This application is based upon and claims the benefit of priority from Japanese Patent Applications No. 2018-206490, filed on 1 Nov. 2018, and No. 2019-133002, filed on 18 Jul. 2019, the entire contents of which are incorporated herein by reference.
The present disclosure relates to a coil component.
In the related art, a coil component is known in which a coil is provided in an element body made of a magnetic material. Patent Literature 1 (Japanese Unexamined Patent Publication No. 2016-72615) discloses an element body having a configuration in which a coil is covered with binder powder in which metal magnetic powder is bound by binder resin.
The coil component is mounted along with various electronic components in many cases, and thus it is required that a magnetic flux adversely affecting the electronic components does not leak from the coil component. Patent Literature 2 (Japanese Unexamined Patent Publication No. 2017-76796) and Patent Literature 3 (Japanese Unexamined Patent Publication No. 2004-266120) disclose techniques for covering an element body surface with a shield layer made of a conductive material in order to suppress magnetic flux leakage from a coil component.
In a case where binder powder constitutes an element body surface as in the coil component disclosed in Patent Literature 1, the element body surface is likely to become uneven due to the metal magnetic powder exposed on the surface. Accordingly, when the element body surface is covered with a shield layer, the shield layer may undergo a thickness variation.
The present disclosure provides a coil component in which a shield layer is uniform in thickness.
A coil component according to an aspect of the present disclosure includes an element body including binder powder in which metal magnetic powder is bound by binder resin and a coil embedded in the binder powder and having a pair of main surfaces facing each other in an axial direction of the coil, an insulating layer covering one of the main surfaces of the element body, and a shield layer provided on the main surface via the insulating layer.
In the coil component, the binder powder constitutes the surface of the element body, and thus unevenness is likely to arise on the surface of the element body. However, the unevenness on the element body surface is smoothened by the insulating layer covering the element body surface. Accordingly, it is possible to suppress a thickness variation of the shield layer provided on the main surface via the insulating layer.
The coil component according to another aspect further includes a pair of external electrode terminals provided on the other main surface of the element body and electrically connected to both end portions of the coil.
In the coil component according to another aspect, the element body has a rectangular parallelepiped outer shape, the insulating layer covers the main surface and four side surfaces of the element body, and the shield layer is provided on the main surface and the four side surfaces via the insulating layer. In this case, magnetic flux leakage from the coil component is further suppressed by the shield layer.
In the coil component according to another aspect, the shield layer has a multilayer structure.
In the coil component according to another aspect, the binder powder has a metal magnetic powder content of 80 to 92 vol %.
Hereinafter, various embodiments will be described in detail with reference to the drawings. In the drawings, the same or corresponding parts are denoted by the same reference numerals without redundant description.
As illustrated in
The element body 10 has a rectangular parallelepiped outer shape and the upper surface 10a (one main surface) and the lower surface 10b (the other main surface) are parallel and face each other. The element body 10 has a coil portion 20 and a coating portion 30 and the coil portion 20 is embedded in the coating portion 30.
The coil portion 20 is provided with a coil C having an axis parallel to the up-down direction that is the direction in which the upper surface 10a and the lower surface 10b face each other.
The coil C has a substrate 22, an upper coil conductor 24A provided on an upper surface 22a of the substrate 22, a lower coil conductor 24B provided on a lower surface 22b of the substrate 22, and a pair of lead conductors 26A and 26B.
The substrate 22 has a flat plate rectangular shape and is disposed so as to be orthogonal to the up-down direction. The substrate 22 has a through hole 22c provided in a region corresponding to the axial center of the coil C. In addition, the substrate 22 has a through hole 22d at a position corresponding to the outer peripheral side end portion of the upper coil conductor 24A. Further, the substrate 22 has a through hole 22e at a position where the inner peripheral side end portion of the upper coil conductor 24A and the inner peripheral side end portion of the lower coil conductor 24B overlap in the edge region of the through hole 22c. Usable as the substrate 22 is a substrate having a plate thickness of 60 μm with a glass cloth impregnated with cyanate resin (Bismaleimide Triazine (BT) resin: registered trademark). Polyimide, aramid, and the like can also be used in addition to the BT resin. Ceramic or glass can be used as the material of the substrate 22. The material of the substrate 22 can be a mass-produced printed circuit board material, or a resin material used for a BT, FR4, or FR5 printed circuit board in particular.
The upper coil conductor 24A and the lower coil conductor 24B are planar coils provided so as to surround the through hole 22c of the substrate 22. In other words, the coil C has a two-stage planar coil. Each of the coil conductors 24A and 24B can be wound in, for example, a circular shape, an elliptical shape, or a quadrangular shape when viewed from the up-down direction of the element body 10. The upper coil conductor 24A and the lower coil conductor 24B are connected via the through hole 22e of the substrate 22. Each of the coil conductors 24A and 24B can be made of a metal material such as Cu. In the present embodiment, each of the coil conductors 24A and 24B is formed by electrolytic plating of Cu.
The pair of lead conductors 26A and 26B extend from an end portion of the coil C to the lower surface 10b of the element body 10. The lead conductor 26A extends from the outer peripheral side end portion of the upper coil conductor 24A to the lower surface 10b of the element body 10 via the through hole 22d on the side surface 10c side of the element body 10. The lead conductor 26B extends from the outer peripheral side end portion of the lower coil conductor 24B to the lower surface 10b of the element body 10 on the side surface 10d side facing the side surface 10c.
The coil portion 20 is provided with coating resin 28 integrally covering each of the coil conductors 24A and 24B and the lead conductors 26A and 26B constituting the coil C. The coating resin 28 electrically insulates the coil C and the coating portion 30.
The coating portion 30 integrally covers the coil portion 20 and constitutes the surfaces 10a to 10f of the element body 10. Binder powder in which metal magnetic powder is bound by binder resin constitutes the coating portion 30. An iron-nickel alloy (permalloy alloy), carbonyl iron, an amorphous, non-crystalline or crystalline FeSiCr alloy, sendust, and so on are capable of constituting the metal magnetic powder. The binder resin is, for example, a thermosetting epoxy resin. In the present embodiment, the content of the metal magnetic powder in the binder powder is 80 to 92 vol % in volume percent and 95 to 99 wt % in mass percent. From the viewpoint of magnetic properties, the content of the metal magnetic powder in the binder powder may be 85 to 92 vol % in volume percent and 97 to 99 wt % in mass percent.
Each of the pair of external electrode terminals 40A and 40B has a rectangular shape. The pair of external electrode terminals 40A and 40B are provided on the side surface 10c side and the side surface 10d side of the lower surface 10b of the element body 10, respectively. The external electrode terminal 40A extends along the side corresponding to the side surface 10c on the lower surface 10b. The external electrode terminal 40A is connected via the lead conductor 26A to one end portion of the coil C (that is, the outer peripheral side end portion of the upper coil conductor 24A). The external electrode terminal 40B extends along the side corresponding to the side surface 10d on the lower surface 10b. The external electrode terminal 40B is connected via the lead conductor 26B to the other end portion of the coil C (that is, the outer peripheral side end portion of the lower coil conductor 24B). Cr, Cu, Ni, Sn, Au, solder, or the like can be used for the external electrode terminals 40A and 40B. The external electrode terminals 40A and 40B may have a multilayer structure. The external electrode terminals 40A and 40B may be made of a conductive resin containing silver powder. A Ni plating layer and a Sn plating layer may be formed on the surface layers of the external electrode terminals 40A and 40B.
The pair of ground electrode terminals 40C and 40D are provided near the longitudinal middle of the element body 10. The ground electrode terminal 40C extends along the side surface 10d from the lower surface 10b of the element body 10 and is connected to a Cu layer 51 of the shield layer 50 (described later) formed on the side surface 10d. The ground electrode terminal 40D extends along the side surface 10f from the lower surface 10b of the element body 10 and is connected to the Cu layer 51 of the shield layer 50 (described later) formed on the side surface 10f. Cr, Cu, Ni, Sn, Au, solder, or the like can be used for the ground electrode terminals 40C and 40D. The ground electrode terminals 40C and 40D may have a multilayer structure. The ground electrode terminals 40C and 40D may be made of a conductive resin containing silver powder. A Ni plating layer and a Sn plating layer may be formed on the surface layers of the ground electrode terminals 40C and 40D.
The shield layer 50 is a layer for preventing the magnetic flux of the coil C from leaking to the outside of the coil component 1. The shield layer 50 has a multilayer structure (two-layer structure in the present embodiment) and is the Cu layer 51 and a permalloy layer 52 in order from the side that is close to the element body 10. The thickness of the Cu layer 51 is, for example, 0.1 to 1 μm. The thickness of the permalloy layer 52 is, for example, 0.1 to 1 μm. The thickness of the permalloy layer 52 may be in the range of 0.1 to 10 μm. The shield layer 50 is provided so as to integrally cover the surfaces 10a, 10c, 10d, 10e, and 10f of the element body 10 via an insulating layer 45. The insulating layer 45 is made of epoxy resin in the present embodiment. The material constituting the insulating layer 45 is not limited to epoxy resin and may be glass or the like. The thickness of the insulating layer 45 is, for example, 1 to 5 μm.
Hereinafter, a procedure for manufacturing the coil component 1 described above will be described with reference to
The element body 10 is prepared as illustrated in
Subsequently, as illustrated in
Further, as illustrated in
In the coil component 1 described above, the insulating layer 45 is interposed between the Cu layer 51 and the surface of the element body 10 (such as the upper surface 10a) as illustrated in
In this regard, in the coil component 1, the shield layer 50 is provided after the unevenness of the surface of the element body 10 is smoothened by the surface being covered with the insulating layer 45. As a result, the Cu layer 51 of the shield layer 50 is provided on a smooth surface as illustrated in
In the coil component 1, the shield layer 50 is kept away from the surface of the element body 10 by the insulating layer 45. Accordingly, a separation distance d between the external electrode terminal 40A and the Cu layer 51 of the shield layer 50 can be sufficiently ensured even in a case where the external electrode terminal 40A is provided so as to be close to the side surface 10c of the element body 10 as illustrated in
The present disclosure is not limited to the embodiment described above and can be changed into various forms.
For example, the shield layer 50 does not necessarily have to be provided on the surfaces 10a, 10c, 10d, 10e, and 10f of the element body 10 without being provided on the lower surface 10b and the shield layer 50 may be provided at least on the upper surface 10a. The upper surface 10a of the element body 10 is a surface orthogonal to the axis of the coil C and is particularly likely to undergo magnetic flux leakage. Accordingly, it is possible to effectively suppress magnetic flux leakage by providing the shield layer 50 on the upper surface 10a of the element body 10. Magnetic flux leakage from the coil component 1 is suppressed more in a case where the shield layer 50 is provided on the surfaces 10a, 10c, 10d, 10e, and 10f of the element body 10 than in a case where the shield layer 50 is provided only on the upper surface 10a.
Illustrated in
The coil C is not limited to the configuration provided with the two-stage planar coil. The number of stages of the planar coil can be increased or decreased as appropriate. The coil may be a spiral coil.
The shield layer is not limited to the two-layer structure and may have a single-layer structure or a multilayer structure having three or more layers. In a case where the shield layer has a multilayer structure, shield effect improvement is achieved as compared with a case where the shield layer has a single-layer structure. The shield layer may be made of a material higher in magnetic permeability than the binder powder constituting the coating portion of the element body. The shield layer can be made of ferrite, Ni, a Ni alloy, or the like as well as the permalloy and Cu described above.
An insulating layer made of epoxy resin or the like may be further provided on the surface of the shield layer. In this case, the coil component 1 can be insulated from the outside. The insulating layer provided on the surface of the shield layer may have a form as illustrated in
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