JP2006210123A - Polarized electromagnetic relay - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a polarized electromagnetic relay which enables the automation of the wiring and soldering of a coil lead line, and reduce the size of the relay. <P>SOLUTION: Coil wiring connection nodes of coil terminals 10, 11, and 16 are arranged on almost the same plane so as not to disturb the winding of a coil. This allows the automatic winding of the coil around a trunk 9c on a coil bobbin 9 and the automatic wiring of the coil lead line to each coil connection node. The coil wiring connection nodes of two coil terminals 10 and 16 are protruded from an end surface S1 in the same direction. This enables the automated soldering of a wired portion and the simultaneous soldering of two coil lead lines. As a result, effective soldering work is achieved with less posture change processes of the coil bobbin 9 compared with the soldering individual three coil lead lines. In addition, the coil wiring connection nodes 11b, 10b, and 16b are protruded from inclined end surfaces S1 and S2. This can provide the smaller-sized polarized electromagnetic relay by the effective use of corner spaces of the base 1 with the contour of a rectangular shape. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a polarized electromagnetic relay for opening and closing an electric circuit.

  Conventionally, a polarized electromagnetic relay generally has an electromagnet block and a contact mechanism that opens and closes according to the excitation state of the electromagnet block. The electromagnet block has an iron core inserted therein and a coil wound around the outside. It has a coil bobbin, and this coil bobbin has a coil terminal to which a lead wire of the coil is connected (see, for example, Patent Document 1).

  This type of polarized electromagnetic relay will be described with reference to FIGS. As shown in FIG. 7, the polarized electromagnetic relay includes an electromagnet block 2, contact mechanisms 3 and 4, an armature block 5, and a movable insulator 14 on a base 1. The electromagnet block 2 has an iron core 8 attached to the inner center of a U-shaped yoke 7 and constitutes an E-shaped magnetic path. The free end of the iron core 8 becomes the central magnetic pole portion 8a, and both ends of the yoke become the opposing magnetic pole portions 7a and 7b facing each other with the central magnetic pole portion 8a therebetween. The central magnetic pole portion 8a and the opposing magnetic pole portions 7a and 7b have opposite polarities due to excitation of a coil (not shown). The iron core 8 is inserted into the center hole 9 a of the coil bobbin 9, and both legs of the yoke 7 are inserted into the flange 9 b on the fixed end side of the iron core 8 of the coil bobbin 9. The flange portion 9b is provided with coil terminals 10 and 11 to which coil lead wires are connected. The coil terminal 16 is connected to a lead wire of a coil for latching, and is attached to the coil bobbin 9 after winding the coil. The coil is wound around the body portion 9 c of the coil bobbin 9.

  The contact mechanisms 3 and 4 are disposed on the coil side of the electromagnet block 2. Each of the contact mechanisms 3 and 4 includes fixed contacts 31 and 41 and movable contacts 32 and 42 that can be opened and closed with these. The fixed contacts 31 and 41 are carried on the fixed contact terminals 33 and 43. The movable contacts 32, 42 are carried by one end of the movable springs 34, 44, and the other ends are carried by the movable contact terminals 35, 45. The fixed contact terminals 33 and 43 and the movable contact terminals 35 and 45 are supported by the base 1.

  In the armature block 5, the armatures 12, 12 made of two magnetic materials form a U-shaped magnetic path with the permanent magnet 13 sandwiched from the magnetization direction, and are attached to one end of the movable insulator 14. In this armature block 5, the two armatures 12 forming the U-shaped magnetic path have gaps in the E-shaped magnetic path formed by the opposed magnetic pole portions 7a and 7b and the central magnetic pole portion 8a of the electromagnet block 2. To be combined with the electromagnet block 2. The movable insulator 14 has movable contact springs 34 and 44 sandwiched between both wings thereof, and a bearing hole 14a is pivotally supported by the rotation shaft 1c of the base 1 so as to be rotatable. The base 1 includes a tunnel 1a. The tunnel 1a is formed of an integrally formed insulating wall 1b, and opens at one end in the longitudinal direction (front side in FIG. 7), and opens at the other end (back). The electromagnet block 2 is accommodated in the tunnel 1a so that the opposing magnetic pole portions 7a and 7b and the central magnetic pole portion 8a face the lower surface opening. After the electromagnet block 2 and other parts are mounted on the base 1, the base 1 is covered with a cover 15. After covering the cover 15, a sealing resin is applied to the lower surface side of the base 1 and cured.

  In the above configuration, when the coil is not energized, the armature block 5 includes, for example, one armature 12 at the opposing magnetic pole portion 7a, the other armature 12 at the central magnetic pole portion 8a, and the magnetic flux of the permanent magnet 13. Is adsorbed by. At this time, the movable contact 32 is closed to the fixed contact 31, and the movable contact 42 is separated from the fixed contact 41. Now, when the coil is energized and the opposing magnetic pole portions 7a, 7b are excited to the N pole and the central magnetic pole portion 8a is excited to the S pole, the armature block 5 rotates around the shaft 1c together with the movable insulator 14, One armature 12 is in contact with the central magnetic pole portion 8a, and the other armature 12 is in contact with the opposing magnetic pole portion 7b. This movement is transmitted to the contact mechanisms 3 and 4 by the movable insulator 14, the movable contact 32 is separated from the fixed contact 31, and the movable contact 42 is closed to the fixed contact 41. Even if the excitation of the coil is stopped, this state is maintained by the magnetic flux of the permanent magnet 13. In this state, when the coil is energized and excited with a polarity opposite to that described above, the armature block 5 rotates in the opposite direction as described above, and the armatures 12 and 12 return to the original positions. Return to the state.

Here, the process of connecting the coil lead wire to the plurality of coil terminals 10, 11, 16 of the coil bobbin 9 will be described. As shown in FIG. 8A, the coil terminal 16 is not integrally formed with the coil bobbin 9, but is a separate part. This is due to the following reason. Of the terminal portions 10 a, 11 a, and 16 a that are parts connected to an external circuit (not shown), the terminal portion 16 a of the coil terminal 16 is disposed inward of the coil bobbin 9. This is to reduce the size of the device and the electromagnetic relay on which the electromagnetic relay is mounted by not arranging the terminal portions on a straight line. However, if the coil terminal 16 is provided on the coil bobbin 9 before the step of winding the coil wire around the coil bobbin 9 by the winding machine, it is difficult to automatically wind the coil by the winding machine because the terminal portion 16a becomes an obstacle. become. Therefore, the coil terminal 16 is attached after winding as shown in FIG. The coil terminal 16 is manually soldered by connecting the coil lead wire to the coil terminal 16 and then bent to a final shape as shown in FIG.
Japanese Patent Publication No. 3-38690

  However, in the above-described polarized electromagnetic relays as shown in FIGS. 7 and 8 and Patent Document 1, management and handling of coil terminals 16 which are separate parts, manual connection and soldering are inconvenient. Also, it is difficult to reduce the size due to the separate parts configuration.

  The present invention solves the above-described problems, and an object of the present invention is to provide a small polarized electromagnetic relay that can automate the connection and soldering of coil lead wires.

  In order to achieve the above object, the invention of claim 1 is characterized in that a coil bobbin made of a molded resin in which an iron core is inserted and a coil is wound outside and a lead wire of the coil are connected, and an external circuit is connected. In a polarized electromagnetic relay comprising: an electromagnet block having at least three coil terminals for contact; and a contact mechanism having a contact that contacts and separates according to the excitation state of the coil, the coil terminal extends from the coil bobbin The terminal holding portion provided at one end of the direction is integrally molded and held on substantially the same plane substantially orthogonal to the extending direction, and one end protrudes from the terminal holding portion and is connected to the coil lead wire and the electric wire. A coil connection part that is connected in a connected manner, and the other end is a terminal part that is led out from the terminal holding part and connected to a connection part of an external circuit, and at least two of the coil connection parts are Both those projecting from the terminal holding portion in the same direction.

  According to a second aspect of the present invention, in the polarized electromagnetic relay according to the first aspect, a protruding direction of the coil connection portion from the terminal holding portion is substantially opposite to a direction in which the terminal portion is led out.

  According to a third aspect of the present invention, in the polarized electromagnetic relay according to the first aspect, the terminal holding portion has an end surface that is parallel to the extending direction and is inclined with respect to a lead-out direction of the terminal portion, and the coil connection The part protrudes from the inclined end face.

  According to the first aspect of the present invention, each coil terminal is integrally formed and held on the terminal holding portion on substantially the same plane, and therefore, the coil connection portion is on substantially the same plane, which obstructs coil winding. Therefore, the coil lead wire can be automatically connected following the automatic coil winding. In addition, since at least two of the coil connection parts protrude from the terminal holding part in the same direction, soldering of the connection part can be automated, and simultaneous soldering (or welding) can be performed. Efficient work can be performed with a small number of coil bobbin posture changing steps for attachment (welding). Moreover, since each coil terminal is integrally molded, a small polarized electromagnetic relay can be realized.

  According to the invention of claim 2, since the protruding direction of the coil connection portion from the terminal holding portion is substantially opposite to the direction in which the terminal portion is led out, the automatic connection machine can be used as the coil connection portion without interfering with the terminal portion. Close the coil lead wires. Also, soldering can be automated.

  According to the invention of claim 3, since the coil connection part protrudes from the inclined end surface of the terminal holding part, the corner space of the polarized electromagnetic relay whose outer shape is generally rectangular can be effectively used, and the size can be reduced. Can be realized.

  Hereinafter, a polarized electromagnetic relay according to an embodiment of the present invention will be described with reference to the drawings. Since the basic configuration of the entire polarized electromagnetic relay is the same as that shown in FIGS. 7 and 8 except for a part thereof, the duplicated explanation is omitted, and the electromagnetic block (especially its coil bobbin) and the coil bobbin that are different from the above are fitted. The structure of the base to be combined will be described in detail. It should be noted that the directions of up, down, front, back, left, and right shown for convenience in the drawings are used as appropriate.

(First embodiment)
FIG. 1 shows a coil bobbin 9 forming an electromagnet block in the polarized electromagnetic relay of the first embodiment. As shown in FIG. 1A, the coil bobbin 9 includes a terminal holding portion 90 at one end in the extending direction, that is, the front-rear direction, and the three coil terminals 10, 11, and 16 are substantially the same as the extending direction. It is arranged on substantially the same plane (front and rear, left and right planes) orthogonal to each other and is held by the terminal holding portion 90 by integral molding. One end of each of the coil terminals 10, 11, 16 protrudes diagonally upward and leftward from the terminal holding portion 90 to become a coil connection portion that is electrically connected to the lead wire of the coil 21, and the other end is downward from the terminal holding portion 90. The terminal portions 10a, 11a, 16a for connection to an external circuit are derived. The terminal holding part 90 has end faces S1 and S2 that are parallel to the extending direction and inclined with respect to the direction in which the terminal part is led out, and the coil connection part projects from the end faces S1 and S2.

  Since the coil connection portions of the coil terminals 10, 11 and 16 are substantially on the same plane and do not interfere with the coil winding, the coil is automatically wound around the body portion 9c of the coil bobbin 9, as shown in FIG. The coil lead wire can be automatically connected to each coil connection portion following the coil winding. In addition, since the coil connection portions of the two coil terminals 10 and 16 both project from the end surface S1 in the same direction (upward and diagonally to the right), it is possible to automate the soldering of the connected portions and simultaneously perform the two soldering operations. This is possible, and it is possible to perform an efficient soldering operation in which the number of steps for changing the posture of the coil bobbin 9 is small as compared with three separate soldering. As described above, after the coil is wound and connected, the connecting portion is a step of soldering (other welding or the like). In the case of soldering, the side where a plurality of coil connecting portions are taken out is a plurality of times at once. It has the advantage that the coil terminal can be soldered.

  Then, after the coil lead wire is connected to each coil connection portion, as shown in FIG. 1C, one terminal portion 16 a is inward (coil bobbin 9) at the root portion 16 c led out from the terminal holding portion 90. The center side of the head), and is arranged out of the substantially same plane.

  2A to 2D show the external appearance of the base 1 in which an electromagnet block configured based on the coil bobbin 9 is incorporated. The gap 17 shown in FIGS. 2C and 2D is a space in which the terminal portions 16a and 10a of the coil terminals 16 and 10 are slid and stored. Points p1, p2, and p3 indicate locations where the terminal portions 11a, 10a, and 16a are disposed when the electromagnet block 2 is mounted on the base 1.

  3A and 3B show the structure of a coil terminal formed integrally with the coil bobbin 9. FIG. The coil terminals 10, 11, and 16 are disposed on substantially the same plane so as not to overlap each other and are integrally formed with the terminal holding portion 90.

  FIG. 4 shows a state in which the electromagnet block 2 is incorporated in the base 1. The coil connection portion 16b protrudes from the inclined end surface S1 provided on the terminal holding portion 90 of the coil bobbin, and the coil connection portions 10b and 11b protrude from the end surface S2 to connect the coil lead wire. Since each of the coil terminals 10, 11, 16 is held integrally with the terminal holding portion 90, sufficient holding strength can be obtained even with a small terminal holding portion, as compared with the case where the coil terminal is held behind. A small polarized electromagnetic relay can be realized. In addition, since the coil connection portions 11b, 10b, and 16b protrude from the end surfaces S1 and S2, the miniaturization of the polarized electromagnetic relay is achieved by effectively using the corner space of the base 1 whose outer shape is rectangular. .

(Second Embodiment)
FIG. 5 shows a state in which the electromagnet block 2 in the polarized electromagnetic relay of the second embodiment is incorporated in the base 1. In the electromagnet block 2, the coil connection portions 10b and 11b are protruded in parallel to each other toward the right side. By projecting the plurality of coil connection portions in the same direction as described above, the plurality of coil connection portions on the side where the plurality of coil connection portions are provided can be simultaneously soldered at a time as in the first embodiment. However, the polarized electromagnetic relay in this embodiment has an outer width in the left-right direction that is larger by X (0 <X) than that in the first embodiment described above. The polarized electromagnetic relay with this structure may be able to reduce the height in the vertical direction, and is effective when there is a dimensional limitation in the height direction rather than in the left-right direction.

(Third embodiment)
FIG. 6 shows a state in which the electromagnet block 2 in the polarized electromagnetic relay of the third embodiment is incorporated in the base 1. The electromagnet block 2 has coil connection portions 10b and 11b protruding in parallel upward. By projecting the plurality of coil connection portions in the same direction as described above, the plurality of coil connection portions on the side where the plurality of coil connection portions are projected can be simultaneously soldered at a time, as in the first embodiment. However, in the polarized electromagnetic relay in this embodiment, the upper space 14b of the base 1 on which the movable insulator 14 (see FIG. 7) is placed is Y (0 <Y) compared to the above-described first embodiment. As a result, the outer shape allowed for the movable insulator 14 is restricted. The polarized electromagnetic relay of this structure may be able to narrow the width in the left-right direction on the premise that the movable insulator 14 can be placed in the upper space 14b, and is limited in size in the left-right direction rather than the vertical direction. It is effective when there is.

  The present invention is not limited to the above-described configuration, and various modifications can be made. For example, you may make it make two coil connection parts protrude in the end surface S2 of the side in which the terminal part 16a which does not exist in the same plane of the terminal holding part 90 in 1st Embodiment is provided. Also, two coil connection portions can be projected on both end faces S1, S2.

(A) is the perspective view of the coil bobbin of the polarized electromagnetic relay which concerns on 1st Embodiment of this invention, (b) is the perspective view of the state which wound the coil around the coil bobbin, (c) is the same which wound the coil The perspective view as a final shape by bending the coil terminal of the coil bobbin. (A) is a top view of the base of the same polarized electromagnetic relay, (b) is a side view, (c) is a bottom view, and (d) is a front view. (A) is a perspective view of the coil bobbin of a polarized electromagnetic relay same as the above, (b) is a perspective view of a coil terminal formed integrally with the coil bobbin. The front view of the state which incorporated the electromagnet block in the base in a polarized electromagnetic relay same as the above. The front view of the state which incorporated the electromagnet block in the base in the polarized electromagnetic relay which concerns on 2nd Embodiment of this invention. The front view of the state which incorporated the electromagnet block in the base in the polarized electromagnetic relay which concerns on 3rd Embodiment of this invention. The exploded perspective view of the conventional polarized electromagnetic relay. (A) is a perspective view of the coil bobbin and coil terminal of the same polarized electromagnetic relay, (b) is a perspective view of the coil bobbin wound with a coil and connected to the coil terminal, (c) is a coil bobbin wound with the coil. The perspective view as a final shape by bending a coil terminal.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Base 2 Electromagnet block 3, 4 Contact mechanism 8 Iron core 9 Coil bobbin 10, 11, 16 Coil terminal 10a, 11a, 16a Terminal part 10b, 11b, 16b Coil connection part 16c Root part 17a Wall part 18 Resin 21 Coil 90 Terminal holding part S1, S2 end face

Claims (3)

An electromagnet block having a coil bobbin made of a molded resin in which an iron core is inserted and a coil wound on the outside, and a lead wire of the coil connected thereto, and having at least three coil terminals for external circuit connection; In a polarized electromagnetic relay comprising a contact mechanism having a contact that contacts and separates according to the excitation state of the coil,
The coil terminal is integrally formed and held on a substantially same surface at a terminal holding portion provided at one end of the coil bobbin in the extending direction, and one end of the coil terminal is the terminal holding portion. Projecting from the coil lead wire that is electrically connected to the coil lead wire, the other end being a terminal portion that is led out from the terminal holding portion and connected to the connection portion of the external circuit,
A polarized electromagnetic relay, wherein at least two of the coil connection portions protrude from the terminal holding portion in the same direction.   The polarized electromagnetic relay according to claim 1, wherein a protruding direction of the coil connection portion from the terminal holding portion is a direction substantially opposite to a direction in which the terminal portion is led out. The terminal holding portion has an end surface that is parallel to the extending direction and is inclined with respect to a direction in which the terminal portion is led out, and the coil connection portion protrudes from the inclined end surface. The described polarized electromagnetic relay.

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