The present disclosure relates to a ceramic electronic component including external electrodes having conductive resin layers thereinside on respective two ends opposed to each other in a rectangular parallelepiped ceramic component body, and a ceramic electronic component production method.
In relation to the ceramic electronic component, a multilayer ceramic capacitor illustrated in
Each underlying metal layer 121 has a rectangular end face portion 121a covering each of the end faces in the lengthwise direction of the ceramic component body 110, and a rectangular cylindrical wraparound portion 121b on respective parts of four faces around the end face, which are continuously formed. In addition, each conductive resin layer 122 has a rectangular end face portion 122a covering each end face portion 121a of the underlying metal layer 121, and a rectangular cylindrical wraparound portion 122b covering each wraparound portion 121b of the underlying metal layer 121, which are continuously formed. A value obtained by subtracting a thickness of the end face portion 122a from a length of the wraparound portion 122b is larger than a length of the wraparound portion 121b of the underlying metal layer 121. Furthermore, each external metal layer 123 has a rectangular end face portion 123a covering each end face portion 122a of the conductive resin layer 122, and a square cylindrical wraparound portion 123b covering each wraparound portion 122b of the conductive resin layer 122, which are continuously formed.
Incidentally, a multilayer ceramic capacitor including an external electrode having another metal layer between the underlying metal layer 121 and the conductive resin layer 122 is also known (see FIG. 3 in Japanese Patent Laid-Open No. Hei 08-107039 (hereinafter referred to as Patent Document 2)), but the value obtained by subtracting the thickness of the end face portion 122a from the length of the wraparound portion 122b of the conductive resin layer 122 is not larger than the length of the wraparound portion 121b of the underlying metal layer 121.
After the multilayer ceramic capacitor illustrated in
Incidentally, it has been confirmed that, even in the multilayer ceramic capacitor illustrated in
The problem to be solved by the present disclosure is to provide a ceramic electronic component which can prevent occurrence of cracks on a ceramic component body as much as possible even when a connection part is repeatedly stressed or excessively stressed after mounting the ceramic electronic component on a circuit board, and a ceramic electronic component production method.
In order to solve the above problem, the ceramic electronic component according to the present disclosure is a ceramic electronic component including external electrodes having conductive resin layers thereinside on respective two ends opposed to each other in a rectangular parallelepiped ceramic component body. When an opposing direction of two faces opposed to each other in the ceramic component body is defined as a first direction, an opposing direction of other two faces opposed to each other is defined as a second direction, an opposing direction of the remaining other two faces opposed to each other is defined as a third direction, and dimensions along respective directions are defined as a first direction dimension, a second direction dimension, and a third direction dimension respectively, each of the external electrodes includes: (1) an underlying metal layer having an end face portion covering each end face in the first direction of the ceramic component body and a wraparound portion covering the respective parts of four faces around the end face that are continuously formed; (2) an intermediate metal layer having an end face portion covering each end face portion of the underlying metal layer and a wraparound portion covering each wraparound portion of the underlying metal layer that are continuously formed; (3) a conductive resin layer having an end face portion covering each end face portion of the intermediate metal layer and a wraparound portion covering each wraparound portion of the intermediate metal layer that are continuously formed, in which a value obtained by subtracting a thickness of the end face portion from the first direction dimension of the wraparound portion is larger than the first direction dimension of the wraparound portion of the intermediate metal layer; (4) an external metal layer having an end face portion covering each end face portion of the conductive resin layer and a wraparound portion covering each wraparound portion of the conductive resin layer that are continuously formed, and on at least a mounting side part of the wraparound portion of the underlying metal layer and on at least a mounting side part of the wraparound portion of the intermediate metal layer, a tip angle α between an outer face of a tip portion of the wraparound portion of the underlying metal layer and a surface of the ceramic component body is 20° or smaller, and a tip angle β between an outer face of a tip portion of the wraparound portion of the intermediate metal layer and a surface of the ceramic component body is 20° or smaller.
The ceramic electronic component production method according to the present disclosure is a production method for a ceramic electronic component including external electrodes having the conductive resin layers thereinside on the respective two ends opposed to each other in a rectangular parallelepiped ceramic component body. When an opposing direction of two faces opposed to each other in the ceramic component body is defined as a first direction, an opposing direction of other two faces opposed to each other is defined as a second direction, an opposing direction of the remaining other two faces opposed to each other is defined as a third direction, and dimensions along respective directions are defined as a first direction dimension, a second direction dimension, and a third direction dimension respectively, each of the external electrodes includes: (1) an underlying metal layer having an end face portion covering each end face in the first direction of the ceramic component body and a wraparound portion covering the respective parts of four faces around the end face that are continuously formed; (2) an intermediate metal layer having an end face portion covering each end face portion of the underlying metal layer and a wraparound portion covering each wraparound portion of the underlying metal layer that are continuously formed; (3) a conductive resin layer having an end face portion covering each end face portion of the intermediate metal layer, and a wraparound portion covering each wraparound portion of the intermediate metal layer that are continuously formed, in which a value obtained by subtracting a thickness of the end face portion from the first direction dimension of the wraparound portion is larger than the first direction dimension of the wraparound portion of the intermediate metal layer; (4) an external metal layer having an end face portion covering each end face portion of the conductive resin layer and a wraparound portion covering each wraparound portion of the conductive resin layer that are continuously formed, and on at least a mounting side part of the wraparound portion of the underlying metal layer and on at least a mounting side part of the wraparound portion of the intermediate metal layer, a tip angle α between an outer face of a tip portion of the wraparound portion of the underlying metal layer and a surface of the ceramic component body is 20° or smaller, and a tip angle β between an outer face of a tip portion of the wraparound portion of the intermediate metal layer and a surface of the ceramic component body is 20° or smaller.
The ceramic electric component according to the present disclosure makes it possible to prevent cracking on the ceramic component body as much as possible even when the connection part is repeatedly stressed or excessively stressed after mounting the ceramic electronic component on the circuit board. In addition, the ceramic electronic component production method according to the present disclosure can makes it possible to properly produce the ceramic electronic component.
In the following description, for the sake of convenience, the opposing direction of the two faces opposed to each other in a ceramic component body 10 (corresponding to the crosswise direction in
Note that, in explanation of dimensions of an internal electrode layer 11, a dielectric layer 12, an underlying metal layer 21, an intermediate metal layer 22, a conductive resin layer 23, and an external metal layer 24, a term “thickness” is used in combination for the purpose of promoting understanding. In addition, a numerical value referred as each dimension means a design basic dimension, but does not include a dimensional tolerance in production.
First, a basic structure in a case of applying the present disclosure to a multilayer ceramic capacitor MLCC will be explained with reference to
The multilayer ceramic capacitor MLCC includes the rectangular parallelepiped ceramic component body 10 and external electrodes 20 on respective two ends opposed to each other in the first direction d1 of the ceramic component body 10, and each external electrode 20 has the conductive resin layer 23 thereinside. Incidentally, a size of the multilayer ceramic capacitor MLCC i.e. the first direction dimension D1 [MLCC] ranges e.g. 400 to 3700 μm, the second direction dimension D2 [MLCC] ranges e.g. 200 to 2800 μm, and the third direction dimension D3 [MLCC] ranges e.g. 30 to 2800 μm.
The ceramic component body 10 includes a capacitance portion (symbol is omitted) in which a plurality of rectangular internal electrode layers 11 (total of 20 layers in the figure) are laminated through the dielectric layers 12 (total of 19 layers in the figure) in the third direction d3, and the capacitance portion (symbol is omitted) is surrounded by dielectric margin portions 13 and 14 on both sides in the third direction d3 and the dielectric margin portions 15 and 16 on both sides in the second direction d2. The plurality of internal electrode layers 11 are alternately shifted in the first direction d1, i.e. one end margin in the first direction d1 of the odd-numbered internal electrode layer 11 from the top in
A principal component of each internal electrode layer 11 is preferably a metal selected from nickel, copper, palladium, platinum, silver, gold, an alloy thereof, and the like. Principal components of the dielectric layer 12 and respective dielectric margin portions 13 to 16 are preferably dielectric ceramics selected from barium titanate, strontium titanate, calcium titanate, magnesium titanate, calcium zirconate, calcium titanate zirconate, barium zirconate, titanium oxide, and the like. Incidentally, a thickness of each internal electrode layer 11 ranges e.g. 0.3 to 1.5 μm, and a thickness of each dielectric layer 12 ranges e.g. 0.5 to 4.0 μm.
Although a total of 20 internal electrode layers 11 are drawn for the sake of convenience of illustration in
Each of the external electrodes 20 has a rectangular end face portion 20a on each end face in the first direction d1 of the ceramic component body 10, and a rectangular cylindrical wraparound portion 20b on the respective parts of four faces around the end face, which are continuously formed. That is, each external electrode 20 is a five-face type external electrode, and the lamination direction of the internal electrode layer 11 is the third direction d3, and therefore one (bottom part or top part in
Each underlying metal layer 21 has a rectangular end face portion 21a covering each end face in the first direction d1 of the ceramic component body 10, and a rectangular cylindrical wraparound portion 21b covering the respective parts of four faces around the end face (both end faces in the second direction d2 and both end faces in the third direction), which are continuously formed. In addition, each intermediate metal layer 22 has a rectangular end face portion 22a covering each end face portion 21a of the underlying metal layer 21, and a rectangular cylindrical wraparound portion 22b covering each wraparound portion 21b of the underlying metal layer 21, which are continuously formed. Furthermore, each conductive resin layer 23 has a rectangular end face portion 23a covering each end face portion 22a of the intermediate metal layer 22, and a rectangular cylindrical wraparound portion 23b covering each wraparound portion 22b of the intermediate metal layer 22, which are continuously formed. A value obtained by subtracting a thickness of the end face portion 23a from the first direction dimension D1 [22b] of the wraparound portion 23b is larger than the first direction dimension D1 [22b] of the wraparound portion 22b of the intermediate metal layer 22. Furthermore, each external metal layer 24 has a rectangular end face portion 24a covering each end face portion 23a of the conductive resin layer 23, and a rectangular cylindrical wraparound portion 24b covering each wraparound portion 23b of the conductive resin layer 23, which are continuously formed.
A principal component of each underlying metal layer 21 is preferably a metal selected from nickel, copper, palladium, platinum, silver, gold, an alloy thereof, and the like. Additionally, in the preparation method for each underlying metal layer 21, preferably a metal paste is applied and baked by a dipping method, a printing method, or the like. Needless to say, each of the underlying metal layer 21 can also be prepared by a dry plating method such as sputtering and vacuum deposition. Incidentally, the thicknesses of the end face portion 21a and the wraparound portion 21b of each underlying metal layer 21 vary e.g. 1 to 10 μm, and the first direction dimension D1 [21b] of the wraparound portion 21b of each underlying metal layer 21 ranges e.g. 1/50 to 1/10 of the first direction dimension D1 [MLCC] of the multilayer ceramic capacitor MLCC.
A principal component of each intermediate metal layer 22 is preferably a metal selected from copper, tin, nickel, gold, zinc, an alloy thereof, and the like. It is desirable that the principal component is different from the principal component of the underlying metal layer 21, e.g. when the principal component of each underlying metal layer 21 is nickel, the principal component of each intermediate metal layer 22 is copper. Additionally, the preparation method for each intermediate metal layer 22 is preferably a wet plating method such as electroplating, or a dry plating method such as sputtering and vacuum deposition. Incidentally, the thicknesses of the end face portion 22a and the wraparound portion 22b of each intermediate metal layer 22 vary e.g. 1 to 5 μm. A range of the first direction dimension D1 [22b] of the wraparound portion 22b of each intermediate metal layer 22 is e.g. a range obtained by adding the thickness of the end face portion 22a to a range of the first direction dimension D1 [21b] of the wraparound portion 21b of the underlying metal layer 21.
The principal ingredient of each conductive resin layer 23 is preferably a mixture (conductive resin) of a thermosetting resin selected from an epoxy resin, a phenol resin, a urethane resin, a silicone resin, a polyimide resin, and the like, with a conductive filler composed of a metal selected from copper, tin, nickel, gold, zinc, an alloy thereof, and the like. The form of the conductive filler is preferably a spherical shape, a flat shape, a fiber shape, and the like, but is not particularly limited as long as the conductivity can be secured. In the preparation method for each conductive resin layer 23, preferably a conductive resin paste is applied and thermally cured by a dipping method, a printing method or the like. Incidentally, the thicknesses of the end face portion 23a of each conductive resin layer 23 varies e.g. 3 to 10 μm, and a thickness of a thick part of the wraparound portion 23b ranges e.g. 5 to 20 μm. A range of the first direction dimension D1 [23b] of the wraparound portion 23b of each conductive resin layer 23 is e.g. a range obtained by subtracting the thickness of the end face portion 24a from a range of the first direction dimension D1 [24b] of the wraparound portion 24b of the external metal layer 24 described hereinafter.
A principal component of each external metal layer 24 is preferably a metal selected from tin, copper, nickel, gold, zinc, an alloy thereof, and the like. Additionally, the preparation method for each external metal layer 24 is preferably a wet plating method such as electroplating, or a dry plating method such as sputtering and vacuum deposition. Incidentally, the thicknesses of the end face portion 24a and the wraparound portion 24b of each external metal layer 24 vary e.g. 1 to 5 μm, and the first direction dimension D1 [24b] of the wraparound portion 24b of each external metal layer 24 ranges e.g. ⅛ to ⅓ of the first direction dimension D1 [MLCC] of the multilayer ceramic capacitor MLCC.
Although the monolayer external metal layer 24 is drawn in
Next, features in a case of applying the present disclosure to the multilayer ceramic capacitor MLCC illustrated in
An angle α illustrated in
Features in a case of applying the present disclosure to the multilayer ceramic capacitor MLCC illustrated in
F1: the tip angle α is 20° or smaller, and the tip angle β is 20° or smaller (α≤20° &β≤20°); and
the second, third and fourth features are:
F2: the tip angle α is 3° or larger, and the tip angle β is 1° or larger (3°≤α&1°≤β);
F3: the tip angle α is not more than the tip angle β(α≤β);
F4: a value obtained by subtracting the tip angle α from the tip angle β is 10° or smaller (10°≤β−α).
Hereinafter, an example of the production method for the multilayer ceramic capacitor MLCC illustrated in
In the production, a ceramic green sheet as a first sheet, and a second sheet obtained by forming an unbaked internal electrode layer pattern on the first sheet are prepared, the first sheet and the second sheet are appropriately laminated and thermally compression-bonded to form a multilayer sheet. Subsequently, the multilayer sheet is divided into chips corresponding to the ceramic component body 10, the chips are baked in an atmosphere and a temperature profile corresponding to the ceramic green sheet and the unbaked internal electrode layer, and the baked chips are ground with a barrel to prepare the ceramic component body 10. Subsequently, on each of the two ends opposed to each other in the first direction d1 of the ceramic component body 10, the underlying metal layer 21, the intermediate metal layer 22, the conductive resin layer 23 and the external metal layer 24 are sequentially formed by the method described hereinbefore. Incidentally, for the method in which the tip angle α of the tip portion 21b1 of the wraparound portion 21b of each underlying metal layer 21 and the tip angle β of the tip portion 22b1 of the wraparound portion 22b of each intermediate metal layer 22 explained with reference to
Next, specifications, observation results, and a comprehensive evaluation of prototypes supporting the features F1 to F4 will be explained with reference to
«Prototype Specification»
The specifications of prototypes TP1 to TP16 (multilayer ceramic capacitors corresponding to multilayer ceramic capacitor MLCC illustrated in
As a supplement to the difference in the specifications described hereinbefore, since the underlying metal layers 21 of the respective external electrodes 20 of the prototypes TP1 to TP16 are baked metal layers composed mainly of nickel, different “TIP ANGLES α” are obtained by changing a viscosity of the nickel paste, a ratio of common materials, a ratio of the additives, and the like, and additionally changing a temperature profile during baking. In addition, since the intermediate metal layers 22 of the respective external electrodes 20 of the prototypes TP1 to TP16 are electroplated metal layers composed mainly of copper, different “TIP ANGLES 13” are obtained by changing conditions such as a pH and a temperature of a plating liquid, a plating current density, and a plating time.
When the intermediate metal layers 22 of the respective external electrodes 20 are sputtered metal layers composed mainly of copper, different “TIP ANGLES β” can be obtained by changing a distance, an angle and the like of the object to be prepared (the ceramic component body 10 on which the underlying metal layer 21 has been made) relative to a target (including a case of rotating the object to be prepared), and additionally by changing conditions such as a gas pressure, a sputtering power, and a sputtering time.
Furthermore, as a supplement to the measurement method for the angles α and β as the bases of the “TIP ANGLE α” and the “TIP ANGLE β” in
Furthermore, as a supplement to the “TIP ANGLE α” and “TIP ANGLE β” in
«Observation Result»
The “CONTINUITY” in
The “CRACKING” in
As a supplement to the deflection test described hereinbefore, the test is carried out by a process that each of the 30 prototypes TP1 to TP16 is soldered to one side of a glass epoxy substrate in compliance with JIS-C-6484, and then both sides 45 mm away from a soldered site of the prototype on one side of the glass epoxy substrate are supported by bridges, and in this state, the other side of the glass epoxy substrate facing the soldered prototype is pressed downward and deformed by a pressing jig (a pressing part is a curved face with a curvature radius of 5 mm) at a constant speed of 0.5 mm/sec, and the pressing is released when the capacity of the prototype is decreased by 12.5% or more during the deformation step.
Incidentally, the method for releasing the pressing in the deflection test may also be carried out by a process that the other side of the glass epoxy substrate facing the soldered prototype is pressed downward and deformed by a pressing jig at a constant speed, and the pressing is released when the deformation amount of the glass epoxy substrate reaches a predetermined value e.g. 10 mm.
The “CRACK ANGLE θ” in
As a supplement to the “CRACK ANGLE θ” in
«Comprehensive Evaluation»
From the observation result of “CONTINUITY” in
From the observation results of “CRACKING” in
In addition, from the observation results of “CRACKING” in
Furthermore, from the observation results of “CRACKING” in
Incidentally, in observation of the “CRACKING” and measurement of the “CRACK ANGLE θ” in
Based on this assumption, predicted problems can be solved by preventing occurrence of the crack CR (see
Next, specifications, observation results, and a comprehensive evaluation of another prototype for supporting the features F1 to F4 described hereinbefore will be supplementarily explained.
Specifications of other prototypes TP21 to TP36 (multilayer ceramic capacitors corresponding to the multilayer ceramic capacitor MLCC illustrated in
Although illustration is omitted, “CONTINUITY,” “CRACKINGS” and “CRACK ANGLE” are observed and measured in the same manner as described hereinbefore for the other prototypes TP21 to TP36, and as a result, it has been confirmed that the same results can be obtained for the “CONTINUITY” and “CRACKINGS,” i.e. the same results can be obtained also for “COMPREHENSIVE EVALUATION.” Incidentally, with regard to “CRACK ANGLE θ,” it has been also confirmed that although “CRACK ANGLES θ” of the other prototypes TP32 to TP36 are smaller by approximately 5° than “CRACK ANGLES θ” of the prototypes TP12 to TP16, these prototypes TP32 to TP36 have the same size, and therefore the respective “CRACK ANGLES θ” are approximate to each other, as also described in BACKGROUND.
That is, any multilayer ceramic capacitor having the same basic structure as of the multilayer ceramic capacitor MLCC illustrated in
In addition, based on the assumption and the comprehensive evaluation of the other prototypes described hereinbefore, occurrence of cracks is considered to depend on the “TIP ANGLE α” and “TIP ANGLE β,” and thus even another type of ceramic electronic component having a ceramic component body and respective external electrodes similar to those of the multilayer ceramic capacitor MLCC illustrated in
Next, application of the features F1 to F4 to other portions of the wraparound portion (20b) of each external electrode (20) will be supplementarily explained.
In the multilayer ceramic capacitor MLCC illustrated in
Furthermore, in another type of ceramic electronic component having a ceramic component body similar to the multilayer ceramic capacitor MLCC illustrated in
It should be understood by those skilled in the art that various modifications, combinations, sub-combinations and alterations may occur depending on design requirements and other factors insofar as they are within the scope of the appended claims or the equivalents thereof.
Number | Date | Country | Kind |
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2018-097734 | May 2018 | JP | national |
The present application is a continuation application of U.S. patent application Ser. No. 16/415,592, filed on May 17, 2019, which claims benefit of priority from Japanese Patent Application No. 2018-097734 filed in the Japan Patent Office on May 22, 2018. Each of the above-referenced applications is hereby incorporated herein by reference in its entirety.
Number | Name | Date | Kind |
---|---|---|---|
5963416 | Honda | Oct 1999 | A |
6100110 | Kawase | Aug 2000 | A |
9685272 | Ahn | Jun 2017 | B2 |
10395839 | Park | Aug 2019 | B1 |
10395840 | Park | Aug 2019 | B1 |
10446320 | Kim | Oct 2019 | B2 |
10622151 | Kobayashi | Apr 2020 | B2 |
10629379 | Cho | Apr 2020 | B2 |
10847315 | Inoue | Nov 2020 | B2 |
20100067170 | Koga | Mar 2010 | A1 |
20140233147 | Hong | Aug 2014 | A1 |
20140284091 | Fujii | Sep 2014 | A1 |
20150084487 | Mori | Mar 2015 | A1 |
20150092316 | Chun | Apr 2015 | A1 |
20150243438 | Ahn | Aug 2015 | A1 |
20150279566 | Otani | Oct 2015 | A1 |
20170330689 | Hatanaka | Nov 2017 | A1 |
20180190433 | Cho | Jul 2018 | A1 |
20190180938 | Tahara | Jun 2019 | A1 |
20190221370 | Cho | Jul 2019 | A1 |
20190362895 | Kobayashi | Nov 2019 | A1 |
20200126726 | Cho | Apr 2020 | A1 |
20200160148 | Chun | May 2020 | A1 |
20200161048 | Chun | May 2020 | A1 |
20210027942 | Kim | Jan 2021 | A1 |
20220108841 | Yokomizo | Apr 2022 | A1 |
20220108842 | Yokomizo | Apr 2022 | A1 |
Number | Date | Country |
---|---|---|
08-107039 | Apr 1996 | JP |
11-219849 | Aug 1999 | JP |
20160033032 | Mar 2016 | KR |
Entry |
---|
Notice of Allowance cited in U.S. Appl. No. 16/415,592, dated Jan. 11, 2021. |
Ex Parte Quayle Action cited in U.S. Appl. No. 16/415,592, mailed Aug. 21, 2020. |
Number | Date | Country | |
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20210175017 A1 | Jun 2021 | US |
Number | Date | Country | |
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Parent | 16415592 | May 2019 | US |
Child | 17116336 | US |