The present invention relates to a laminated coil component.
A laminated coil component in the related art is disclosed, for example, in Patent Literature 1. In the laminated coil component, a conductive pattern of a coil conductor is formed on a glass-ceramic sheet, each of the sheets is laminated, the coil conductors in the sheets are electrically connected with each other, the resultant body is baked, and thus, an element assembly is formed to have a coil unit arranged therein. In addition, external electrodes are formed on both end surfaces of the element assembly to be electrically connected with end portions of the coil unit.
[Patent Literature 1] Japanese Unexamined Patent Application Publication No. 11-297533
Herein, a laminated coil component has a low Q (quality factor) value compared to a wound coil obtained by winding wires due to reason such as the structure of the laminated coil component or a method of manufacturing the laminated coil component. However, as a component is required in recent years which can particularly cope with a high frequency, a high Q value is required even for a laminated coil component. A laminated coil component in the related art cannot achieve a Q value high enough to satisfy such a demand.
The present invention is made to solve such a problem, and an object of the present invention is to provide a laminated coil component which can show a high Q value.
Smoothness of the surface of a coil conductor is preferably improved to increase a Q value of a coil. When surface resistance of a coil conductor is large at a high frequency, a Q value cannot be increased due to a skin effect. When smoothness of the surface of a coil conductor is deteriorated, surface resistance is increased. The inventors find that, after baking is completed, the grain diameter of a conductor is preferably set to be in a predetermined range of size to improve smoothness of the surface of a coil conductor and thus to increase a Q value.
Specifically, the inventors find that, when the grain diameter of a coil conductor is set to be 10 μm or larger after baking is completed, surface roughness of the coil conductor can be reduced to such an extent that a satisfactory Q value can be obtained at a high frequency. On the other hand, the inventors find that, when the grain diameter of a coil conductor is set to be excessively large after baking is completed, metal of the coil conductor is rapidly melted down during baking, thereby causing an open circuit of the coil conductor, a pull-in of a lead-out portion, or the like. The inventors find that metal of a coil conductor can be refrained from being rapidly melted down by making the grain diameter of the coil conductor to be a target size of 22 μm or smaller after baking is completed.
A laminated coil component according to an aspect of the present invention includes an element assembly formed by laminating a plurality of insulation layers, and a coil unit formed inside the element assembly by a plurality of coil conductors. The grain diameter of the coil conductor is 10 μm to 22 μm after baking is completed.
In a laminated coil component according to the aspect of the present invention, when the grain diameter of a coil conductor is set to be 10 μm or larger after baking is completed, surface roughness of the coil conductor can be reduced to such an extent that a satisfactory Q value can be obtained at a high frequency. In addition, when the grain diameter of a coil conductor is set to be 22 μm or smaller after baking is completed, metal of the coil conductor can be refrained from being rapidly melted down during baking. Accordingly, a high Q value can be obtained while a high quality is ensured.
In addition, in a laminated coil component, an element assembly may be made from glass-ceramic. Accordingly, dielectric constant of the element assembly can be decreased and a Q value can be increased.
In addition, in a laminated coil component, the glass-ceramic may contain 86.7 weight % to 92.5 weight % of SiO2 and 0.5 weight % to 2.4 weight % of Al2O3. When a composition of a glass-ceramic of an element assembly comes within such a range, smoothness of the surface of a coil conductor can be even more improved.
In addition, in a laminated coil component, a potassium coating layer may be formed to cover a coil conductor. When potassium is present around a coil conductor, a softening point of an element assembly around the coil conductor can be lowered, the region of the element assembly is softened and thus is prone to be smooth during baking. Accordingly, the surface of the coil conductor in contact therewith also can become smooth.
In addition, in a laminated coil component, the grain diameter of a coil conductor may be 11 μm to 18 μm after baking is completed. Accordingly, metal of the coil conductor can be even more refrained from being rapidly melted down, and surface roughness of the coil conductor can be even more reduced.
According to the present invention, a Q value of a laminated coil component can be increased.
Hereinafter, preferred embodiments of a laminated coil component according to the present invention will be described with reference to the drawings.
The element assembly 2 is a rectangular parallelepiped or cubic laminated body which consists of a sintered body obtained by laminating a plurality of ceramic green sheets. Herein, as illustrated in
The coil unit arrangement layer 2A is not particularly specified as far as the grain diameter of the coil conductor 4 can be within a predetermined range. However, for example, the coil unit arrangement layer 2A made from glass-ceramic is preferable. Accordingly, dielectric constant of the element assembly 2 can be decreased and a Q value can be increased. In addition, the coil unit arrangement layer 2A is preferably made from amorphous ceramics. Accordingly, smoothness of the coil conductors 4 and 5 can be improved. In addition, the coil unit arrangement layer 2A preferably contains SiO2. Accordingly, dielectric constant of the coil unit arrangement layer 2A can be decreased. In addition, the coil unit arrangement layer 2A preferably contains Al2O3. Accordingly, crystal transition of the coil unit arrangement layer 2A can be prevented. In addition, since the coil unit arrangement layer 2A forms a coating layer 7 which covers the coil conductors 4 and 5, K2O is preferably contained.
The coil unit arrangement layer 2A contains, as main constituents, 35 weight % to 60 weight % of borosilicate glass, 15 weight % to 35 weight % of quartz and amorphous silica in the remainder, and contains alumina as an accessory constituent, and 0.5 weight % to 2.5 weight % of alumina is contained with respect to 100 weight % of the main constituents. After baking is completed, the coil unit arrangement layer 2A has a composition in which 86.7 weight % to 92.5 weight % of SiO2, 6.2 weight % to 10.7 weight % of B2O3, 0.7 weight % to 1.2 weight % of K2O and 0.5 weight % to 2.4 weight % of Al2O3 are contained. When glass-ceramics contain 86.7 weight % to 92.5 weight % of SiO2 and 0.5 weight % to 2.4 weight % of Al2O3, smoothness of the surfaces of the coil conductors 4 and 5 can be even more improved. MgO or CaO (1.0 weight % or less) may be contained.
Alternatively, the coil unit arrangement layer 2A contains, as main constituents, 35 weight % to 75 weight % of borosilicate glass, 5 weight % to 40 weight % of quartz and 5 weight % to 60 weight % of zinc silicate. Borosilicate glass contains, as main constituents, SiO2=70 weight % to 90 weight % and B2O3=10 weight % to 30 weight % and contains, as accessory constituents, at least one or more type of constituents selected from K2O, Na2O, BaO, SrO, Al2O3 and CaO by a total of 5 weight % or less. After baking is completed, the coil unit arrangement layer 2A may have a composition containing SiO2=53.7 weight % to 89.5 weight %, B2O3=3.5 weight % to 22.5 weight %, ZnO=3.0 weight % to 35.8 weight % and at least one or more type of constituents selected from K2O, Na2O, BaO, SrO, Al2O3 and CaO by a total of 3.8 weight % or less.
As illustrated in
In the configuration as illustrated in
The shape retention layer 2B contains, as main constituents, 50 weight % to 70 weight % of glass and 30 weight % to 50 weight % of alumina. After baking is completed, the shape retention layer 2B has a composition containing 23 weight % to 42 weight % of SiO2, 0.25 weight % to 3.5 weight % of B2O3, 34.2 weight % to 58.8 weight % of Al2O3 and 12.5 weight % to 31.5 weight % of alkaline earth metal oxide, in which 60 weight % or more of the alkaline earth metal oxide (that is, 7.5 weight % to 31.5 weight % of the entirety of the shape retention layer 2B) is SrO.
In the configuration as illustrated in
Since a softening point cannot be lowered when SrO is contained, SrO is not contained in the coil unit arrangement layer 2A. Herein, since SrO is difficult to diffuse, SrO of the shape retention layer 2B is refrained from diffusing to the coil unit arrangement layer 2A during baking. In addition, the coil unit arrangement layer 2A can contain SiO2 having a relatively low dielectric constant by such an amount that is deficient in SrO, whereby dielectric constant can be decreased. Accordingly, a Q (quality factor) value of a coil can be increased. On the other hand, the shape retention layer 2B can contain less SiO2 compared to the coil unit arrangement layer 2A by such an amount that SrO is contained, whereby dielectric constant is increased. However, the shape retention layer 2B does not contain the coil conductors 4 and 5 therein, and does not affect a Q value of a coil. In addition, the coil unit arrangement layer 2A has a large amount of SiO2 and a low strength whereas the shape retention layer 2B has a small amount of SiO2 and a high strength. The shape retention layer 2B can function as a reinforcement layer for the coil unit arrangement layer 2A after baking is completed.
Herein, when an element assembly is crystalline as illustrated in
The coil unit 3 has the coil conductor 4 related to a winding pack and the coil conductor 5 related to a lead-out portion which is connected with the external electrode 6. The coil conductors 4 and 5 are formed by a conductive paste having, for example, any of silver, copper and nickel as a main constituent. In the configuration of
The K (potassium) coating layer 7 is formed around the coil conductors 4 and 5 of the coil unit 3 to cover the coil conductors 4 and 5. When potassium is contained in the ceramic green sheet which forms the coil unit arrangement layer 2A before baking is carried out, potassium is concentrated around the coil conductors 4 and 5 during baking, and thus the coating layer 7 is formed.
The grain diameter of the coil conductors 4 and 5 is preferably 10 μm to 22 μm after baking is completed, more preferably 11 μm to 18 μm. Surface roughness of the coil conductors 4 and 5 is preferably reduced to decrease surface resistance. When the grain diameter of the coil conductors 4 and 5 is set to be 10 μm or larger, surface roughness can be reduced to increase a Q value at a high frequency. In addition, when the grain diameter of the coil conductors 4 and 5 is set to be 22 μm or smaller, an open circuit, a pull-in of a lead-out portion or the like can be refrained from occurring due to the melting of metal (for example, silver) forming the coil conductors 4 and 5.
A pair of external electrodes 6 is formed to cover both end surfaces facing each other in a direction orthogonal to the laminating direction among end surfaces of the element assembly 2. Each of the external electrodes 6 is formed to entirely cover each of both end surfaces and a portion thereof may go around to other four surfaces from each of both end surfaces. Each of the external electrodes 6 is formed by screen-printing a conductive paste having, for example, any of silver, copper and nickel as a main constituent, or by a dip method.
Next, a method of manufacturing the laminated coil component 1 of the above-described configuration will be described.
First, ceramic green sheets forming the coil unit arrangement layer 2A are prepared. A ceramic paste is adjusted to have the above-described composition, is molded to have a sheet shape by a doctor blade method or the like, and each of the ceramic green sheets is prepared. In the configuration as illustrated in
A conductive paste forming the coil conductors 4 and 5 is prepared. The conductive paste contains conducting powder having silver, nickel or copper as a main constituent and a predetermined grain size distribution. Specifically, conducting powder is used which has 1 μm to 3 μm of mean grain diameter and 0.7 μm to 1.0 μm of a standard deviation. Grain grading may be carried out to obtain conducting powder with such a grain size distribution.
Subsequently, each of the through-holes is formed by laser processing or the like at a predetermined position on each of the ceramic green sheets which become the coil unit arrangement layer 2A, that is, each of the through-holes is formed at a pre-arranged position where a through-hole electrode is formed. Next, each of the conductive patterns is formed on each of the ceramic green sheets which become the coil unit arrangement layer 2A. Herein, each of the conductive patterns and each of the through-hole electrodes are formed by a screen printing method using a conductive paste which contains silver, nickel or the like.
Subsequently, each of the ceramic green sheets is laminated. In the configuration as illustrated in
Subsequently, a laminated body is baked, for example, at 900 to 940° C. for 10 to 60 minutes to form the element assembly 2. Baking conditions are adjusted to have a target range of 10 μm to 22 μm for the grain diameter of a coil conductor. In the configuration as illustrated in
Subsequently, the external electrodes 6 are formed on the element assembly 2. Accordingly, the laminated coil component 1 is formed. An electrode paste, which has silver, nickel or copper as a main constituent, is coated on each of both end surfaces of the element assembly 2 in the longitudinal direction, baking is carried out at a predetermined temperature (for example, approximately 600 to 700° C.), and electroplating is carried out to form the external electrode 6. Cu, Ni, Sn and the like can be used for the electroplating.
Next, an operation and effect of the laminated coil component 1 according to the embodiments will be described.
Smoothness of the surface of a coil conductor is preferably improved to increase a Q (quality factor) value of a coil. The higher a frequency becomes, the shallower skin depth becomes, and smoothness of the surface of a coil conductor affects a Q value at a high frequency. For example, when, as illustrated in
Herein, the inventors find that, when the grain diameter of a coil conductor is set to be 10 μn or larger after baking is completed, surface roughness of the coil conductor can be reduced to such an extent that a satisfactory Q value can be obtained at a high frequency. On the other hand, the inventors find that, when the grain diameter of a coil conductor after baking is completed is set to be excessively large by the adjustment of baking conditions or the like, metal of the coil conductor is rapidly melted down during baking, thereby causing an open circuit of the coil conductor, a pull-in of a lead-out portion, or the like. The inventors find that metal of a coil conductor can be refrained from being rapidly melted down by aiming to set the grain diameter of the coil conductor to be 22 μm or smaller after baking is completed.
Accordingly, in the laminated coil component 1 according to the embodiments, the grain diameter of the coil conductors 4 and 5 is 10 μm to 22 μM after baking is completed. When the grain diameter of the coil conductors 4 and 5 is set to be 10 μM or larger after baking is completed, surface roughness of the coil conductors 4 and 5 can be reduced to such an extent that a satisfactory Q value can be obtained at a high frequency. In addition, when the grain diameter of the coil conductors 4 and 5 is set to be 22 μm or smaller after baking is completed, metal of the coil conductors 4 and 5 can be refrained from being rapidly melted down during baking. Accordingly, a high Q value can be obtained while a high quality is ensured.
In addition, in the laminated coil component 1, the potassium coating layer 7 is formed to cover the coil conductors 4 and 5. When potassium is present around the coil conductors 4 and 5, a softening point of the element assembly 2 around the coil conductors 4 and 5 can be lowered, the region of the element assembly 2 is softened and thus is prone to be smooth during baking. Accordingly, the surface of the coil conductors 4 and 5 in contact therewith also can become smooth. In addition, the coil conductors 4 and 5 are covered and protected by the potassium coating layer 7, whereby cracks can be prevented from occurring near the boundary between the coil conductors 4 and 5, and glass-ceramics.
The present invention is not limited to the above-described embodiments.
For example, in the above-described embodiments, a laminated coil component having one coil unit is illustrated. However, for example, a laminated coil component may have a plurality of coil units in an array.
Laminated coil components A-1 to A-7 (group A), laminated coil components B-1 to B-6 (group B) and laminated coil components C-1 to C-5 (group C) are manufactured, and a relation between conductor diameter and surface roughness of a coil conductor of each of the laminated coil components is investigated. In addition, a relation between surface roughness and an AC resistance value is investigated, and states of the coil conductors are observed.
<Manufacturing Conditions (Group A)>
The laminated coil components of the group A have, as illustrated in
A composition of a ceramic paste forming the coil unit arrangement layers 2A of the laminated coil components A-1 to A-7 has 66.1 weight % of borosilicate glass, 25.4 weight % of quartz, 8.5 weight % of zinc silicate, 10 weight % of ethylcellulose (binder) and 140 weight % of terpineol (solvent).
A composition of a ceramic paste forming the shape retention layers 2B of the laminated coil components A-1 to A-7 has 70 weight % of glass, 30 weight % of alumina, 10 weight % of ethylcellulose (binder) and 140 weight % of terpineol (solvent).
A composition of a conductive paste forming the coil conductors 4 and 5 of the laminated coil components A-1 to A-7 has 100 weight % of Ag, 10 weight % of ethylcellulose (binder) and 40 weight % of terpineol (solvent).
Baking conditions are set to the conditions illustrated in a table of
In the laminated coil components A-1 to A-7 described above, base material characteristics become amorphous and electrode characteristics become easy grain growth.
<Manufacturing Conditions (Group B)>
The laminated coil components of the group B have, as illustrated in
A composition of a ceramic paste forming the coil unit arrangement layers 2A of the laminated coil components B-1 to B-6 has 60 weight % of borosilicate glass, 20 weight % of quartz, 20 weight % of amorphous silica, 1.5 weight % of alumina, 10 weight % of ethylcellulose (binder) and 140 weight % of terpineol (solvent).
A composition of a ceramic paste forming the shape retention layers 2B of the laminated coil components B-1 to B-6 has 70 weight % of glass, 30 weight % of alumina, 10 weight % of ethylcellulose (binder) and 140 weight % of terpineol (solvent).
A composition of a conductive paste forming the coil conductors 4 and 5 of the laminated coil components B-1 to B-6 has 100 weight % of Ag, 10 weight % of ethylcellulose (binder) and 40 weight % of terpineol (solvent).
Baking conditions are set to the conditions illustrated in a table of
In the laminated coil components B-1 to B-6 described above, base material characteristics become amorphous and electrode characteristics become easy grain growth.
<Manufacturing Conditions (Group C)>
The laminated coil components of the group C have, as illustrated in
A composition of a ceramic paste forming the coil unit arrangement layers 2A of the laminated coil components C-1 to C-5 has 70 weight % of glass, 30 weight % of alumina, 10 weight % of ethylcellulose (binder) and 140 weight % of terpineol (solvent).
A composition of a conductive paste forming the coil conductors 4 and 5 of the laminated coil components C-1 to C-5 has 100 weight % of Ag, 10 weight % of ethylcellulose (binder) and 40 weight % of terpineol (solvent).
Baking conditions are set to the conditions illustrated in a table of
In the laminated coil components C-2 to C-5 described above, base material characteristics become crystalline and electrode characteristics become difficult grain growth. On the other hand, in the laminated coil components C-1, base material characteristics become crystalline and electrode characteristics become easy grain growth.
<Measurement of Conductor Grain Diameter and Surface Roughness>
Conductor grain diameter and surface roughness of the above-described laminated coil components are measured. A relation between the conductor grain diameter and the surface roughness is plotted on a graph illustrated in
<Measurement of AC Resistance Value>
The laminated coil components A-1, A-7, C-1 and C-2 are picked up among the laminated coil components in
<Observation of a State of Coil Conductor>
Next, in each of the laminated coil components, a state of a coil conductor is observed for an open circuit, a pull-in of a lead-out portion due to the melting of metal. In this observation, 100 pieces of laminated coil components are manufactured according to each condition and observed, respectively. In the laminated coil components A1 and A2, 100 out of 100 pieces of laminated coil components show an open circuit or the like. On the other hand, in the laminated coil components according to other conditions, such a open circuit or the like is not observed and a good state is shown in 100 out of 100 pieces of laminated coil components. It is understood from the results that, when the grain diameter of a coil conductor is equal to or smaller than 22 μm, the coil conductor can be refrained from being rapidly melted down, thereby preventing an open circuit or the like.
<Comprehensive Evaluation>
It is understood from the above results that, when the grain diameter of a coil conductor is made to have a target range of 10 μm to 22 μm, a high Q value can be obtained even at a high frequency and a laminated coil component showing a good state without an open circuit or the like can be obtained.
The present invention can be used in a laminated coil component.
1 laminated coil component
2 element assembly
2A coil unit arrangement layer
2B shape retention layer
3 coil unit
4, 5 coil conductor
6 external electrode
Number | Date | Country | Kind |
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2011-194913 | Sep 2011 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP2012/070996 | 8/20/2012 | WO | 00 | 12/12/2013 |
Publishing Document | Publishing Date | Country | Kind |
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WO2013/035516 | 3/14/2013 | WO | A |
Number | Name | Date | Kind |
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7229939 | Nonoue et al. | Jun 2007 | B2 |
Number | Date | Country |
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A-7-82041 | Mar 1995 | JP |
A-10-65335 | Mar 1998 | JP |
A-11-297533 | Oct 1999 | JP |
A-2004-99378 | Apr 2004 | JP |
A-2005-286127 | Oct 2005 | JP |
A-2008-243738 | Oct 2008 | JP |
Entry |
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International Search Report issued in International Application No. PCT/JP2012/070996 on Nov. 20, 2012 (with translation). |
International Preliminary Report on Patentability issued in International Application No. PCT/JP2012/070996 issued Mar. 12, 2014. |
Number | Date | Country | |
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20140118100 A1 | May 2014 | US |