This application is based upon and claims the benefit of priority from Japanese Patent Application No. 2021-054929, filed on 29 Mar., 2021, the entire contents of which are incorporated herein by reference.
The present disclosure relates to a multi-layer coil component.
Conventionally, known in the art is a multi-layer coil component in which a coil having a coil axis parallel to a stacking direction is provided in an element body having a stacking structure. Japanese Patent Laid-Open No. 2015-173197 (Patent Document 1) discloses a structure where a multi-layer coil component is solder-mounted on a substrate in a posture in which a coil axis of a coil is parallel to the substrate on which the multi-layer coil component is mounted.
In the multi-layer coil component according to the conventional art described above, when the mounted substrate is bent, bending stresses corresponding to the bending of the substrate are generated in the element body, and a crack may be generated starting from the mounting surface of the element body facing the substrate. The crack tends to propagate parallel to the layers of the element body, and the coil may be split.
According to various aspects of the present disclosure, there is provided a multi-layer coil component in which splitting of a coil due to a crack is prevented.
A multi-layer coil component according to an aspect of the present disclosure includes an element body including a plurality of layers stacked and having a mounting surface parallel to a stacking direction of the plurality of layers and a pair of end surfaces facing each other in a first direction parallel to the stacking direction of the plurality of layers, a coil provided in the element body and having a coil axis parallel to the first direction, a pair of external electrodes continuously extending from each of the end surfaces to the mounting surface of the element body, a pair of lead conductors penetrating a layer of the element body located between the coil and the end surface, the pair of lead conductors being electrically connected to end portions of the coil, the pair of lead conductors being exposed from the end surfaces of the element body and connected to the external electrodes; and a fragile portion provided in a layer through which the lead conductor penetrates, wherein, in a cross section orthogonal to the mounting surface and parallel to the coil axis, a distance from a tip position of the external electrode on the mounting surface to the fragile portion is shorter than a distance from the tip position of the external electrode on the mounting surface to the coil.
In the multi-layer coil component, when a crack is generated starting from the tip position of the external electrode on the mounting surface of the element body, the crack does not progress toward the coil but progresses toward the fragile portion located at a distance closer than the coil. As a result, splitting of the coil due to a crack is effectively prevented.
In the multi-layer coil component according to another aspect, the fragile portion has an elongated shape extending parallel to the first direction.
In the multi-layer coil component according to another aspect, a plurality of the fragile portions is provided in a layer of the element body located between one of the pair of end surfaces and the coil.
In the multi-layer coil component according to the other aspect, in a cross section orthogonal to the mounting surface and parallel to the coil axis, the fragile portion is provided on each of a side of the mounting surface and a side opposite to the mounting surface with respect to the coil axis.
In the multi-layer coil component according to another aspect, the fragile portion is a hole penetrating a layer of the element body.
Hereinafter, embodiments of the present disclosure will be described with reference to the accompanying drawings. In the description of the drawings, the same or equivalent element is denoted by the same reference numeral, and redundant description is omitted.
A structure of a multi-layer coil component according to an embodiment will be described with reference to
The element body 12 has a substantially rectangular parallelepiped outer shape and includes a pair of end surfaces 12a and 12b facing each other in the extending direction of the element body 12. The element body 12 further includes four side surfaces 12c to 12f extending in the direction in which the end surfaces 12a and 12b face each other and connecting the end surfaces 12a and 12b to each other. In the present embodiment, the side surface 12d is a mounting surface facing the mounting base when the multi-layer coil component 10 is mounted, and the side surface 12c facing the side surface 12d is a top surface when the multi-layer coil component 1 is mounted. When the dimension of the element body 12 in the facing direction of the end surfaces 12a and 12b is a length, the dimension in the facing direction of the side surfaces 12e and 12f is a width, and the dimension in the facing direction of the side surfaces 12c and 12d is a thickness, the dimension of the element body 11 is, for example, 0.7 mm length×0.3 mm width×0.45 mm thickness.
The element body 12 has a structure where an internal conductor 18 is provided inside a magnetic body 16. The element body 12 has a stacking structure. The magnetic body 16 has a stacking structure in which a plurality of magnetic layers 17 are stacked in a direction in which the end surfaces 12a and 12b face each other. In the present embodiment, the magnetic body 16 has a rectangular outer shape whose long sides are parallel to the facing direction of the side surfaces 12c and 12d when viewed from the stacking direction of the element body 12. In the following description, the facing direction of the end surfaces 12a and 12b is also referred to as a stacking direction or a first direction of the element body 12.
The magnetic body 16 is made of a magnetic material such as ferrite. The magnetic body 16 is obtained by stacking a plurality of magnetic sheets (ferrite green sheets) or magnetic pastes (for example, ferrite pastes) to be the magnetic body layers 17 and sintering the stacked magnetic sheets or magnetic pastes. That is, the element body 12 has a stacking structure and is a sintered element body, in which a plurality of magnetic layers 17 are stacked and sintered. The magnetic layer 17 constituting the element body 12 includes magnetic layers 17A in which coil layers 20b to 20e described later are formed, a magnetic layer 17B in which a connection layer 20a described later is formed, a magnetic layer 17C in which a connection layer 20f described later is formed, and magnetic layers 17D in which lead layers 23 described later are formed. As an example, the number of magnetic layers 17 constituting the element body 12 is 50 to 60 layers in total, the number of magnetic layers 17A is 40 to 50 layers, and the total number of magnetic layers 17B, 17C, and 17D is 10 to 20 layers. The number of magnetic layers 17 constituting the element body 12 can be increased or decreased as needed. In the actual element body 12, the plurality of magnetic layers 17 are integrated so that boundaries between the layers are not visible.
The thicknesses of the magnetic layers 17 are, for example, 5 to 10 μm for the magnetic layer 17A, 5 to 10 μm for the magnetic layer 17B, 15 to 20 μm for the magnetic layer 17C, and 15 to 20 μm for the magnetic layer 17D. All the magnetic layers 17 may have the same thickness (for example, 20 μm).
The inner conductor 18 includes a coil 20 and a pair of lead conductors 22A and 22B. Each of the coil 20 and the lead conductors 22A and 22B of the inner conductor 18 has a stacking structure in the stacking direction of the element body 12.
As shown in
In the present embodiment, as shown in
Each of the coil layers 20b to 20e has a U-shape when viewed from the stacking direction of the element body 12, and constitutes about 3/4 turn of the coil 20. For example, the coil layer 20b has a shape including one pair of short side portions and one long side portion of the coil 20 having a rectangular ring shape when viewed from the stacking direction of the element body 12. The coil layer 20c has a shape including one pair of long side portions and one short side portion of the coil 20 when viewed from the stacking direction of the element body 12. Similarly to the coil layer 20b, the coil layer 20d includes one pair of short side portions and one long side portion of the coil 20 when viewed from the stacking direction of the element body 12, and has a point symmetrical relationship with the coil layer 20b with respect to the coil axis Z. Similar to the coil layer 20c, the coil layer 20e includes one pair of long side portions and one short side portion of the coil 20 when viewed from the stacking direction of the element body 12, and has a point symmetrical relationship with the coil layer 20c with respect to the coil axis Z.
One set of the coil layers 20b to 20e arranged in order in the stacking direction of the element body 12 have end portions overlapping with each other in the stacking direction of the element body 12, and are electrically connected to each other via some via conductors (not shown) penetrating the magnetic layers 17A. One set of the coil layers 20b to 20e constitute three turns of the coil 20. In the present embodiment, the coil 20 includes a plurality of sets of the coil layers 20b to 20e.
The connection layer 20a is provided on the uppermost layer of the coil 20 and constitutes one end portion of the coil 20. The connection layer 20a is connected to a lower coil layer via the via conductor, and is connected to the upper lead layer 23 constituting one lead conductor 22A. The connection layer 20f is provided in the lowermost layer of the coil 20 and constitutes the other end portion of the coil 20. The connection layer 20f is connected to an upper coil layer via the via conductor, and is connected to the lower lead layer 23 constituting the other lead conductor 22B.
The pair of lead conductors 22A and 22B lead out the connection layers 20a and 20f constituting the end portions of the coil 20 to the end surfaces 12a and 12b of the element body 12. Each of the pair of lead conductors 22A and 22B is electrically connected to the connection layers 20a and 20f constituting the end portion of the coil 20. The pair of lead conductors 22A and 22B are exposed from the end surfaces 12a and 12b of the element body 12 and connected to the pair of external electrodes 14A and 14B, respectively.
Each of the pair of lead conductors 22A and 22B is provided to penetrate the magnetic layer 17D located between the coil 20 and the end surfaces 12a and 12b of the element body 12. Each of the pair of lead conductors 22A and 22B has a structure in which a plurality of lead layers 23 are stacked. In
As shown in
The pair of external electrodes 14A and 14B are provided on the end surfaces 12a and 12b of the element body 12, respectively. In the present embodiment, the external electrode 14A integrally covers the entire region of the end surface 12a and the side surfaces 12c to 12f of the region adjacent to the end surface 12a. Similarly, the external electrode 14B integrally covers the entire region of the end surface 12b and the side surfaces 12c to 12f of the region adjacent to the end surface 12b.
The multi-layer coil component 10 described above can be mounted on the substrate 50 by soldering as shown in
Here, when the substrate 50 is bent, bending stresses corresponding to the bending of the substrate 50 are generated in the element body 12 of the multi-layer coil component 10, and a crack may occur in the element body 12. The starting point of the crack may be a portion where stresses are likely to concentrate, that is, a tip position P of the external electrodes 14A and 14B on the mounting surface 12d of the element body 12 facing the substrate 50. When the crack progresses in parallel to the magnetic layer 17 of the element body 12 (that is, along the thickness direction of the element body 12), the coil 20 may be split by the crack.
In the multi-layer coil component 10 described above, the hole portion 30 (fragile portion) is provided in the magnetic layer 17D in which the lead conductors 22A and 22B are provided. Since the hole portion 30 is a depletion portion, the mechanical strength of the inside and the periphery of the hole portion 30 is lower than the mechanical strength of the portion where the magnetic material constituting the magnetic body 16 is present. As shown in
Therefore, when a crack is generated starting from the tip position P of the external electrodes 14A and 14B on the mounting surface 12d of the element body 12, the crack does not progress in the thickness direction of the element body 12 toward the coil 20, but progress in a direction intersecting the thickness direction of the element body 12 toward the hole portion 30 located at a distance closer than the coil 20. Therefore, in the multi-layer coil component 10, splitting of the coil 20 due to a crack 20 is effectively prevented.
The cross-sectional shape of the hole 31 constituting the hole portion 30 is not limited to a circular shape, and may be a polygonal shape or an elliptical shape. The positions of the holes 31 and the positions of the holes 31 in the magnetic layer 17D can be changed as needed. For example, as shown in
The holes 31 adjacent to each other in the stacking direction of the element body 12 may or may not communicate with each other.
Although the embodiments of the present disclosure have been described above, the present disclosure is not necessarily limited to the above-described embodiments, and various modifications can be made without departing from the gist thereof.
For example, the fragile portion may be hollow or solid. For example, the fragile portion may have a structure in which a through hole provided in a layer constituting the element body is filled with a filler. As the filler, a material (for example, a metal material such as Ag) that is more resistant to brittle fracture than the material of the layer constituting the element body can be employed.
The shape of the coil is not limited to the rectangular ring shape, and may be a square ring shape, a polygonal ring shape, a circular ring shape, or an elliptical ring shape. In the case that the coil has a square ring shape, the end surface shape and the cross-sectional shape of the element body may be a square.
The height position of the coil (i.e., the height position of the coil axis) of the element body with respect to the mounting surface is not limited to the intermediate position of the element body (position dividing the element body into two equal parts), and may be a position biased toward the side of the top surface facing the mounting surface.
Number | Date | Country | Kind |
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2021-054929 | Mar 2021 | JP | national |