Patent Grant
11443888
The invention relates to a coil device used as such as an inductor and to a coil component disposed inside the coil device.
Many coil devices used as such as the inductor are mounted in various electronic and electric equipments. As an example of the coil component constituting the coil device, a coil component disclosed in the below Patent Document 1 has been developed. In the coil component disclosed in the below Patent Document 1, the coil component is constituted by forming a connection part and a bending part in a portion protruding from an annular coil pattern.
However, as the thickness of a conductive plate part constituting the coil component increases due to the miniaturization in size and the increase in current of the coil device, the connection part and the bending part protruding from the annular part cannot cope with downsizing.
In particular, when the coil device shown in Patent Document 1 is covered with the core made of a compression body including such as magnetic powder to constitute the coil device, the connection part and the bending part that protrude largely from the annular coil pattern are also covered with the core, and there is a problem that miniaturization in size of the coil device cannot be achieved. In addition, since the core covers the connection part and the bending part protruding from the annular coil pattern, the core covers a waste part that does not function as the coil, which is a waste of material and leads to an increase in cost.
Patent Document 1: Japanese Unexamined Patent Application Publication No. 2013-187454
The invention has been made in view of such circumstances, and an object thereof is to provide a coil component and a coil device which are easy to satisfy both miniaturization in size and an increase in current of the coil component.
In order to achieve the above object, the coil component according to the invention includes
a first conductive plate part formed with a first coil pattern having a first opening,
a second conductive plate part formed with a second coil pattern having a second opening and disposed at a predetermined interval in the laminating direction with respect to the first conductive plate part, and
a bent joining segment connecting the first conductive plate part and the second conductive plate part, wherein
the bent joining segment is made of the same single plate with the first conductive plate part and the second conductive plate, and
the bent joining segment directly connects a part of a first outer edge of the first coil pattern contacting (forming or defining) the first opening with a part of a second outer edge of the second coil pattern contacting (forming or defining) the second opening.
In the coil component according to the embodiment, the bent joining segment directly connects a part of the first outer edge of the first coil pattern forming the first opening and a part of the second outer edge of the second coil pattern forming the second opening. Therefore, it is possible to minimize the protruding amount of the bent joining segment protruding from the annular first coil pattern and the annular second coil pattern. Thus, it is easy to miniaturize the coil component in size.
In addition, since it is easy to reduce the size of the coil component, it is also easy to reduce the size of the coil device including the coil component and a compressed powder body having the coil component integrally incorporated therein. Further, since it is easy to reduce the size of the coil component, it is easy to reduce the size of the coil device including the coil component and the core member to which the coil component is mounted therein. Also, it is easy to make the first conductive plate part forming the first coil pattern and the second conductive plate part forming the second coil pattern to be relatively thick, and it becomes possible to increase the current flow flowing through the coil patterns.
Preferably, the bent joining segment is connected to the first coil pattern by a predetermined first end length extending from the first pattern end point of the first coil pattern along a periphery of the first opening, and to the second coil pattern by a predetermined second end length extending from the second pattern end point of the second coil pattern along a periphery of the second opening.
The width of the connection between the bent joining segment and the first coil pattern corresponds to the first end length, and the width of the connection between the bent joining segment and the second coil pattern corresponds to the second end length. And by keeping the lengths within the predetermined range, it is possible to suppress an increase in the electrical resistance at these connections.
Preferably, the first end length is longer than a first width of the first coil pattern, and the second end length is longer than a second width of the second coil pattern. With such configuration, it becomes possible to suppress a decrease in the cross sectional area of the bent joining segment and to suppress an increase in electrical resistance, even when the thickness of the bent joining segment is made thin. In addition, the first end length and the second end length are substantially the same. It is preferable that the width of the bent joining segment is substantially the same along the bending direction. The bent joining segment is not necessarily arranged at the same position toward the laminating direction, and both edge lines of the bent joining segment in the width direction may be inclined.
A first cutout recessed in the direction towards the first opening may be formed on the first coil pattern at a position apart from the first pattern end point by the first end length, and a second cutout recessed in the direction towards the second opening may be formed on the second coil pattern at a position apart from the second pattern end point by the second end length.
With such configuration, it is possible to further reduce the protruding amount of the bent joining segment projecting from the annular first coil pattern and the annular second coil pattern. Therefore, it is possible to further downsize the coil component.
Preferably, a bending concave is formed on a curved inner surface or a curved outer surface of the bent joining segment. The thickness of the bent joining segment may be smaller than the first thickness of the first coil pattern and smaller than the second thickness of the second coil pattern.
With the configuration, it is possible to further reduce the protruding amount of the bent joining segment, which protrudes from the annular first coil pattern and the annular second coil pattern. Therefore, it is possible to further reduce the size of the coil component. Further, by reducing the thickness of the bent joining segment, it becomes easy to further reduce the gap in laminating direction between the first coil pattern and the second coil pattern. As a result, it becomes possible to strengthen the magnetic coupling between these coil patterns, and such as the metal magnetic powder contained in the compressed powder body becomes difficult to enter between the coil patterns. Therefore, it becomes difficult to generate such as a short-circuit failure.
An insulating member is interposed between the first coil pattern and the second coil pattern. An adhesive is exemplified as the insulating member.
The first conductive plate part may have a first lead part connected to the first coil pattern at a first start point by a predetermined first start length extending from the first pattern start point of the first coil pattern along the periphery of the first opening.
The first lead part is preferably bent from a plane of the first coil pattern toward the laminating direction. With such configuration, it is possible to further reduce the size of the coil component. Preferably, a taper having a narrower width toward the distal end is formed at the distal end of the first lead part.
The distal end of the first lead part is exposed from such as the compressed powder body and forms a connection with the mounting part. By forming a taper at the distal end of the first lead part, it is possible to easily avoid contact with the compressed powder body containing the metallic magnetic material. And it is possible to effectively prevent a short circuit with the metallic magnetic material.
Preferably, the first conductive plate part other than the distal end of the first lead part is covered with an insulating layer. With such configuration, for example, it is possible to easily avoid contact with the compressed powder body containing a metallic magnetic material, and it is possible to effectively prevent a short circuit between the first conductive plate part and the metal magnetic body.
The second conductive plate part may have a second lead part connected to the second coil pattern at a second start point by a predetermined second start length extending from the second pattern start point of the second coil pattern along the periphery of the second opening. Preferably, the second lead part is bent from a plane of the second coil pattern toward the laminating direction and located outside the first coil pattern. With such configuration, it is possible to further downsize the coil component. Further, preferably, a distal end of the second lead part forms the taper whose width becomes narrower toward the distal end, similar to the first lead part. Also, preferably, the second conductive plate part is also covered with an insulating layer other than the front end part of the second lead part, similar to the first conductive plate part.
An inner side surface positioned at an end in a longitudinal direction of the first opening may have a first arcuate inner curved surface, an outer side surface of the first conductive plate part corresponding to the first arcuate inner curved surface may have a first corner protrusion, an inner side surface positioned at an end in a longitudinal direction of the second opening may have a second arcuate inner curved surface, and an outer side surface of the second conductive plate part corresponding to the second arcuate inner curved surface may have a second corner protrusion.
With such configuration, it becomes possible to extend the magnetic flux even to the core member or the compressed powder body located near the first corner protrusions and the second corner protrusions and to spread the magnetic flux to the entire core member and compressed powder body. And, it is possible to effectively use the corners of the core or the compressed powder body. Further, in the first corner protrusions, the cross sectional area of the first conductive plate part is widened and the electric resistance is lowered, and the cross sectional area of the second conductive plate part is widened and the electric resistance is lowered.
The coil device according to the first aspect of the invention includes the coil component described in any one of the above, and a compressed powder body containing a magnetic material, integrally covering an inside of the first opening, an inside of the second opening, an outer surface of the first coil pattern, an outer surface of the second coil pattern, and an outer surface of the bent joining segment of the coil component.
The coil device according to the second aspect of the invention includes the coil component described in any one of the above, and the core member compacted from a magnetic material and having the coil component mounted therein. The core member includes a central leg inserted into the insides of the first and the second openings of the coil component, a planar base disposed on an outer surface in the axial direction of the first coil pattern and an outer surface in the axial direction of the second coil pattern, and an outer leg disposed on an outer side surface of the first coil pattern, an outer side surface of the second coil pattern, and an outer side surface of the bent joining segment.
Hereinafter, the invention will be described based on embodiments shown in the drawings.
As shown in
The upper surface 4A of the core 4 is an outer surface opposite to the mounting side, substantially parallel to the lower surface 4B, and the four side surfaces 4C are substantially perpendicular to these upper and lower surfaces. However, the shape of the core 4 is not particularly limited, and it is not limited to a hexahedron but may be a cylindrical shape, an elliptical column, a polygonal column, etc.
Further, in the embodiment, the core 4 is formed so as to be elongated in the X-axis direction rather than the Y-axis direction. And the lead parts 66 and 67 shown in
As shown in
As shown in
In order to expose the lower end of each lead part 66 and 67 in the Z-axis direction in a range not less than the predetermined height Z1 not to contact the core 4, as shown in
With the configuration, it is possible to easily connect the lower ends of each lead part 66 and 67 to the land parts of the circuit board with such as solder, and the solder becomes difficult to adhere to the lower surface 4B of the core 4. Note that the insulating layer 64 described later is peeled at the lower ends of each lead part 66 and 67, and the surfaces of the metals constituting the lead parts 66 and 67 are exposed.
As shown in
As shown in
In the embodiment, the first coil pattern 61b has a pattern that surrounds the first opening slenderly elongated in the X-axis direction by approximately less than one round from the first pattern start point 61c to the first pattern end point 61d. A first cutout part is formed between the first pattern start point 61c and the first pattern end point 61d, and the first opening 61a is opened toward the outside at the first cutout. The cutout width of the first cutout part in the X-axis direction is not particularly limited as long as it is a width that maintains insulation between the first pattern start point 61c and the first pattern end point 61d.
The second coil pattern 62b has a pattern that surrounds the second opening slenderly elongated in the X-axis direction by approximately less than one round from the second pattern starting point 62c to the second pattern end point 62d. A second cutout part is formed between the second pattern starting point 62c and the second pattern end point 62d, and the second opening 62a is opened toward the outside at the second cutout. The cutout width of the second cutout part in the X-axis direction is not particularly limited as long as it is a width that maintains insulation between the second pattern start point 62c and the second pattern end point 62d.
In the embodiment, the first conductive plate part 61 and the second conductive plate part 62 are connected by a bent joining segment 63, made of the same single plate as the first conductive plate part 61 and the second conductive plate part 62. The bent joining segment 63 directly connect a part of the first outer edge of the first coil pattern 61b contacting (defining) the first opening 61a and a part of the second outer edge of the second coil pattern 62b contacting (defining) the second opening 62a.
That is, the bent joining segment 63 is integrally connected to the first outer edge of the first coil pattern 61b by a predetermined first end length X1 (the length in the X-axis direction) along a periphery of the first opening 61a from the first pattern end point 61d of the first coil pattern 61b. Further, the bent joining segment 63 is integrally connected to the second outer edge of the second coil pattern 62b by a predetermined second end length X2 (the length in the X-axis direction) along a periphery of the second opening 62a from the second pattern end point 62d of the second coil pattern 62b.
These end lengths X 1 and X 2 are preferably approximately the same but may be different. Further, in the embodiment, the X-axis direction position of the connection between the first coil pattern 61b and the bent joining segment 63, and the X-axis direction position of the connection between the second coil pattern 62 and the bent joining segment 63 are substantially the same but may be out of position in the X-axis direction.
In the embodiment, the first cutout 61e is preferably formed on the first coil pattern 61b at a position apart from the first pattern end point 61d by a first end length X1. The first cutout 61e is recessed in the direction opposite to the bending direction of the bent joining segment 63 (the direction towards the first opening 61a). Further, the second cutout 62e is preferably formed on the second coil pattern 62b at a position apart from the second pattern end point 62d by a second end length X2. The second cutout 62e is recessed in the direction opposite to the bending direction of the bent joining segment 63 (the direction towards the second opening 62a).
These cutouts 61e and 62e are not necessarily provided, but by being provided, it is possible to further reduce the protrusion amount of the bent joining segment 63 projecting in the Y-axis direction from the annular first coil pattern 61b and the annular second coil pattern 62b. Therefore, it is possible to further downsize the coil component 2.
The width in the X-axis direction of each cutout 61e and 62e is not particularly limited, but it is preferably around 0.1 to 2 times the thickness (thickness in the Z-axis direction) of the first conductive plate part 61 or the same of the second conductive plate part 62. The depth in the Y-axis direction of each cutout 61e and 62e is not particularly limited, but it is preferably around 0.1 to 0.7 times the width (width in the Y-axis direction) of the first conductive plate part 61 or the same of the second conductive plate part 62.
In addition, a recess 63a for bending is formed on the bent inner surface of the bent joining segment 63. As shown in
The first end length X1 shown in
In the embodiment, the representative first width W1 of the first coil pattern 61b shown in
As shown in
As shown in
The second starting length Y2 is preferably substantially the same as the first starting length Y1, but it is not always necessary to be the same. These lengths Y1 and Y2 are preferably equal to or greater than the representative first width W1 of the first coil pattern 61b shown in
As shown in
The metal constituting the first conductive plate part 61, the second conductive plate part 62 and the bent joining segment 63 is not particularly limited, but examples thereof include Cu, Al, Fe, Ag, Au, and alloys thereof. The insulating layer 64 is not particularly limited, but is formed of a metal oxide, a resin, etc.
The metal oxide constituting the insulating layer 64 is not particularly limited, but titanium oxide, alumite, etc. is exemplified. The resin constituting the insulating layer 64 is not particularly limited, but thermoplastic resins such as an epoxy resin, a urethane resin or a polyimide resin, thermosetting resins such as a melamine resin or a phenol resin, an ultraviolet curing resins such as epoxy resin, etc. are exemplified. Note that the method of applying the insulation coating or the oxide coating is not particularly limited, but an electrodeposition method, a vapor deposition method, a sputtering method, etc. are exemplified.
As shown in
With such configuration, it becomes possible to extend the magnetic flux to the core 4 as the compressed powder body located near the first corner protrusions 61g and the second corner protrusions 62g. Thus, it is possible to effectively use the corner part of the core 4 made of the compressed powder body. Further, at the first corner protrusions 61g, the cross sectional area of the first conductive plate part 61 is widened and the electric resistance is lowered, and at the second corner protrusions 62g, the cross sectional area of the second conductive plate part 62 is widened and the electric resistance is lowered.
As shown in
The core 4 is formed by compression compacting or injection molding of granules containing magnetic powder and binder. The magnetic powder is not particularly limited, but metal magnetic powder including Sendust (Fe—Si—Al; iron-silicon-aluminum), Fe—Si—Cr (iron-silicon-chromium), Permalloy (Fe—Ni), Carbonyl Iron type, Carbonyl Ni type, amorphous powder, nanocrystal powder, etc. are preferably used.
The grain diameter of the magnetic powder is preferably 0.5 to 50 μm. In the embodiment, it is preferable that the magnetic powder is the metal magnetic grain and the grain periphery is coated with insulation. As the insulation coating, a metal oxide coating, a resin coating, a chemical treated film such as phosphorus, zinc, etc. are exemplified.
However, as the magnetic powder, ferrite magnetic powder such as Mn—Zn, Ni—Cu—Zn, etc. may be used. The binder resin is not particularly limited, but examples thereof include an epoxy resin, a phenol resin, an acrylic resin, a polyester resin, a polyimide, a polyamideimide, a silicone resin, and a combination thereof.
In the embodiment, the lower surface 4B of the core 4 shown in
Although the size of the inductor element 2 of the embodiment is not particularly limited, for example, the width in X-axis direction is 1.0 to 20 mm, the width in Y-axis direction Y0 is 1.0 to 20 mm and the height Z0 is 1.0 to 10 mm. The inductor element 2 can be used as such as a transformer, a balun, a common mode filter (common mode choke), a circuit element such as a DC/DC converter, a choke coil in a power supply line, a decoupling element, an element for impedance matching, a component element for filter, an antenna element, etc.
Next, a method of producing the inductor element 2 shown in
The second conductive plate part 62 is integrally formed with each first conductive plate part 61 via the bent joining segment 63. The first coil pattern 61b having the first opening 61a is formed on the first conductive plate part 61. The first lead part 66 is formed at the first pattern start point 61c of the first coil pattern 61b. The second coil pattern 62b having the second opening 62a is formed at the second conductive plate part 62. The second lead part 67 is formed at the second pattern starting point 62c of the second coil pattern 62b.
The recess 63a for bending is formed on the surface of the bent joining segment 63, and only at the recess 63a for bending, the plate thickness is thinner than the other part. The thickness of the bent joining segment 63 at the recess 63a for bending corresponds to the thickness t0 shown in
Next, the second conductive plate part 62 shown in
As a polymer used for the electrodeposition solution for forming the insulating layer 64 by electrodeposition, various anionic or cationic synthetic polymer resins having electrodeposition properties can be mentioned. In order to impart adhesiveness to the polymer resins, an adhesive resin such as a rosin type, a terpene type, a petroleum resin, etc. may be added as required.
In particular, from the viewpoint of insulation, strength, and chemical stability, it is preferable that the insulating layer 64 is a polyimide resin. For example, the insulating layer 64 may be an insulating resin layer which is formed by electrodeposing an electrodeposition coating composition including polyimide resin containing an ionic group, an organic solvent capable of dissolving the polyimide resin, water, an ionic compound having polarity different from that of the ionic group, followed by drying and heat treating. Note that the insulating layer 64 may also be formed by heating and melting the resin, applying the molten resin to each of the conductive plate parts 61 and 62, and then curing the resin. Before or after the processes thereof, the second lead part 67 may be bent in a substantially vertical direction from the plane of the first coil pattern 62b.
Next, as shown in
Next, the main part of the coil component 6 is inserted into a press mold, the distal ends of the lead parts 66 and 67 are exposed from the press mold, and the core 4 is formed by compression compacting in the press mold (a molding step). At the time of compression compacting, the mixture containing the magnetic powder and the binder resin is filled in the cavity of the press mold, and the whole is heat compressed, whereby the inductor element 2 shown in
The heating temperature during the heat compression is preferably 50 to 300° C. and a compression pressure is preferably 1 to 400 Pa. As a method for the compression compacting, the press mold may be used, or oil pressure or water pressure may be used. In compression compacting, instead of the above-mentioned mixture, only the resin may be filled in the cavity. Also, the molding step may be omitted, and the main part of the coil component 6 may simply put into an exterior packaging (a sealing body) and fixed.
The lead frame 10 shown in
As shown in
In addition, since it is easy to reduce the size of the coil component 6, it is also easy to reduce the size of the inductor element 2 having the coil component 6 and the core 4 including the compressed powder body in which the coil component 6 is integrally incorporated. Further, it is easy to make the first conductive plate part 61 defining the first coil pattern 61b and the second conductive plate part 62 defining the second coil pattern 62b to be relatively thick, and it becomes possible to increase the current flow flowing through the coil patterns 61b and 62b.
In the embodiment, the width of the connection between the bent joining segment 63 and the first coil pattern 61b corresponds to the first end length X1, and the width of the connection between the bent joining segment 63 and the second coil pattern 62b corresponds to the second end length X2. And by keeping the lengths X1, X2 within the predetermined ranges, it is possible to suppress an increase in the electrical resistance at these connections.
In the embodiment, by setting the end lengths X1 and X2 shown in
Furthermore, in the embodiment, since the recess 63a for bending is formed on the bent inner surface of the bent joining segment 63, it is possible to further reduce the protruding amount of the bent joining segment 63 in the Y-axis direction, which protrudes from the annular first coil pattern 61b and the annular second coil pattern 62b. Therefore, it is possible to further reduce the size of the coil component 6.
Further, by reducing the thickness t0 (see
In the embodiment, as shown in
In the embodiment, since the conductive plate parts 61 and 62 are covered with the insulating layer 64 except for the distal ends of the lead parts 66 and 67, it is possible to easily avoid a contact of lead parts with the core 4 including such as the metal magnetic body. Thus, it is possible to effectively prevent a short circuit between the metal exposed surface of the conductive plate parts 61 and 62 and the metal magnetic body.
Further, in the embodiment, the second conductive plate part 62 has a second lead part connected to the second coil pattern 62b by a predetermined second starting length Y2 extending from the second pattern starting point 62c of the second coil pattern along the periphery of the second opening 62a. The second lead part 67 is bent from a plane of the second coil pattern 62b toward the laminating direction, and located outside the first coil pattern 61b. With such configuration, the coil component 6 can be further reduced in size.
Shown in
As shown in
In the embodiment, the first conductive plate part 161 and the second conductive plate part 162 are connected by a bent joining segment 163, made of the same single plate as the first conductive plate part 61 and the second conductive plate part 62. The bent joining segment 163 directly connect a part of the first outer edge of the first coil pattern 161b forming the first opening 161a and a part of the second outer edge of the second coil pattern 162b forming the second opening 162a.
That is, the bent joining segment 163 is integrally connected to the first outer edge of the first coil pattern 161b by the predetermined first end length X1 (see
In the embodiment, a recess 163a for bending is formed on the bent outer surface of the bent joining segment 63. At the recess 63a for bending, the thickness t0 (see
In the embodiment, the core has a lower core member 41 and an upper core member 42, which are formed in advance as separate members and are combined with the coil component 106 in a later step. The lower core member 41 has a base 41a having a substantially square plate shape. The outer legs 41c1 and 41c2 are integrally formed around the base 41a. The outer legs 41c1 and 41c2 are formed to protrude from the base 41a so as to have a predetermined height in the Z-axis direction and are formed to be separated from each other by a pair of cutouts 41e for lead.
The pair of cutouts 41e for lead are formed so as to allow the first lead part 66 and the second lead part 67, formed on both sides in the X-axis direction of the coil component 106, to extend outside of X-axis direction and downside of Z-axis direction from the base 41a. Also, the cutouts 41e make the outer legs 41c1 and 41c2 mutually separated.
In the substantially central part in the X-axis and the Y-axis directions of the base 41a, a central leg 41b is integrally formed so as to protrude in the Z-axis direction. The central leg 41b has a shape which can be inserted inside the first opening 161a of the coil device 106 and has substantially the same shape but slightly smaller than the internal shape of the first opening 161a.
As shown in
Further, the outer legs 42c1 and 42c2 are integrally formed around the base 42a. The outer legs 42c1 and 42c2 are formed to protrude from the base 42a so as to have a predetermined height in the Z-axis direction and are formed to be separated from each other by a pair of cutouts 42e for lead.
The pair of cutouts 42e1 and 42e2 for lead are formed so as to allow the first lead part 66 and the second lead part 67, formed on both sides in the X-axis direction of the coil component 106 shown in
The first lead part 66 of the coil component 106 is taken out from the first conductive plate part 161, a second lead part 67 is taken out from the second conductive plate part 162. Thus, taken out positions thereof in the Z-axis direction are different from each other. Therefore, the cutout 42e1 for lead corresponding to the first lead part 66 is not necessarily provided, and even if it is provided, the depth of the cutout 42e1 in the Z-axis direction may be set to be shallow compared to that of the other cutout 42e2 for lead.
In the embodiment, the central leg 41b of the lower core member 41 enters the first opening 161a of the coil component 106, the central leg 42b of the upper core member 42 enters the second opening 162a. And distal ends of the central legs 41b and 42b mutually abut to contact each other or face each other with a predetermined gap, in order to make a part of the magnetic circuit.
Further, the outer leg 41c1 of the core member 41 and the outer leg 42c1 of the core member 42 abut to contact each other in Z-axis direction at an outside of the bent joining segment 163 of the coil component 106, in order to constitute a part of the magnetic circuit. In addition, the outer leg 41c2 of the core member 41 and the outer leg 42c2 of the core member 42 face each other in Z-axis direction at the opposite outside of the bent joining segment 163 of the coil component 106 in order to constitute a part of the magnetic circuit.
As shown in
The length of the stepped part 41d in the X-axis direction is preferably substantially the same as the length of the bent joining segment 163 of the coil device 106 in the X-axis direction. In the coil component 106, as compared with a portion where the bent joining segment 163 is formed, the magnetic property as a coil becomes stronger in a portion of the coil component 106 positioned on the opposite side of the bent joining segment 163 in the Y-axis direction. Therefore, by providing the step 41d in the outer leg 41c2 (and/or 42c2) of the core member 41 or 42 and providing a gap in the facing part thereof, it becomes easy to balance the magnetic property on both sides of the coil device 106 in the Y-axis direction.
The core members 41 and 42 may bond at least at four corners with such as an adhesive. The core members 41 and 42 may bond between the outer leg 41c1 and the outer leg 42c1 and between the outer leg 41c2 and the outer leg 42c2. The core members 41 and 42 will surround main parts of the coil component 106 other than the lead parts 66 and 67. That is, bases 41a, 42a of the core members 41, 42 cover the outer surface of the first coil pattern 161b in the axial direction and the outer surface of the second coil pattern 162b in the axial core direction, respectively. The outer side surface of the first coil pattern 161b, the outer side surface of the second coil pattern 162b, and the outer side surface of the bent joining segment 163 are covered with the outer legs 41c1, 41c2, 42c1, and 42c2.
In the embodiment, the core members 41 and 42 can each be made of the magnetic material or the resin which are the same material as the core 4 of the first embodiment. Unlike the core 4, the core members 41 and 42 can also be made of a magnetic material of a sintered body not including the resin, since it is not necessary to integrally form with coil component 106 including metals. In the embodiment, unlike the core 4, the core members 41 and 42 can be made of magnetic materials such as Ni—Zn based ferrite, Mn—Zn based ferrite, Fe based powder, Fe-based sintered body, etc.
The coil component 106 and the inductor element 102 according to the embodiment have the same configurations as the coil component 6 and the inductor element 2 of the first embodiment and exhibit similar operational effects, except the descriptions above.
The invention is not limited to the above-described embodiments and can be variously modified within the scope of the invention.
For example, the coil component 6 includes two conductive plate parts 61 and 62 and a single bent joining segment 63 in the above embodiment, however, it may include three or more conductive plate parts and two or more bent joining segments.
2, 102 . . . Inductor element (Coil device)
4 . . . Core (Compressed powder body)
4A . . . Upper surface
4B . . . Lower surface
4C . . . Side surface
4D . . . Tapered concave
41 . . . Lower core member
42 . . . Upper core member
6, 106 . . . Coil component
61, 161 . . . First conductive plate part
62, 162 . . . Second conductive plate part
63, 163 . . . Bent joining segment
64 . . . Insulating layer
66 . . . First lead part
67 . . . Second lead part
8 . . . Adhesive (Insulating member)
10 . . . Lead frame
| Number | Date | Country | Kind |
|---|---|---|---|
| JP2018-090812 | May 2018 | JP | national |
| Number | Name | Date | Kind |
|---|---|---|---|
| 20040189430 | Matsutani et al. | Sep 2004 | A1 |
| 20060145804 | Matsutani | Jul 2006 | A1 |
| Number | Date | Country |
|---|---|---|
| S53-095136 | Aug 1978 | JP |
| H05-062006 | Aug 1993 | JP |
| H06-077077 | Mar 1994 | JP |
| 2003-188026 | Jul 2003 | JP |
| 2004-111457 | Apr 2004 | JP |
| 2004-296630 | Oct 2004 | JP |
| 2013-187454 | Sep 2013 | JP |
| Number | Date | Country | |
|---|---|---|---|
| 20190348211 A1 | Nov 2019 | US |
