover one end (extension piece 73) of the return spring 7, but may have other shapes. In other words, the limiting wall 32 may have a shape that makes contact with the return spring 7 in an elastically deformed state at least when the armature 6 is in the second state. Whether or not to adopt the above configuration is arbitrary.

  Here, in order to suppress the cutting of the limiting wall 32, it is preferable that the tip of the extension piece 73 does not contact the limiting wall 32. In order to realize this configuration, it is conceivable to widen the space inside the limiting wall 32, but the limiting wall 32 becomes large. Therefore, in the present embodiment, an opening 322 is provided on the distal end side of the extension piece 73 of the restriction wall 32 so that the distal end of the extension piece 73 does not contact the restriction wall 32. For this reason, the electromagnetic relay 100 of this embodiment can avoid the front-end | tip of the extension piece 73 contacting the restriction wall 32, avoiding the enlargement of the restriction wall 32. FIG. Note that whether or not to adopt the configuration is arbitrary.

  By the way, in this embodiment, in a state where the pair of movable contacts 14 are in the open position, the portion (connecting piece 82) that contacts the armature 6 of the transmission spring 8 has a gap with the mover 15. However, this gap may not be present. That is, in a state where the pair of movable contacts 14 are in the open position, the connecting piece 82 of the transmission spring 8 may be in contact with the movable element 15.

  In the present embodiment, the protrusion 611 of the armature 6 has a spherical surface that contacts the transmission spring 8. In this configuration, the armature 6 can be prevented from being scraped by the transmission spring 8 coming into contact with the armature 6. In addition, the shape of the surface which contacts the transmission spring 8 of the protrusion 611 is not limited to a spherical shape, and may be another shape. In the present embodiment, the protrusion 611 is in contact with the transmission spring 8, but the transmission spring 8 may be in direct contact with the armature 6. In this case, the protrusion 611 of the armature 6 is unnecessary.

  In the present embodiment, the protrusion 74 of the return spring 7 has a spherical surface that contacts the restriction wall 32. In this configuration, it is possible to prevent the limit wall 32 from being scraped when the return spring 7 contacts the limit wall 32. In addition, the shape of the surface which contacts the restriction | limiting wall 32 of the protrusion 74 is not limited to spherical shape, Other shapes may be sufficient. In the present embodiment, the protrusion 74 is in contact with the restriction wall 32, but the extension piece 73 of the return spring 7 may be in direct contact with the restriction wall 32. In this case, the protrusion 74 of the return spring 7 is not necessary.

  Moreover, in the electromagnetic relay 100 of this embodiment, although the contact apparatus A1 is provided with a pair of fixed contact 13 and a pair of movable contact 14, another structure may be sufficient. For example, the contact device A <b> 1 may include one fixed contact 13 and one movable contact 14. Further, the contact device A1 may include three or more fixed contacts 13 and three or more movable contacts 14.

  Moreover, the electromagnetic relay 100 of this embodiment can be used for any of a contact relay, b contact relay, and c contact relay. For example, when the electromagnetic relay 100 is used as a c-contact relay, a fixed contact that contacts when the movable contact 14 is in the open position may be provided separately from the fixed contact 13. In this configuration, depending on whether the coil 2 is energized or de-energized, an electric circuit connected to the fixed contact 13 where the movable contact 14 contacts in the closed position, and an electric circuit connected to the fixed contact where the movable contact 14 contacts in the open position. And can be switched.

DESCRIPTION OF SYMBOLS 13 Fixed contact 14 Movable contact 15 Movable element 153 1st end 154 2nd end 2 Coil 3 Bobbin 32 Limit wall 6 Armature 7 Return spring 8 Transmission spring 100 Electromagnetic relay

Claims (4)

A fixed contact;
A movable contact that moves between a closed position in contact with the fixed contact and an open position away from the fixed contact;
A movable element provided with the movable contact at a first end in one direction, and moving the movable contact between the closed position and the open position with a second end opposite to the first end as a fulcrum;
Coils,
An armature that drives the mover by magnetic flux generated by energization of the coil;
A transmission spring that is provided between the armature and the mover and transmits a force between the armature and the mover;
The electromagnetic relay according to claim 1, wherein the transmission spring contacts the armature in an elastically deformed state when the movable contact is in the open position.   The electromagnetic relay according to claim 1, wherein the transmission spring is attached to the mover.   The electromagnetic relay according to claim 2, wherein the transmission spring is attached to the first end of the mover. A bobbin around which an electric wire constituting the coil is wound;
A return spring attached to the armature;
The return spring has a direction in which the armature moves the armature from a first state in which the armature closes the mover to a second state in which the armature opens the mover by an elastic force. A force is applied to the armature;
4. The bobbin according to claim 1, further comprising a limiting wall that contacts the return spring in an elastically deformed state when the armature is in the second state. 5. Electromagnetic relay.

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