DE102017004119A1 - Electromagnetic induction device and method for its production - Google Patents

Abstract

OBJECTIVE To provide an electromagnetic induction device that is smaller in size while avoiding a short circuit. [Solution] An electromagnetic induction device includes a body portion for winding a coil around the body portion, a jaw portion extending radially outward from an end portion in an axial direction of the body portion, a terminal block extending along a direction orthogonal to the axial direction of the body portion extends on a tip portion of the jaw portion and is provided with a plurality of terminals to be connected to the spool and the spool to be wound around the trunk portion. The plurality of terminals are each formed into an L-shape bent at a right angle, and are arranged side by side along an extending direction of the terminal block, and an end of each of the at least some of the plurality of terminals protrudes from a surface of the terminal block a side opposite to a side in which the body portion is arranged. The terminal block is formed with a wiring groove between a pair of adjacent two terminals of the plurality of terminals. The lead wire of the coil is pulled out from the trunk portion to the outside of the terminal block in the axial direction of the trunk portion by the wiring groove. The one ends of the adjacent two terminals above the wiring groove through which the extracted terminal wire passes are each bent so as to surround the drawn-out terminal wire from both sides, and connected to the drawn-out wire by soldering.

Description

[Technical area]

The present invention relates to an electromagnetic induction apparatus and a method of manufacturing the same, and more particularly, to an electromagnetic induction apparatus used as a transformer or reactor for board mounting and a method of manufacturing the same.

[State of the art]

Conventionally, a board-mounting-type transformer to be incorporated in a wiring board (printed wiring board) has been known as a component or the like of an electric device. The PCB mounting transformer comprises a tubular bobbin, a primary coil (winding wire) and a secondary coil are wound around an axis of the bobbin, and the two coils are e.g. B. isolated by winding an insulating tape. The bobbin includes a plurality of terminals to be connected to end portions (terminal ends) of lead wires of the coils, and each of the plurality of terminals becomes a primary-side terminal or secondary-side terminal of the transformer for board mounting. As described above, the coils are connected by means of the terminals of the bobbin with pad portions and the like provided on wirings of the wiring board.

For example, Patent Document 1 discloses an electromagnetic induction apparatus for board mounting, which includes a bobbin integrally formed with a cylindrical tubular body portion, jaw portions provided at both end portions of the body portion, and terminal blocks. The electromagnetic induction device is also used as a transformer. A plurality of terminals to be connected to end portions of lead wires of a coil are formed side by side in a row in each terminal block. The plurality of terminals are inserted into a wiring board and connected to components on this wiring board.

[Document List]

[Patent Document]

• Patent Document 1: Japanese Unexamined Patent Publication No. 2016-31978

Summary of the Invention

[Technical problem]

In recent years, along with the downsizing and the like of electrical devices, electromagnetic induction devices as described above have had to be further downsized. On the other hand, the current flowing in a coil of an electromagnetic induction device has become larger in recent years due to an increase in the performance of a switch-controlled power supply to be mounted on a wiring board. Consequently, a conductive wire, such. For example, a strand used in a coil may be made thicker (or the number of conductive wires used must be increased). Conventionally, when connecting a terminal wire of a coil to a terminal of a bobbin, the terminal wire is connected after being applied to the terminal by soldering. Thickening the lead wire (conductive wire) often uses two adjacent leads as a connection for a lead wire. In this case, since the lead wire is applied to each terminal and soldered, parts applied to the terminals often bulge outward from the two terminals. Consequently, to prevent a short circuit, the distance between the terminals of the coil must be increased.

As described above, the electromagnetic induction device has a problem that downsizing is required and, on the other hand, the electromagnetic induction device is increased as a result of increasing the distance between the terminals of the coil bobbin as a whole. The present invention has been developed to solve this problem, and an object of the present invention is to provide an electromagnetic induction device that is smaller in size while preventing a short circuit.

[The solution of the problem]

To achieve the above object, the present invention relates to an electromagnetic induction device having a body portion for winding a coil around the body portion, a jaw portion extending radially outward from an end portion in an axial direction of the body portion, a terminal block extending along one direction orthogonal to the axial direction of the body portion extends on a tip portion of the jaw portion and is provided with a plurality of terminals to be connected to the coil, and the coil to be wound around the body portion, wherein the plurality of terminals side by side along an extension direction the terminal block is arranged, each of at least some of the plurality of terminals is formed in an L-shape, which is bent at a right angle, and an end of each of the at least some of the plurality of terminals of a surface of the terminal block on one side protrudes from a side in which the body portion is arranged, the terminal block is formed with a wiring groove for extracting a terminal wire of the coil from the body portion to the outside of the terminal block in the axial direction of the body portion, wherein the wiring groove between a pair is formed from adjacent two terminals of the at least some of the plurality of terminals, the terminal wire of the coil is pulled out from the body portion to the outside of the terminal block in the axial direction of the body portion by the wiring groove, and the one ends of the adjacent two terminals above the wiring groove through which the extracted lead wire passes are each bent so as to surround the lead wire pulled out from both sides, and connected to the drawn lead wire by soldering.

According to the present invention thus constructed, the terminal wire of the coil wound around the body portion is pulled out from the body portion to the outside of the terminal block in the axial direction of the body portion by the wiring groove formed in the terminal block and having one ends of the body adjacent two terminals above the wiring groove are bent so as to surround the drawn-out lead wire from both sides, and are connected to the drawn lead wire by soldering. In this way, the drawn-out lead wire of the coil can be fixed while being electrically connected to the two terminals on inner sides of the two terminals without being applied to the one ends of the two terminals above the wiring groove. Further, since the lead wire can be soldered to the insides of the two terminals above the wiring groove, the warpage of the solder away from the two terminals can be reduced as compared with a structure in which the lead wire is applied and soldered to each terminal, and a structure, with which a short circuit can be prevented can be realized.

Further, in the present invention, the length of protrusion of the one end of each of the two adjacent two terminals from the terminal block is preferably larger than half the length between the adjacent two terminals.

According to the present invention having this structure, by making the length of projection of the one end of the terminal from the terminal block larger than half the length between the adjacent two terminals above the wiring groove, the bent one end of the terminal Terminal wire, which has been pulled out by the wiring groove, surrounded stable.

Further, the present invention for achieving the above object relates to a method of manufacturing an electromagnetic induction device by mounting a coil on a bobbin having a body portion for winding the coil around the body portion, a jaw portion extending radially outward from an end portion in an axial direction of the body portion, and a terminal block extending along a direction orthogonal to the axial direction of the body portion on a tip portion of the jaw portion and provided with a plurality of terminals to be connected to the spool, the plurality of terminals side by side is arranged along an extension direction of the terminal block, wherein each of at least some of the plurality of terminals is formed in an L-shape, which is bent at a right angle, and an end of each of the at least some of the plurality of Terminals from a surface of the terminal block projects on a side opposite to a side in which the body portion is arranged, the terminal block is formed with a wiring groove for pulling out a terminal wire of the coil from the body portion to the outside of the terminal block in the axial direction of the body portion the wiring groove is formed between a pair of adjacent two terminals of the at least some of the plurality of terminals, the method comprising a step of winding the coil around the body portion, a step of extracting a terminal wire of the coil from the body portion to the outside of the terminal block the axial direction of the trunk portion through the wiring groove and a step of bending the one ends of the adjacent two terminals above the wiring groove through which the extracted lead wire passes so as to pull it out Surround the connecting wire from both sides, and connect one end to the other extracted lead wire by soldering.

According to the present invention having this structure, by pulling the terminal wire of the coil wound around the body portion from the body portion to the outside of the terminal block in the axial direction of the body portion through the wiring groove of the terminal block of the bobbin, the electromagnetic induction apparatus becomes Bending the one ends of the adjacent two terminals above the wiring groove so as to surround the extracted terminal wire from both sides, and connecting the one ends to the extracted terminal wire by soldering. In this way, the drawn-out lead wire of the coil can be fixed while being electrically connected to the two terminals after being temporarily fixed to inner sides of the two terminals while being brought into contact with the two terminals, without abutting the one ends of the two terminals two terminals are placed over the wiring groove.

[Effect]

According to the present invention, a smaller size electromagnetic induction device can be provided while preventing a short circuit.

[Brief Description of the Drawings]

1 FIG. 15 is a perspective view of an electromagnetic induction apparatus according to an embodiment of the present invention; FIG.

2 Fig. 12 is a perspective view of a terminal block A of a spool before a spool is assembled according to the one embodiment of the present invention;

3 Fig. 12 is a front view of the terminal block A of the bobbin before the coil is assembled according to the one embodiment of the present invention;

4 FIG. 15 is a perspective view of the terminal block A of the bobbin in a state in which lead wires of primary coils are extracted in the electromagnetic induction device according to the one embodiment of the present invention; FIG.

5 FIG. 15 is a perspective view of the terminal block A of the bobbin in a state where the lead wires of the primary coils in the electromagnetic induction device according to the one embodiment of the present invention are temporarily fixed; FIG.

6 FIG. 16 is a front view of the terminal block A of the bobbin in the state where the lead wires of the primary coils in the electromagnetic induction device according to the one embodiment of the present invention are temporarily fixed; FIG.

7 FIG. 15 is a front view of the terminal block A of the bobbin in a state where the lead wires of the primary coils in an electromagnetic induction device according to the one embodiment of the present invention are connected by soldering, as compared with the prior art;

8th FIG. 15 is a front view of a terminal block A of a bobbin in a state where lead wires of primary coils are temporarily fixed in an electromagnetic induction device according to a modification of the one embodiment of the present invention, and FIG

9 Fig. 12 is a front view of a terminal block B of the bobbin before the coil is mounted in the electromagnetic induction apparatus according to the one embodiment of the present invention.

[Embodiment]

Hereinafter, an embodiment of the present invention will be described based on the attached drawings. It should be noted that in each figure, the same reference numerals designate the same or corresponding components, unless otherwise specified, and that elements or parts may, for convenience, be shown in vertical and horizontal scales different from the actual scales could be.

The 1 is a perspective view of an electromagnetic induction device 1 according to an embodiment of the present invention. The electromagnetic induction device 1 includes a bobbin 10 and a coil 20 around the bobbin 10 is wound. It should be noted that the coordinate axes of the x, y, and z directions which are orthogonal to each other are used to simplify the description in each figure, including FIG 1 are shown.

The bobbin 10 includes a body portion 11 for winding the coil 20 around the fuselage section, cheek sections 12 on both end parts of the fuselage section 11 in an axial direction (x-direction) are formed, and a Terminal block A 13 and a terminal block B 14 , each on the baking sections 12 formed on the two end portions, and these constituent elements are integrally formed. The baking sections 12 extend radially outward from the two axial end portions of the body portion 11 with the axial direction of the trunk section 11 as a center. The bobbin 10 however, may be formed by integrally welding or fixing the above constituent elements in a separate state. The bobbin 10 is made of an insulating resin, such as. As polyethylene terephthalate (PET) or phenol (PF) prepared.

The bobbin 10 includes an insertion hole 15 passing through the fuselage section 11 and the baking sections 12 in the axial direction of the body portion 11 passes. The electromagnetic induction device 1 According to one embodiment of the present invention, as a transformer for a printed circuit board mounting (for a printed circuit board insertion) by inserting a core into the insertion hole of the bobbin 10 and fixing and mounting the core can be used. The electromagnetic induction device 1 can also be applied to a choke coil or the like.

The sink 20 comprises one or more primary coil (s) 21 and one or more secondary coil (s) 22 , The 1 shows a state before connecting wires of the primary coils to simplify the description 21 with connections of the terminal block A 13 get connected. It should be noted, however, that in the actual electromagnetic induction device used 1 the connecting wires of the primary coils 21 with the connections of the terminal block A 13 are connected, as will be described later.

In one embodiment of the present invention, connection targets of the lead wires of the primary coils 21 a lower voltage than connection destinations of the secondary coil leads 22 , The conductive wires that are in the primary coils 21 must therefore be thicker than those used in the secondary coils 22 be used. For example, if the connection targets of the lead wires of the primary coils 21 are an input of 12V and those of the secondary coil leads 22 are an output of 100V, must be the cross-sectional area or the number of leads of the primary coils 21 that is, the conductive wires used in the primary coils may be about eight times larger, or about eight times as many as the secondary coil leads 22 , It is also possible to use the primary coils 21 to use as output (secondary coils) and the secondary coils 22 as input (primary coils) to use.

The 2 and the 3 are a perspective view and a front view of the terminal block A. 13 of the bobbin 10 before the coil 20 is mounted. The terminal block A 13 extends in a direction (y-direction) orthogonal to the axial direction of the body portion 11 on a top part of the baking section 12 and includes a plurality of terminals 16 connected to the connecting wires of the primary coils 21 to be connected. Furthermore, the terminal block A includes 13 a base floor section 13a projecting like a projection in a base floor part and the base floor section 13a serves as a contact surface when the core is mounted.

The respective connections 16 have an L-shape that is bent substantially at a right angle, and are along a extending direction (y-direction) of the terminal block A 13 arranged side by side and mounted. Preferably, the connections 16 partially in the terminal block A 13 through the terminal block A 13 assembled. For example, the port is 16 mounted such that an L-shaped bent part in the terminal block A 13 is embedded and two top parts of the terminal block A 13 protrude.

In every connection 16 stands out 16a of the connection 16 from a surface of the terminal block A 13 towards a side where the body portion 11 is arranged. The one end 16a preferably protrudes in one direction (protruding in a + x direction) substantially parallel to the axial direction of the body portion 11 in front. Furthermore, juts in every connection 16 another end 16b of the connection 16 from a surface of the terminal block A 13 opposite to the side in front of which the insertion hole 15 is arranged. The other end 16b preferably protrudes in one direction (protruding in a + z direction) substantially perpendicular to the axial direction of the body portion 11 and the extension direction of the terminal block A 13 in front.

The one end 16a is connected to the lead wire of the primary coil 21 connected and the other end 16b is inserted into a wiring board to be connected to a component on this wiring board. As has been described above, the conductive wire (lead) used in the primary coil 21 is used, be thicker than the conductive wire (connecting wire), which is in the secondary coil 22 is used. As a result, the lead wire becomes a primary coil 21 with two adjacent connections 16 connected so that a cross-sectional area of the terminals 16 connected to the lead wire of the primary coil 21 be ensured, and the connected two connections 16 are used as a connection for connecting to the wiring board.

In one example, the conductive wire is in the coil 20 is used to one or more strand (s), which is or are generally used for high-frequency currents. In another example, there are 120 strands with a diameter φ of 0.2 with the two adjacent terminals 16 connected. By using many strands in this way, wiring is possible that is more flexible than in the case of using a thick conductive wire. However, it can be any wire for the coil 20 be used. For example, a single wire or can be several single wires for the coil 20 be used.

As described above, the two adjacent ports 16 connected to the lead wire of a primary coil 21 to be connected, as a connection pair 16 ' be considered. In this case, the plurality of terminals forms 16 According to one embodiment of the present invention, a plurality of terminal pairs 16 ' , It should be noted, however, that the connection pair 16 ' A concept is a positional relationship of adjacent terminals 16 describes, and that two connectors 16 that the connection pair 16 ' form, within the terminal block A 13 are not electrically connected.

The terminal block A 13 is with wiring grooves 13b between two connections 16 formed, which each connection pair 16 ' form around the connecting wires of the primary coils 21 from the body section 11 to the outside of the terminal block A 13 in the axial direction of the body portion 11 (in the + x direction) to pull out (to wire). The wiring grooves 13b have a width which is the lead wire of a primary coil 21 can record.

The 4 is a perspective view of the terminal block A 13 in the state of 1 and shows the terminal block A 13 in a state where the lead wires of the primary coils 21 through the wiring grooves 13b pulled out. As it is in the 4 is shown is the primary coil 21 around the fuselage section 11 wound and the lead wire of the primary coil 21 is from the fuselage section 11 to the outside of the terminal block A 13 in the axial direction of the body portion 11 through the wiring groove 13b pulled out. An end part (terminal end) of this terminal wire is located with respect to the terminal block A. 13 on the same page as the one end 16a ,

When the primary coil 21 a plurality of primary coils 21 includes, the primary coils 21 , with different connection pairs 16 ' are connected, z. B. by winding an insulating tape on the body portion 11 isolated. Furthermore, also the secondary coil 22 accordingly around the fuselage section 11 wrapped and z. B. by winding an insulating tape from the primary coil 21 isolated.

The 5 and 6 are a perspective view and a front view of the terminal block A. 13 in a state where the lead wires of the primary coils 21 starting from the in the 4 state temporarily fixed. As it is in the 5 and 6 shown are the one ends 16a the two connections 16 that the connection pair 16 ' over the wiring groove 13b Form so bent that they pass the connecting wire through the wiring groove 13 has been pulled out, surrounded by both sides. By using such a structure, the lead wire of the primary coil 21 temporarily on insides of the two connections 16 be fixed while using the two connectors 16 is brought into contact, without the one ends 16a the two connections 16 over the wiring groove 13b to be applied in this embodiment.

The 7 is a front view of the terminal block A 13 , in which the connecting wires of the primary coils 21 are connected by soldering, compared to a terminal block A. 113 , in the connecting wires of primary coils 21 are connected by soldering in a conventional electromagnetic induction device. The conventional electromagnetic induction device includes the terminal block A. 113 which has the same shape as the terminal block A 13 according to one embodiment of the present invention, however, the lead wire becomes 21 the primary coil to the one ends 16a the two connections 16 created and is then passed through a solder joint 23 connected as it is in the 7 is shown. In contrast, in this embodiment, the lead of the primary coil 21 and the one ends 16a the two connections 16 , which are bent so that they surround the connecting wire, through which in the 7 shown solder joint 23 connected.

By using such a construction, in this embodiment, the lead wire of the primary coil 21 that in the wiring groove 13b is wired, and the connections 16 over this wiring groove 13b be fixed while they are electrically connected. Further, there is soldering on the insides of the two terminals 16 over the wiring groove 13b The protrusion of solder away from the two terminals can be performed 16 compared to the conventional structure in which the connecting wire to each terminal 16 are applied and soldered, diminished, and a construction that short circuits can prevent, can be realized. Consequently, as compared with the conventional structure in which the lead wire can be connected to each terminal 16 is applied and soldered, the distances between the terminals 16 be made shorter, with the result that the width of the terminal block A 13 in an arrangement direction (y direction) of the terminals 16 can be diminished, as it is in the 7 is shown. Therefore, the electromagnetic induction device 1 as a whole be further downsized. Further, since it is not necessary to connect the lead wire (conductive wire) to one ends 16a the two connections 16 can be applied, the wires to be used and the amount of solder to be used can be reduced.

In a modification, a terminal block A 13 be formed so that the one ends 16a of two connections 16 that a connection pair 16 ' form, at different height positions of the terminal block A. 13 protrude. The 8th is a front view of the terminal block A 13 according to the modification in a state where lead wires of primary coils 21 temporarily fixed. As it is in the 8th is shown, the two terminals differ 16 that the connection pair 16 ' over a wiring groove 13b with respect to the height (z-direction) of the protruding base parts. The one ends 16a these two connections 16 are bent so that they are the connecting wire through the wiring groove 13b has been pulled out, surrounded by both sides. By using such a construction, in this embodiment, the bent ones can have one ends 16a the connections 16 the connecting wire through the wiring groove 13b has been pulled out, surrounded more stable.

In a further modification, the length of the projection may be from one end 16a a connection 16 greater than half the length between two terminals 16 over a wiring groove 13b in a bending direction. By using such a construction, in this embodiment, the bent ones can have one ends 16a the connections 16 the connecting wire through the wiring groove 13b has been pulled out, surrounded more stable.

In another modification, some of the ports (eg, any two adjacent ports) that are to a port block A are 13 to be mounted, rod-shaped terminals and along an extension direction (y-direction) of the terminal block A. 13 according to some of the remaining connections 16 according to the 2 are formed, arranged side by side and mounted. The rod-shaped terminal is mounted so that one end in the terminal block A 13 is embedded and the other end of a surface of the terminal block A 13 protrudes opposite to a side in which an insertion hole 15 is arranged, according to the other end 16b that in the 2 is shown. The other end of this bar-shaped terminal is inserted into a wiring board and connected to a component on this wiring board, corresponding to the other end 16b that in the 2 is shown. A lead wire of a primary coil 21 is applied to the other end of a bar-shaped terminal and connected by soldering. It should be noted that the wiring groove 13b between adjacent rod-shaped connections must not be formed.

In the further modification, only the structure concerning the rod-shaped terminals is different from the structure of the terminal block A. 13 different, in the 2 is shown. By using such a structure, the terminal block A can 13 the connections 16 and the wiring grooves 13b in this embodiment, according to the number of lead wires of the primary coils 21 , which are to be applied to two terminals, are formed as shown in the 2 is shown.

The 9 is a front view of the terminal block B. 14 of the bobbin 10 before mounting the coil 20 , The connection block B 14 extends in a direction (y-direction) orthogonal to the axial direction of the body portion 11 on a tip part of the other baking section 12 , the top part of the baking section 12 corresponds to the connection block A 13 is formed, and includes a plurality of terminals 17 connected to the connecting wires of the secondary coils 21 to be connected. Furthermore, the terminal block B comprises 14 a base floor section 14a projecting like a projection in a base floor part and the base floor section 14a serves as a contact surface when the core is mounted.

The respective connections 17 have an L-shape that is bent substantially at a right angle and are corresponding to the terminals 16 along an extending direction (y direction) of the terminal block B 14 arranged side by side and mounted. Preferably, the connections 17 partially in the terminal block B 14 through the terminal block B 14 assembled. Further protrudes according to the connection 16 in every connection 17 an end 17a of the connection 17 from a surface of the terminal block B 14 opposite to the side where the body section 11 is arranged, and the other end 17b protrudes from a surface of the terminal block B 14 opposite the side in front of the insertion hole 15 is arranged. The terminal block A 14 is with wiring grooves 14b between the respective connections 17 to pull out the connecting wires of secondary coils 22 from the body section 11 to the outside of the terminal block A 14 in the axial direction of the body portion 11 (in an -x direction) formed.

An end 17a is connected to the connecting wire of the secondary coil 22 connected and the other end 17b is inserted into a wiring board and connected to a component on this wiring board. As described above, the lead wires of the secondary coils 22 thinner than those of the primary coils 21 , As a result, the lead wire of a secondary coil becomes 22 through the wiring groove 14b pulled out and at one end 17a created as it is in the 1 is shown. Thereafter, the lead wire of the secondary coil 22 connected by soldering. In this way, the lead wire can be fixed while being electrically connected. It should be noted that when the secondary coil 22 a plurality of secondary coils 22 includes, the secondary coils 22 , with different connection pairs 16 ' are connected, z. B. by winding an insulating tape on the body portion 11 are isolated.

It should be noted that the structure of the terminal block B 14 may be another known construction, with the proviso that a terminal block and terminals the connection wire from a secondary coil 22 with one end 17a can connect by soldering. For example, the connections must be 17 not be bent to an L-shape.

Next, a method of manufacturing the electromagnetic induction device 1 described. To simplify the description it is assumed that the coil 20 a primary coil 21 and a secondary coil 22 includes. First, the one in the 1 shown bobbin 10 made and the coil 20 that is a primary coil 21 and a secondary coil 22 includes, around the fuselage section 11 wrapped while each coil is insulated.

Subsequently, a lead wire of the primary coil 21 from the fuselage section 11 to the outside of the terminal block A 13 in the axial direction of the body portion 11 through the wiring groove 13b pulled out. Then the one ends 16a of two connections 16 that the connection pair 16 ' over the wiring groove 13b form, bent so that they surround the withdrawn lead wire and temporarily fix. The other lead wire of the primary coil 21 will also be equally through a further connection pair 16 ' temporarily fixed.

On the other hand, a lead wire of the secondary coil 22 from the fuselage section 11 to the outside of the terminal block B 14 in the axial direction of the body portion 11 through the wiring groove 14b pulled out and for temporary fixing at one end 17a of the connection 17 created. The other connecting wire of the secondary coil 22 will also pass through the other wiring groove accordingly 14b pulled out and for temporary fixing at one end 17a another connection 17 created.

After the temporary fixing, as described above, the temporarily fixed parts by soldering, such. B. by immersion in a solder bath, connected. By using such a structure, the lead wire of the primary coil 21 be fixed while using the two connectors 16 on insides of the second ports 16 is electrically connected, without in this embodiment to the one ends 16a the two connections 16 to be applied over the wiring groove. Further, it is possible to bulge solder outward from the two terminals 16 to prevent and avoid a short circuit. Furthermore, the one ends 16a the two connections 16 bent using a simple tool and then without applying the connecting wire to one end 16a the two connections 16 immersed in solder, causing the electromagnetic induction device 1 will be produced. Consequently, the working hours can be reduced. Further, a variation in the degree of connection caused by an application operation can be eliminated because the connection wires do not have to be applied.

Next, functions and effects of the electromagnetic induction device will be described 1 according to the embodiment of the present invention. In this embodiment, the lead wire of the primary coil 21 around the fuselage section 11 is wound from the body section 11 to the outside of the terminal block A 13 in the axial direction of the body portion 11 through the wiring groove 13b pulled out in the terminal block A 13 is formed, and the one ends 16a the adjacent two connections 16 over this wiring groove 13b are bent so that they surround the pulled-out lead wire from both sides, and connected by soldering to the pulled-out lead wire. In this way, the withdrawn connection wire of the primary coil 21 be fixed while using the two connectors 16 on the insides of the two ports 16 is electrically connected, without the one ends 16a the two connections 16 over the wiring groove 13b to be created. Further, because the lead wire to the insides of the two terminals 16 over the wiring groove 13b The soldering of solder can be soldered outward from the two terminals 16 be reduced compared with the structure in which the lead wire to each terminal 16 can be applied and soldered to it, and a structure in which a short circuit can be prevented, can be realized.

In this embodiment, the length of the projection of the one end 16a of the connection 16 from the terminal block A 13 made larger than half the length between the adjacent two terminals 16 over the wiring groove 13b , which makes the curved one end 16a of the connection 16 the connecting wire through the wiring groove 13b has been pulled out, can surround more stable.

The above-described respective embodiments are an illustration of the present invention, and the present invention is not limited to these embodiments. The respective embodiments may be combined in a suitable manner and applied to any embodiment of the present invention as long as not inconsistent. In particular, the present invention may be embodied in various forms without departing from the spirit thereof.

LIST OF REFERENCE NUMBERS

1

Electromagnetic induction device

10

bobbins

11

fuselage section

12

Back section

13

Terminal block A

13a

Base bottom portion

13b

wiring groove

14

Terminal block B

14a

Base bottom portion

14b

wiring groove

15

insertion

16, 17

connection

16a, 17a

An end

16b, 17b

Other end

20

Kitchen sink

21

primary coil

22

secondary coil

23

solder

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• JP 2016-31978 [0004]

Claims (5)

An electromagnetic induction apparatus having a body portion for winding a coil around the body portion, a jaw portion extending radially outward from an end portion in an axial direction of the body portion, a terminal block extending along a direction orthogonal to the axial direction of the body portion on a tip portion of the body Jaw portion and having a plurality of terminals to be connected to the coil, and the coil to be wound around the body portion, wherein: the plurality of terminals are arranged side by side along an extension direction of the terminal block, each of at least some of the plurality of terminals being formed in an L-shape bent at a right angle and one end of each of the at least some of the plurality of terminals projects from a surface of the terminal block on a side opposite to a side where the body portion is arranged; the terminal block is formed with a wiring groove for extracting a terminal wire of the coil from the body portion to the outside of the terminal block in the axial direction of the body portion, the wiring groove being formed between a pair of adjacent two terminals of the at least some of the plurality of terminals; the lead wire of the coil is pulled out from the body portion to the outside of the terminal block in the axial direction of the body portion by the wiring groove; and the one ends of the adjacent two terminals above the wiring groove through which the extracted terminal wire passes are each bent so as to surround the extracted terminal wire from both sides, and are connected to the drawn-out terminal wire by soldering. The electromagnetic induction apparatus according to claim 1, wherein the length of protrusion of the one end of each of the two adjacent two terminals of the terminal block is greater than half the length between the adjacent two terminals. A printed circuit board mounting transformer comprising the electromagnetic induction device according to claim 1 or 2. A choke coil for a circuit board assembly, which comprises the electromagnetic induction device according to claim 1 or 2. A method of manufacturing an electromagnetic induction device by mounting a coil on a bobbin having a body portion for winding the coil around the body portion, a jaw portion extending radially outward from an end portion in an axial direction of the body portion, and a terminal block extending along a body Extends orthogonal to the axial direction of the body portion on a tip portion of the jaw portion and is provided with a plurality of terminals to be connected to the coil, wherein the plurality of terminals are arranged side by side along an extending direction of the terminal block, each of at least some of the plurality of terminals being formed in an L-shape bent at a right angle and one end of each of the at least some of the plurality of terminals Protruding from a surface of the terminal block on a side opposite to a side in which the body portion is arranged, the terminal block is formed with a wiring groove for extracting a terminal wire of the coil from the body portion to the outside of the terminal block in the axial direction of the body portion, the wiring groove being formed between a pair of adjacent two terminals of the at least some of the plurality of terminals; the method comprising: a step of winding the coil around the body portion; a step of extracting a terminal wire of the coil from the body portion to the outside of the terminal block in the axial direction of the body portion through the wiring groove; and a step of bending the one ends of the adjacent two terminals above the wiring groove through which the extracted terminal wire passes so as to surround the pulled-out terminal wire from both sides, and connecting the one ends to the extended terminal wire by soldering.

Images