JP2018110053A - Electromagnetic relay - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an electromagnetic relay in which connection work of a terminal part of a coil wire can be effectively simplified and also cost of the coil wire can be reduced.SOLUTION: The electromagnetic relay comprises: a coil 4 comprised of a coil bobbin 14 and a coil wire 15 that is wound around the coil bobbin 14; a yoke 19 that forms a magnetic path together with a core; a stationary contact terminal 12 in which a stationary contact is provided; a movable contact which is electrically connected to the yoke 19 and provided in such a manner that the movable contact can be brought into contact with and separated from the stationary contact; a movable contact terminal 10 of which one end is fitted to the yoke 19; a coil terminal 8 for supplying a current to the coil wire 15; and a coil hook 83 to which a terminal part of the coil wire 15 is connected. The coil hook 83 is disposed in such a manner that the coil hook at least partially overlaps a formation region of the coil wire 15 in a view in an axial direction of the core, and is disposed at a position that is separated from the coil 4 by a predetermined distance.SELECTED DRAWING: Figure 4

Description

  The present invention relates to an electromagnetic relay.

  For example, in an electromagnetic relay mounted on a vehicle or the like, a contact portion and a coil wire material that excites and demagnetizes an iron core are provided adjacent to each other on a base portion. The contact portion includes a movable contact connected to the movable contact terminal and a fixed contact connected to the fixed contact terminal. The movable contact is brought into contact with and separated from the fixed contact based on demagnetization and excitation of the coil wire.

  Specifically, the movable contact is provided on one end side of a plate spring-like movable contact spring, and the other end side of the movable contact spring is supported by a yoke that forms a magnetic path together with the iron core. The base end of the movable contact terminal is also attached to the yoke. Thus, the movable contact and the movable contact terminal are connected via the movable contact spring and the yoke. Furthermore, the movable contact and the fixed contact are provided in a state of being separated from each other. The coil wire is connected to the movable contact terminal, and the coil is energized through the movable contact terminal.

  When the coil wire is energized, the movable contact is attracted to and abuts the fixed contact by the electromagnetic force generated in the coil wire, and both are electrically connected to energize the fixed contact terminal and the movable contact terminal. On the other hand, when the energization to the coil wire is interrupted, the movable contact is separated from the fixed contact by the elastic action of the movable contact spring provided with the movable contact, and the energization of the fixed contact terminal and the movable contact terminal is interrupted.

  Here, in order to connect the movable contact terminal and the coil wire, a connection piece for locking the terminal portion of the coil wire is often provided on the movable contact terminal. The connection space between the terminal part of the coil wire and the connection piece is very narrow due to the restriction of the size of the electromagnetic relay, and the connection work between the terminal part of the coil wire and the connection piece becomes troublesome. For this reason, various techniques for simplifying the connection work between the terminal portion of the coil wire and the connection piece have been proposed.

For example, a technique is proposed in which the movable contact terminal is provided so as to be rotatable with respect to the base portion, and the movable contact terminal is turned 90 ° from a predetermined position when the coil wire terminal portion and the connection piece are connected. (For example, refer to Patent Document 1).
According to this, since the movable contact terminal is rotated, a wide connection space between the terminal portion of the coil wire and the connection piece can be secured. That is, the end portion of the coil wire rod is pulled out in a predetermined direction, and then the end portion of the coil wire rod is drawn in a direction orthogonal to the predetermined direction so as to lock the end portion of the coil wire rod to the connection piece. Then, after the terminal portion of the coil wire rod is locked to the connection piece, the movable contact terminal is returned to a predetermined position. Thereby, simplification of the connection work of a coil wire is aimed at.

Japanese Patent Laid-Open No. 4-144022

  However, in the above-described prior art, the terminal portion of the coil wire rod is drawn out in a predetermined direction, and thereafter, the terminal portion of the coil wire rod is drawn in a direction to be locked to the connection piece. There are two directions. For this reason, it is difficult to say that the connection work between the terminal portion of the coil wire and the connection piece can be simplified, and it is necessary to set the terminal portion of the coil wire to be long because the drawing direction is two directions.

Furthermore, since the movable contact terminal is rotated in order to connect the terminal portion of the coil wire and the connection piece, this rotating operation becomes troublesome. For this reason, it is difficult to say that the connection work between the terminal portion of the coil wire and the connection piece can be simplified.
As described above, there is a problem that the connection work of the terminal portion of the coil wire cannot be effectively simplified, and the cost of the coil wire is increased.

  Then, this invention is made in view of the situation mentioned above, Comprising: The electromagnetic relay which can simplify the connection operation | work of the terminal part of a coil wire rod effectively, and can also reduce the cost of a coil wire rod is provided. is there.

  In order to solve the above problems, an electromagnetic relay according to the present invention includes a coil bobbin, a coil made of a coil wire wound around the coil bobbin, and an iron core around which the coil wire is wound via the coil bobbin, A yoke that supports the iron core and forms a magnetic path together with the iron core, a fixed contact terminal provided with a fixed contact, and is electrically connected to the yoke and can be connected to and separated from the fixed contact. A movable contact provided at one end of the yoke, a coil terminal for supplying a current to the coil wire, and a terminal portion of the coil wire provided on the coil terminal. A terminal connection portion to which the coil wire is connected, and the terminal connection portion is disposed so as to at least partially overlap the formation region of the coil wire as viewed from the axial direction of the iron core. Rutotomoni, characterized in that it is arranged at a position separated by a predetermined distance from the coil.

  By comprising in this way, this terminal part and a terminal connection part can be connected only by pulling out the terminal part of a coil wire in one direction, without rotating a movable contact terminal conventionally. For this reason, the connection operation | work of the terminal part of a coil wire can be simplified effectively, and the cost of a coil wire can also be reduced.

  In the electromagnetic relay according to the present invention, the coil bobbin is provided at a cylindrical bobbin body that is externally fitted to the iron core and wound with the coil wire, and at both axial ends of the bobbin body. Two outer flange portions, and one of the two outer flange portions is interposed between the coil wire rod and the terminal connection portion, and the terminal portion of the coil wire rod is connected to the terminal connection portion. The lead-out groove is led to the side, and at least a part of the lead-out groove is arranged at a position overlapping with the terminal connection portion when viewed from the axial direction.

With this configuration, the terminal connecting portion is arranged radially inward of the outer flange portion of the coil bobbin, and the direction in which the terminal portion of the coil wire is routed can be unidirectional. For this reason, an electromagnetic relay can be reduced in size, simplifying the connection operation of the terminal part of a coil wire.
Moreover, since the lead-out groove functions as a guide for guiding the terminal portion of the coil wire to the terminal connecting portion side, the connection work of the terminal portion of the coil wire can be facilitated.

  In the electromagnetic relay according to the present invention, the movable contact terminal has an element connecting portion for connecting an element that absorbs the counter electromotive voltage of the coil, and the element connecting portion is at least partially from the axial direction. As a result, it is arranged at a position overlapping the terminal connecting portion.

  By comprising in this way, the connection location of each component can be collected in one place. For this reason, the connection workability | operativity of each component can be improved.

  According to the present invention, it is possible to connect the terminal portion and the terminal connecting portion only by pulling out the terminal portion of the coil wire material in one direction without rotating the movable contact terminal as in the prior art. For this reason, the connection operation | work of the terminal part of a coil wire can be simplified effectively, and the cost of a coil wire can also be reduced.

It is a side view of the electromagnetic relay in the embodiment of the present invention. It is a front view of the electromagnetic relay in the embodiment of the present invention. It is the perspective view which looked at the base part in embodiment of this invention from the coil side. It is the perspective view which looked at the electromagnetic relay in embodiment of this invention from each terminal side. It is a perspective view of the coil bobbin in the embodiment of the present invention. It is the top view which looked at the electromagnetic relay in embodiment of this invention from each terminal side, Comprising: The state which permeate | transmitted the base part is shown. It is an expansion perspective view of the connection piece in the embodiment of the present invention.

  Next, embodiments of the present invention will be described with reference to the drawings.

(Electromagnetic relay)
Next, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is a side view of the electromagnetic relay 1. FIG. 2 is a front view of the electromagnetic relay 1.
The electromagnetic relay 1 is used, for example, to turn on / off a lamp (Lamp) mounted on a vehicle.
As shown in FIGS. 1 and 2, the electromagnetic relay 1 includes a base part 2, a coil 4 provided on the one surface 2 a side of the base part 2, and a contact provided between the base part 2 and the coil 4. The coil terminal 8, the movable contact terminal 10, the fixed contact terminal 12, the resistor 16 connected to the coil terminal 8, and the coil 4. And a rectangular box-shaped cover 17 for covering.

  The resistor 16 is for absorbing the counter electromotive voltage of the coil 4. The register 16 includes a register main body 61 and a pair of lead wires 62 extending from the register main body 61. In the following description, the protruding direction of each terminal 8, 10, 12 may be referred to as the lower side, and the opposite side of the protruding direction of these terminals 8, 10, 12 may be referred to as the upper side.

(Base part)
FIG. 3 is a perspective view of the base portion 2 as viewed from the coil 4 side.
As shown in FIGS. 1-3, the base part 2 is formed in the substantially rectangular flat plate shape with resin which has insulation. On one end side in the longitudinal direction of the base portion 2 (the left side in FIGS. 1 and 3 and the front side in FIG. 2), there are long coil terminal slits 7 along the longitudinal direction of the base portion 2 on both sides in the short direction. Is formed. The coil terminals 8 are inserted or press-fitted into the coil terminal slits 7, respectively.

The base portion 2 is formed with a movable contact terminal slit 9 that is long along the short side direction of the base portion 2 on the other end side in the longitudinal direction (right side in FIG. 1). The movable contact terminal 10 is inserted or press-fitted into the movable contact terminal slit 9.
Further, a long fixed contact terminal slit 11 is formed along the short direction of the base portion 2 at the center of the base portion 2 in the longitudinal direction. The fixed contact terminal 12 is inserted or press-fitted into the fixed contact terminal slit 11.

  Further, a register housing recess 40 for housing the register 16 is formed between the movable contact terminal slit 9 and the fixed contact terminal slit 11 on the one surface 2 a side of the base portion 2. The register storage recess 40 is formed along the length of the main body storage recess 41 along the short direction of the base portion 2 and at both longitudinal ends of the main body storage recess 41 (both sides of the base portion 2 in the short direction of the base portion 2). Each of the lead wire storage recesses 42 is formed in communication with the main body storage recess 41.

  The lead wire storage recess 42 is bent from the opposite end of the short side portion 42a to the main body storage recess 41, and the short side portion 42a extending from both longitudinal ends of the main body storage recess 41 to the front of both ends of the base portion 2 in the short direction. A longitudinal portion 42c that is bent and extended along the longitudinal direction of the base portion 2 via the portion 42b is formed in communication. The long portion 42c extends from the end of the short portion 42a until it communicates with the coil terminal slit 7.

(register)
The register body 61 of the register 16 is housed in the body housing recess 41 of the register housing recess 40 configured as described above. Further, the lead wire 62 of the register 16 is bent along the lead wire storage recess 42 and stored in the lead wire storage recess 42. That is, in the register 16, the register main body 61 is disposed between the fixed contact terminal slit 11 (fixed contact terminal 12) and the movable contact terminal slit 9 (movable contact terminal 10). Then, the lead wire 62 extends from the register main body 61 to the coil terminal slit 7 (coil terminal 8) so as to bypass (straddle) the fixed contact terminal slit 11 (fixed contact terminal 12). Yes.

  Further, the first support column 5 is provided on one end side in the longitudinal direction of the base portion 2 so as to project toward the side opposite to the projecting direction of the terminals 8, 10, 12 (upper side). Further, on the other end in the longitudinal direction of the base portion 2, second support columns 6 are provided on both sides in the short direction of the base portion 2 so as to protrude in the opposite direction to the protruding direction of the terminals 8, 10, 12. ing.

(yoke)
The first support column 5 and the second support column 6 support a yoke 19 having a substantially L-shaped cross section. A magnetic path is formed in the yoke 19, and the metal plate is bent by pressing. That is, the yoke 19 has an upper wall 19a facing the base portion 2 at a predetermined interval, and a vertical wall 19b that bends and extends substantially perpendicularly to the upper wall 19a from the end of the upper wall 19a on the second support column 6 side. And have. Furthermore, the yoke 19 is formed so that the direction in which the upper wall 19a and the vertical wall 19b are continuous becomes longer.

Here, as for the 1st support | pillar 5 standingly arranged by the base part 2, the cross-sectional shape along the surface direction of the base part 2 is formed in the substantially C shape. Further, an engagement piece 19c that can be inserted into the first support column 5 is bent and extended on the upper wall 19a of the yoke 19 at the end of the first support column 5 side. Thereby, one end of the yoke 19 is supported by the first support column 5.
On the other hand, the two second support columns 6 are respectively disposed at both ends of the base portion 2 in the short direction. The two second struts 6 also have a substantially C-shaped cross section along the surface direction, and the opening directions thereof are opposed to each other. And the 2nd support | pillar 6 is supporting so that the vertical wall 19b of the yoke 19 may be clamped from the transversal direction both sides.

  As shown in FIGS. 1 and 2, an iron core 18 formed in a bar shape with a magnetic material is fixed to the upper wall 19 a of the yoke 19. The iron core 18 is suspended from the upper wall 19 a of the yoke 19 toward the base portion 2. The coil 4 is fitted and fixed to such an iron core 18. Further, a flange portion 18a is formed at the tip of the iron core 18, and the coil 4 is prevented from coming off from the iron core 18.

(coil)
FIG. 4 is a perspective view of the electromagnetic relay 1 as viewed from the terminals 8, 9, 10 (coil terminal 8, movable contact terminal 10, fixed contact terminal 12) side, with the base 2 and the cover 17 removed. Show. FIG. 5 is a perspective view of the coil bobbin 14.
As shown in FIGS. 1, 4, and 5, the coil 4 includes a coil bobbin 14 that is externally fitted and fixed to an iron core 18, and a coil wire 15 that is wound around the coil bobbin 14.
The coil bobbin 14 is formed of an insulating material such as resin. The coil bobbin 14 includes a cylindrical bobbin main body 71 and two outer flange portions 72 and 73 (an upper outer flange portion 72 and a lower outer flange portion 72 provided on both ends in the axial direction of the bobbin main body 71 and projecting radially outward. And an outer flange portion 73).

The bobbin main body 71 is externally fixed to the iron core 18. A coil wire 15 is wound around the outer peripheral surface of the bobbin main body 71.
The two outer flange portions 72 and 73 have a role of preventing the coil wire 15 from being collapsed. Of the two outer flange portions 72 and 73, the lower outer flange portion 73 disposed on the base portion 2 side has a coil at a position corresponding to the coil terminal slit 7 formed in the base portion 2. A terminal support 74 is integrally formed. The coil terminal support portion 74 is formed in a substantially rectangular tube shape, and is formed to protrude toward the base portion 2 side so that the proximal end of the coil terminal 8 can be press-fitted.

  Further, the lower outer flange portion 73 is integrally formed with a restricting portion 75 at a position corresponding to the longitudinal portion 42 c of the lead wire housing recess 42 formed in the base portion 2. The restricting portion 75 is formed in a substantially quadrangular prism shape and protrudes toward the base portion 2. The restricting portion 75 is formed in a substantially rectangular shape so that a cross section along the surface direction of the base portion 2 becomes longer along the longitudinal portion 42 c of the lead wire accommodating recess 42. Further, the restricting portion 75 is disposed closer to the bent portion 42b in the longitudinal portion 42c. Further, the protruding length of the restricting portion 75 is set to a length that faces the inside of the longitudinal portion 42 c of the lead wire housing recess 42.

The restriction portion 75 configured as described above is for preventing the register 16 housed in the lead wire housing recess 42 from being lifted from the base portion 2. In other words, the restricting portion 75 is for restricting the displacement of the register 16 toward the coil 4.
More specifically, when the leading end of the restricting portion 75 is exposed in the longitudinal portion 42 c of the lead wire storing recess 42, the tip contacts the lead wire 62 of the register 16 stored in the lead wire storing recess 42. For this reason, the restricting portion 75 restricts the displacement of the register 16 toward the coil 4 side.
Further, the leading end of the restricting portion 75 is exposed in the longitudinal portion 42 c of the lead wire housing recess 42, so that the lead wire 62 of the register 16 is sandwiched between the tip and the bottom surface of the lead wire housing recess 42. . As a result, the register 16 is securely fixed in the register housing recess 40.

  Further, a lead-out groove 76 is formed in the vicinity of the coil terminal support portion 74 of the lower outer flange portion 73. The lead-out groove 76 is formed from the outer peripheral edge of the lower outer flange portion 73 to the region around which the coil wire 15 is wound. That is, the lead-out groove 76 is formed so that a part thereof overlaps with the winding region of the coil wire 15 as viewed from the axial direction of the iron core 18 (coil bobbin 14). The lead-out groove 76 formed in this way is for leading the terminal portion 15a (see FIG. 7) of the coil wire 15 wound around the coil bobbin 14 to the coil terminal 8 side (details will be described later). ).

(Coil terminal)
FIG. 6 is a plan view of the electromagnetic relay 1 as viewed from the terminals 8, 9, 10 (coil terminal 8, movable contact terminal 10, fixed contact terminal 12) side, and shows a state where the electromagnetic relay 1 is transmitted through the base portion 2.
As shown in FIGS. 1, 4, and 6, the coil terminal 8 is formed in a substantially long plate shape. Moreover, the coil terminal 8 is extended along the direction orthogonal to the surface direction of the base part 2, ie, the axial direction of the iron core 18 (coil bobbin 14). Furthermore, the coil terminal 8 is formed so that the cross-sectional shape along the surface direction of the base portion 2 is along the extending direction of the coil terminal slit 7 (longitudinal direction of the base portion 2). The coil terminal 8 is inserted through the coil terminal slit 7 of the base portion 2.

  A support piece 81 is integrally formed at the base end of the coil terminal 8. The support piece 81 is press-fitted into a coil terminal support portion 74 that is integrally formed with the coil bobbin 14. A connection piece 82 extending toward the fixed contact terminal 12 is integrally formed at the base end of the coil terminal 8. The connection piece 82 extends to the vicinity of the fixed contact terminal 12.

FIG. 7 is an enlarged perspective view of the connection piece 82.
As shown in FIGS. 4, 6, and 7, a coil hook 83 that protrudes toward the coil 4 side is integrally formed at the base of the connection piece 82 so as to avoid the coil terminal support portion 74 of the coil bobbin 14. Yes. Further, the coil hook 83 is located directly below the lead-out groove 76 of the coil bobbin 14. In other words, the coil hook 83 is disposed at a position overlapping the lead-out groove 76 of the coil bobbin 14 when viewed from the axial direction of the iron core 18 (coil bobbin 14).
The terminal part 15a of the coil wire 15 led out via the lead-out groove 76 is locked to such a coil hook 83, and is fixed by, for example, fusing. Thereby, the coil wire 15 and the coil terminal 8 are connected.

  Further, a resistor connecting portion 83 is bent and extended from the tip of the connecting piece 82 toward the side opposite to the coil 4. Further, the register connecting portion 83 is disposed at a position where a part thereof overlaps the coil hook 83 when viewed from the axial direction of the iron core 18 (coil bobbin 14). Thus, since the coil hook 83 and the resistor connecting portion 83 are provided on the connecting piece 82, the coil hook 83 and the resistor connecting portion 83 are arranged close to each other.

  Here, as shown in detail in FIG. 3, the coil terminal slit 7 formed in the base portion 2 is formed so as to allow only the coil terminal 8 to be inserted therethrough. In other words, the coil terminal slits 7 of the base portion 2 are formed so as to penetrate in the thickness direction of the base portion 2 only at locations corresponding to the coil terminals 8. And the location corresponding to the connection piece 82 and the register connection part 84 of the slit 7 for coil terminals is made into the connection piece accommodation recessed part 7a recessedly provided so that the one surface 2a side might open. The connection piece storage recess 7 a communicates with the longitudinal portion 42 c of the register storage recess 40.

Further, the bottom surface of the connection piece housing recess 7 a is formed to be uneven so as to correspond to the unevenness of the connection piece 82 and the register connection portion 84. As a result, the connection piece 82 of the coil terminal 8 and the register connection portion 84 are surely brought into contact with the bottom surface of the connection piece storage recess 7a, and the positioning of the coil terminal 8 (connection piece 82, coil hook 83 and register connection portion 84) is achieved. Done.
The lead wire 62 of the register 16 accommodated in the register accommodating recess 40 is extended to the register connecting portion 84 arranged in this way. The tip of the lead wire 62 is fixed to the register connection portion 84 by, for example, fusing.

(Contact part)
As shown in FIGS. 1 and 4, a movable contact spring 20 is attached to the vertical wall 19 b of the yoke 19. The movable contact spring 20 is for supporting the movable contact 21 constituting one of the contact portions 3. The movable contact spring 20 is formed of a conductive leaf spring material having a substantially L-shaped cross section. The movable contact spring 20 has a mounting seat 31 attached to the vertical wall 19b of the yoke 19 and a base 2 side end of the mounting seat 31. The working piece 32 is bent and extended so as to be interposed between the base portion 2 and the coil 4.

  The mounting seat 31 is formed in the most part of the center of the vertical wall 19b of the yoke 19 and is formed in a substantially U shape in plan view. That is, the mounting seat 31 extends in the longitudinal direction so as to straddle the pair of arm portions 31a facing each other in the short-side direction and the opposite ends of the base portions 2 of the arm portions 31a. It is comprised by the connection part 31b which connects the arm part 31a. Both ends of the connecting portion 31b that are connected to each arm portion 31a are fixed to the vertical wall 19b of the yoke 19 by caulking or welding, respectively.

The operating piece 32 is bent and extended from the tip of each arm portion 31a, the main body 32b extending from the tip of the support piece 32a, and set to a plate width capable of connecting the support pieces 32a, It is comprised by. And the movable contact 21 is attached to the front-end | tip of the main-body part 32b.
Moreover, the iron piece 25 is provided in the surface at the side of the coil 4 of the main-body part 32b. The operating piece 32 is provided such that the iron piece 25 is separated from the flange portion 18a of the iron core 18 by a predetermined interval.

  A mounting seat 33 is attached to the vertical wall 19b of the yoke 19 and is provided at the base end of the movable contact terminal 10 and extends along the vertical wall 19b. The mounting seat 33 is disposed so as to avoid the two arm portions 31 a of the mounting seat 31 that constitutes the movable contact spring 20. And the front-end | tip of the attachment seat 33 is being fixed to the vertical wall 19b of the yoke 19 by caulking or welding, respectively. Here, the fixing position of the mounting seat 33 of the movable contact terminal 10 and the fixing position of the mounting seat 31 of the movable contact spring 20 are arranged substantially on the same straight line.

  The movable contact terminal 10 is formed in a substantially long plate shape, and extends along a direction orthogonal to the surface direction of the base portion 2, that is, along the axial direction of the iron core 18 (coil bobbin 14). The movable contact terminal 10 is formed so that the cross-sectional shape along the surface direction of the base portion 2 is along the extending direction of the movable contact terminal slit 9 (short direction of the base portion 2). Such a movable contact terminal 10 is inserted into the movable contact terminal slit 9 of the base portion 2. And most of the movable contact terminal 10 protrudes from the base portion 2 toward the side opposite to the coil 4 except for the base end portion.

  The fixed contact terminal 12 inserted through the fixed contact terminal slit 11 of the base portion 2 also extends in a direction orthogonal to the surface direction of the base portion 2, that is, along the axial direction of the iron core 18 (coil bobbin 14). . The fixed contact terminal 12 is formed so that the cross-sectional shape along the surface direction of the base portion 2 is along the extending direction of the fixed contact terminal slit 11 (short direction of the base portion 2). Such a fixed contact terminal 12 is inserted into the fixed contact terminal slit 11 of the base portion 2. And most of the fixed contact terminal 12 protrudes from the base portion 2 toward the side opposite to the coil 4 except for the base end portion.

  An inner contact portion 36 that bends and extends toward the movable contact 21 is integrally formed at the base end of the fixed contact terminal 12. The tip of the internal contact portion 36 is interposed between the movable contact 21 and the coil 4. The fixed contact 22 is attached to the tip of the internal contact portion 36. Thereby, the movable contact 21 and the fixed contact 22 are arranged to face each other with a predetermined interval.

(Assembly of electromagnetic relay)
Next, a method for assembling the electromagnetic relay 1 will be described.
First, the coil 4 is formed by winding the coil wire 15 around the bobbin body 71 of the coil bobbin 14. Next, the end opposite to the flange portion 18 a of the iron core 18 is directed to the lower outer flange 73 side of the bobbin main body 71, and the iron core 18 is inserted into the bobbin main body 71 as it is. Then, the end portion of the iron core 18 is fixed to the upper wall 19 a of the yoke 19 with the flange portion 18 a of the iron core 18 in contact with the lower outer flange portion 73 of the bobbin main body 71.

  Subsequently, the mounting seat 31 of the movable contact spring 20 and the mounting seat 33 of the movable contact terminal 10 are fixed to the vertical wall 19b of the yoke 19 by caulking or welding. Further, the support piece 81 of the fixed contact terminal 12 is directed to the coil terminal support portion 74 side of the coil bobbin 14, and the connection piece 82 of the fixed contact terminal 12 is directed to the movable contact terminal 10 side. Then, the support piece 81 is press-fitted into the coil terminal support portion 74 as it is.

  Subsequently, the terminal portion 15 a of the coil wire 15 is directed toward the coil hook 83 formed on the support piece 81 of the fixed contact terminal 12 through the lead-out groove 76 formed in the lower outer flange portion 73 of the coil bobbin 14. Is derived. And the terminal part 15a of the coil wire 15 is latched to the coil hook 83, and the coil hook 83 and the terminal part 15a of the coil wire 15 are fixed by, for example, fusing.

  Here, the lead-out groove 76 is formed from the outer peripheral edge of the lower outer flange portion 73 to the region around which the coil wire 15 is wound. That is, the lead-out groove 76 is formed so that a part thereof overlaps with the winding region of the coil wire 15 as viewed from the axial direction of the iron core 18 (coil bobbin 14). The coil hook 83 is disposed directly below the lead-out groove 76, that is, at a position overlapping the lead-out groove 76 when viewed from the axial direction of the iron core 18. For this reason, the terminal part 15a of the coil wire 15 is directly under the lead-out groove 76 and the coil hook 83 from the part (between the upper outer flange part 72 and the lower outer flange part 73) where the coil wire 15 is wound ( The coil hook 83 can be locked only by pulling it out in one direction. Further, when the terminal portion 15 a of the coil wire 15 is pulled out toward the coil hook 83, the lead-out groove 76 functions as a guide that guides the terminal portion 15 a to the coil hook 83.

  Subsequently, the tip of the lead wire 62 of the register 16 is fixed to the register connecting portion 84 formed on the support piece 81 of the fixed contact terminal 12 by, for example, fusing. At this time, the lead wire 62 of the register 16 is bent in advance along the lead wire housing recess 42 formed in the base portion 2 in advance. By bending the lead wire 62 in this manner, the lead wire 62 comes into contact with the tip of the restricting portion 75 protruding from the coil bobbin 14. That is, when connecting the lead wire 62 of the register 16 to the register connecting portion 84, the restricting portion 75 functions as a guide for positioning the register 16.

  Thereafter, the coil terminal 8, the movable contact terminal 10, and the fixed contact terminal 12 are respectively inserted into the coil terminal slit 7, the movable contact terminal slit 9, and the fixed contact terminal slit 11 formed in the base portion 2. Insert or press fit. At this time, the lead wire 62 extends from the register body 61 to the coil terminal 8 so as to bypass the fixed contact terminal 12. For this reason, the register 16 and the fixed contact terminal 12 do not interfere with each other.

Further, since the lead wire 62 is bent in advance along the lead wire housing recess 42 formed in the base portion 2, the fixed contact terminal 12 is inserted into the fixed contact terminal slit 11 of the base portion 2, or When press-fitting, the register 16 is smoothly accommodated in the lead wire accommodating recess 42. Then, the restricting portion 75 restricts the displacement of the register 16 toward the coil 4 side.
Further, the leading end of the restricting portion 75 is exposed in the longitudinal portion 42 c of the lead wire housing recess 42, so that the lead wire 62 of the register 16 is sandwiched between the tip and the bottom surface of the lead wire housing recess 42. . For this reason, the register 16 is securely fixed in the register housing recess 40. Thereby, the assembly of the electromagnetic relay 1 is completed.

(Operation of electromagnetic relay)
Next, the operation of the electromagnetic relay 1 will be described.
In a state where the coil wire 15 of the coil 4 is not energized, the movable contact 21 and the fixed contact 22 constituting the contact portion 3 are separated (hereinafter referred to as a separated state of the movable contact 21).
On the other hand, when a current is supplied to the coil terminal 8 (hereinafter, the current supplied to the coil terminal 8 is referred to as a primary current), a current flows through the coil wire 15 via the coil terminal 8 and the iron core 18 is excited. .

When the iron core 18 is excited, an attractive force toward the iron core 18 acts on the iron piece 25 provided on the movable contact spring 20. For this reason, the movable contact spring 20 is elastically deformed, the iron piece 25 is attracted to the iron core 18, and the movable contact 21 comes into contact with the fixed contact 22 (hereinafter referred to as a connected state of the movable contact 21). Then, the movable contact spring 20 and the fixed contact terminal 12 are electrically connected via the movable contact 21 and the fixed contact 22.
Since the movable contact spring 20 is electrically connected to the movable contact terminal 10 via the vertical wall 19b of the yoke 19, the movable contact terminal 10 and the fixed contact terminal 12 are electrically connected. As a result, a current from an external power source (not shown) is supplied to a load (not shown, for example, a lamp). In the following description, the current supplied to the movable contact terminal 10 and the fixed contact terminal 12 is referred to as a secondary current.

  When the supply of the primary current is stopped again, the iron core 18 is demagnetized. Then, the iron piece 25 is separated from the iron core 18 by the elastic action of the movable contact spring 20. Accordingly, the movable contact 21 is separated from the fixed contact 22. Thereby, the movable contact terminal 10 and the fixed contact terminal 12 are electrically disconnected, and the supply of the secondary current is stopped.

  Here, with the supply and stop of the primary current, the movable contact spring 20 causes the operating piece 32 to swing between the separated state and the connected state of the movable contact 21. At this time, the restriction portion 75 formed on the coil bobbin 14 prevents the register 16 from being lifted from the base portion 2. That is, the restriction portion 75 restricts the displacement of the register 16 toward the coil 4 side. For this reason, the movable contact spring 20 and the register 16 do not come into contact with each other.

  Thus, in the above-described embodiment, the lead-out groove 76 formed in the lower outer flange portion 73 of the coil bobbin 14 extends from the outer peripheral edge of the lower outer flange portion 73 to the region where the coil wire 15 is wound. Is formed. That is, the lead-out groove 76 is formed so that a part thereof overlaps with the winding region of the coil wire 15 as viewed from the axial direction of the iron core 18 (coil bobbin 14). The coil hook 83 provided on the coil terminal 8 is disposed directly below the lead-out groove 76, that is, at a position overlapping the lead-out groove 76 when viewed from the axial direction of the iron core 18.

For this reason, without rotating the movable contact terminal 10 as in the prior art, the terminal portion 15a of the coil wire 15 is placed at a location where the coil wire 15 is wound (upper outer flange portion 72 and lower outer flange portion 73). Can be locked to the coil hook 83 simply by pulling it down (one direction) to the lead-out groove 76 and the coil hook 83. Therefore, the connection work of the terminal portion 15a of the coil wire 15 can be simplified effectively. Moreover, since it is not necessary to route the coil wire 15 uselessly, the cost of the coil wire 15 can also be reduced.
Furthermore, since the lead-out groove 76 and the coil hook 83 are arranged so as to overlap the winding region of the coil wire 15 as viewed from the axial direction of the iron core 18 (coil bobbin 14), the electromagnetic relay 1 is large in the radial direction of the coil bobbin 14. The electromagnetic relay 1 can be downsized without downsizing.

Further, when the terminal portion 15 a of the coil wire 15 is pulled out toward the coil hook 83, the lead-out groove 76 functions as a guide that guides the terminal portion 15 a to the coil hook 83. For this reason, the connection work of the terminal part 15a of the coil wire 15 can be facilitated.
Furthermore, the coil hook 83 that connects the coil terminal 8 and the coil wire 15 and the register connection portion 94 that connects the coil terminal 8 and the register 16 are each concentrated on a connection piece 82 extending from the base end of the coil terminal 8. Is formed. For this reason, each workability | operativity of the connection operation | work of the coil wire 15 to the coil terminal 8 and the connection operation | work of the register | resistor 16 can be improved.

In addition, a regulating portion 75 that regulates displacement of the register 16 toward the coil side 4 is integrally formed with the lower outer flange portion 73 of the coil bobbin 14. For this reason, the contact between the movable contact spring 20 and the register 16 can be prevented only by the restricting portion 75 without providing new parts as in the prior art. Therefore, increase in the manufacturing cost and assembly man-hour of the electromagnetic relay 1 can be suppressed, and the operation of the electromagnetic relay 1 can be stabilized.
Furthermore, since the restriction part 75 is integrally formed with the coil bobbin 14, it is possible to suppress an increase in the number of parts of the electromagnetic relay 1, so that the manufacturing cost and assembly man-hour of the electromagnetic relay 1 can be surely reduced.

  Further, the leading end of the restricting portion 75 is exposed in the longitudinal portion 42 c of the lead wire housing recess 42 formed in the base portion 2. As a result, this tip abuts on the lead wire 62 of the register 16 housed in the lead wire housing recess 42. That is, the lead wire 62 of the register 16 is held between the restricting portion 75 and the base portion 2. For this reason, the register 16 can be firmly fixed, and the contact between the movable contact spring 20 and the register 16 can be reliably prevented.

  Further, in the register 16, the register main body 61 is disposed between the fixed contact terminal slit 11 (fixed contact terminal 12) and the movable contact terminal slit 9 (movable contact terminal 10). Then, the lead wire 62 extends from the register main body 61 to the coil terminal slit 7 (coil terminal 8) so as to bypass (straddle) the fixed contact terminal slit 11 (fixed contact terminal 12). Yes. In this manner, the register 16 can be disposed in the dead space of the electromagnetic relay 1 by arranging the lead wire 62 of the register 16 to be bent. For this reason, the electromagnetic relay 1 can be reduced in size.

  Further, the restricting portion 75 is disposed closer to the bent portion 42 b in the longitudinal portion 42 c of the lead wire housing recessed portion 42 formed in the base portion 2. In other words, the restricting portion 75 is pressing the root portion of the lead wire 62 extending from the register main body 61. For this reason, compared with the case where the front end side of the lead wire 62 is pressed by the restricting portion 75, the displacement of the register 16 toward the coil 4 side can be reliably restricted.

  Further, in the electromagnetic relay 1, the axial direction of the iron core 18, the contact / separation direction of the movable contact 21 with respect to the fixed contact 22, and the extending directions of the coil terminal 8, the fixed contact terminal 12, and the movable contact terminal 10 are all set to the same direction. Has been. Thus, flattening of the electromagnetic relay 1 can be achieved by aligning the extending direction of each component.

The present invention is not limited to the above-described embodiment, and includes various modifications made to the above-described embodiment without departing from the spirit of the present invention.
For example, the case where the electromagnetic relay 1 is used to turn on / off a lamp (Lamp) mounted on a vehicle has been described. However, it is not restricted to this, It is possible to employ | adopt the electromagnetic relay 1 to various electric equipment.

  In the above-described embodiment, the case where the restriction portion 75 is integrally formed with the coil bobbin 14 has been described. However, the restricting portion 75 may not be formed integrally with the coil bobbin 14. Even in this case, since the configuration of the restricting portion 75 is simple, an increase in manufacturing cost and assembly man-hour of the electromagnetic relay 1 can be suppressed. Further, in place of the restricting portion 75, one that can restrict the displacement of the register 16 toward the movable contact spring 20 may be provided.

  Furthermore, in the above-described embodiment, the case where the lead wire 62 of the register 16 is sandwiched between the restriction portion 75 and the base portion 2 has been described. However, it is not restricted to this, The electromagnetic relay 1 should just be comprised so that the displacement to the movable contact spring 20 side of the register | resistor 16 at least by the control part 75 can be controlled.

  In the above-described embodiment, the lead groove 76 is formed in the lower outer flange portion 73 of the coil bobbin 14, and the terminal portion 15 a of the coil wire 15 is pulled out toward the register connecting portion 84 through the lead groove 76. explained. However, the lead-out groove 76 may not be formed in the lower outer flange portion 73 of the coil bobbin 14. In this case, for example, it is preferable to set the outer diameters of the outer flange portions 72 and 73 so as to correspond to the formation region of the coil wire 15. That is, it is preferable to set the outer diameters of the outer flange portions 72 and 73 to be the same as the outer diameter of the winding bundle when the coil wire 15 is wound.

DESCRIPTION OF SYMBOLS 1 ... Electromagnetic relay, 4 ... Coil, 8 ... Coil terminal, 10 ... Movable contact terminal, 12 ... Fixed contact terminal, 14 ... Coil bobbin, 15 ... Coil wire, 15a ... Terminal part, 16 ... Resistor (element), 18 ... Iron core , 19 ... Yoke, 21 ... movable contact, 22 ... fixed contact, 71 ... bobbin main body, 72 ... upper / outer flange (outer flange), 73 ... lower / outer flange (outer flange), 76 ... leading groove, 83 ... Coil hook (terminal connection part), 84 ... Register connection part (element connection part)

Claims (3)

A coil made of a coil bobbin and a coil wire wound around the coil bobbin;
An iron core around which the coil wire is wound via the coil bobbin;
A yoke that supports the iron core and forms a magnetic path with the iron core;
A fixed contact terminal provided with a fixed contact;
A movable contact that is electrically connected to the yoke and that is detachable from the fixed contact;
A movable contact terminal having one end attached to the yoke;
A coil terminal for supplying current to the coil wire;
A terminal connection portion provided on the coil terminal, to which a terminal portion of the coil wire is connected;
With
The terminal connecting portion is disposed so as to at least partially overlap the formation region of the coil wire as viewed from the axial direction of the iron core, and is disposed at a position separated from the coil by a predetermined distance. Electromagnetic relay. The coil bobbin
A cylindrical bobbin body that is externally fitted to the iron core and on which the coil wire is wound;
Two outer flange portions provided at both axial ends of the bobbin body to prevent the coil wire rod from being collapsed;
With
One of the two outer flange portions is interposed between the coil wire and the terminal connecting portion, and has a lead-out groove that guides the terminal portion of the coil wire to the terminal connecting portion side,
2. The electromagnetic relay according to claim 1, wherein at least a part of the lead-out groove overlaps with the terminal connection portion when viewed from the axial direction. The movable contact terminal has an element connection part for connecting an element that absorbs a counter electromotive voltage of the coil,
3. The electromagnetic relay according to claim 1, wherein at least a part of the element connection portion is disposed at a position overlapping the terminal connection portion when viewed from the axial direction.

Images