JP7057686B2 - Manufacturing method of coil parts and coil parts - Google Patents

Description

The present invention relates to a method for manufacturing a coil component and a coil component.

As a coil component of this type, there is one disclosed in Patent Document 1. With reference to FIG. 9, the coil component 900 of Patent Document 1 includes a magnetic material 910 and a coil 950 made of metal. The magnetic body 910 has an upper surface (+ Z surface) and a lower surface (−Z surface) in the vertical direction (Z direction). The magnetic material 910 has a plurality of through holes 912. The through hole 912 penetrates the magnetic material 910 in the vertical direction (Z direction). The coil 950 includes a plurality of upper conductors (plate conductors) 954, a plurality of lower conductors (plate conductors) 956, a plurality of through conductors 952, and connecting portions 960 and 970. The upper conductor 954 is arranged on the upper surface of the magnetic body 910. The upper conductor 954 is arranged in an orthogonal direction (X direction) orthogonal to the vertical direction. Gap 955 is provided in all of the adjacent upper conductors 954. The lower conductor 956 is arranged on the lower surface of the magnetic body 910. The lower conductor 956 is arranged in the orthogonal direction (X direction). Gap 957 is provided in all of the adjacent lower conductors 956. The penetrating conductor 952 penetrates the inside of the magnetic body 910 in the vertical direction. The upper conductor 954 and the lower conductor 956 are connected to each other by a through conductor 952. The connection portions 960 and 970 are connected to the circuit board when the coil component 900 is mounted on the circuit board (not shown).

Japanese Patent No. 5474251

When assembling the coil component 900 of Patent Document 1, it is necessary to position a plurality of flat plate conductors 954 and 956 on the magnetic body 910, respectively. However, in the case of a manufacturing method in which the flat plate conductors 954 and 956 are individually positioned with respect to the magnetic material 910, there is a drawback that the number of manufacturing steps is increased. Further, when the gaps 955 and 957 between the flat plate conductors 954 and 956 are narrow, there is a possibility that the flat plate conductors 954 and 956 are short-circuited due to a manufacturing error or the like.

Therefore, an object of the present invention is to provide a method for manufacturing a coil component that can reduce the number of manufacturing steps while preventing short circuits between flat plate conductors. Another object of the present invention is to provide a coil component manufactured by the manufacturing method thereof.

INDUSTRIAL APPLICABILITY According to the present invention, as a first method for manufacturing a coil component,
A method of manufacturing a coil component comprising two or more lower conductors, a magnetic material, two or more through conductors, and one or more upper conductors.
The first preparation step of preparing a first lead frame in which the two or more lower conductors arranged through the gap are supported by the first tie bar, respectively.
A first positioning step of positioning the first lead frame in a predetermined plane orthogonal to the vertical direction to position the two or more lower conductors at the first predetermined position on the predetermined plane.
The magnetic material having an upper surface and a lower surface in the vertical direction and provided with two or more through conductor accommodating holes, each of the through conductor accommodating holes penetrates the magnetic material in the vertical direction. The second preparation step of preparing the magnetic material is
While arranging the magnetic material with respect to the first lead frame so that the lower surface of the magnetic material and the lower conductor face each other in the vertical direction, the magnetic material passes through the first predetermined position. In addition, a second positioning step of positioning at a second predetermined position located on a straight line extending in the vertical direction,
A through-conductor accommodating step of accommodating the through-conductor in the through-conductor accommodating hole,
A third preparation step of preparing a second lead frame in which the one or more upper conductors are supported by the second tie bar, and
While arranging the second lead frame with respect to the magnetic material so that the upper surface of the magnetic material and the upper conductor face each other in the vertical direction, the upper conductor passes through the second predetermined position and passes through the second predetermined position. A third positioning step of positioning at a third predetermined position located on a straight line extending in the vertical direction,
A joining step of joining the lower conductor and the upper conductor to the through conductor, respectively.
An upper conductor separation step of separating the upper conductor from the second lead frame after the joining step.
Provided is a method for manufacturing a coil component including a lower conductor separating step of separating the lower conductor from the first lead frame after the joining step.

Further, the present invention is a first manufacturing method of a coil component as a second manufacturing method of a coil component.
Each of the lower conductors is supported by the first lead frame by two or more of the first tie bars.
The upper conductor provides a method of manufacturing a coil component supported by the second lead frame by two or more of the second tie bars.

Further, the present invention is a first or second manufacturing method for coil parts as a third manufacturing method for coil parts.
The connection portion between the first tie bar and the lower conductor protrudes from the lower conductor by the length D1 in the vertical direction.
When the size of the first tie bar in the vertical direction is D8, 0.5 ≦ D1 / D8 ≦ 0.95 is satisfied.
The connection portion between the second tie bar and the upper conductor protrudes from the upper conductor by the length D3 in the vertical direction.
Provided is a method for manufacturing a coil component that satisfies 0.5 ≦ D3 / D6 ≦ 0.95, where D6 is the size of the second tie bar in the vertical direction.

Further, the present invention is a method for manufacturing any of the first to third coil parts as the fourth manufacturing method for the coil parts.
The first preparation step is
A dividing step in which a flat metal plate supported by the first lead frame is divided to form the two or more lower conductors and the gap is formed between the two or more lower conductors. Provided is a method for manufacturing a coil component provided with.

Further, the present invention is a method for manufacturing any one of the first to third coil parts as the fifth manufacturing method for the coil parts.
The first preparation step is
A bending step of bending a flat metal plate supported by the first lead frame to form a bent portion.
A coil component comprising a dividing step of dividing the bent flat metal plate to form the two or more lower conductors and forming the gap between the two or more lower conductors. Provide a manufacturing method.

Further, the present invention is a fourth or fifth manufacturing method for coil parts as a sixth manufacturing method for coil parts.
Provided is a method for manufacturing a coil component, which comprises a plating step of plating a flat metal plate before the first preparation step.

Further, the present invention is a fourth or fifth manufacturing method for coil parts as a seventh manufacturing method for coil parts.
Provided is a method for manufacturing a coil component, which comprises a pressing step of pressing the lower conductor along the vertical direction after the dividing step.

Further, according to the present invention, as the eighth manufacturing method of the coil component, any one of the first to seventh manufacturing methods of the coil component is used.
The first lead frame has a first positioning hole and has a first positioning hole.
The second lead frame has a second positioning hole.
In the first positioning step, the first lead frame is positioned so that the first positioning protrusion is accommodated in the first positioning hole with respect to the first jig having the predetermined plane and the first positioning protrusion. Made by doing,
In the second positioning step, the second jig having the second positioning protrusion, the third positioning hole, and the magnetic material accommodating hole is provided with the first positioning protrusion in the third positioning hole with respect to the first jig. It is performed by accommodating the magnetic material in the magnetic material accommodating hole after positioning so as to be accommodated.
The third positioning step is performed by positioning the second lead frame with respect to the second jig so that the second positioning protrusion is accommodated in the second positioning hole. Provide a method.

Further, according to the present invention, as the first coil component,
A coil component mounted on a circuit board
The coil component comprises a magnetic material, one or more upper conductors, two or more lower conductors, and two or more through conductors.
The magnetic material has an upper surface and a lower surface in the vertical direction, and has an upper surface and a lower surface.
The upper conductor is arranged on the upper surface of the magnetic material.
The lower conductor is arranged on the lower surface of the magnetic material.
The two or more lower conductors are arranged in an orthogonal direction orthogonal to the vertical direction.
Gap is provided in all of the adjacent lower conductors.
Each of the upper conductor and the lower conductor has at least one cutting mark.
Each of the upper conductor and the lower conductor has a base metal and a plating layer.
The base metal is exposed in a part of the cut mark, and the base metal is exposed.
The penetrating conductor penetrates the magnetic body in the vertical direction.
The upper conductor and the lower conductor provide a coil component connected to each other by the through conductor.

Further, the present invention is the first coil component as the second coil component.
Provided is a coil component in which the base metal is exposed in the gap.

Further, the present invention is the first or second coil component as the third coil component.
The lower conductor includes a bend and
The bent portion provides a coil component that is connected to wiring on the circuit board when the coil component is mounted on the circuit board.

Further, the present invention is any one of the first to third coil parts as the fourth coil part.
Each of the lower conductors provides a coil component having two or more of the cut marks.

In the method for manufacturing a coil component of the present invention, a first preparation step of preparing a first lead frame in which two or more lower conductors arranged via a gap are supported by a first tie bar, and a vertical direction are used. It comprises a first positioning step of positioning two or more lower conductors at a first predetermined position on a predetermined plane by positioning the first lead frame in orthogonal predetermined planes. This avoids short circuits between flat plate conductors due to manufacturing errors and the like.

Further, in the method for manufacturing a coil component of the present invention, in addition to the above steps, the magnetic material is arranged with respect to the first lead frame so that the lower surface of the magnetic material and the lower conductor face each other in the vertical direction. A second positioning step of positioning the magnetic material in a second predetermined position located on a straight line extending in the vertical direction and passing through the first predetermined position, and a second tie bar supporting one or more upper conductors. While arranging the second lead frame with respect to the magnetic material so that the upper surface of the magnetic material and the upper conductor face each other in the vertical direction in the third preparation step of preparing the lead frame, the upper conductor is placed in the second predetermined position. It is provided with a third positioning step of positioning at a third predetermined position located on a straight line extending in the vertical direction and passing through the position. By having these steps, it is possible to position the lower conductor, the magnetic material, and the upper conductor only by positioning the first lead frame of the lower conductor, the magnetic material, and the second lead frame of the upper conductor. The number of steps is also reduced.

It is a perspective view which shows the coil component by embodiment of this invention. The circuit board is shown by a dotted line in the figure. It is an exploded perspective view which shows the coil component of FIG. In the figure, a part of the upper conductor is enlarged and shown. It is a perspective view which shows the lower conductor included in the coil component of FIG. In the figure, a part of the lower conductor is enlarged and shown. It is a perspective view for demonstrating the manufacturing method of the lower conductor of FIG. Here, the flat metal plate is supported by the first lead frame by the first tie bar. Further, the flat metal plate does not have a bent portion or a gap. It is another perspective view for demonstrating the manufacturing method of the lower conductor of FIG. Here, the flat metal plate is supported by the first lead frame by the first tie bar. Further, the flat metal plate has a bent portion formed, but no gap is formed. It is still another perspective view for demonstrating the manufacturing method of the lower conductor of FIG. Here, the flat metal plate is supported by the first lead frame by the first tie bar. Further, a bent portion and a gap are formed in the flat metal plate. In the figure, a part of the lower conductor is enlarged and shown. It is a perspective view for demonstrating the manufacturing method of the coil component of FIG. Here, the lower conductor is supported by the first lead frame by the first tie bar, and the upper conductor is supported by the second lead frame by the second tie bar. Further, the first jig, the first lead frame, the second jig, the magnetic material, the through conductor, and the second lead frame are shown with their positions shifted in the vertical direction. In the figure, a part of the upper conductor is shown in an enlarged manner, and a part of the second jig is shown by a dotted line. It is another perspective view for demonstrating the manufacturing method of the coil component of FIG. Here, the lower conductor is supported by the first lead frame by the first tie bar, and the upper conductor is supported by the second lead frame by the second tie bar. Further, the first jig, the first lead frame, the second jig, the magnetic material, the through conductor, and the second lead frame are overlapped in the vertical direction. In the figure, a part of the first jig, a part of the first lead frame, and a part of the second jig are shown by dotted lines. It is a perspective view which shows the coil component of Patent Document 1. FIG.

(Coil parts)
As shown in FIGS. 1 and 2, the coil component 100 according to the embodiment of the present invention is mounted on the circuit board 800. The coil component 100 according to the embodiment of the present invention includes a magnetic body 200, one upper conductor 300, two lower conductors 400, and two through conductors 500. However, the present invention is not limited to this, and the coil component 100 includes a magnetic material 200, one or more upper conductors 300, two or more lower conductors 400, and two or more through conductors 500. You just have to.

With reference to FIGS. 1 and 2, the magnetic material 200 according to the present embodiment is formed by using a soft magnetic metal material. Specifically, the magnetic material 200 is mainly formed of a soft magnetic metal powder having a flat shape and a binder (insulating material) made of an insulating resin. Such a magnetic material 200 can be formed by binding soft magnetic metal powder with a binder. For example, a solvent, a thickener, and a thermosetting binder component (binder) are mixed with a soft magnetic metal powder to prepare a slurry, and the applied slurry is heated to volatilize the solvent to form a material for the magnetic material 200. can do. The magnetic material 200 preferably has a high relative permeability, for example 100 or more.

As shown in FIGS. 1 and 2, the magnetic material 200 of the present embodiment has a substantially rectangular parallelepiped shape. The magnetic body 200 has an upper surface 210 and a lower surface 220 in the vertical direction. The upper surface 210 of the magnetic body 200 is a surface facing upward in the vertical direction. The lower surface 220 of the magnetic body 200 is a surface facing downward in the vertical direction. Each of the upper surface 210 and the lower surface 220 is orthogonal to the vertical direction. In the present embodiment, the vertical direction is the Z direction. The upper part is in the + Z direction, and the lower part is in the −Z direction.

As shown in FIG. 2, the magnetic material 200 of the present embodiment is formed with two through-conductor accommodating holes 230. Each of the through conductor accommodating holes 230 is a substantially cylindrical hole that penetrates the magnetic material 200 in the vertical direction.

With reference to FIGS. 1 and 2, the upper conductor (flat plate conductor) 300 of the present embodiment is made of a conductive material. The upper conductor 300 has a flat plate shape orthogonal to the vertical direction. The upper conductor 300 of this embodiment is one. The present invention is not limited to this, and the coil component 100 may have two or more upper conductors 300. In this case, it is necessary to provide a gap between two or more adjacent upper conductors 300, and the gap between the gaps is preferably 0.1 mm or more in consideration of the insulation withstand voltage of the space. .. The upper conductor 300 has a base metal 320 and a plating layer 325. The base metal 320 of the present embodiment is made of copper. Further, the plating layer 325 of the present embodiment is made of tin from the viewpoints of ensuring the wettability of solder, facilitating resistance welding, preventing corrosion of the base metal 320, and the like. The upper conductor 300 is arranged on the upper surface 210 of the magnetic body 200. That is, the upper conductor 300 is arranged so as to cover the upper opening of the two through conductor accommodating holes 230 of the magnetic material 200.

With reference to FIG. 2, the upper conductor 300 of this embodiment has two cutting marks 310. However, the present invention is not limited to this, and the upper conductor 300 may have at least one cutting mark 310. The base metal 320 is exposed in a part of the cut mark 310 of the upper conductor 300.

With reference to FIG. 3, each of the lower conductors (flat plate conductors) 400 of the present embodiment is made of a conductive material. Each of the lower conductors 400 has a base metal 440 and a plating layer 445. The base metal 440 of the present embodiment is made of copper. Further, the plating layer 445 of the present embodiment is made of tin from the viewpoint of ensuring the wettability of solder, facilitating resistance welding, preventing corrosion of the base metal 440, and the like. With reference to FIGS. 1 and 2, each of the lower conductors 400 is located on the lower surface 220 of the magnetic material 200. That is, the two lower conductors 400 are arranged so as to cover the lower openings (not shown) of the two through conductor accommodating holes 230 of the magnetic material 200. The two lower conductors 400 are arranged in an orthogonal direction orthogonal to the vertical direction. In this embodiment, the orthogonal direction is the X direction. The present invention is not limited to this, and when the coil component 100 has two or more lower conductors 400, if the two or more lower conductors 400 are arranged in an orthogonal direction orthogonal to the vertical direction. good. A gap 410 is provided between the adjacent lower conductors 400. The gap 410 has a staircase shape when viewed along the vertical direction. The distance between the gaps 410 is preferably 0.1 mm or more in consideration of the insulation withstand voltage of the space. The present invention is not limited to this, and when the coil component 100 has two or more lower conductors 400, gaps 410 may be provided in all of the adjacent lower conductors 400.

With reference to FIG. 3, each of the lower conductors 400 has two cut marks 430. The two cutting marks 430 are located on both sides in the width direction orthogonal to both the vertical direction and the orthogonal direction of the lower conductor 400. In the present embodiment, the width direction is the Y direction. However, the present invention is not limited to this, and the lower conductor 400 may have at least one cut mark 430. Further, each of the lower conductors 400 may have two or more cutting marks 430. The base metal 440 is exposed in a part of the cut mark 430 of the lower conductor 400. Further, the base metal 440 is exposed in the gap 410 of the lower conductor 400.

As shown in FIG. 3, the lower conductor 400 of the present embodiment includes a flat surface portion 425 and a bent portion 420.

As shown in FIG. 3, the flat surface portion 425 of the present embodiment has a flat plate shape orthogonal to the vertical direction. With reference to FIGS. 1 and 2, the flat surface portion 425 faces the lower surface 220 of the magnetic body 200 in the vertical direction. The flat surface portion 425 of the lower conductor 400 on the + X side and the flat surface portion 425 of the lower conductor 400 on the −X side are arranged in the orthogonal direction. The flat surface portion 425 of the lower conductor 400 on the + X side and the flat surface portion 425 of the lower conductor 400 on the −X side are located on the same plane orthogonal to the vertical direction. A gap 410 is located between the flat surface portion 425 of the lower conductor 400 on the + X side and the flat surface portion 425 of the lower conductor 400 on the −X side.

With reference to FIG. 1, the bent portion 420 of the present embodiment is connected to a wiring (not shown) on the circuit board 800 when the coil component 100 is mounted on the circuit board 800. As shown in FIG. 3, the bent portion 420 of the present embodiment extends downward in the vertical direction from the outer end in the orthogonal direction of the flat surface portion 425. More specifically, the bent portion 420 of the lower conductor 400 on the + X side extends downward from the + X end of the flat surface portion 425, and the bent portion 420 of the lower conductor 400 on the −X side is the −X of the flat surface portion 425. It extends downward from the edge. The bending portion 420 of the present embodiment has a bending angle of about 90 ° with respect to the flat surface portion 425. The present invention is not limited to this, and the bent portion 420 may have a bending angle of 80 ° or more and 100 ° or less with respect to the flat surface portion 425. By having the bent portion 420 having such a bending angle, it is possible to reduce the mounting area of the coil component 100 on the circuit board 800.

With reference to FIG. 2, each of the through conductors 500 of this embodiment is made of a conductive material. More specifically, each of the through conductors 500 is made of copper. Each of the through conductors 500 has a substantially cylindrical shape extending in the vertical direction. Each of the penetrating conductors 500 penetrates the inside of the magnetic body 200 in the vertical direction. In the coil component 100 of the present embodiment, the upper conductor 300 and the lower conductor 400 are connected to each other by a through conductor 500. More specifically, the flat surface portion 425 of the lower conductor 400 on the + X side is connected to the upper conductor 300 by the through conductor 500 on the + X side, and the flat surface portion 425 of the lower conductor 400 on the −X side is −. It is connected to the upper conductor 300 by the through conductor 500 on the X side. That is, the lower surface of the through conductor 500 on the + X side is connected to the upper surface of the flat surface portion 425 of the lower conductor 400 on the + X side, and the lower surface of the through conductor 500 on the −X side is the lower conductor 400 on the −X side. It is connected to the upper surface of the flat surface portion 425 of. By connecting the upper conductor 300, the two through conductors 500, and the two lower conductors 400 as described above, the lower conductor 400 on the −X side, the through conductor 500 on the −X side, and the upper side are connected. A continuous conductive portion (coil) is formed in the order of the conductor 300, the through conductor 500 on the + X side, and the lower conductor 400 on the + X side. Further, the magnetic material 200 of the present embodiment functions as a magnetic core of the above-mentioned conductive portion (coil).

(Manufacturing method of coil parts)
With reference to FIGS. 2 and 4 to 8, the coil component 100 of the present embodiment is manufactured as follows.

First, referring to FIG. 4, a preparatory step of preparing a flat metal plate 485 supported by the first tie bar 470 in the first lead frame 450 is performed. Here, the first lead frame 450 has a first positioning hole 460, and the flat metal plate 485 is supported by the first lead frame 450 by four first tie bars 470. Further, the first positioning hole 460 is a hole that penetrates the first lead frame 450 in the vertical direction. The present invention is not limited to this, and the flat metal plate 485 may be supported by the first lead frame 450 by two or more first tie bars 470. Further, the first lead frame 450 may have two or more first positioning holes 460.

After performing the preparatory step, the plating step of plating the flat metal plate 485 with reference to FIG. 4 is performed. By this plating step, a plating layer 487 is formed on the surface of the base metal of the flat metal plate 485.

After performing the plating process, reference to FIGS. 4 to 6, a first lead frame 450 is prepared, in which the two lower conductors 400 arranged via the gap 410 are supported by the first tie bar 470, respectively. 1 Perform the preparation process. That is, in the method for manufacturing the coil component 100 of the present embodiment, a plating step for plating the flat metal plate 485 is provided before the first preparation step.

Specifically, the first preparation step of the present embodiment includes a bending step of bending a flat plate-shaped metal plate 485 supported by the first lead frame 450 to form a bent portion 420, and a bent flat plate-shaped metal plate. The dividing step of dividing the metal plate 490 to form two lower conductors 400 and forming a gap 410 between the two lower conductors 400, and pressing the lower conductor 400 in the vertical direction. It has a pressing process.

In the bending step of the first preparation step, the flat metal plate 485 supported by the first lead frame 450 is bent to form the two bent portions 420 with reference to FIGS. 4 and 5.

Further, in the dividing step of the first preparation step, referring to FIGS. 5 and 6, the flat plate-shaped metal plate 490 bent in the above-mentioned bending step is divided, and the two lower conductors 400 are separated. Along with the formation, a gap 410 is formed between the two lower conductors 400. That is, in the method for manufacturing the coil component 100 of the present embodiment, the dividing step is performed after the bending step. As a result, the distance between the gaps 410 between the lower conductors 400 can be set more precisely as compared with the case where the bending step is performed after the cutting step.

Further, in the pressing step of the first preparation step, referring to FIG. 6, a pressing step of pressing the lower conductor 400 supported by the first tie bar 470 against the first lead frame 450 along the vertical direction. To carry out. That is, in the method for manufacturing the coil component 100 of the present embodiment, a pressing step of pressing the lower conductor 400 in the vertical direction is provided after the dividing step. More specifically, by pressing the first lead frame 450 against the lower conductor 400 supported by the first tie bar 470 from below, the upper surface of the lower conductor 400 becomes the upper surface 472 of the first tie bar 470. The connection portion 480 between the lower conductor 400 and the first tie bar 470 is deformed so as to be located above.

By going through the above-mentioned bending step, breaking step, and pressing step, a first lead frame 450 is prepared in which two lower conductors 400 arranged via the gap 410 are supported by the first tie bar 470, respectively. At this time, each of the lower conductors 400 is supported by the first lead frame 450 by two first tie bars 470. Here, the connection portion 480 between the first tie bar 470 and the lower conductor 400 projects vertically from the lower conductor 400 by a length D1. Further, when the size of the first tie bar 470 in the vertical direction is D8, 0.5 ≦ D1 / D8 ≦ 0.95 is satisfied. Further, when the wall thickness of the lower conductor 400 is D2, 0.5 ≦ D1 / D2 ≦ 0.95 is satisfied. Further, 0.8 ≦ D1 / D8 ≦ 0.9 is more preferable, and 0.8 ≦ D1 / D2 ≦ 0.9 is more preferable. The present invention is not limited to this, as long as each of the lower conductors 400 is supported by the first lead frame 450 by one or more first tie bars 470, by two or more first tie bars 470. It may be supported by the first lead frame 450. If the number of the first tie bars 470 is larger, it is possible to further suppress the deformation and positional deviation of the lower conductor 400 and the deviation of the gap 410 between the lower conductors 400 when the above-mentioned bending process is performed. can.

The present invention is not limited to this, and in the first preparation step, a first lead frame 450 is prepared in which two or more lower conductors 400 arranged via the gap 410 are supported by the first tie bar 470, respectively. May be good. That is, in the first preparation step, the bent flat metal plate 490 is divided to form two or more lower conductors 400 and a gap 410 is formed between the two or more lower conductors 400. It may be provided with a dividing step.

Further, the first preparation step does not have to include a bending step of bending a flat metal plate 485 supported by the first lead frame 450 to form a bent portion 420. That is, in the first preparation step, the flat metal plate 485 supported by the first lead frame 450 is divided to form two or more lower conductors 400 and between the two or more lower conductors 400. It may be provided with only a dividing step that forms a gap 410 in the.

After performing the first preparation step, by positioning the first lead frame 450 in the predetermined plane S orthogonal to the vertical direction with reference to FIG. 7, the two lower conductors 400 are first placed on the predetermined plane S. The first positioning step of positioning to the predetermined position P1 is performed. More specifically, in the first positioning step, the first lead frame 450 is placed in the first positioning hole 460 with respect to the first jig 600 having the predetermined plane S and the first positioning protrusion 610. Is done by positioning so that it is accommodated. Here, the first positioning protrusion 610 is a protrusion protruding upward in the vertical direction from the predetermined plane S. The present invention is not limited to this, and by positioning the first lead frame 450 in a predetermined plane S orthogonal to the vertical direction, two or more lower conductors 400 are placed at the first predetermined positions on the predetermined plane S. The first positioning step of positioning to P1 may be performed. Further, the first jig 600 may have two or more first positioning protrusions 610.

After performing the first positioning step, referring to FIG. 2, the magnetic material 200 has an upper surface 210 and a lower surface 220 in the vertical direction and is provided with two through-conductor accommodating holes 230, and accommodates the through-conductor. The second preparation step of preparing the magnetic material 200 in which each of the holes 230 penetrates the magnetic material 200 in the vertical direction is performed. The specific manufacturing method of the magnetic material 200 is as described above, and the details will be omitted. The present invention is not limited to this, and is a magnetic material 200 having an upper surface 210 and a lower surface 220 in the vertical direction and provided with two or more through conductor accommodating holes 230, wherein the through conductor accommodating hole 230 is provided. A second preparation step may be performed in which the magnetic material 200 is prepared, each of which penetrates the magnetic material 200 in the vertical direction.

After performing the second preparation step, the magnetic material 200 is attached to the first lead frame 450 so that the lower surface 220 of the magnetic material 200 and the lower conductor 400 face each other in the vertical direction with reference to FIGS. 7 and 8. The second positioning step of positioning the magnetic body 200 at the second predetermined position P2 located on the straight line L extending in the vertical direction and passing through the first predetermined position P1 is performed. More specifically, in the second positioning step, the second jig 700 having the second positioning protrusion 710, the third positioning hole 720, and the magnetic material accommodating hole 730 is thirdly positioned with respect to the first jig 600. This is performed by positioning the first positioning protrusion 610 so as to be accommodated in the hole 720 and then accommodating the magnetic material 200 in the magnetic material accommodating hole 730. Here, the second positioning protrusion 710 is a protrusion that protrudes upward in the vertical direction. Further, the third positioning hole 720 is a hole that penetrates the second jig 700 in the vertical direction. The magnetic material accommodating hole 730 is a hole that penetrates the second jig 700 in the vertical direction. The present invention is not limited to this, and the second jig 700 may have two or more second positioning protrusions 710, or may have two or more third positioning holes 720. ..

After performing the second positioning step, referring to FIG. 7, a through conductor accommodating step of accommodating the through conductor 500 in each of the through conductor accommodating holes 230 of the magnetic material 200 is performed. At the end of the through conductor accommodating step, the two lower conductors 400 are located at the first predetermined position P1, the magnetic body 200 is located at the second predetermined position P2, and the lower surface 220 of the magnetic body 200 is located. And the upper surface of the flat surface portion 425 of the lower conductor 400 face each other in the vertical direction. Further, at the end of the through conductor accommodating step, the lower surface of the through conductor 500 on the + X side is in contact with the upper surface of the flat surface portion 425 of the lower conductor 400 on the + X side, and the lower surface of the through conductor 500 on the −X side is in contact with the upper surface. -It is in contact with the upper surface of the flat surface portion 425 of the lower conductor 400 on the X side. The present invention is not limited to this, and it is desired that the through conductor 500 has a diameter larger than the diameter of the through conductor accommodating hole 230, or that the through conductor 500 is fixed to the magnetic material 200 in advance by adhesion or caulking. In this case, the through conductor 500 may be accommodated in each of the through conductor accommodating holes 230 of the magnetic body 200 before the second positioning step. That is, when the through conductor 500 has a diameter larger than the diameter of the through conductor accommodating hole 230, or when the through conductor 500 is to be fixed to the magnetic body 200 in advance by adhesion, caulking, or the like, after the second preparation step. Therefore, a through conductor accommodating step may be provided before the second positioning step.

After performing the through conductor accommodating step, the third preparation step of preparing the second lead frame 350 in which the upper conductor 300 is supported by the second tie bar 370 is carried out with reference to FIG. 7. Here, the upper conductor 300 is supported by the second lead frame 350 by two second tie bars 370. Further, the connecting portion 380 between the second tie bar 370 and the upper conductor 300 protrudes from the upper conductor 300 in the vertical direction by a length D3. Further, when the size of the second tie bar 370 in the vertical direction is D6, 0.5 ≦ D3 / D6 ≦ 0.95 is satisfied. Further, when the wall thickness of the upper conductor 300 is D4, 0.5 ≦ D3 / D4 ≦ 0.95 is satisfied.
Further, 0.8 ≦ D3 / D6 ≦ 0.9 is more preferable, and 0.8 ≦ D3 / D4 ≦ 0.9 is more preferable. Further, the second lead frame 350 has a second positioning hole 360. Here, the second positioning hole 360 is a hole that penetrates the second lead frame 350 in the vertical direction. The present invention is not limited to this, and a third preparation step of preparing a second lead frame 350 in which one or more upper conductors 300 are supported by the second tie bar 370 may be performed. Further, the upper conductor 300 may be supported by the second lead frame 350 by one or more second tie bars 370, and may be supported by the second lead frame 350 by two or more second tie bars 370. .. Further, the second lead frame 350 may have two or more second positioning holes 360.

After performing the third preparation step, the second lead frame 350 is attached to the magnetic body 200 so that the upper surface 210 of the magnetic body 200 and the upper conductor 300 face each other in the vertical direction with reference to FIGS. 7 and 8. While arranging, the third positioning step of positioning the upper conductor 300 at the third predetermined position P3 located on the straight line L extending in the vertical direction and passing through the second predetermined position P2 is performed. Specifically, the third positioning step is performed by positioning the second lead frame 350 with respect to the second jig 700 so that the second positioning protrusion 710 is accommodated in the second positioning hole 360. .. At the end of the third positioning step, the two lower conductors 400 are located at the first predetermined position P1, the magnetic body 200 is located at the second predetermined position P2, and the upper conductor 300 is located at the third predetermined position P2. It is located at a predetermined position P3. Further, at the end of the third positioning step, the lower surface 220 of the magnetic body 200 and the upper surface of the flat surface portion 425 of the lower conductor 400 face each other in the vertical direction, and the upper surface 210 of the magnetic body 200 and the lower surface of the upper conductor 300 Are facing each other in the vertical direction. Further, at the end of the third positioning step, the lower surface of the through conductor 500 on the + X side is in contact with the upper surface of the flat surface portion 425 of the lower conductor 400 on the + X side in the vertical direction, and the through conductor 500 on the −X side is in contact with the upper surface. The lower surface of the is in contact with the upper surface of the flat surface portion 425 of the lower conductor 400 on the −X side in the vertical direction. In addition, at the end of the third positioning step, the upper surface of the through conductor 500 on the + X side and the upper surface of the through conductor 500 on the −X side are in contact with the lower surface of the upper conductor 300 in the vertical direction.

After performing the third positioning step, referring to FIG. 8, a joining step of joining the lower conductor 400 and the upper conductor 300 to the through conductor 500 is performed. Specifically, in the joining step of this embodiment, a structure composed of an upper conductor 300, a magnetic material 200, a through conductor 500, and a lower conductor 400 is sandwiched between two tungsten electrodes (not shown) in the vertical direction. By resistance welding with, the lower conductor 400 and the upper conductor 300 are joined to the through conductor 500, respectively. At the time of this resistance welding, one of the tungsten electrodes is in downward pressure contact with the upper surface of the upper conductor 300, which is located directly above the through conductor 500 to be welded, and is made of tungsten. The remaining one of the electrodes is in pressure contact with the lower surface of the flat surface portion 425 of the lower conductor 400, which is located directly below the through conductor 500 to be welded. Further, by applying a current to the two tungsten electrodes, the above-mentioned resistance welding is realized. As a result, the upper conductor 300, the lower conductor 400 and the through conductor 500 can be welded at the same time. The present invention is not limited to this, and the lower conductor 400 and the upper conductor 300 may be joined to the through conductor 500 with a conductive bonding agent such as a brazing material or solder.

After performing the joining step, referring to FIG. 8, the upper conductor separating step of separating the upper conductor 300 from the second lead frame 350 is performed. Specifically, the connecting portion 380 of the second tie bar 370 of the second lead frame 350 is cut from above with a cutting jig (not shown) to separate the second tie bar 370 and the upper conductor 300. At this time, the cut mark 310 (see FIG. 2) of the above-mentioned upper conductor 300 is formed. That is, a cut mark 310 (see FIG. 2) is formed on the upper conductor 300 after the upper conductor separation step. With reference to FIGS. 2 and 7, the vertical size D5 of the base metal 320 in the cut mark 310 satisfies 0.1 ≦ D5 / D6 ≦ 0.6.

Further, after performing the upper conductor separation step, the lower conductor separation step of separating the lower conductor 400 from the first lead frame 450 is performed. Specifically, after the second jig 700 is pulled upward and removed, the connection portion 480 of the first tie bar 470 of the first lead frame 450 is cut from above with a cutting jig (not shown), and the first The tie bar 470 and the lower conductor 400 are separated. At this time, a cut mark 430 (see FIG. 3) of the lower conductor 400 described above is formed. That is, a cut mark 430 (see FIG. 3) is formed on the lower conductor 400 after the lower conductor separation step. With reference to FIGS. 3 and 6, the vertical size D7 of the base metal 440 in the cut mark 430 satisfies 0.1 ≦ D7 / D8 ≦ 0.6.

The present invention is not limited to this, and the upper conductor separation step and the lower conductor separation step may be performed at the same time, or the lower conductor separation step may be performed before the upper conductor separation step.

Through these steps, the coil component 100 of the present embodiment is manufactured.

Although the present invention has been specifically described above with an embodiment, the present invention is not limited to this, and various modifications and changes can be made.

In the method for manufacturing the coil component 100 of the present embodiment, the positioning of the first jig 600 and the first lead frame 450, the positioning of the first lead frame 450 and the second jig 700, and the positioning of the second jig 700 And the second lead frame 350, one first positioning protrusion 610, one first positioning hole 460, one third positioning hole 720, one second positioning protrusion 710 and one second positioning hole 360. However, the present invention is not limited to this. That is, the first positioning protrusion 610, the first positioning hole 460, the third positioning hole 720, the second positioning protrusion 710, and the second positioning hole 360 are provided, respectively, and the first jig 600 and the first lead frame 450 are provided. , Positioning of the first lead frame 450 and the second jig 700, and positioning of the second jig 700 and the second lead frame 350 may be performed. By manufacturing the coil component 100 in this way, the positioning of the first jig 600 and the first lead frame 450, the positioning of the first lead frame 450 and the second jig 700, and the positioning of the second jig 700 The positioning with the second lead frame 350 can be performed more accurately, and the positioning of the two lower conductors 400, the magnetic body 200 and the upper conductor 300 can be performed more accurately.

The third positioning step of the present embodiment is performed by positioning the second lead frame 350 with respect to the second jig 700 so that the second positioning protrusion 710 is accommodated in the second positioning hole 360. However, the present invention is not limited to this. Positioning of the second lead frame 350 with respect to the second jig 700 may be performed by using the first positioning protrusion 610 of the first jig 600. That is, in the second positioning step, when the first positioning protrusion 610 is positioned so as to be accommodated in the third positioning hole 720, the first fixing protrusion 610 protrudes from the upper surface of the second jig 700. After configuring the first positioning protrusion 610 of the tool 600, the second lead frame 350 is positioned with respect to the second jig 700 so that the first positioning protrusion 610 is accommodated in the second positioning hole 360. May carry out the third positioning step.

100 Coil parts 200 Magnetic material 210 Upper surface 220 Lower surface 230 Through conductor accommodation hole 300 Upper conductor (flat conductor)
310 Cut marks 320 Base metal 325 Plating layer 350 2nd lead frame 360 2nd positioning hole 370 2nd tie bar 380 Connection part 400 Lower conductor (flat conductor)
410 Gap 420 Bending part 425 Flat part 430 Cutting mark 440 Base metal 445 Plated layer 450 1st lead frame 460 1st positioning hole 470 1st tie bar 472 Top surface 480 Connection part 485 Metal plate 487 Plated layer 488 Top surface 490 Metal plate 500 Penetration Conductor 600 1st jig 610 1st positioning protrusion 700 2nd jig 710 2nd positioning protrusion 720 3rd positioning hole 730 Magnetic material accommodating hole D1 Length D2 Wall thickness D3 Length D4 Wall thickness D5 size D6 size D7 size D8 Size L Straight line S Predetermined plane P1 1st Predetermined position P2 2nd Predetermined position P3 3rd Predetermined position 800 Circuit board

Claims (10)

A method of manufacturing a coil component comprising two or more lower conductors, a magnetic material, two or more through conductors, and one or more upper conductors.
The first preparation step of preparing a first lead frame in which the two or more lower conductors arranged through the gap are supported by the first tie bar, respectively.
A first positioning step of positioning the first lead frame in a predetermined plane orthogonal to the vertical direction to position the two or more lower conductors at the first predetermined position on the predetermined plane.
The magnetic material having an upper surface and a lower surface in the vertical direction and provided with two or more through conductor accommodating holes, each of the through conductor accommodating holes penetrates the magnetic material in the vertical direction. The second preparation step of preparing the magnetic material is
While arranging the magnetic material with respect to the first lead frame so that the lower surface of the magnetic material and the lower conductor face each other in the vertical direction, the magnetic material passes through the first predetermined position. In addition, a second positioning step of positioning at a second predetermined position located on a straight line extending in the vertical direction,
A through-conductor accommodating step of accommodating the through-conductor in the through-conductor accommodating hole,
A third preparation step of preparing a second lead frame in which the one or more upper conductors are supported by the second tie bar, and
While arranging the second lead frame with respect to the magnetic material so that the upper surface of the magnetic material and the upper conductor face each other in the vertical direction, the upper conductor passes through the second predetermined position and passes through the second predetermined position. A third positioning step of positioning at a third predetermined position located on a straight line extending in the vertical direction,
A joining step of joining the lower conductor and the upper conductor to the through conductor, respectively.
An upper conductor separation step of separating the upper conductor from the second lead frame after the joining step.
A method for manufacturing a coil component including a lower conductor separation step of separating the lower conductor from the first lead frame after the joining step.
The first preparation step is
A dividing step in which a flat metal plate supported by the first lead frame is divided to form the two or more lower conductors and the gap is formed between the two or more lower conductors. Equipped with
A plating step for plating the flat metal plate is provided before the first preparation step.
The lower conductor, the through conductor, and the upper conductor form a coil of the coil component.
Manufacturing method of coil parts . A method of manufacturing a coil component comprising two or more lower conductors, a magnetic material, two or more through conductors, and one or more upper conductors.
The first preparation step of preparing a first lead frame in which the two or more lower conductors arranged through the gap are supported by the first tie bar, respectively.
A first positioning step of positioning the first lead frame in a predetermined plane orthogonal to the vertical direction to position the two or more lower conductors at the first predetermined position on the predetermined plane.
The magnetic material having an upper surface and a lower surface in the vertical direction and provided with two or more through conductor accommodating holes, each of the through conductor accommodating holes penetrates the magnetic material in the vertical direction. The second preparation step of preparing the magnetic material is
While arranging the magnetic material with respect to the first lead frame so that the lower surface of the magnetic material and the lower conductor face each other in the vertical direction, the magnetic material passes through the first predetermined position. In addition, a second positioning step of positioning at a second predetermined position located on a straight line extending in the vertical direction,
A through-conductor accommodating step of accommodating the through-conductor in the through-conductor accommodating hole,
A third preparation step of preparing a second lead frame in which the one or more upper conductors are supported by the second tie bar, and
While arranging the second lead frame with respect to the magnetic material so that the upper surface of the magnetic material and the upper conductor face each other in the vertical direction, the upper conductor passes through the second predetermined position and passes through the second predetermined position. A third positioning step of positioning at a third predetermined position located on a straight line extending in the vertical direction,
A joining step of joining the lower conductor and the upper conductor to the through conductor, respectively.
An upper conductor separation step of separating the upper conductor from the second lead frame after the joining step.
After the joining step, the lower conductor separating step of separating the lower conductor from the first lead frame is provided.
It is a manufacturing method of coil parts.
The first preparation step is
A bending step of bending a flat metal plate supported by the first lead frame to form a bent portion.
It is provided with a dividing step of dividing the bent flat metal plate to form the two or more lower conductors and forming the gap between the two or more lower conductors.
A plating process for plating the flat metal plate is provided before the first preparation process.
The lower conductor, the through conductor, and the upper conductor form a coil of the coil component.
Manufacturing method of coil parts . The method for manufacturing a coil component according to claim 1 or 2 .
Each of the lower conductors is supported by the first lead frame by two or more of the first tie bars.
A method for manufacturing a coil component in which the upper conductor is supported by the second lead frame by two or more second tie bars. The method for manufacturing a coil component according to any one of claims 1 to 3 .
The connection portion between the first tie bar and the lower conductor protrudes from the lower conductor by the length D1 in the vertical direction.
When the size of the first tie bar in the vertical direction is D8, 0.5 ≦ D1 / D8 ≦ 0.95 is satisfied.
The connection portion between the second tie bar and the upper conductor protrudes from the upper conductor by the length D3 in the vertical direction.
A method for manufacturing a coil component that satisfies 0.5 ≦ D3 / D6 ≦ 0.95, where D6 is the size of the second tie bar in the vertical direction. The method for manufacturing a coil component according to any one of claims 1 to 4 .
A method for manufacturing a coil component, which comprises a pressing step of pressing the lower conductor along the vertical direction after the dividing step. The method for manufacturing a coil component according to any one of claims 1 to 5 .
The first lead frame has a first positioning hole and has a first positioning hole.
The second lead frame has a second positioning hole.
In the first positioning step, the first lead frame is positioned so that the first positioning protrusion is accommodated in the first positioning hole with respect to the first jig having the predetermined plane and the first positioning protrusion. Made by doing,
In the second positioning step, the second jig having the second positioning protrusion, the third positioning hole, and the magnetic material accommodating hole is provided with the first positioning protrusion in the third positioning hole with respect to the first jig. It is performed by accommodating the magnetic material in the magnetic material accommodating hole after positioning so as to be accommodated.
The third positioning step is performed by positioning the second lead frame with respect to the second jig so that the second positioning protrusion is accommodated in the second positioning hole. Method. The method for manufacturing a coil component according to any one of claims 1 to 6.
A preparatory step for preparing the flat metal plate supported by the first lead frame by two or more of the first tie bars is provided before the plating step.
Manufacturing method of coil parts. A coil component mounted on a circuit board
The coil component comprises a magnetic material, one or more upper conductors, two or more lower conductors, and two or more through conductors.
The magnetic material has an upper surface and a lower surface in the vertical direction, and has an upper surface and a lower surface.
The upper conductor is arranged on the upper surface of the magnetic material.
The lower conductor is arranged on the lower surface of the magnetic material.
The two or more lower conductors are arranged in an orthogonal direction orthogonal to the vertical direction.
Gap is provided in all of the adjacent lower conductors.
Each of the upper conductor and the lower conductor has at least one cutting mark.
Each of the upper conductor and the lower conductor has a base metal and a plating layer.
The base metal is exposed in a part of the cut mark, and the base metal is exposed.
The penetrating conductor penetrates the magnetic body in the vertical direction.
The upper conductor and the lower conductor are connected to each other by the through conductor .
In the gap, the base metal is exposed and
The lower conductor, the through conductor, and the upper conductor form a coil of the coil component.
Coil parts. The coil component according to claim 8 .
The lower conductor includes a bend and
The bent portion is a coil component that is connected to wiring on the circuit board when the coil component is mounted on the circuit board. The coil component according to claim 8 or 9 .
Each of the lower conductors is a coil component having two or more of the cut marks.

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