This application claims benefit of priority to Japanese Patent Application No. 2017-110925, filed Jun. 5, 2017, the entire content of which is incorporated herein by reference.
The present disclosure relates to a coil component such as a common mode choke coil.
In the past, examples of a coil component have been disclosed in Japanese Unexamined Patent Application Publication No. 2007-81228 and No. 2016-178140.
Japanese Unexamined Patent Application Publication No. 2007-81228 discloses a surface-mounted electronic component array to be mounted to another component. The array includes a base body having a substantially rectangular parallelepiped shape, and at least four outer electrodes formed on surfaces of the base body. The base body has a first surface that constitutes a mounting surface of the other component, four second surfaces adjacent to the first surface, and a third surface opposing to the first surface and adjacent to each of the second surfaces. Each of the outer electrodes includes a first electrode portion formed on the first surface, and a second electrode portion formed in continuation with the first electrode portion and extending to a corner between the second and third surfaces, any of the outer electrodes being substantially not formed on the third surface.
Japanese Unexamined Patent Application Publication No. 2016-178140 discloses a common mode noise filter including a multilayer body constituted by a plurality of laminated insulator layers, three coil conductors disposed inside the multilayer body, and outer electrodes connected to the coil conductors disposed inside the multilayer body. The three coil conductors are disposed on one of the insulator layers, each of the three coil conductors being provided in a spiral shape of one or more turns, and being formed to have a substantially rectangular outer shape made up of a long side and a short side when viewed in a plane perpendicular to a winding axis of the one or more spiral turns. Two of the three coil conductors are arranged with the long sides of the two coil conductors facing each other, and the short sides of the two coil conductors are arranged to face the long side of the remaining coil conductor.
With increasing size reduction of electronic components such as coil components, the size of an outer electrode provided in the electronic component tends to reduce. With further size reduction of the outer electrode, however, adhesion force between the outer electrode and the multilayer body is more apt to weaken. This may result in a possibility that the outer electrode peels off from the multilayer body upon application of mechanical stress.
Accordingly, the present disclosure provides a coil component in which adhesion force between an outer electrode and a multilayer body is increased, and in which high reliability is ensured.
According to a preferred embodiment of the present disclosure, there is provided a coil component including a multilayer body, at least one coil provided inside the multilayer body, and outer electrodes disposed on at least onesurface of the multilayer body. The multilayer body includes a first magnetic layer, an insulating layer laminated on the first magnetic layer, and a second magnetic layer laminated on the insulating layer. The coil has lead-out portions, each of which extends to the surface of the multilayer body and is connected to a respective one of the outer electrodes. The outer electrodes are each present over respective surfaces of the first magnetic layer, the insulating layer, and the second magnetic layer. A width of a portion of at least one of the outer electrodes contacting the insulating layer is larger than a width of each of portions of the one outer electrode contacting the first magnetic layer and the second magnetic layer.
With the above coil component according to the preferred embodiment of the present disclosure, the width of at least one of the outer electrodes at its portion contacting the insulating layer is larger than that of each of the portions of the one outer electrode contacting the first magnetic layer and the second magnetic layer. Therefore, adhesion force between the outer electrode and the multilayer body is increased, and peeling-off of the outer electrode can be prevented. Hence reliability of the coil component can be increased.
In the coil component according to another preferred embodiment of the present disclosure, the insulating layer contains glass and/or a composite material of glass and ferrite. With this embodiment, when the outer electrode contains glass, the adhesion force between the outer electrode and the multilayer body can be further increased due to interaction between a glass component contained in the outer electrode and a glass component contained in the insulating layer.
In the coil component according to still another preferred embodiment of the present disclosure, the outer electrode contains glass. With this embodiment, when the insulating layer contains glass and/or a composite material of glass and ferrite, the adhesion force between the outer electrode and the multilayer body can be further increased due to interaction between a glass component contained in the outer electrode and a glass component contained in the insulating layer.
In the coil component according to still another preferred embodiment of the present disclosure, the first magnetic layer and the second magnetic layer contain ferrite. With this embodiment, characteristics (such as an inductance value and DC superposed characteristics) of the coil component can be improved.
In the coil component according to still another preferred embodiment of the present disclosure, plural ones of the outer electrodes are present adjacent to each other on one surface of the multilayer body. With this embodiment, the distance between the outer electrodes adjacent to each other can be made relatively large in portions of the outer electrodes, and those portions contact the first magnetic layer and the second magnetic layer. It is hence possible to reduce a risk of the occurrence of a short circuit failure, and to enhance electrical reliability of the coil component.
In the coil component according to still another preferred embodiment of the present disclosure, the coil has lead-out portions, each of which extends to the surface of the insulating layer and is connected to a respective one of the outer electrodes. With this embodiment, the lead-out portion extend up to the surface of the insulating layer is connected to the relatively wide portion of the outer electrode. Therefore, the incidence of an exposure failure in the lead-out portion of the coil can be reduced.
In the coil component according to still another preferred embodiment of the present disclosure, the multilayer body further includes a first outermost insulating layer laminated under the first magnetic layer, and a second outermost insulating layer laminated on the second magnetic layer. In that case, the outer electrodes are each present over respective surfaces of the first outermost insulating layer, the first magnetic layer, the insulating layer, the second magnetic layer, and the second outermost insulating layer, and the first outermost insulating layer and the second outermost insulating layer contain glass and/or a composite material of glass and ferrite. With this embodiment, when the outer electrode contains glass, the adhesion force between the outer electrode and the multilayer body can be further increased due to interaction between a glass component contained in the outer electrode and a glass component contained in each of the first outermost insulating layer and the second outermost insulating layer.
In the coil component according to still another preferred embodiment of the present disclosure, widths of portions of at least one of the outer electrodes contacting the first outermost insulating layer and the second outermost insulating layer, are larger than the widths of the portions of the one outer electrode contacting the first magnetic layer and the second magnetic layer. With this embodiment, since the widths of the outer electrode in its portions contacting the first outermost insulating layer and the second outermost insulating layer are relatively large, the adhesion force between the outer electrode and each of the first outermost insulating layer and the second outermost insulating layer can be further increased.
In the coil component according to still another preferred embodiment of the present disclosure, a width of the insulating layer in a direction perpendicular to a lamination direction of the multilayer body is smaller than that of each of the first magnetic layer and the second magnetic layer in at least one of cross-sections that pass a center of the multilayer body and are perpendicular or parallel to the surface of the multilayer body where at least one of the outer electrodes is disposed. With this embodiment, a contact area between the outer electrode and the insulating layer can be increased. As a result, the adhesion force between the outer electrode and the multilayer body can be further increased.
In the coil component according to still another preferred embodiment of the present disclosure, 0≤L<R is satisfied such that, in a cross-section passing a center of the multilayer body and being perpendicular to a lamination direction of the multilayer body, R represents the radius of curvature of a corner formed by a first side of the multilayer body contacting any one of the outer electrodes and a second side of the multilayer body adjacent to the first side, and L represents a shortest distance from the second side to the one outer electrode along a direction parallel to the first side. With this embodiment, the contact area between the outer electrode and the multilayer body can be further increased. As a result, the adhesion force between the outer electrode and the multilayer body can be further increased.
In the coil component according to still another preferred embodiment of the present disclosure, a value of R is not less than about 0.01 mm, and a rate of R with respect to a length of the first side is not more than about 9%. With this embodiment, the contact area between the outer electrode and the multilayer body can be further increased. As a result, the adhesion force between the outer electrode and the multilayer body can be further increased.
Other features, elements, characteristics and advantages of the present disclosure will become more apparent from the following detailed description of preferred embodiments of the present disclosure with reference to the attached drawings.
The present disclosure will be described in detail below in connection with illustrated embodiments. It is to be noted that shapes, arrangements, etc. of coil components and constituent elements according to the embodiments of the present disclosure are not limited to examples described in the following embodiments and illustrated in the drawings.
The multilayer body 2 includes a first magnetic layer 22, an insulating layer 21 laminated on the first magnetic layer 22, and a second magnetic layer 23 laminated on the insulating layer 21. In other words, the multilayer body 2 includes the insulating layer 21, and the first magnetic layer 22 and the second magnetic layer 23 sandwiching the insulating layer 21 therebetween in a vertical direction.
The insulating layer 21 is made of an insulating material, such as a resin material, a glass material, or a glass ceramic. Preferably, the insulating layer 21 contains glass and/or a composite material of glass and ferrite. The glass may be, for example, alkali borosilicate glass. The composite material of glass and ferrite may be, for example, a composite material of alkali borosilicate glass and Ni—Cu—Zn based ferrite. When the insulating layer 21 contains such a glass component, adhesion force between the outer electrode and the multilayer body is increased as described later.
The first magnetic layer 22 and the second magnetic layer 23 are made of an oxide magnetic material. Preferably, each of the first magnetic layer 22 and the second magnetic layer 23 contains ferrite. The ferrite may be, for example, Ni—Cu—Zn based ferrite. With each of the first magnetic layer 22 and the second magnetic layer 23 containing the magnetic material, characteristics (such as an inductance value and DC superposed characteristics) of the coil component 1 can be improved. The first magnetic layer 22 and the second magnetic layer 23 may have the same composition or different compositions.
The multilayer body 2 is formed in a substantially rectangular parallelepiped shape. Corners of the multilayer body 2 may be rounded. A lamination direction of the multilayer body 2 is defined as a Z-axis direction, a direction along a long side of the multilayer body 2 is defined as an X-axis direction, and a direction along a short side of the multilayer body 2 is defined as a Y-axis direction. An X-axis, a Y-axis, and a Z-axis are perpendicular to one another. In the drawings, an upper side is defined as an upward direction in the Z-axis direction, and a lower side is defined as a downward direction in the Z-axis direction.
The coil component 1 includes coils as inner conductors. The coil component 1 illustrated in
The coils including the primary coil 3a and the secondary coil 3c are arranged inside the insulating layer 21 of the multilayer body 2. The primary coil 3a and the secondary coil 3c are successively positioned in the lamination direction of the multilayer body 2, and they constitute a common mode choke coil. The coils including the primary coil 3a and the secondary coil 3c are each made of a conductive material such as Ag, Ag—Pd, Cu, or Ni, for example. Each coil may further contain a metal oxide such as Al2O3.
The primary coil 3a and the secondary coil 3c have spiral patterns spirally wound in the same direction when viewed from above. Each of the coils including the primary coil 3a and the secondary coil 3c has, at both ends thereof, lead-out portions each of which extends up to the surface of the multilayer body 2 and is connected to any one of the outer electrodes. More specifically, one end of the primary coil 3a on the outer peripheral side of the spiral shape has one lead-out portion 3a-1 extending up to the surface 2a of the multilayer body 2, and the other end of the primary coil 3a at a center of the spiral shape has a pad portion 3a-2. The pad portion 3a-2 of the primary coil 3a is electrically connected to the other lead-out portion (denoted by a reference sign 3b in
The coil component 1 illustrated in
In the coil component 1 illustrated in
As discussed above, preferably, the coil 3a has, at the respective ends thereof, the lead-out portions 3a-1 and 3b which extend up to the respective surfaces 21a and 21b of the insulating layer 21. Lead-out portion 3a-1 is connected to any one of the outer electrodes 4a or 4c, and lead-out portion 3b is connected to any one of the outer electrodes 4b or 4d. Similarly, the coil 3c has, at the respective ends thereof, the lead-out portions 3c-1 and 3d which extend up to the respective surfaces 21a and 21b of the insulating layer 21. Lead-out portion 3c-1 is connected to any one of the outer electrodes 4a or 4c, and lead-out portion 3d is connected to any one of the outer electrodes 4b or 4d. A width W1 of a portion of each of the outer electrodes 4a through 4d contacting the insulating layer 21 is larger than a width W2 of the portions contacting each of the first magnetic layer 22 and the second magnetic layer 23. Therefore, the lead-out portions 3a-1, 3c-1, 3b and 3d of the coils 3a and 3c that extend up to the surfaces 21a and 21b of the insulating layer 21 as discussed above are connected to the relatively wide portions of the outer electrodes 4a through 4d. As a result, the incidence of exposure failures in the lead-out portions 3a-1, 3c-1, 3b and 3d of the coils 3a and 3c can be reduced.
The outer electrodes 4a through 4d are present over respective surfaces of the first magnetic layer 22, the insulating layer 21, and the second magnetic layer 23 as discussed herein. In the coil component 1 illustrated in
As discussed above, in at least one of the outer electrodes 4a through 4d, the width W1 of its portion contacting the insulating layer 21 is larger than the widths W2 of its portions contacting the first magnetic layer 22 and the second magnetic layer 23. In the coil component 1 illustrated in
Each of the outer electrodes 4a through 4d is made of a conductive material such as Ag, Ag—Pd, Cu, or Ni, for example. Preferably, each of the outer electrodes 4a through 4d contains glass such as alkali borosilicate glass. When the outer electrode 4 contains glass and the insulating layer 21 contains glass and/or a composite material of glass and ferrite, the adhesion force between the outer electrode 4 and the multilayer body 2 can be further increased due to interaction between a glass component contained in the outer electrode 4 and a glass component contained in the insulating layer 21. The effect of increasing the adhesion force due to the interaction between the glass component contained in the outer electrode 4 and the glass component contained in the insulating layer 21 is made more significant with the above-described feature; namely the width W1 of the outer electrode 4 in its portion contacting the insulating layer 21 is larger than the width W2 of the outer electrode 4 in its portion contacting each of the first magnetic layer 22 and the second magnetic layer 23.
In the coil component 1, plural ones of the outer electrodes 4 may exist adjacent to each other on one surface of the multilayer body 2. In the coil component 1 illustrated in
It is here assumed, as illustrated in
0≤L<R
When R and L satisfy the above formula, a contact area between the outer electrode 4 and the multilayer body 2 becomes larger than that in the case where R is smaller than L (see
The value of R is preferably not less than about 0.01 mm. A rate of R with respect to a length of the first side S1 of the multilayer body 2 in the XY-section is preferably not more than about 9%. It is here assumed that, as illustrated in
The values of R and L can be measured with a measuring microscope or a digital microscope, for example, in a cross-section that is obtained by cutting the multilayer body 2 perpendicularly to the lamination direction at a position of ½ of the height of the multilayer body 2 in the lamination direction. The length of the first side S1in the XY-section can be measured with a micrometer.
A method of manufacturing the coil component 1 will be described below.
The coils 3a and 3c are formed on insulator sheets each containing glass such as alkali borosilicate glass, or a composite material of glass, such as alkali borosilicate glass, and ferrite, such as Ni—Cu—Zn based ferrite. A method of forming the coils 3a and 3c is not limited to particular one, and it may be plating or screen printing, for example. A conductive material used in forming the coils 3a and 3c may be Ag, Ag—Pd, Cu, or Ni, for example, and may further contain a metal oxide such as Al2O3.
Via holes are bored in the insulating sheets by an appropriate technique, such as laser processing, and via conductors are formed by filling the conductive material in the via holes such that, when the insulating sheets are laminated into a multilayer body 2, the multilayer body 2 functions as the coil component 1, such as a common mode choke coil, an inductance element, or an LC composite component, with the conductive materials in some layers being connected to those in other layers through the via conductors. The insulator sheets are laminated and sandwiched between the first magnetic layer and the second magnetic layer, each containing the magnetic material such as Ni—Cu—Zn based ferrite, from above and below. The multilayer body 2 thus obtained is subjected to pressure bonding with isostatic press, for example, and is cut into individual chip-like multilayer bodies each having a predetermined shape. The chip-like multilayer bodies are fired, and chips after the firing are subjected to barrel polishing, thereby removing burrs on surfaces of the multilayer bodies.
An outer electrode paste is coated over the surfaces of each of the multilayer bodies to form outer electrode patterns corresponding to two or more outer electrodes 4. The outer electrode paste is coated such that a portion of the outer electrode pattern, the portion being positioned on the insulating layer, has a larger width than each of portions thereof being positioned in the first magnetic layer and the second magnetic layer. The outer electrodes 4 are formed by baking the outer electrode paste that has been coated in the pattern forms as described above. Plating may be applied to the outer electrodes 4. Thus, the coil component 1 according to this embodiment can be obtained.
In the coil component 1A according to the second embodiment, as illustrated in
Preferably, widths W1 of at least one of the outer electrodes 4 in its portions contacting the first outermost insulating layer 24 and the second outermost insulating layer 25 are larger than the widths W2 of the one outer electrode 4 in its portions contacting the first magnetic layer 22 and the second magnetic layer 23. Since the widths of the one outer electrode in its portions contacting the first outermost insulating layer 24 and the second outermost insulating layer 25 are relatively large, the adhesion force between the outer electrode and each of the first outermost insulating layer 24 and the second outermost insulating layer 25 can be further increased, and the effect of suppressing the outer electrode from peeling off from the multilayer body 2A can be made more significant.
The glass and/or the composite material of glass and ferrite possibly contained in the first outermost insulating layer 24 and the second outermost insulating layer 25 may be similar to the glass and/or the composite material possibly contained in the insulating layer 21. The first outermost insulating layer 24 and the second outermost insulating layer 25 may have the same composition as the insulating layer 21, or a different composition from that of the insulating layer 21. The first outermost insulating layer 24 and the second outermost insulating layer 25 may have the same composition or different compositions.
In the coil component 1B according to the third embodiment, as illustrated in
The shape of the multilayer body 2 according to the third embodiment can be formed by appropriately adjusting a processing time, a diameter of barrel media, a barrel rotation speed, etc. when barrel polishing is performed on the multilayer body 2. While, in the coil component 1B illustrated in
As illustrated in
On condition of the coil components having the same overall sizes, there is a tendency that, in the coil component IC according to the fourth embodiment and including the six outer electrodes, the width of each outer electrode 4 is smaller than that in the coil component 1 according to the first embodiment and including the four outer electrodes 4. In the coil components according to the embodiments of the present disclosure, however, the adhesion force between the outer electrode 4 and the multilayer body 2 can be increased, and the outer electrode 4 can be prevented from peeling off from the multilayer body. Accordingly, the coil component providing the increased adhesion force between the outer electrode 4 and the multilayer body 2 and having high reliability can be obtained even when the size (width) of the outer electrode 4 is small.
Because the adhesion force between the outer electrode 4 and the multilayer body 2 is increased and high reliability is ensured, the coil components according to the preferred embodiments of the present disclosure can be applied to a variety of electronic devices, such as personal computers, DVD players, digital cameras, TV's, cellular phones, and car electronics.
While preferred embodiments of the disclosure have been described above, it is to be understood that variations and modifications will be apparent to those skilled in the art without departing from the scope and spirit of the disclosure. The scope of the disclosure, therefore, is to be determined solely by the following claims.
Number | Date | Country | Kind |
---|---|---|---|
2017-110925 | Jun 2017 | JP | national |