The present disclosure relates to a coil component.
As an existing coil component (reactor), a main body portion of the coil component is made up of a magnetic core and a coil. The magnetic core is made of a composite material obtained by mixing metal magnetic particles with resin. The composite material of the magnetic core is manufactured from a soft magnetic composite material.
The soft magnetic composite material according to an existing technology has such a drawback that the magnetic permeability is low and, as a result, the inductance of a reactor manufactured from the soft magnetic composite material is low. In the existing technology, a method is configured to mix metal magnetic particles with resin in advance and then to form the mixed material into a designated shape. Therefore, there is a drawback that the amount of resin used to the amount of metal magnetic particles used increases. This leads to a decrease in the magnetic permeability of the obtained soft magnetic composite material, with the result that direct-current superposition characteristics undesirably deteriorate due to a decrease in density.
For this reason, there has been suggested a technology for making it possible to increase the density of obtained soft magnetic composite material by adding second particles with a smaller mean particle size to first particles with a high circularity and a large mean particle size to bury gaps between the particles. Thus, the magnetic core formed from the soft magnetic composite material has a high magnetic permeability, and the inductance of the reactor using the magnetic core can be improved, as described, for example, in Japanese Unexamined Patent Application Publication No. 2016-039331.
However, the soft magnetic composite material used for the magnetic core of the reactor described in Japanese Unexamined Patent Application Publication No. 2016-039331 uses a particle size having a high circularity, for example, a particle size of 100 μm to 200 μm so the magnetic permeability increases, while, on the other hand, there are concerns about an issue that a loss increases in a radio-frequency range.
Therefore, the present disclosure provides a coil component that provides a high magnetic permeability and that has good radio-frequency characteristics.
A coil component according to the disclosure includes an element assembly including a coil conductor formed by winding a conductor and a magnetic portion containing metal magnetic particles and resin, and an outer electrode electrically connected to an exposed surface, exposed on a surface of the element assembly, of an extended part of the coil conductor and disposed on the surface of the element assembly. The metal magnetic particles include first metal magnetic particles and second metal magnetic particles. A particle size distribution of the metal magnetic particles, calculated in accordance with a circle equivalent diameter obtained from a cross-sectional image in a cross section of the magnetic portion, has at least two peaks and at least one bottom. The metal magnetic particles larger than or equal to the bottom having a minimum frequency are defined as the first metal magnetic particles. Metal magnetic particles smaller than the bottom having the minimum frequency are defined as the second metal magnetic particles. The first metal magnetic particles include particles each having a recessed portion that satisfies a predetermined condition in the cross section. Where a minimum distance between distal ends at an opening of the recessed portion is Loi and a longest distance of line segments parallel to a line segment that has the minimum distance between the distal ends at the opening in line segments corresponding to chords in the recessed portion of a cross section of each of the second metal magnetic particles is L02, the predetermined condition is L02>L01. At least part of at least one of the second metal magnetic particles is disposed inside the recessed portion of at least one of the first metal magnetic particles.
With the coil component according to the disclosure, the particle size distribution of the metal magnetic particles, calculated in accordance with the circle equivalent diameter obtained from the cross-sectional image in the cross section of the magnetic portion, has at least two peaks and at least one bottom. The metal magnetic particles larger than or equal to the bottom having the minimum frequency are defined as the first metal magnetic particles, and the metal magnetic particles smaller than the bottom having the minimum frequency are defined as the second metal magnetic particles. The first metal magnetic particles include particles each having the recessed portion that satisfies the predetermined condition in the cross section, and at least part of at least one of the second metal magnetic particles is disposed inside the recessed portion of at least one of the first metal magnetic particles having the recessed portion. Therefore, the packing fraction of metal magnetic particles in the magnetic portion increases, so the magnetic permeability of the coil component is increased. The coil component according to the disclosure, in the magnetic portion containing metal magnetic particles and resin, includes the first metal magnetic particles each having the recessed portion that satisfies the predetermined condition in the cross section, and the predetermined condition is L02>L01 where the minimum distance between the distal ends at the opening of the recessed portion is L01 and the longest distance of line segments parallel to the line segment that has the minimum distance between the distal ends at the opening in line segments corresponding to chords in the recessed portion of a cross section of each of the first metal magnetic particles is L02. Therefore, the surface area of the first metal magnetic particles with respect to the volume of the magnetic portion is increased, with the result that an eddy current loss in a radio-frequency range reduces, and the coil component is usable even at further higher frequencies.
The above-described object, the other objects, features, and benefits of the disclosure will be further apparent from the following description of modes for carrying out the disclosure with reference to the accompanying drawings.
1. Coil Component
Hereinafter, a coil component according to an embodiment of the present disclosure will be described in detail with reference to the accompanying drawings.
The coil component 10 includes a rectangular parallelepiped element assembly 12 and outer electrodes 30.
(a) Element Assembly
The element assembly 12 includes a magnetic portion 14, and a coil conductor 16 embedded in the magnetic portion 14. The external shape of the element assembly 12 is a substantially rectangular parallelepiped shape. The element assembly 12 has a first major surface 12a and a second major surface 12b opposite to each other in a pressure direction x, a first side surface 12c and a second side surface 12d opposite to each other in a width direction y orthogonal to the pressure direction x, and a first end surface 12e and a second end surface 12f opposite to each other in a length direction z orthogonal to the pressure direction x and the width direction y. The dimensions of the element assembly 12 are not limited.
(b) Magnetic Portion
The magnetic portion 14 covers the coil conductor 16. The external shape of the magnetic portion 14 substantially coincides with the external shape of the element assembly 12 and is a substantially rectangular parallelepiped shape. The magnetic portion 14 is formed by heating and pressurizing a first molded body 50 and a second molded body 60 (described later) in a die. The magnetic portion 14 includes a plurality of metal magnetic particles and resin.
The resin is not limited. Examples of the resin include thermosetting resins and include organic materials, such as epoxy resin, phenolic resin, polyester resin, polyimide resin, and polyolefin resin. The resin material may be made up of only one material or may be made up of two or more resin materials.
The metal magnetic particles include first metal magnetic particles 40 and second metal magnetic particles 42.
The first metal magnetic particles 40 and the second metal magnetic particles 42 are not limited. Examples of the first metal magnetic particles 40 and the second metal magnetic particles 42 include iron, cobalt, nickel, and alloys containing one or two or more of them. Preferably, the first metal magnetic particles and the second metal magnetic particles are made of iron or iron alloy. The iron alloy is not limited. Examples of the iron alloy include Fe—Si, Fe—Si—Cr, Fe—Ni, and Fe—Si—Al. The first metal magnetic particles and the second metal magnetic particles each may be made of only one material or two or more materials.
The metal magnetic particles of each of the set of first metal magnetic particles 40 and the set of second metal magnetic particles 42 are defined as follows.
Initially, a median diameter (D50) that is a mean particle size of metal magnetic particles in the magnetic portion 14 is calculated from the cross-sectional images of particles. In other words, initially, the cross section of the coil component 10 is prepared by polishing, FIB, cross section milling, or the like with a method of measuring a circularity (described later) to expose the cross section of metal magnetic particles. Thus, an exposed surface is formed. After the exposed surface is formed by exposing the cross section, the exposed surface is observed with an SEM by a magnification of 500 to 5000. A circle equivalent diameter is calculated for 50 or more particles with an image analysis software WinROOF2018. A circle equivalent diameter is the diameter of a circle with the same area as the cross-sectional area of each of the metal magnetic particles. The circle equivalent diameter is calculated as a median diameter (D50) that is a mean particle size of the metal magnetic particles. As shown in
The metal magnetic particles larger than or equal to the bottom having the minimum frequency are defined as the first metal magnetic particles 40, and the metal magnetic particles smaller than the bottom having the minimum frequency are defined as the second metal magnetic particles 42. When there are only two peaks in the particle size distribution, the bottom between the peaks is a bottom having a minimum frequency.
The shape of each of the first metal magnetic particles 40 is spherical. The first metal magnetic particles 40 include the ones each having inside a spherical recessed portion 40a that satisfies a predetermined condition. As for the first metal magnetic particles 40 each having the recessed portion 40a, as shown in
As shown in
The peak having the maximum frequency in the particle size distribution of the first metal magnetic particles 40 is preferably greater than the peak having the maximum frequency in the particle size distribution of the second metal magnetic particles 42. Since particles with different particle sizes are included, the packing fraction increases, so the magnetic permeability of the magnetic portion 14 is increased, and the direct-current superposition characteristics are improved.
The mean circularity of the first metal magnetic particles 40 each having the recessed portion 40a is preferably less than or equal to 0.89.
For measurement of the circularity of each metal magnetic particle, calculation is performed as follows. In other words, where, in the cross section of each of the metal magnetic particles, the area of each of the metal magnetic particles is S and the perimeter is L, the circularity is defined as 4 πS/L2. The cross section of metal magnetic particles means the cross section of metal magnetic particles on an exposed surface formed to expose the element assembly 12 of the coil component 10 by polishing, focused ion beam (FIB), cross-section polisher (CP), or the like. After the cross section of the element assembly 12 is exposed to form the exposed surface, the metal magnetic particles are observed with a scanning electron microscope (SEM) by a magnification of 500 to 5000. An area S and a perimeter L are measured for 50 or more particles with an image analysis software WinROOF2018 (Mitani Corporation), and a mean circularity is calculated.
Where a total content of the first metal magnetic particles 40 and the second metal magnetic particles 42 is 100% in area, the content of the first metal magnetic particles 40 is preferably higher than or equal to 40% and lower than or equal to 85% (i.e., from 40% to 85%). When the content of the first metal magnetic particles 40 is higher than or equal to 70% and lower than or equal to 85% (i.e., from 70% to 85%), the effective magnetic permeability of the coil component 10 is increased.
Where a total content of the first metal magnetic particles 40 and the second metal magnetic particles 42 is 100% in area, the content of the second metal magnetic particles 42 is preferably higher than or equal to 15% and lower than or equal to 60% (i.e., from 15% to 60%). When the content of the second metal magnetic particle 42 is higher than or equal to 15% and lower than or equal to 30% (i.e., from 15% to 30%), the effective magnetic permeability of the coil component 10 is increased.
Here, the content of each of the set of first metal magnetic particles 40 and the set of second metal magnetic particles 42 is calculated as will be described below. In other words, the cross section of the magnetic portion 14 is exposed, and, for example, in a selected region of 500 μm×500 μm in the cross section, the content of each set of metal magnetic particles ((Content of first metal magnetic particles=Sa/(Sa+Sb), and (Content of second metal magnetic particles)=Sb/(Sa+Sb)) is calculated from the total sum of the cross-sectional areas of each set of metal magnetic particles (the total sum of cross-sectional areas S1 of the first metal magnetic particles 40 is Sa, and the total sum of cross-sectional areas S2 of the second metal magnetic particles 42 is Sb).
Each of the first metal magnetic particles 40 and each of the second metal magnetic particles 42 may have the same composition. Because of the same composition, the flow of magnetic flux inside the magnetic portion 14 is uniform, so the superposition characteristics are raised.
The composition of a metal magnetic particle can be analyzed as follows. In other words, the composition of a metal magnetic particle can be analyzed with a chemical composition analyzer, such as energy dispersive X-ray spectroscopy (EDX), (X-ray photoelectron spectroscopy (XPS), and time of flight secondary ion mass spectroscopy (TOF-SIMS).
In the magnetic portion 14, the content of resin (in area) is preferably higher than or equal to 5% and lower than or equal to 25% (i.e., from 5% to 25%). Thus, the area ratio of the metal magnetic particles contained in the magnetic portion 14 increases, so the magnetic permeability of the magnetic portion 14 is increased. When the content of resin is lower than or equal to 5%, flowability is not ensured during molding, so high filling is difficult to be obtained.
Here, in the magnetic portion 14, the content of resin is calculated as will be described below. In other words, the cross section of the magnetic portion 14 is exposed, and, for example, in a selected region of 500 μm×500 μm in the cross section, the content of resin is calculated as the area of resin to the area St of the selected region of 500 μm×500 μm.
In the cross section of the magnetic portion 14, as shown in
In the cross section of the magnetic portion 14, as shown in
In the cross section of the magnetic portion 14, of the first metal magnetic particles 40 each having the recessed portion 40a, the percentage of the number of the first metal magnetic particles 40 having the recessed portion 40a inside which at least part of at least one of the second metal magnetic particles 42 is disposed is higher than or equal to 50%. Since the percentage of the first metal magnetic particles 40 having the recessed portion 40a inside which the second metal magnetic particle 42 is disposed is high, the magnetic permeability of the magnetic portion 14 is increased.
In the cross section of the magnetic portion 14, when the whole of at least one of the second metal magnetic particles 42 is placed inside the recessed portion 40a of each of the first metal magnetic particles 40 as shown in
In the cross section of the magnetic portion 14, as shown in
In the cross section of the magnetic portion 14, as shown in
As for the first metal magnetic particles 40, where, as shown in
Here, the perimeter of the first metal magnetic particle 40 is measured from the cross section of the magnetic portion 14. In other words, the cross section of a metal magnetic particle is the cross section of a metal magnetic particle in an exposed surface formed by exposing a molded body cross section including the center of the element assembly 12 of the coil component 10 and orthogonal to the length direction z of the element assembly 12, by cross-section polisher (or polishing, FIB processing, or the like). After the exposed surface is formed by exposing the cross section of the element assembly 12, particles are observed with an SEM by a magnification of 500 to 5000. L1 and L2 are calculated with an image analysis software WinROOF2018. L1/L2 is calculated for 50 or more particles, and the average value is calculated by obtaining the average value of them.
As for the first metal magnetic particles 40, where, as shown in
L01 and Lc are measured from the cross-sectional image of the element assembly 12 of the coil component 10. Here, L01 and Lc of each of the first metal magnetic particles 40 are calculated by the following procedure. The cross section of a metal magnetic particle is the cross section of a metal magnetic particle in an exposed surface formed by exposing the cross section of the element assembly 12, including the center of the element assembly 12 of the coil component 10 and orthogonal to the length direction z of the element assembly 12, by cross-section polisher (or polishing, FIB processing, or the like). After the exposed surface is formed by exposing the cross section of the element assembly 12, particles are observed with an SEM by a magnification of 500 to 5000. L01 and Lc are calculated with an image analysis software WinROOF2018. L01 is a shortest distance between the distal ends at the opening 40b of each of the first metal magnetic particles 40. Lc is a perimeter other than the inside of the opening 40b of each of the first metal magnetic particles 40. L01/(Lc +L01) is calculated for 10 or more particles, and the average value is calculated by obtaining the average value of them.
As for the first metal magnetic particles 40, where, as shown in
S0 and Sc are measured from the cross-sectional image of the magnetic portion 14. Here, S0 and Sc of each of the first metal magnetic particles 40 can be calculated by the following procedure. The cross section of a metal magnetic particle is the cross section of a metal magnetic particle in an exposed surface formed by exposing the cross section of the element assembly 12, including the center of the element assembly 12 of the coil component 10 and orthogonal to the length direction z of the element assembly 12, by cross-section polisher (or polishing, FIB processing, or the like). After the exposed surface is formed by exposing the cross section of the element assembly 12, particles are observed with an SEM by a magnification of 500 to 5000. S0 and Sc are calculated with an image analysis software WinROOF2018. S0 is the area of the region R0 of the recessed portion 40a inside the line segment connecting the distal ends at the opening 40b of each of the first metal magnetic particles 40 by a shortest distance. Sc is the cross-sectional area of each of the first metal magnetic particles 40. S0/(Sc+S0) is calculated for 50 or more particles, and the average value is calculated by obtaining the average value of them.
The magnetic portion 14 preferably further contains inorganic oxide particles 44. The inorganic oxide particles 44 are, for example, a silica filler, ferrite, or glass. Since the inorganic oxide particles 44 have higher electric resistivity than the metal magnetic particles, the withstand voltage of the coil component 10 is improved when the magnetic portion 14 contains the inorganic oxide particles 44. The inorganic oxide particles 44 are preferably glass or non-magnetic ferrite. Since glass or non-magnetic ferrite has a high magnetic reluctance, the superposition characteristics of the coil component 10 are raised. The inorganic oxide particles 44 are preferably magnetic ferrite. Since magnetic ferrite has a high magnetic permeability, the magnetic permeability of the coil component 10 is further increased.
As for the first metal magnetic particles 40, as shown in
As for the first metal magnetic particles 40, as shown in
The surface of each of the first metal magnetic particles 40 and the second metal magnetic particles 42 may be covered with an electrically insulating coating. By covering the surface of each of the metal magnetic particles with the electrically insulating coating, the internal resistance of the magnetic portion 14 is increased. Since electrical insulating properties of the surface of each of the metal magnetic particles are ensured by the electrically insulating coating, a short-circuit failure between the coil conductor 16 and each of the outer electrodes 30 is suppressed.
As shown in
Examples of the material of the electrically insulating coating include silicon oxide, phosphoric acid glass, and bismuth glass.
The thickness of the electrically insulating coating is not limited and can be preferably greater than or equal to 5 nm and less than or equal to 500 nm (i.e., from 5 nm to 500 nm), more preferably greater than or equal to 5 nm and less than or equal to 100 nm (i.e., from 5 nm to 100 nm), and further preferably greater than or equal to 10 nm and less than or equal to 100 nm (i.e., from 10 nm to 100 nm). By further increasing the thickness of the electrically insulating coating, improvement in the withstand voltage characteristics of the magnetic portion 14 and improvement in direct-current superposition characteristics are expected. By further reducing the thickness of the electrically insulating coating, the amount of metal magnetic particles in the magnetic portion 14 is further increased, so the magnetic permeability of the magnetic portion 14 improves.
(c) Coil Conductor
The coil conductor 16 has a winding part 18, a first extended part 22a, and a second extended part 22b. The winding part 18 is formed by winding a conductor containing an electrically conductive material in a coil shape. The first extended part 22a is extended to one side of the winding part 18. The second extended part 22b is extended to the other side of the winding part 18. A hollow region 20 is formed at the center of the winding part 18. The winding part 18 is formed by winding in two stages. The coil conductor 16 is formed by winding a rectangular conductor in an α-winding shape. The first extended part 22a is exposed from the first end surface 12e of the element assembly 12 to form a first exposed portion 24a. The second extended part 22b is exposed from the second end surface 12f of the element assembly 12 to form a second exposed portion 24b. In the first exposed portion 24a, an exposed surface of the first extended part 22a is formed so as to intersect with an extension direction of the first extended part 22a. In the second exposed portion 24b, an exposed surface of the second extended part 22b is formed so as to intersect with an extension direction of the second extended part 22b.
The coil conductor 16 is made up of a conductor, such as a metal wire and a wire. The electrically conductive material of the coil conductor 16 is not limited and is, for example, a metal component made of Ag, Au, Cu, Ni, Sn, or an alloy of at least one of them. Preferably, the electrically conductive material is copper. The electrically conductive material may be made up of only one material or may be made up of two or more materials.
The surface of the conductor that makes up the coil conductor 16 is coated with an electrically insulating substance to form an electrically insulating film. By coating the conductor that makes up the coil conductor 16 with an electrically insulating substance, electrical insulation between portions of the wound coil conductor 16 and between the coil conductor 16 and the magnetic portion 14 is further ensured. No electrically insulating film is formed on each of portions respectively corresponding to the first exposed portion 24a and the second exposed portion 24b of the conductor that makes up the coil conductor 16.
The electrically insulating substance of the electrically insulating film is not limited. Examples of the electrically insulating substance include polyurethane, polyester resin, epoxy resin, polyamide-imide resin, and polyimide resin. Preferably, the electrically insulating film is polyamide-imide resin. The thickness of the electrically insulating film is preferably greater than or equal to 2 μm and less than or equal to 10 μm (i.e., from 2 μm to 10 μm).
No electrically insulating film is disposed on an exposed part (exposed surface) of each of the first exposed portion 24a and second exposed portion 24b of the coil conductor 16 on a corresponding one of both end surfaces 12e, 12f of the element assembly 12. Thus, the coil conductor 16 can be directly electrically connected to a first base electrode layer 32a and a second base electrode layer 32b, so it is possible to reduce electrical resistance between the coil conductor 16 and each of the first base electrode layer 32a and the second base electrode layer 32b.
(d) Outer Electrode
The outer electrodes 30 are respectively disposed on the first end surface 12e side of the element assembly 12 and the second end surface 12f side of the element assembly 12. The outer electrodes 30 include a first outer electrode 30a and a second outer electrode 30b.
The first outer electrode 30a is disposed on the surface of the first end surface 12e of the element assembly 12. The first outer electrode 30a may be formed so as to extend from the first end surface 12e and cover part of each of the first major surface 12a, the second major surface 12b, the first side surface 12c, and the second side surface 12d or may be formed so as to extend from the first end surface 12e to the second major surface 12b and cover part of each of the first end surface 12e and the second major surface 12b. In this case, the first outer electrode 30a is directly electrically connected to the first exposed portion 24a of the coil conductor 16 and is electrically connected to the first extended part 22a.
The second outer electrode 30b is disposed on the surface of the second end surface 12f of the element assembly 12. The second outer electrode 30b may be formed so as to extend from the second end surface 12f and cover part of each of the first major surface 12a, the second major surface 12b, the first side surface 12c, and the second side surface 12d or may be formed so as to extend from the second end surface 12f to the second major surface 12b and cover part of each of the second end surface 12f and the second major surface 12b. In this case, the second outer electrode 30b is directly electrically connected to the second exposed portion 24b of the coil conductor 16 and is electrically connected to the second extended part 22b.
The thickness of each of the first outer electrode 30a and the second outer electrode 30b is not limited and can be, for example, greater than or equal to 1 μm and less than or equal to 50 μm (i.e., from 1 μm to 50 μm) and preferably greater than or equal to 5 μm and less than or equal to 20 μm (i.e., from 5 μm to 20 μm).
The first outer electrode 30a includes the first base electrode layer 32a and a first plating layer 34a disposed on the surface of the first base electrode layer 32a. Similarly, the second outer electrode 30b includes the second base electrode layer 32b and a second plating layer 34b disposed on the surface of the second base electrode layer 32b.
The first base electrode layer 32a is disposed on the surface of the first end surface 12e of the element assembly 12. Therefore, the first base electrode layer 32a is directly in contact with the first exposed portion 24a of the coil conductor 16. The first base electrode layer 32a may be formed so as to extend from the first end surface 12e and cover part of each of the first major surface 12a, the second major surface 12b, the first side surface 12c, and the second side surface 12d or may be formed so as to extend from the first end surface 12e and cover part of each of the first end surface 12e and the second major surface 12b.
The second base electrode layer 32b is disposed on the surface of the second end surface 12f of the element assembly 12. Therefore, the second base electrode layer 32b is directly in contact with the second exposed portion 24b of the coil conductor 16. The second base electrode layer 32b may be formed so as to extend from the second end surface 12f and cover part of each of the first major surface 12a, the second major surface 12b, the first side surface 12c, and the second side surface 12d or may be formed so as to extend from the second end surface 12f and cover part of each of the second end surface 12f and the second major surface 12b.
The first base electrode layer 32a and the second base electrode layer 32b may be made up of a resin electrode layer. The resin electrode layer includes a resin component and a metal component. The resin component of the resin electrode layer includes at least one selected from among urethane resin, epoxy resin, phenolic resin, acrylic resin, silicon resin, polyimide resin, polyamide-imide resin, polyamide resin, and the like. The metal component of the resin electrode layer includes, for example, at least one selected from among Cu, Ni, Ag, Pd, Ag—Pd alloy, Au, and the like. The resin electrode layer may be made up of multiple layers. The resin electrode layer may be formed by applying electrically conductive paste containing a resin component and a metal component on the element assembly 12 by dipping and then thermally curing the electrically conductive paste.
The first base electrode layer 32a and the second base electrode layer 32b may be respectively formed as plated electrodes. The first base electrode layer 32a and the second base electrode layer 32b may be formed by electrolytic plating or may be formed by electroless plating.
A main component of a metal material that is a component of the first base electrode layer 32a and a component of the second base electrode layer 32b and a main component of a metal material that is a component of the coil conductor 16 preferably have the same composition. Thus, a metallic bond between the coil conductor 16 and each of the first base electrode layer 32a and the second base electrode layer 32b gets stronger, so the bonding strength increases, and a direct current resistance is reduced.
The average thickness of the first base electrode layer 32a and the second base electrode layer 32b is, for example, 10 μm.
The first plating layer 34a is disposed so as to cover the first base electrode layer 32a. Specifically, the first plating layer 34a may be disposed so as to cover the first base electrode layer 32a disposed on the first end surface 12e, and may be disposed so as to extend from the first end surface 12e and cover the surface of the first base electrode layer 32a disposed on the first major surface 12a, the second major surface 12b, the first side surface 12c, and the second side surface 12d, or may be disposed so as to extend from the first end surface 12e and cover the first base electrode layer 32a disposed so as to cover part of the second major surface 12b.
The second plating layer 34b is disposed so as to cover the second base electrode layer 32b. Specifically, the second plating layer 34b may be disposed so as to cover the second base electrode layer 32b disposed on the second end surface 12f, and may be disposed so as to extend from the second end surface 12f and cover the surface of the second base electrode layer 32b disposed on the first major surface 12a, the second major surface 12b, the first side surface 12c, and the second side surface 12d, or may be disposed so as to cover the second base electrode layer 32b disposed so as to extend from the second end surface 12f and cover part of the second major surface 12b.
The metal material of the first plating layer 34a and the second plating layer 34b includes, for example, at least one selected from among Cu, Ni, Ag, Sn, Pd, Ag—Pd alloy, Au, and the like.
The first plating layer 34a and the second plating layer 34b each may be formed in multiple layers. The first plating layer 34a has a two-layer structure of a first Ni plating layer 36a and a first Sn plating layer 38a formed on the surface of the first Ni plating layer 36a. The second plating layer 34b has a two-layer structure of a second Ni plating layer 36b and a second Sn plating layer 38b formed on the surface of the second Ni plating layer 36b.
The average thickness of each of the first Ni plating layer 36a and the second Ni plating layer 36b is, for example, 5 μm. The average thickness of each of the first Sn plating layer 38a and the second Sn plating layer 38b is, for example, 10 μm.
The first outer electrode 30a and the second outer electrode 30b may be provided with the following configuration. For example, the first base electrode layer 32a and the second base electrode layer 32b each may be an Ag-containing resin electrode or may be made up of an Ag sputter layer, Cu sputter layer, or Ti sputter layer through sputtering. When the first base electrode layer 32a and the second base electrode layer 32b each are made up of an Ag-containing resin electrode, a glass frit may be contained. When the first base electrode layer 32a and the second base electrode layer 32b each are made up of a sputter layer, a Cu sputter layer may be formed on a Ti sputter layer. The first plating layer 34a may have an outermost layer made up of the Sn plating layer 38a only. The second plating layer 34b may have an outermost layer made up of the Sn plating layer 38b only. In addition, an Ag plating layer or an Ni plating layer may be formed on the element assembly 12 without forming the first base electrode layer 32a or the second base electrode layer 32b.
Where the dimension of the coil component 10 in the length direction z is defined as L dimension, the L dimension is preferably greater than or equal to 1.0 mm and less than or equal to 12.0 mm (i.e., from 1.0 mm to 12.0 mm). Where the dimension of the coil component 10 in the width direction y is defined as W dimension, the W dimension is preferably greater than or equal to 0.5 mm and less than or equal to 12.0 mm (i.e., from 0.5 mm to 12.0 mm). Where the dimension of the coil component 10 in the pressure direction x is defined as T dimension, the T dimension is preferably greater than or equal to 0.5 mm and less than or equal to 6.0 mm (i.e., from 0.5 mm to 6.0 mm).
With the coil component 10 shown in
With the coil component 10 shown in
2. Manufacturing Method for Coil Component
Next, a manufacturing method for the coil component will be described.
The manufacturing method for the coil component includes (a) a process of manufacturing granulated powder, (b) a process of manufacturing a first molded body and a second molded body, (c) a process of manufacturing an element assembly, and (d) a process of forming outer electrodes.
(a) Process of Manufacturing Granulated Powder
Granulated powder to be manufactured is a composite material containing metal magnetic particles A, metal magnetic particles B, resin, and solvent.
Preparation of Metal Magnetic Particles
Initially, the metal magnetic particles A and the metal magnetic particles B are prepared.
Metal Magnetic Particles A
For example, Fe-based soft magnetic material powder made of a-Fe, Fe—Si, Fe—Si—Cr, Fe—Si—Al, Fe—Ni, Fe—Co, or the like can be used as the metal magnetic particles A. The material form of metal magnetic particles is preferably amorphous with good soft magnetic characteristics; however, the configuration is not limited thereto. The material form may be crystalline.
The mean particle size of the metal magnetic particles A is preferably greater than or equal to 10 μm and less than or equal to 50 μm (i.e., from 10 μm to 50 μm). A mean particle size is, for example, a median diameter (D50). When the mean particle size of the metal magnetic particles B exceeds 50 an eddy current loss in a radio-frequency range increases, with the result that characteristics in the radio-frequency range decrease.
The metal magnetic particles A include particles with a recessed portion. To form a recessed portion in each of the metal magnetic particles A, a process that will be described below is performed. In other words, the metal magnetic particles A are prepared by gas atomization or water atomization on magnetic material powder prepared. Here, by increasing the amount of spray of gas or water or increasing a spray pressure, it is possible to facilitate formation of cavities, increase the size of cavities, or control the sphericity. Ordinarily, a recessed portion is intended to be formed in each metal magnetic particle by atomization, the shape of each particle deviates from spherical form, and the mean sphericity of all the particles prepared increases. In the present embodiment, the metal magnetic particles A are prepared by water atomization. The content ratio between metal magnetic particles with a cavity and metal magnetic particles without a cavity can be adjusted by sorting the appearances of the metal magnetic particles prepared. A method of preparing metal magnetic particles with a recessed portion is not limited to atomization, and another method may be used.
The outer surface of each of the metal magnetic particles A is coated with an electrically insulating coating. Here, when the electrically insulating coating is formed by a mechanical method, metal magnetic particles and electrically insulating material powder are charged in a rotating container, and particulate composite is formed by mechanochemical process. Thus, an electrically insulating coating is formed to coat the surface of magnetic powder. It is preferable that no electrically insulating coating be formed inside the recessed portion of each of the metal magnetic particles A. When no electrically insulating coating is formed inside the recessed portion of each of the metal magnetic particles A, the effective magnetic permeability of the coil component is increased.
As for the material of the above-described metal magnetic particles A with a recessed portion, for example, Fe—Si—Cr alloy particles having a mean particle size of 26 μm and coated with an electrically insulating coating made of zinc phosphate glass with a thickness of 10 nm is prepared. The Fe—Si—-Cr alloy particles contain 90.8 wt % of Fe, 6.7 wt % of Si, and 2.5 wt % of Cr.
Metal Magnetic Particles B
For example, Fe-based soft magnetic material powder made of a-Fe, Fe—Si, Fe—Si—Cr, Fe—Si—Al, Fe—Ni, Fe—Co, or the like can be used as the metal magnetic particles B. The material form of metal magnetic particles is preferably amorphous with good soft magnetic characteristics; however, the configuration is not limited thereto. The material form may be crystalline.
The metal magnetic particles B are prepared by gas atomization or water atomization.
The mean particle size of the metal magnetic particles B is preferably greater than or equal to 0.2 μm and less than or equal to 10 μm (i.e., from 0.2 μm to 10 μm). The mean particle size of the metal magnetic particles B is more preferably less than or equal to 8 μm and further preferably less than or equal to 5 μm. A mean particle size is, for example, a median diameter (D50). When the mean particle size of the metal magnetic particles B is less than 0.2 μm, flowability during molding decreases, so high filling is difficult.
The outer surface of each of the metal magnetic particles B is coated with an electrically insulating coating. Here, when the electrically insulating coating is formed by a mechanical method, metal magnetic particles and electrically insulating material powder are charged in a rotating container, and particulate composite is formed by mechanochemical process. Thus, an electrically insulating coating is formed to coat the surface of magnetic powder.
As for the material of the above-described metal magnetic particles B, for example, Fe—Si—Cr alloy particles having a mean particle size of 4 μm and coated with an electrically insulating coating made of zinc phosphate glass with a thickness of 10 nm is prepared. The Fe—Si—Cr alloy particles contain 90.8 wt % of Fe, 6.7 wt % of Si, and 2.5 wt % of Cr.
The mean particle size of each set of metal magnetic particles is measured by the following method. Initially, a median diameter (D50) that is the mean particle size of each set of metal magnetic particles before granulation can be measured with a laser diffraction particle size distribution measuring device or the like. Here, a median diameter (D50) means an average particle size D50 (a particle size equivalent to 50% in accumulated percentage on a volume basis).
Resin
Examples of the resin material contained in a composite material include thermosetting resins and include organic materials, such as epoxy resin, phenolic resin, polyester resin, polyimide resin, and polyolefin resin. The resin material may be made up of only one material or may be made up of two or more resin materials. In the present embodiment, epoxy resin is used as the thermosetting resin. The content of resin is preferably relatively low because the effective magnetic permeability of the coil component 10 is increased. Specifically, the content of resin is particularly preferably lower than or equal to 25% (in area). On the other hand, when the content of resin is lower than 5%, flowability is not ensured during molding, and high filling is difficult, so the content of resin is preferably higher than or equal to 5%.
In the present embodiment, granulated powder molding is mixed at the following volume ratio. In other words, (Metal magnetic particles A):(Metal magnetic particles B):(Resin)=56:19:25.
Solvent
Acetone is prepared as a solvent.
Manufacture of Granulated Powder
Subsequently, granulated powder is manufactured by using the prepared metal magnetic particles A, metal magnetic particles B, resin material, and solvent.
Initially, the metal magnetic particles A and the metal magnetic particles B are mixed in a stirring container and stirred. A mixture ratio of the sets of metal magnetic particles to be mixed is, in weight ratio, (Metal magnetic particles A):(Metal magnetic particles B)=75:25. As the ratio of particle size between the metal magnetic particles A and the metal magnetic particles B ((Mean particle size of the metal magnetic particles A)/(Mean particle size of the metal magnetic particles B)) increases, the packing fraction of metal magnetic particles of a coil component increases, with the result that the magnetic permeability is increased, and the direct-current superposition characteristics are raised.
After that, the prepared resin and solvent are charged into the metal magnetic particles A and metal magnetic particles B mixed and stirred in the stirring container. The amount of resin charged is 3.0 wt % of the total weight of the metal magnetic particles A and the metal magnetic particles B, and the amount of solvent charged is 1.0 wt % of the total weight of the metal magnetic particles A and the metal magnetic particles B.
Subsequently, the metal magnetic particles A, the metal magnetic particles B, the resin, and the solvent, charged in the stirring container, are stirred and dried.
Granulated powder is obtained by removing coarse particles from the composite material of the stirred metal magnetic particles A, metal magnetic particles B, resin, and solvent with a sieve shaker.
By changing the mixture ratio of the sets of metal magnetic particles, mixing and stirring time, the value of L01/d2, and the like, a percentage by which another one of the first metal magnetic particles or a second metal magnetic particle is disposed inside the recessed portion of each of the first metal magnetic particles is adjusted.
(b) Process of Manufacturing First Molded Body and Second Molded Body
Next, the first molded body 50 and the second molded body 60 are manufactured by using the obtained granulated powder.
Here, initially, the structure of the first molded body 50 will be described. As shown in
Next, the structure of the second molded body 60 will be described. As shown in
The above-described first molded body 50 and second molded body 60 are manufactured as follows. Initially, granulated powder manufactured in the process of manufacturing granulated powder is molded with a die into a first molded body. At this time, the temperature is set to a room temperature, and a pressure of 50 MPa is applied. After that, the manufactured granulated powder is molded with a die into a second molded body. At this time, the temperature is set to a room temperature, and a pressure of 50 MPa is applied.
The first molded body and the second molded body manufactured as described above are further subjected to a temperature of 100° C. for 10 seconds to be temporarily cured. Thus, the first molded body 50 and the second molded body 60 are manufactured.
(c) Process of Manufacturing Element Assembly
Subsequently, the element assembly 12 in which the coil conductor 16 is embedded is manufactured by using the manufactured first molded body 50 and second molded body 60.
As shown in
More specifically, initially, the first molded body 50 is accommodated in the cavity of a die for molding an element assembly. Subsequently, the coil conductor 16 is disposed between the first molded body 50 and the second molded body 60 such that the winding axis portion 54 of the first molded body 50 is disposed in the hollow region 20 of the winding part 18. At this time, the coil conductor 16 is disposed such that the first extended part 22a of the coil conductor 16 is extended through the first notch 58a of the first molded body 50 and the second extended part 22b is extended through the second notch 58b of the first molded body 50. An electrically insulating coating is formed on the surface of the coil conductor 16. The second molded body 60 is placed so as to cover the first molded body 50 in which the coil conductor 16 is disposed. Subsequently, the temperature is increased to 200° C. in a state where the second molded body 60 is placed on the first molded body 50. Then, in a heated state, a pressure of 10 MPa is applied for 120 seconds for thermoforming.
The element assembly 12 is manufactured in this way.
(d) Process of Forming Outer Electrodes
Next, the first outer electrode 30a is formed on the first end surface 12e of the element assembly 12, and the second outer electrode 30b is formed on the second end surface 12f.
Subsequently, Ag-containing electrically conductive paste that will be a base electrode layer is applied to the first end surface 12e and second end surface 12f of the element assembly 12 to form base electrode layers. When a resin electrode layer is formed as the base electrode layer, electrically conductive paste containing a resin component and metal is applied by a method of, for example, dipping or the like, and then a thermosetting process is performed. Thus, the base electrode layer is formed. The temperature of the thermosetting process at this time is preferably higher than or equal to 120° C. and lower than or equal to 200° C. (i.e., from 120° C. to 200° C.).
Next, a plating layer is formed on the surface of the base electrode layer. More specifically, an Ni plating layer is formed on the base electrode layer, an Sn plating layer is formed on the Ni plating layer. Thus, the outer electrode 30 is formed. In this way, the first exposed portion 24a of the coil conductor 16 is electrically connected to the first outer electrode 30a, and the second exposed portion 24b of the coil conductor 16 is electrically connected to the second outer electrode 30b. In performing a plating process, plating is formed by electroless plating.
The coil component 10 is manufactured in this way.
As described above, the embodiment of the present disclosure is described in the specification; however, the present disclosure is not limited thereto. Various modifications may be added to the embodiment described above in terms of mechanism, shape, material, number, location, arrangement, or the like without departing from the scope of the technical idea and object of the present disclosure, and the present disclosure encompasses those modifications.
Number | Date | Country | Kind |
---|---|---|---|
2022-054174 | Mar 2022 | JP | national |
This application claims benefit of priority to Japanese Patent Application No. 2022-054174, filed Mar. 29, 2022, the entire content of which is incorporated herein by reference.