Source: https://patents.google.com/patent/KR101647772B1/en
Timestamp: 2020-01-19 04:22:13
Document Index: 590022252

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KR101647772B1 - Multilayer ceramic capacitor - Google Patents
KR101647772B1
KR101647772B1 KR1020140113790A KR20140113790A KR101647772B1 KR 101647772 B1 KR101647772 B1 KR 101647772B1 KR 1020140113790 A KR1020140113790 A KR 1020140113790A KR 20140113790 A KR20140113790 A KR 20140113790A KR 101647772 B1 KR101647772 B1 KR 101647772B1
lower protective
KR1020140113790A
KR20150026954A (en
류이치 시바사키
신이치 사사키
나오키 사이토
타카후미 스즈키
다이요 유덴 가부시키가이샤
2013-08-30 Priority to JPJP-P-2013-179361 priority Critical
2013-08-30 Priority to JP2013179361 priority
2014-07-29 Priority to JPJP-P-2014-153566 priority
2014-07-29 Priority to JP2014153566A priority patent/JP5897661B2/en
2014-08-29 Application filed by 다이요 유덴 가부시키가이샤 filed Critical 다이요 유덴 가부시키가이샤
2015-03-11 Publication of KR20150026954A publication Critical patent/KR20150026954A/en
2016-08-11 Publication of KR101647772B1 publication Critical patent/KR101647772B1/en
The present invention provides a multilayer ceramic capacitor having high practicality against noise suppression in a mounted state.
The capacitor main body 11 of the multilayer ceramic capacitor 10-1 includes a capacitor portion 11a in which a plurality of internal electrode layers 11a1 are stacked in a height direction via a dielectric layer 11a2; An upper protective portion 11b of a dielectric system located above the uppermost internal electrode layer 11a1 of the plurality of internal electrode layers 11a1; And a lower protective portion 11c of a dielectric system located below the lowest internal electrode layer 11a1 of the plurality of internal electrode layers 11a1 and the capacitor portion 11a is integrally formed with the lower protective portion 11c of the capacitor main body 11 The thickness Tc of the lower protective portion 11c is made thicker than the thickness Tb of the upper protective portion 11b so as to be positioned on the upper side in the height direction.
The multilayer ceramic capacitor generally has a substantially rectangular parallelepiped capacitor body defined by a length, a width, and a height, and an external electrode provided at a longitudinal end portion of the capacitor body, respectively. The capacitor body includes a capacitor portion in which a plurality of internal electrode layers are stacked in a height direction with a dielectric layer interposed therebetween, an upper protective portion of a dielectric structure located above the uppermost (highest) internal electrode layer in the plurality of internal electrode layers, And a lower protective portion of a dielectric system located below the lowest (lowest) internal electrode layer among the electrode layers (see FIG. 1 of Patent Document 1, which will be described later).
The multilayer ceramic capacitor is mounted on the circuit board by bonding the surfaces to be bonded of the external electrodes of the multilayer ceramic capacitor to the surfaces of the pads provided on the circuit board by using solder . Since the outline shape of the surface of each pad is generally a rectangle that is larger than the outline shape of the surface to be bonded of each external electrode, the end faces of the external electrodes after mounting are based on free wetting of molten solder A solder fillet is formed (see Figs. 1 and 2 of Patent Document 1 which will be described later).
When a voltage, particularly an alternating voltage, is applied to both external electrodes through the respective pads in this mounted state, expansion and contraction of the capacitor body based on the electrostriction phenomenon And the stress due to the elongation and shrinkage is transmitted to the circuit board through the external electrode, the solder, and the pad to cause vibration (mainly deformation such as concave portions between the pads and restoration thereof) The sound of the audible range (so-called sounding [sounding]) may occur due to vibration.
In order to suppress the above-mentioned noise, in order to suppress the sounding, the height of the solder fillet with respect to the surface of the pad is lower than the thickness of the lower protection portion of the condenser main body and the interval between the surface of the pad and the condenser main body A mounting structure is described (see Fig. 2).
However, since the solder fillet is formed based on the free wetting of the molten solder with respect to the cross section of each of the external electrodes, the solder oiliness of the cross section of each of the external electrodes is good. Therefore, It is extremely difficult to control the height of the solder fillet with respect to the surface.
Specifically, in a multilayer ceramic capacitor having a cross-section height of 500 mu m of each external electrode, the height of the solder fillet with respect to the lower end of the cross section of each external electrode is substantially 200 mu m or more, Non-insufficient mounting occurs as a non-mounting defect.
That is, the mounting structure described in Patent Document 1 described later does not adopt a special method of controlling the height of the solder fillet with respect to the surface of the pad, so in effect, the "height of the solder fillet with respect to the surface of the pad" It is extremely difficult to lower the gap between the surface of the pad and the capacitor body and the thickness of the lower protective portion of the capacitor body. Therefore, practicality in suppressing noise is extremely low.
1. Japanese Patent Laid-Open Publication No. 2013-046069
SUMMARY OF THE INVENTION An object of the present invention is to provide a multilayer ceramic capacitor having high practicality in suppressing noise in a mounted state.
In order to achieve the above object, the present invention provides a capacitor body having a rectangular parallelepiped shape defined by a length, a width, and a height; And an external electrode provided at a lengthwise end of the capacitor body, wherein the capacitor body includes: a capacitor portion in which a plurality of internal electrode layers are stacked in a height direction with a dielectric layer interposed therebetween; An upper protective portion of a dielectric structure located above the uppermost internal electrode layer among the plurality of internal electrode layers; And a lower protective portion of a dielectric structure located below the lowest internal electrode layer among the plurality of internal electrode layers so that the capacitance portion is located at an upper side in the height direction of the capacitor body, The height H and the thickness Tb satisfy the relation of Tb / H (Tb / H), where T is the height of the capacitor body, Tb is the thickness of the upper protective part, and Tc is the thickness of the lower protective part.
0.06, and the height H and the thickness Tc satisfy 0.31
Tc / H
0.50. &Lt; / RTI &gt;
According to the present invention, it is possible to provide a multilayer ceramic capacitor which is highly practical for suppressing noise in a mounted state.
1 is a top view of a multilayer ceramic capacitor (first embodiment) to which the present invention is applied.
2 is a longitudinal sectional view along the SS line of Fig. 1; Fig.
Fig. 3 is a partial vertical cross-sectional view showing a structure in which the multilayer ceramic capacitor shown in Figs. 1 and 2 is mounted on a circuit board. Fig.
Fig. 4 is a diagram showing the specifications and characteristics of Samples 1 to 5 for effect confirmation; Fig.
Fig. 5 is a multilayer ceramic capacitor (second embodiment) to which the present invention is applied, and is a longitudinal sectional view corresponding to Fig. 2; Fig.
6 is a view showing the specifications and characteristics of the sample 6 for effect confirmation.
Fig. 7 is a multilayer ceramic capacitor (third embodiment) to which the present invention is applied, and is a longitudinal sectional view corresponding to Fig. 2; Fig.
8 is a view showing the specifications and characteristics of the sample 7 for effect confirmation.
Fig. 9 is a multilayer ceramic capacitor (fourth embodiment) to which the present invention is applied, and is a longitudinal sectional view corresponding to Fig. 2; Fig.
10 is a view showing the specifications and characteristics of the sample 8 for effect confirmation;
Fig. 11 is a multilayer ceramic capacitor (fifth embodiment) to which the present invention is applied, and is a longitudinal sectional view corresponding to Fig. 2; Fig.
12 is a view showing the specifications and characteristics of the sample 9 for effect confirmation.
Fig. 1 and Fig. 2 show the basic structure of a multilayer ceramic capacitor 10-1 (first embodiment) to which the present invention is applied. This multilayer ceramic capacitor 10-1 has a substantially rectangular parallelepiped capacitor main body 11 defined by a length L, a width W and a height H, And an external electrode (12).
The capacitor main body 11 includes a capacitor portion 11a stacked in a height direction via a plurality of dielectric layers 11a2 (31 layers in total) The upper protective portion 11b of the dielectric system located on the uppermost level of the internal electrode layer 11a1 of the electrode layer 11a1 and the upper protective portion 11b of the dielectric system located below the lowest internal electrode layer 11a1 of the plurality of internal electrode layers 11a1, And a lower protective portion 11c. Although FIG. 2 shows a total of 32 internal electrode layers 11a1 for the sake of convenience, there is no particular limitation on the number of internal electrode layers 11a1.
The plurality of internal electrode layers 11a1 included in the capacitor portion 11a are rectangular shapes having substantially the same outline shapes, and their thicknesses are also substantially the same. The plurality of dielectric layers 11a2 (the portion interposed in the adjacent internal electrode layer 11a1 and the portion including the peripheral portion not interposed) contained in the capacitor portion 11a are substantially equal in contour shape, The rectangular shape is larger than the outline shape of the electrode layer 11a1, and the respective thicknesses are also substantially equal. 2, the plurality of internal electrode layers 11a1 are alternately shifted in the longitudinal direction, and the edge of the internal electrode layer 11a1 corresponding to the odd-numbered upper portion is located on the left external electrode 12, And the end edge of the internal electrode layer 11a1 corresponding to the even-numbered upper electrode is electrically connected to the external electrode 12 on the right side.
The plurality of internal electrode layers 11a1 included in the capacitor portion 11a are made of conductors of the same composition. The conductors are preferably made of nickel, copper, palladium, platinum, silver, gold, Can be used. In addition, the plurality of dielectric layers 11a2 included in the capacitor portion 11a are made of a dielectric having the same composition, and the dielectric material preferably includes barium titanate, strontium titanate, calcium titanate, magnesium titanate, calcium zirconate, Dielectric ceramics mainly composed of calcium oxide, barium zirconate, titanium oxide and the like, more preferably dielectric ceramics having a dielectric constant of ε> 1000 or class 2 (high permittivity system) can be used. For reference, &quot; the same composition &quot; described in this paragraph means that the components are the same and does not mean that the components are the same and the contents of the components are the same.
The composition of the upper protective portion 11b and the composition of the lower protective portion 11c are the same as those of the plurality of dielectric layers 11a2 included in the capacitor portion 11a. In this case, the dielectric constant of the upper protective portion 11b and the dielectric constant of the lower protective portion 11c are equal to the dielectric constant of the plurality of dielectric layers 11a2 included in the capacitor portion 11a. The thickness Tc of the lower protective portion 11c is made thicker than the thickness Tb of the upper protective portion 11b so that the capacitor portion 11a is positioned at the upper side in the height direction of the capacitor main body 11. For reference, "the same composition" described in this paragraph means that the components are the same and does not mean that the components are the same and the content of each component is the same.
The thickness Tb of the upper protective part 11b and the thickness Tc of the lower protective part 11c are respectively expressed by the ratio of the height H of the capacitor main body 11. The thickness Tb is preferably Tb / H
0.06, and the thickness Tc is preferably Tc / H
0.20 is satisfied. The thickness Tb and the thickness Tc of the upper protective portion 11b and the lower protective portion 11c are preferably set to Tc / Tb
Meets the conditions of 4.6. The height H and the width W of the capacitor main body 11 preferably satisfy the condition of H > W when the height H and the width W of the capacitor main body 11 are expressed by the ratio of both.
Each of the external electrodes 12 covers a longitudinal end face of the capacitor main body 11 and a part of four side faces adjacent to the end face, and a lower face of a portion covering a part of the four side faces, Plane. Although not shown, each external electrode 12 has a two-layer structure of a base film (lower film) adhered to the outer surface of the capacitor body 11 and a surface film in close contact with the outer surface of the base film, Layer structure including at least one interlayer. The base film is made of, for example, a baked conductor film, and the conductor is preferably made of a good conductor mainly composed of nickel, copper, palladium, platinum, silver, gold and alloys thereof. The surface film is made of, for example, a plated conductor film, and the conductor is preferably made of a good conductor mainly composed of tin, palladium, money, zinc, alloys thereof, or the like. The intermediate film is made of, for example, a plated conductor film, and the conductor is preferably a conductor of good quality mainly composed of platinum, palladium, silver, copper, nickel, alloys thereof and the like.
Here, a preferred production example of the multilayer ceramic capacitor 10-1 shown in Figs. 1 and 2 will be described. The main components of the plurality of internal electrode layers 11a1 included in the capacitor portion 11a are nickel and the main components of the plurality of dielectric layers 11a2 included in the capacitor portion 11a and the main components of the upper protective portion 11b and the lower protective portion 11c are made of barium titanate, an internal electrode layer paste containing nickel powder, terpineol (solvent), ethyl cellulose (binder) and dispersant is first prepared, and a barium titanate powder and ethanol A solvent), polyvinyl butyral (binder) and a dispersant.
Then, a ceramic slurry is coated on the carrier film using a coating device such as a die coater and a drying device and dried to produce a first green sheet. The internal electrode layer paste is printed on a first green sheet in a matrix or zigzag shape using a printing apparatus such as a screen printer and a drying apparatus and dried to form a second group of pattern groups Green sheet is made.
Then, a unit sheet punched from the first green sheet is stacked and thermocompressed until a predetermined number of sheets are stacked using a laminating apparatus such as a suction head including a punching blade and a heater, and a portion corresponding to the lower protective portion 11c is produced do. Subsequently, the unit sheet (including the pattern group for the internal electrode layer) punched from the second green sheet is superimposed and thermocompressed until a predetermined number of sheets are reached, and a portion corresponding to the capacity portion 11a is produced. Subsequently, the unit sheet punched from the first green sheet is superimposed and thermocompression bonded until a predetermined number of sheets are reached, and a portion corresponding to the upper protective portion 11b is produced. Subsequently, each part is superimposed by using a main compression bonding apparatus such as a hot hydrostatic press machine, and finally, thermocompression is performed to produce an unfired laminated sheet.
Then, the unbaked laminated sheet is cut into a lattice shape using a cutting device such as a dicing machine to produce a microchip corresponding to the capacitor main body 11. Then, a plurality of unbaked chips are fired in a reducing atmosphere or a low oxygen partial pressure atmosphere using a firing apparatus such as a tunnel type firing furnace in a temperature profile according to nickel and barium titanate (including binder removal treatment and firing treatment ) To produce a plastic chip.
Then, an electrode paste (internal electrode layer paste for flow) is applied to each longitudinal end of the fired chip using a coating device such as a roller applicator, followed by drying and baking treatment in the same atmosphere as above, And a surface film, or an interlayer film and a surface film, is formed thereon by a plating process such as electrolytic plating, thereby manufacturing the external electrode 12. For reference, the base film of each of the external electrodes may be produced by coating electrode paste on the longitudinal end portions of the untreated chips, drying them, and then co-firing them with the unbaked chips.
Fig. 3 shows a structure in which the multilayer ceramic capacitor 10-1 shown in Figs. 1 and 2 is mounted on the circuit board 21. Fig. The circuit board 21 has the conductive pads 22 corresponding to the external electrodes 12 and the surfaces to be bonded of the external electrodes 12 are formed on the surfaces of the pads 22 by using the solder 23 . Since the contour of the surface of each pad 22 is generally a rectangle larger than the contour of the surface to be bonded of each external electrode 12, the end surface 12a of each external electrode 12, The solder fillet 23a is formed. 3, Hf is the height of the top point 23a1 (topmost point) of the solder fillet 23a with respect to the lower surface of the capacitor main body 11.
Here, a preferred mounting example of the multilayer ceramic capacitor 10-1 shown in Figs. 1 and 2 will be described. First, an appropriate amount of cream solder is applied on each pad 22 of the circuit board 21. The multilayer ceramic capacitor 10-1 is mounted so that the bonded surfaces of the external electrodes 12 are bonded to the cream solder applied. The cream solder is once melted and then cured by heat treatment such as reflow soldering or the like so that the surfaces to be bonded of the external electrodes 12 are bonded to the surface of each pad 22 via the solder 23.
Fig. 4 shows the specifications and characteristics of Samples 1 to 5 prepared for confirming the effect obtained by the multilayer ceramic capacitor 10-1 shown in Figs. 1 and 2. Fig.
Samples 1 to 5 shown in Fig. 4 were produced in accordance with the above-described production example, and the respective basic specifications are as follows.
<Basic Specification of Sample 1>
The length L of the condenser main body 11 is 1,000 mu m, the width W is 500 mu m, and the height H is 685 mu m.
The thickness Ta of the capacitor portion 11a is 450 占 퐉, the thickness Tb of the upper protective portion 11b is 25 占 퐉 and the thickness Tc of the lower protective portion 11c is 210 占 퐉.
The number of internal electrode layers 11a1 included in the capacitor portion 11a is 350 layers, the number of layers of the dielectric layer 11a2 is 349, the thickness of each internal electrode layer 11a1 is 0.7 占 퐉, the thickness of each dielectric layer 11a2 is 0.6 μm.
The main component of each internal electrode layer 11a1 included in the capacitor portion 11a is nickel, the main component of each dielectric layer 11a2 included in the capacitor portion 11a, the upper protective portion 11b and the lower protective portion 11c: barium.
Thickness of each external electrode 12: 10 mu m, length of a portion covering part of four sides: 250 mu m.
Each of the external electrodes 12 has a three-layer structure of a base film composed mainly of nickel, an interlayer film composed mainly of copper, and a surface film composed mainly of tin.
<Basic Specification of Sample 2>
The thickness Tc of the lower protective portion 11c is 320 占 퐉 and the height H of the capacitor main body 11 is 795 占 퐉. Others are the same as Sample 1.
<Basic specifications of sample 3>
The thickness Tc of the lower protective portion 11c is 115 占 퐉 and the height H of the capacitor main body 11 is 590 占 퐉. Others are the same as Sample 1.
<Basic specification of sample 4>
The thickness Tc of the lower protective portion 11c is 475 占 퐉 and the height H of the capacitor main body 11 is 950 占 퐉. Others are the same as Sample 1.
<Basic specification of sample 5>
The thickness Tc of the lower protective portion 11c is 25 占 퐉 and the height H of the capacitor main body 11 is 500 占 퐉. Others are the same as Sample 1.
The numerical value of &quot; Tb / H &quot; in Fig. 4 is a numerical value (ten average values) in which the thickness Tb of the upper protective portion 11b is expressed as a ratio with the height H of the capacitor main body 11, Is a numerical value (ten average values) in which the thickness Tc of the lower protective portion 11b is expressed as a ratio with the height H of the capacitor main body 11 and the numerical value of &quot; Tc / Tb &quot; And the thickness Tc of the lower protective portion 11c in terms of the ratio of the thickness Tb and the thickness Tc of the lower protective portion 11c.
The numerical values of the "sounding" in FIG. 4 are obtained by fabricating the following mounting structure by using 10 samples 1 to 5, and setting the number of external electrodes 12 of samples 1 to 5 The intensity (unit: db) of the sound of the audible sound generated at this time was applied to the TYPe-3560-B130 of Bruelkea Japan Co., Ltd., while the AC voltage 5 V was applied while increasing the frequency from 0 MHz to 1 MHz. (Averaged value of 10) measured individually by SONORA TECHNOLOGY.
Each mounting structure is manufactured in accordance with the above mounting examples, and the respective basic specifications are as follows.
<Basic Specification of Mounting Structure>
Thickness of circuit board 21: 150 mu m, main component: epoxy resin.
Each pad 22 has a length of 400 mu m, a width of 600 mu m, a lengthwise spacing of 400 mu m, a thickness of 15 mu m, and a main component of copper.
Cream solder: tin-antimony.
Application amount of cream solder on each pad 22: 50 m in terms of thickness.
The widthwise center of the surface to be bonded of each external electrode 12 coincides with the widthwise center of the surface of each pad 22 and the cross section of each external electrode 12 extends in the longitudinal direction of the surface of each pad 22 And each sample 1 to sample 5 were mounted so as to substantially coincide with the center.
Since the ideal upper limit value of the sounding is generally known to be 25 db, Sample 5 of Sample 1 to Sample 5 shown in Fig. 4 can not be said to be effective in suppressing the sounding by exceeding the value of " Since the numerical values of &quot; Sounding &quot; of Sample 4 to Sample 4 are all less than 25 db, the above-mentioned Sample 1 to Sample 4, that is, the multilayer ceramic capacitor 10-1 shown in Figs. 1 and 2, .
After considering the values of "Tb / H", "Tc / H", "Tc / Tb" and "Sound" of samples 1 to 4 shown in FIG. 4, A numerical range of "Tb / H", a numerical range of "Tc / H" and a numerical range of "Tc / Tb", which are preferable for suppressing the sounding in the multilayer ceramic capacitor 10-1 shown in FIG.
&Lt; About the numerical range of &quot; Tb / H &
It is preferable to make the thickness Tb of the upper protective part 11b as thin as possible in order to position the capacitor part 11a in the heightwise direction of the capacitor main body 11. [ However, in order to obtain a desired protection effect on the upper protective portion 11b, a thickness of at least 20 mu m to 35 mu m is required for practical use. When the upper limit value of this numerical range of 35 mu m is applied to the sample 1 to the sample 4, the maximum value of &quot; Tb / H &quot; is 0.06, so that the thickness Tb of the upper protective part 11b is Tb /
0.06 is satisfied. When the lower limit value of the above numerical range of 20 占 퐉 is applied to the sample 1 to the sample 4, the minimum value of &quot; Tb / H &quot; becomes 0.02 and therefore the thickness Tb of the upper protective part 11b is 0.02
Tb / H
0.06 is satisfied.
&Lt; About the numerical range of &quot; Tc / H &
The elongation and contraction in the longitudinal direction which occurs when an AC voltage is applied to the external electrode 12 is not uniform in the height direction as shown by the white arrow in Fig. 3, and the capacitance portion 11a The maximum expansion amount D11a appears. The electric field intensity generated in the upper protective part 11b and the lower protective part 11c is much lower than the electric field strength of the capacitive part 11a and the amounts of expansion and contraction D11b and D11c in the case of both of them are smaller than the electric field strength of the capacitive part 11a. The stress due to elongation and contraction of the capacitor portion 11a is transmitted without decline to the upper portion of the upper protective portion 11b and the upper protective portion 11c. However, when the thickness Tc corresponding to the lower protective portion 11c is secured, the stress transmitted to the lower side from the upper portion of the lower protective portion 11c gradually decreases and the expansion / contraction amount D11c can be gradually reduced.
On the other hand, on the end face of the external electrode 12, a solder fillet 23a as shown in Fig. 3 is formed at the time of mounting. This solder fillet 23a is based on the free wetting of the molten solder to the end face 12a of the external electrode 12 and therefore the height Hf of the top point 23a1 of the solder fillet 23a is substantially Change. Concretely, even if the non-packaging is defective, the height Hf of the uppermost point 23a1 of the solder fillet 23a becomes substantially equal to the upper surface of the lower protective portion 11c (see the solid line) When the height Hf becomes lower than the upper surface of the lower protective portion 11c (refer to the lower two-dot chain line) when the height becomes higher than the upper surface of the protective portion 11c (see the two-dot chain line on the upper side) .
In all of these cases, the solder fillet 23a has a sectional shape in which the thickness of the topmost point 23a1 is the thinnest and the thickness gradually decreases toward the bottom. The portion Hf of the uppermost point 23a1 of the solder fillet 23a is higher than the upper surface of the lower protective portion 11c because flexibility is expected in a portion where the thickness of the solder fillet 23a is thin The expansion and contraction amount D11a of the capacitor portion 11a can be absorbed by the flexibility even when the upper protective portion 11c is in contact with the lower protective portion 11c can do. In the latter case, when the height Hf of the uppermost point 23a1 of the solder fillet 23a is substantially equal to the upper surface of the lower protective portion 11c (see solid line) and the height Hf is lower than the lower protective portion 11c (See the lower two-dot chain line at the lower side).
In other words, in order to suppress the sounding which may occur in the mounting structure shown in Fig. 3, when the thickness Tc of the lower protective portion 11c is set to a thickness capable of absorbing the decline of the transmission stress and the expansion and contraction, . &Lt; / RTI &gt; In the numerical values of "sounding" of the samples 1 to 4 shown in FIG. 4, when the "Tc / H" is 0.20 or more, the sounding can be suppressed to 25 db or less. The thickness Tc of the lower protective portion 11c in the capacitor 10-1 is Tc / H
0.20. &Lt; / RTI &gt; From the numerical values of the "sounding" of the samples 1 to 4 shown in FIG. 4, it can be said that it is effective to suppress the sounding noise by making the thickness Tc of the lower protective part 11c as large as possible. However, The ratio H / W between the height H and the width W of the capacitor main body 11 becomes large when the thickness Tc of the multilayer ceramic capacitor 10-1 is made thick and the multilayer ceramic capacitor 10-1 is easily collapsed at the time of mounting Lt; / RTI &gt; On the basis of this point, considering the specifications of the samples 1 to 4 shown in Fig. 4, the upper limit value of &quot; Tc / H &quot; is 0.40 of the sample 2, and therefore the multilayer ceramic capacitor 10 -1), the thickness Tc of the lower protective portion 11c is 0.20
0.40 is satisfied.
&Lt; About the numerical range of &quot; Tc / Tb &
In the values of "sounding" of the samples 1 to 4 shown in FIG. 4, when the "Tc / Tb" is 4.6 or more, the sounding can be suppressed to 25 db or less. ) And the thickness Tc of the lower protective portion 11c are Tc / Tb
It is desirable to satisfy the condition of 4.6. Also, in order to solve the problem mentioned in the preceding paragraph, since the upper limit value of &quot; Tc / Tb &quot; is 12.8 of the sample 2, the upper protective portion 11b of the multilayer ceramic capacitor 10-1 shown in FIGS. The thickness Tb of the lower protective portion 11c and the thickness Tc of the lower protective portion 11c are 4.6
Tc / Tb
It is more desirable to satisfy the condition of 12.8.
Fig. 5 shows a basic structure of a multilayer ceramic capacitor 10-2 (second embodiment) to which the present invention is applied. The multilayer ceramic capacitor 10-2 is different from the multilayer ceramic capacitor 10-1 shown in Figs. 1 and 2 in that the composition of the upper protective portion 11b and the upper portion of the lower protective portion 11c 11c1 is the same as the composition of the plurality of dielectric layers 11a2 included in the capacitor portion 11a and the lower portion 11c2 of the lower protective portion 11c except for the upper portion 11c1 has a composition Is different from the composition of the plurality of dielectric layers 11a2 included in the portion 11a. The thickness Tc1 of the upper portion 11c1 of the lower protective portion 11c may be the same as the thickness Tb of the upper protective portion 11b or may be thinner or thicker than the thickness Tb of the upper protective portion 11b good. 5, a total of 32 internal electrode layers 11a1 are shown for the sake of convenience. However, as with the multilayer ceramic capacitor 10-1 shown in Figs. 1 and 2, the number of layers of the internal electrode layers 11a1 is limited There is no.
The "same composition" mentioned in the preceding paragraph means that the components are the same and does not mean that the content of each component is the same. In addition, the term "different composition" mentioned in the preceding paragraph means that the components are different and the components are the same and the contents are different. As a technique for realizing "the composition is different" mentioned in the preceding paragraph, there are a technique of changing the content or the kind of the subcomponent without changing the kind of the main component (dielectric ceramics) of the lower part 11c2 of the lower protective part 11c, A method of changing the kind of the main component (dielectric ceramics) in the lower portion 11c2 of the portion 11c can be exemplified.
In the former technique described in the preceding paragraph, in the lower portion 11c2 of the lower protective portion 11c, a subcomponent capable of lowering the dielectric constant, for example, an alkaline earth metal such as Mg, Ca, or Sr, Transition metals such as Mn, V, Mo, W and Cr and rare earth elements such as La, Ce, Pr, Nd, Sm, Eu, Gd, Tb, Dy, Ho, Er, Tm, It is preferable to contain at least one selected from the elements. Also, in the latter technique described in the preceding paragraph, it is preferable to select dielectric ceramics which can be a main component (dielectric ceramics) of the lower portion 11c2 of the lower protective portion 11c and which can lower the dielectric constant. In this case, the dielectric constant of the upper protective portion 11b and the dielectric constant of the upper portion 11c1 of the lower protective portion 11c become equal to the dielectric constant of the plurality of dielectric layers 11a2 included in the capacitor portion 11a, The dielectric constant of the lower portion 11c2 of the capacitor portion 11c becomes lower than the dielectric constant of the plurality of dielectric layers 11a2 included in the capacitor portion 11a.
Here, a preferable production example of the multilayer ceramic capacitor 10-2 shown in Fig. 5 will be described. The main component of the plurality of internal electrode layers 11a1 included in the capacitor portion 11a is nickel, the plurality of dielectric layers 11a2 included in the capacitor portion 11a, the main component of the upper protective portion 11b and the lower protective portion 11c In the case of barium titanate, an internal electrode layer paste containing nickel powder, terpineol (solvent), ethyl cellulose (binder) and dispersant is prepared first, and barium titanate powder, ethanol (solvent) and polyvinyl A first ceramic slurry containing an additive such as butyral (binder) and a dispersant, and a second ceramic slurry prepared by adding a proper amount of MgO to the first ceramic slurry.
Then, a first ceramic slurry is coated on a carrier film using a coating device such as a die coater and a drying device and dried to form a first green sheet, and a second ceramic slurry is coated on a separate carrier film and dried To prepare a second green sheet (containing MgO). Further, the internal electrode layer paste is printed in a matrix or zigzag shape on the first green sheet using a printing apparatus such as a screen printer and a drying apparatus, and dried to produce a third green sheet having the pattern group for the internal electrode layer formed thereon.
Then, a unit sheet punched from the second green sheet (containing MgO) is stacked and thermocompressed until a predetermined number of sheets are stacked using a laminating apparatus such as an adsorption head including a punching blade and a heater, A portion corresponding to the lower portion 11c2 is fabricated. Subsequently, the unit sheet punched from the first green sheet is superimposed and thermocompressed until a predetermined number of sheets are reached, and a portion corresponding to the upper portion 11c1 of the lower protective portion 11c is produced. Subsequently, the unit sheet (including the pattern group for the internal electrode layer) punched out from the third green sheet is superimposed and thermocompressed until a predetermined number of sheets are reached, and a portion corresponding to the capacity portion 11a is produced. Subsequently, the unit sheet punched from the first green sheet is superimposed and thermocompression bonded until a predetermined number of sheets are reached, and a portion corresponding to the upper protective portion 11b is produced. Subsequently, each of the parts is successively superimposed on each other using a main compression bonding apparatus such as a hot-water hydrostatic press, and finally, thermally pressed to produce an unfired laminated sheet.
Then, the unbaked laminated sheet is cut into a lattice shape by using a cutting device such as a dicing machine to produce an unfabricated chip corresponding to the capacitor main body 11. Then, a plurality of unbaked chips are fired (including a binder removal treatment and a firing treatment) in a reducing atmosphere or in a temperature profile according to barium and nickel barium titanate under a low oxygen partial pressure atmosphere using a firing apparatus such as a tunnel type firing furnace A plastic chip is produced.
Then, an electrode paste (internal electrode layer paste is used) is applied to the end portions in the longitudinal direction of the fired chip using a coating device such as a roller applicator, dried, and baked under the same atmosphere as above to form a base film, A surface film, or an intermediate film and a surface film are formed by a plating process such as electrolytic plating on the surface film or the external electrode 12. For reference, the base film of each of the external electrodes may be produced by coating electrode paste on the longitudinal end portions of the untreated chips, drying them, and then co-firing them with the unbaked chips.
The structure in which the multilayer ceramic capacitor 10-2 shown in Fig. 5 is mounted on the circuit board 21 and its preferable mounting example are the same as the mounting structure (see Fig. 3) described in the first embodiment and the preferred mounting examples So that the description thereof is omitted.
Fig. 6 shows the specifications and characteristics of the sample 6 prepared for confirming the effect obtained by the multilayer ceramic capacitor 10-2 shown in Fig. For reference, FIG. 6 shows the specifications and characteristics of the sample 1 shown in FIG. 4 for comparison.
Sample 6 shown in Fig. 6 was manufactured in accordance with the above-described production example, and its basic specifications are as follows.
<Basic Specification of Sample 6>
The thickness Tc1 of the upper portion 11c1 is 25 占 퐉 and the thickness Tc2 of the lower portion 11c2 is 185 占 퐉 among the thickness Tc of the lower protective portion 11c (210 占 퐉). Similar to Sample 1 except that the lower portion 11c2 contains Mg.
In addition, the basic specification of the mounting structure for the measurement method and the measurement method of the numerical value of "Tb / H", the value of "Tc / H", the method of calculating the value of "Tc / Tb" Are the same as those of the calculation method and measurement method described in the first embodiment and the basic specifications of the mounting structure, respectively, so that the description thereof will be omitted.
As described above, since the ideal upper limit value of the sounding is generally 25dB, the sample 6 shown in FIG. 6, that is, the multilayer ceramic capacitor 10-2 shown in FIG. 5, is effective for suppressing the sounding. Of course, in the multilayer ceramic capacitor 10-2 shown in Fig. 5, the numerical range of "Tb / H", the numerical range of "Tc / H" Quot; can be applied.
The lower dielectric constant of the lower protective portion 11c is lower than the dielectric constant of the plurality of dielectric layers 11a2 included in the capacitor portion 11a and the dielectric constant of the upper portion 11c1 of the lower protective portion 11c The electric field intensity generated in the lower protective portion 11c at the time of application of the voltage in the mounted state can be reduced and the decline of the transmission stress described in the first embodiment can more reliably be made to contribute to suppression of sound.
The composition of the lower portion 11c2 of the lower protective portion 11c corresponds to the composition of the plurality of dielectric layers 11a2 included in the capacitor portion 11a and the composition of the upper protective portion 11b and the composition of the lower protective portion 11c The upper and lower directions when the multilayer ceramic capacitor 10-2 is mounted on the basis of the appearance color of the lower portion 11c2 of the lower protective portion 11c different from the other portions are easily distinguished can do.
In the above-mentioned Production Example and Sample 6, Mg is contained in the lower portion 11c2 of the lower protective portion 11c in order to satisfy the requirement (M1) described in the beginning of the second embodiment. However, The same effect as described above can be obtained by including one kind selected from alkaline earth metal elements such as Ca and Sr other than Mg in the magnetic layer 11c2 or by containing two or more types of alkaline earth metal elements (including Mg) . Even if at least one selected from mutual metal elements such as Mn, V, Mo, W and Cr is contained in the lower portion 11c2 of the lower protective portion 11c instead of the alkaline earth metal element, La, Ce, Pr, Nd , Sm, Eu, Gd, Tb, Dy, Ho, Er, Tm, Yb, Lu and the like can be obtained. That is, if the lower portion 11c2 of the lower protective portion 11c contains at least one selected from the alkaline earth metal element, the transition metal element, and the rare earth element, the same effect as described above can be obtained. Of course, the alkaline earth metal element, the transition metal element, the rare earth element (s) and the rare earth element (s) may be added to the upper portion 11c1 of the lower protective portion 11c and the plurality of dielectric layers 11a2, The same effects as those described above can be obtained if the content contained in the lower portion 11c2 of the lower protective portion 11c is larger than the above content. In order to satisfy the requirement M1 described in the beginning of the second embodiment, the type of the main component (dielectric ceramics) of the lower portion 11c2 of the lower protective portion 11c is set to be the same as that of the dielectric layers 11c included in the capacitor portion 11a (Dielectric ceramics) of the upper portion 11c2 of the upper protective portion 11a2 and the upper protective portion 11b and the upper portion 11c1 of the lower protective portion 11c are different from each other.
Fig. 7 shows a basic structure of a multilayer ceramic capacitor 10-3 (third embodiment) to which the present invention is applied. This multilayer ceramic capacitor 10-3 has the same composition as that of the multilayer ceramic capacitor 10-1 shown in Figs. 1 and 2 and the composition of the upper protective portion 11b and the lower protective portion 11c of the (M2) The composition of the upper protective portion 11b and the composition of the lower protective portion 11c are different from the composition of the plurality of dielectric layers 11a2 included in the capacitor portion 11a. 7, a total of 32 internal electrode layers 11a1 are shown for the sake of convenience. However, like the multilayer ceramic capacitor 10-1 shown in Figs. 1 and 2, the number of layers of the internal electrode layers 11a1 is limited There is no.
The "same composition" mentioned in the preceding paragraph means that the components are the same and does not mean that the content of each component is the same. In addition, the term "different composition" mentioned in the preceding paragraph means that the components are different and the components are the same and the contents are different. As a technique for realizing "the composition is different" mentioned in the preceding paragraph, there are a technique of changing the content or the kind of the subcomponent without changing the kind of the main component (dielectric ceramics) of the upper protective part 11b and the lower protective part 11c, A technique of changing the kind of the main component (dielectric ceramics) of the protective portion 11b and the lower protective portion 11c can be exemplified.
In the former technique described in the preceding paragraph, it is presumed that suppression of sound is suppressed. In the former technique, the lower protective portion 11b and the lower protective portion 11c are provided with subcomponents capable of lowering the permittivity, such as alkaline earth elements such as Mg, A transition metal element such as Mn, V, Mo, W and Cr and a rare earth element such as La, Ce, Pr, Nd, Sm, Eu, Gd, Tb, Dy, Ho, Er, Tm, It is preferable to contain at least one selected. Also, in the latter technique described in the preceding paragraph, it is preferable to select dielectric ceramics capable of lowering the dielectric constant as main components (dielectric ceramics) of the upper protective part 11b and the lower protective part 11c. In this case, the dielectric constant of the upper protective portion 11b and the dielectric constant of the lower protective portion 11c become equal, and the dielectric constant of the upper protective portion 11b and the dielectric constant of the lower protective portion 11c are included in the capacitance portion 11a Becomes lower than the dielectric constant of the plurality of dielectric layers 11a2.
Here, a preferred production example of the multilayer ceramic capacitor 10-3 shown in Fig. 7 will be described. The main component of the plurality of internal electrode layers 11a1 included in the capacitor portion 11a is nickel, the plurality of dielectric layers 11a2 included in the capacitor portion 11a, the main component of the upper protective portion 11b and the lower protective portion 11c In the case of barium titanate, an internal electrode layer paste containing nickel powder, terpineol (solvent), ethyl cellulose (binder) and dispersant, and the like are prepared first, and barium titanate powder, ethanol (solvent) A first ceramic slurry containing additives such as vinyl butyral (binder) and a dispersant, and a second ceramic slurry prepared by adding a proper amount of MgO to the first ceramic slurry.
Then, a first ceramic slurry is coated on a carrier film using a coating device such as a die coater and a drying device and dried to form a first green sheet, and a second ceramic slurry is coated on a separate carrier film and dried To prepare a second green sheet (containing MgO). The internal electrode layer paste is printed on the first green sheet in a matrix or zigzag shape using a printing apparatus such as a screen printer and a drying apparatus and dried to produce a third green sheet having a pattern group for internal electrode layers formed thereon , The internal electrode layer paste is printed in the form of a matrix or zigzag on the second green sheet (containing MgO) and dried to prepare a fourth green sheet (containing MgO) having the internal electrode layer pattern group formed thereon.
Then, a unit sheet punched from the second green sheet (containing MgO) is superimposed and thermocompressed until a predetermined number of sheets are stacked using a laminating apparatus such as a suction head including a punching blade and a heater, Make corresponding parts. Subsequently, on the unit sheet (including the pattern group for the internal electrode layer) punched from the fourth green sheet (containing MgO), a unit sheet punched from the third green sheet (including the pattern group for the internal electrode layer) And thermosetting is carried out to fabricate a portion corresponding to the capacitor portion 11a. Subsequently, the unit sheet punched from the second green sheet (containing MgO) is superimposed and thermally compressed until a predetermined number of sheets are reached, and a portion corresponding to the upper protective portion 11b is produced. Subsequently, each of the parts is successively superimposed on each other using a main compression bonding apparatus such as a hot-water hydrostatic press, and finally, thermally pressed to produce an unfired laminated sheet.
The structure in which the multilayer ceramic capacitor 10-3 shown in Fig. 7 is mounted on the circuit board 21 and its preferable mounting example are the same as the mounting structure (see Fig. 3) described in the first embodiment and the preferred mounting examples So that the description thereof is omitted.
Fig. 8 shows the specifications and characteristics of the sample 7 prepared for confirming the effect obtained by the multilayer ceramic capacitor 10-3 shown in Fig. For reference, FIG. 8 shows the specifications and characteristics of the sample 1 shown in FIG. 4 for comparison
Sample 7 shown in Fig. 8 was manufactured in accordance with the above-mentioned production example, and its basic specifications are as follows.
<Basic Specifications of Sample 7>
Similar to Sample 1 except that the upper protective portion 11b and the lower protective portion 11c contain Mg.
In addition, the basic specification of the measurement method and the mounting structure for measurement of the numerical values of "Tb / H", "Tc / H", "Tc / Tb" Are the same as those of the calculation method and measurement method described in the first embodiment and the basic specifications of the mounting structure, respectively, so that the description thereof will be omitted.
As described above, since the ideal upper limit value of the sound resonance is generally known to be 25 dB, the sample 7 shown in FIG. 8, that is, the multilayer ceramic capacitor 10-3 shown in FIG. Of course, in the multilayer ceramic capacitor 10-3 shown in Fig. 7, the numerical range of "Tb / H", the numerical range of "Tc / H" Quot; can be applied.
The dielectric constant of the lower protective portion 11c is lower than the dielectric constant of the plurality of dielectric layers 11a2 included in the capacitor portion 11a so that the electric field intensity generated in the lower protective portion 11c at the time of voltage application in the mounted state is set to So that the decline of the transmission stress described in the first embodiment can more reliably contribute to the suppression of the noise.
The composition of the upper protective part 11b and the composition of the lower protective part 11c are different from the composition of the plurality of dielectric layers 11a2 included in the capacitor part 11a and the thickness Tc of the lower protective part 11c is On the basis of the external color of the upper protective part 11b and the lower protective part 11c and the thickness Tc of the lower protective part 11c different from those of the other protective part 11b and the upper protective part 11b The vertical direction when the multilayer ceramic capacitor 10-3 is mounted can be easily determined.
In the above-described production example and sample 7, Mg is contained in the upper protective part 11b and the lower protective part 11c in order to satisfy the requirement (M2) described in the beginning of the third embodiment. However, The protective portion 11b and the lower protective portion 11c may contain one kind selected from alkaline earth metal elements such as Ca and Sr other than Mg, or two or more types of alkaline earth metal elements (including Mg) The same effects as those described above can be obtained. Further, even if at least one selected from transition metal elements such as Mn, V, Mo, W and Cr is contained in place of the alkaline earth metal element in the upper protective portion 11b and the lower protective portion 11c, The same effects as those described above can be obtained by including at least one selected from rare earth elements such as Nd, Sm, Eu, Gd, Tb, Dy, Ho, Er, Tm, Yb and Lu. That is, when the upper protective portion 11b and the lower protective portion 11c contain at least one selected from the alkaline earth metal element, the transition metal element, and the rare earth element, the same effects as described above can be obtained. Of course, when the plurality of dielectric layers 11a2 included in the capacitor portion 11a include at least one selected from the alkaline earth metal element, the transition metal element, and the rare earth element, And the lower protective portion 11c are increased, the same effect as described above can be obtained. In order to satisfy the requirement (M2) described in the beginning of the third embodiment, the kinds of the main components (dielectric ceramics) of the upper protective part 11b and the lower protective part 11c are referred to as a plurality The same effect as described above can be obtained even when the main component (dielectric ceramics) of the dielectric layer 11a2 is different.
&Quot; Fourth Embodiment &
Fig. 9 shows a basic structure of a multilayer ceramic capacitor 10-4 (fourth embodiment) to which the present invention is applied. The multilayer ceramic capacitor 10-4 is different from the multilayer ceramic capacitor 10-1 shown in Figs. 1 and 2 in that the composition of the upper protective portion 11b and the composition of the lower protective portion 11c are different The composition of the upper protective portion 11b and the composition of the lower protective portion 11c are different from the composition of the plurality of dielectric layers 11a2 included in the capacitor portion 11a. 9 shows a total of 32 internal electrode layers 11a1 for the sake of convenience. However, as with the multilayer ceramic capacitor 10-1 shown in Figs. 1 and 2, the number of layers of the internal electrode layers 11a1 is limited There is no.
The "composition is different" as described in the previous step means that the constituents are different and that the constituents are the same and the content is different. As a technique for realizing "the composition is different" mentioned in the preceding paragraph, there are a technique of changing the content or the kind of the subcomponent without changing the kind of the main component (dielectric ceramics) of the upper protective part 11b and the lower protective part 11c, A technique of changing the kind of the main component (dielectric ceramics) of the protective portion 11b and the lower protective portion 11c can be exemplified.
In the former technique described in the preceding paragraph, it is presumed that suppression of sound is suppressed. In the former technique, the lower protective portion 11b and the lower protective portion 11c are provided with subcomponents capable of lowering the permittivity, such as alkaline earth elements such as Mg, A transition metal element such as Mn, V, Mo, W and Cr and a rare earth element such as La, Ce, Pr, Nd, Sm, Eu, Gd, Tb, Dy, Ho, Er, Tm, It is preferable that at least one selected is contained and the content of the lower protective portion 11c is increased more than the content of the upper protective portion 11b. In the latter technique described in the preceding paragraph, it is preferable to select two kinds of dielectric ceramics as main components (dielectric ceramics) of the upper protective part 11b and the lower protective part 11c, which can lower their dielectric constants. In this case, the dielectric constant of the upper protective portion 11b and the dielectric constant of the lower protective portion 11c are lower than the dielectric constant of the plurality of dielectric layers 11a2 included in the capacitor portion 11a, and the dielectric constant of the lower protective portion 11c is Is lower than that of the upper protective portion 11b.
Here, a preferable production example of the multilayer ceramic capacitor 10-4 shown in Fig. 9 will be described. The main component of the plurality of internal electrode layers 11a1 included in the capacitor portion 11a is nickel, the plurality of dielectric layers 11a2 included in the capacitor portion 11a, the main component of the upper protective portion 11b and the lower protective portion 11c In the case of barium titanate, an internal electrode layer paste containing nickel powder, terpineol (solvent), ethyl cellulose (binder) and dispersant is prepared first, and barium titanate powder, ethanol (solvent) A first ceramic slurry containing an additive such as vinyl butyral (binder) and a dispersing agent, a second ceramic slurry to which MgO is added in an appropriate amount to the first ceramic slurry, and a second ceramic slurry containing MgO To prepare a third ceramic slurry.
Then, a first ceramic slurry is coated on a carrier film using a coating device such as a die coater and a drying device and dried to form a first green sheet, and a second ceramic slurry is coated on a separate carrier film and dried , A third green sheet (containing MgO) is prepared, a third ceramic slurry is coated on another carrier film and dried to produce a third green sheet (containing MgO). The internal electrode layer paste is printed on the first green sheet in a matrix or zigzag shape using a printing apparatus such as a screen printer and a drying apparatus and dried to produce a fourth green sheet having the internal electrode layer pattern group formed thereon , The internal electrode layer paste is printed on the third green sheet (containing MgO) in the form of a matrix or zigzag and dried to prepare a fifth green sheet (containing MgO) on which a pattern group for an internal electrode layer is formed.
Then, a unit sheet punched from the third green sheet (containing MgO) is superimposed and thermocompressed until a predetermined number of sheets are stacked using a laminating apparatus such as an adsorption head including a punching blade and a heater, Make corresponding parts. Subsequently, a unit sheet (including a pattern group for the internal electrode layer) punched out from the fourth green sheet is placed on a unit sheet (including the pattern group for the internal electrode layer) punched from the fifth green sheet (containing MgO) And thermosetting is carried out to fabricate a portion corresponding to the capacitor portion 11a. Subsequently, the unit sheet punched from the second green sheet (containing MgO) is superimposed and thermally compressed until a predetermined number of sheets are reached, and a portion corresponding to the upper protective portion 11b is produced. Subsequently, each of the parts is successively superimposed on each other using a main compression bonding apparatus such as a hot-water hydrostatic press, and finally, thermally pressed to produce an unfired laminated sheet.
The structure in which the multilayer ceramic capacitor 10-4 shown in Fig. 9 is mounted on the circuit board 21 and its preferable mounting examples are the same as the mounting structure (see Fig. 3) described in the first embodiment and the preferred mounting examples So that the description thereof is omitted.
Fig. 10 shows the specifications and characteristics of the sample 8 prepared for confirming the effect obtained by the multilayer ceramic capacitor 10-4 shown in Fig. For reference, FIG. 10 shows the specifications and characteristics of the sample 1 shown in FIG. 4 for comparison
Sample 8 shown in Fig. 10 was produced in accordance with the above production example, and the basic specifications thereof are as follows.
<Basic Specifications of Sample 8>
The upper protective portion 11b and the lower protective portion 11c contain Mg and the Mg content of the lower protective portion 11c is larger than the Mg content of the upper protective portion 11b.
In addition, the basic specification of the measurement method and measurement method of the numerical value of "Tb / H", the value of "Tc / H", the method of calculating the value of "Tc / Tb" Are the same as those of the calculation method and measurement method described in the first embodiment and the basic specifications of the mounting structure, respectively, so that the description thereof will be omitted.
As described above, since the ideal upper limit value of the sound resonance is known to be approximately 25 dB, the sample 8 shown in FIG. 10, that is, the multilayer ceramic capacitor 10-4 shown in FIG. Of course, the multilayer ceramic capacitor 10-4 shown in Fig. 9 also has a numerical range of "Tb / H", a numerical range of "Tc / H" and a numerical range of "Tc / Tb Quot; can be applied.
The dielectric constant of the lower protective portion 11c is made lower than the dielectric constant of the plurality of dielectric layers 11a2 included in the capacitor portion 11a so that the electric field intensity generated in the lower protective portion 11c And the decline of the transmission stress described in the first embodiment can more reliably be performed, contributing to suppression of the sound.
The composition of the upper protective part 11b and the composition of the lower protective part 11c are different from the composition of the plurality of dielectric layers 11a2 included in the capacitor part 11a and the thickness Tc of the lower protective part 11c is On the basis of the external color of the upper protective part 11b and the lower protective part 11c and the thickness Tc of the lower protective part 11c different from those of the other protective part 11b and the upper protective part 11b It is possible to easily determine the vertical direction when mounting the multilayer ceramic capacitor 10-4.
In the above-described production example and sample 8, Mg is contained in the upper protective part 11b and the lower protective part 11c in order to satisfy the requirement (M3) described in the beginning of the fourth embodiment. However, The protective portion 11b and the lower protective portion 11c may contain one kind selected from alkaline earth metal elements such as Ca and Sr other than Mg, or two or more types of alkaline earth metal elements (including Mg) The same effects as those described above can be obtained. Further, even if at least one selected from transition metal elements such as Mn, V, Mo, W and Cr is contained in place of the alkaline earth metal element in the upper protective portion 11b and the lower protective portion 11c, The same effects as those described above can be obtained by including at least one selected from rare earth elements such as Nd, Sm, Eu, Gd, Tb, Dy, Ho, Er, Tm, Yb and Lu. That is, when the upper protective portion 11b and the lower protective portion 11c contain at least one selected from the alkaline earth metal element, the transition metal element, and the rare earth element, the same effects as described above can be obtained. Of course, when the plurality of dielectric layers 11a2 included in the capacitor portion 11a include at least one selected from the alkaline earth metal element, the transition metal element, and the rare earth element, And the lower protective portion 11c are increased, the same effect as described above can be obtained. In order to satisfy the requirement (M3) described in the beginning of the fourth embodiment, the kinds of the main components (dielectric ceramics) of the upper protective part 11b and the lower protective part 11c are set to a plurality of The same effect as described above can be obtained even when the main component (dielectric ceramics) of the dielectric layer 11a2 is different.
&Quot; Fifth Embodiment &
Fig. 11 shows a basic structure of a multilayer ceramic capacitor 10-5 (fifth embodiment) to which the present invention is applied. The multilayer ceramic capacitor 10-5 is different from the multilayer ceramic capacitor 10-1 shown in Figs. 1 and 2 in that the composition of the upper protective portion 11b and the upper portion of the lower protective portion 11c 11c1 are the same and the composition of the upper protective portion 11b and the composition of the upper portion 11c1 of the lower protective portion 11c is different from the composition of the plurality of dielectric layers 11a2 included in the capacitive portion 11a, The composition of the lower protective portion 11b and the composition of the upper portion 11c1 of the lower protective portion 11c and the composition of the lower portion 11c2 of the portion 11c But differs from the composition of a plurality of dielectric layers 11a2 included. 11 shows a total internal electrode layer 11a1 of 32 layers for the sake of convenience of illustration. However, like the multilayer ceramic capacitor 10-1 shown in Figs. 1 and 2, the number of layers of the internal electrode layers 11a1 is limited There is no.
Quot; different composition &quot; described in the previous step means that the components are different, and that the constituents are the same and the content is different. As a technique for realizing "the composition is different" mentioned in the preceding paragraph, there are a technique of changing the content or the kind of the subcomponent without changing the kind of the main component (dielectric ceramics) of the upper protective part 11b and the lower protective part 11c, A technique of changing the kind of the main component (dielectric ceramics) of the protective portion 11b and the lower protective portion 11c can be exemplified.
In the former technique described in the preceding paragraph, it is assumed that suppression of sound is suppressed in the upper portion 11c1 and the lower portion 11c2 of the upper protective portion 11b and the lower protective portion 11c, A transition metal element such as Mn, V, Mo, W and Cr and a transition metal element such as La, Ce, Pr, Nd, Sm, Eu, Gd, Tb, Dy, Ho, And the content of the lower portion 11c2 of the lower protective portion 11c is set so that the content of the upper protective portion 11b and the content of the lower protective portion 11c ) Of the upper portion 11c1 of the upper portion 11c1. In the latter technique described in the preceding paragraph, as the main components (dielectric ceramics) of the upper protective portion 11b and the lower protective portion 11c and the upper portion 11c1 of the lower protective portion 11c, It is preferable to select two kinds of dielectric ceramics capable of lowering the dielectric constant. In this case, the dielectric constant of the upper protective portion 11b is equal to the dielectric constant of the upper portion 11c1 of the lower protective portion 11c, and the dielectric constant of the upper protective portion 11b and the dielectric constant of the upper protective portion 11c Is lower than the dielectric constant of the plurality of dielectric layers 11a2 included in the capacitor portion 11a and the dielectric constant of the lower portion 11c2 of the lower protective portion 11c is smaller than the dielectric constant of the upper protective portion 11b and the dielectric constant of the lower protective portion 11c Becomes lower than the dielectric constant of the upper portion 11c1 of the portion 11c.
Here, a preferred production example of the multilayer ceramic capacitor 10-5 shown in Fig. 11 will be described. The main component of the plurality of internal electrode layers 11a1 included in the capacitor portion 11a is nickel, the plurality of dielectric layers 11a2 included in the capacitor portion 11a, the main component of the upper protective portion 11b and the lower protective portion 11c In the case of barium titanate, an internal electrode layer paste containing nickel powder, terpineol (solvent), ethyl cellulose (binder) and dispersant is first prepared, and barium titanate powder, ethanol (solvent) and polyvinyl A first ceramic slurry containing an additive such as butyral (binder) and a dispersant, a second ceramic slurry in which MgO is added to the first ceramic slurry in an appropriate amount, and a second ceramic slurry in which MgO is added to the first ceramic slurry To prepare a third ceramic slurry.
Then, a first ceramic slurry was coated on a carrier film using a coating device such as a die coater and a drying device and dried to prepare a first green sheet, and a second ceramic slurry was coated on a separate carrier film and dried A second green sheet (containing MgO) is prepared, a third ceramic slurry is coated on a separate carrier film, and dried to produce a third green sheet (containing MgO). The internal electrode layer paste is printed on the first green sheet in a matrix or zigzag shape using a printing apparatus such as a screen printer and a drying apparatus and dried to produce a fourth green sheet having the internal electrode layer pattern group formed thereon , The internal electrode layer paste is printed in the form of a matrix or zigzag on the second green sheet (containing MgO) and dried to prepare a fifth green sheet (containing MgO) having the internal electrode layer pattern group formed thereon
Then, a unit sheet punched from the third green sheet (containing MgO) is superimposed and thermocompressed until a predetermined number of sheets are stacked using a laminating apparatus such as an adsorption head including a punching blade and a heater, A portion corresponding to the lower portion 11c2 is fabricated. Subsequently, the unit sheet punched from the second green sheet (containing MgO) is superimposed and thermocompressed until a predetermined number of sheets are reached, and a portion corresponding to the upper portion 11c1 of the lower protective portion 11c is produced. Subsequently, a unit sheet (including a pattern group for the internal electrode layer) punched out from the fourth green sheet is placed on a unit sheet (including the pattern group for the internal electrode layer) punched from the fifth green sheet (containing MgO) And thermosetting is carried out to fabricate a portion corresponding to the capacitor portion 11a. Subsequently, the unit sheet punched from the second green sheet (containing MgO) is superimposed and thermally compressed until a predetermined number of sheets are reached, and a portion corresponding to the upper protective portion 11b is produced. Subsequently, each of the parts is successively superimposed on each other using a main compression bonding apparatus such as a hot-water hydrostatic press, and finally, thermally pressed to produce an unfired laminated sheet.
Then, the unbaked laminated sheet is cut into a lattice shape by using a cutting device such as a dicing machine to produce an unfabricated chip corresponding to the capacitor main body 11. Then, a plurality of unbaked chips are fired (including a binder removal treatment and a firing treatment) in a temperature profile according to nickel and barium titanate in a reducing atmosphere or a low oxygen partial pressure atmosphere using a firing apparatus such as a tunnel type firing furnace, Chip.
The structure in which the multilayer ceramic capacitor 10-5 shown in FIG. 11 is mounted on the circuit board 21 and its preferable mounting example are the same as the mounting structure (see FIG. 3) described in the first embodiment, So that the description thereof is omitted.
Fig. 12 shows the specifications and characteristics of the sample 9 prepared for confirming the effect obtained by the multilayer ceramic capacitor 10-5 shown in Fig. For reference, FIG. 12 shows the specifications and characteristics of the sample 1 shown in FIG. 4 for comparison
Sample 9 shown in Fig. 12 was manufactured in accordance with the above-described production example, and its basic specifications are as follows.
<Basic Specifications of Sample 9>
The thickness Tc1 of the upper portion 11c1 is 25 占 퐉 and the thickness Tc2 of the lower portion 11c2 is 185 占 퐉 among the thickness Tc of the lower protective portion 11c (210 占 퐉). The upper portion 11c1 and the lower portion 11c2 and the upper protective portion 11b contain Mg and the Mg content of the lower portion 11c2 of the lower protective portion 11c is larger than the Mg content of the upper protective portion 11b and the lower protective portion 11c. Is larger than the Mg content of the upper portion 11c1 of the upper portion 11c.
The basic specification of the mounting structure for the measurement method and the measurement method of the numerical values of "Tb / H", "Tc / H", "Tc / Tb" Are the same as those of the calculation method and measurement method described in the first embodiment and the basic specifications of the mounting structure, respectively, so that the description thereof will be omitted.
As described above, since the ideal upper limit value of the sound resonance is known to be approximately 25 db, the sample 9 shown in Fig. 12, that is, the multilayer ceramic capacitor 10-5 shown in Fig. Of course, in the multilayer ceramic capacitor 10-5 shown in Fig. 11, the numerical range of "Tb / H" and the numerical range of "Tc / H" Quot; can be applied.
The dielectric constant of the upper protective portion 11b and the dielectric constant of the upper portion 11c1 of the lower protective portion 11c are made lower than the dielectric constant of the plurality of dielectric layers 11a2 included in the capacitor portion 11a, The dielectric constant of the lower protective portion 11c2 is lower than the dielectric constant of the upper protective portion 11c of the lower protective portion 11c so as to reduce the electric field intensity generated in the lower protective portion 11c during voltage application in the mounted state , The decline of the transmission stress described in the first embodiment can more reliably be performed, contributing to suppressing the sounding.
The composition of the upper protective portion 11b and the composition of the upper portion 11c1 of the lower protective portion 11c and the lower portion 11c2 of the lower protective portion 11c are the same as those of the plurality of Since the lower protective portion 11c is different from the composition of the dielectric layer 11a2 and the thickness Tc of the upper protective portion 11b is thicker than the thickness Tb of the upper protective portion 11b, It is possible to easily determine the vertical direction when mounting the multilayer ceramic capacitor 10-5 on the basis of the external color of the multilayer ceramic capacitor 11c and the thickness Tc of the lower protective portion 11c.
In the above-described production example and sample 9, in order to satisfy the requirement (M4) described in the beginning of the fifth embodiment, the upper portion 11c1 of the upper protective portion 11b and the upper protective portion 11c1 of the lower protective portion 11c The upper portion 11c1 of the lower protective portion 11c and the lower portion 11c2 of the lower protective portion 11c are made of Mg in the lower portion 11c2 of the lower protective portion 11c, The same effect as described above can be obtained by including one selected from alkaline earth metal elements such as Ca and Sr other than Mg, or by containing two or more kinds of alkaline earth metal elements (including Mg). V, Mo, W, Cr, etc. instead of the alkaline earth metal element in the upper part 11c1 of the upper protective part 11b and the lower protective part 11c and the lower part 11c2 of the lower protective part 11c At least one selected from rare earth elements such as La, Ce, Pr, Nd, Sm, Eu, Gd, Tb, Dy, Ho, Er, Tm, Yb and Lu, The same effects as those described above can be obtained. That is, the upper part 11c1 of the upper protective part 11b and the lower protective part 11c and the lower part 11c2 of the lower protective part 11c are selected from the alkaline earth metal element, the transition metal element and the rare earth element The same effects as those described above can be obtained by adding one or more kinds of them. Of course, when the plurality of dielectric layers 11a2 included in the capacitor portion 11a include at least one selected from the alkaline earth metal element, the transition metal element, and the rare earth element, And the upper portion 11c1 of the lower protective portion 11c and the lower portion 11c2 of the lower protective portion 11c are increased, the same effect as described above can be obtained. The upper part 11c1 of the upper protective part 11b and the lower protective part 11c and the lower part 11c2 of the lower protective part 11c satisfy the requirement M4 described in the beginning of the fifth embodiment, (Dielectric ceramics) of the plurality of dielectric layers 11a2 included in the capacitor portion 11a is different from that of the main component (dielectric ceramics) included in the capacitor portion 11a.
&Quot; Other Embodiments &
(1) In the description of the first to fifth embodiments, the multilayer ceramic capacitors 10-1 to 10-5 in which the height H of the capacitor main body 11 is larger than the width W are exemplified. However, Even if the height H of the condenser main body is smaller than the width W even if the height H of the condenser main body is the same as the width W when the thickness Ta of the condenser main body 11a can be made thinner, 11c can be made thicker than the thickness Tb of the upper protective portion 11b so that the capacitor portion 11a can be positioned above the capacitor main body 11 in the height direction.
(2) In the second embodiment and the fifth embodiment, dielectric ceramics is used as a main component as the lower portion 11c2 of the lower protective layer 11c of the capacitor main body 11. However, the lower portion 11c2 may be made of dielectric It is also possible to use a dielectric material other than ceramics such as glass of Li-Si, B-Si, Li-Si-Ba or B-Si-Ba glass, glass in which filler such as silica or alumina is dispersed, thermosetting (Thermosetting) plastic. In this case, the lower protective layer 11c is removed except for the lower protective layer 11c in the unbaked laminated sheet process of the production example described in the second embodiment and the fifth embodiment, and then the lower protective layer 11c is made to correspond to the lower part 11c2 A method of adhering the sheet material to the sheet material using an adhesive or the like can be preferably adopted.
10, 10-1, 10-2, 10-3, 10-4, and 10-5: Multilayer Ceramic Capacitors
11: capacitor body L: length of capacitor body
W: width of capacitor body H: length of capacitor body
11a: capacitance portion 11a1: internal electrode layer
11a2: dielectric layer 11b: upper protective portion
11c: lower protective portion 11c1: upper portion of the lower protective portion
11c2: Lower part of the lower protective part Ta: Thickness of the capacitive part
Tb: thickness of upper protective portion Tc: thickness of lower protective portion
A capacitor body of a rectangular parallelepiped shape defined by a length, a width, and a height; And an external electrode provided at a longitudinal end of the capacitor body, respectively, the multilayer ceramic capacitor comprising:
Wherein the capacitor main body includes: a capacitor portion in which a plurality of internal electrode layers are stacked in a height direction via a dielectric layer; An upper protective portion of a dielectric body disposed above the uppermost (highest) internal electrode layer among the plurality of internal electrode layers; And a lower protective portion of a dielectric structure located below a lowest (lowest) internal electrode layer among the plurality of internal electrode layers,
The thickness of the lower protective portion is thicker than the thickness of the upper protective portion so that the capacitance portion is positioned at an upper side in the height direction of the capacitor body,
The height H and the thickness Tb satisfy a relation of Tb / H, where T is the height of the capacitor body, Tb is the thickness of the upper protective portion, and Tc is the thickness of the lower protective portion.
The thickness Tb and the thickness Tc satisfy Tc / Tb
Multilayer ceramic capacitors meeting the requirements of 4.6.
Wherein a composition of the upper protective part and a composition of the lower protective part are the same as those of the dielectric layer.
The composition of the upper protective portion and the composition of the upper portion (upper portion) of the lower protective portion are the same as the composition of the dielectric layer,
Wherein the composition of the lower portion (lower portion) excluding the upper portion of the lower protective portion is different from the composition of the dielectric layer.
The composition of the upper protective part and the composition of the lower protective part are the same,
Wherein a composition of the upper protective part and a composition of the lower protective part are different from a composition of the dielectric layer.
The composition of the upper protective part is different from that of the lower protective part,
The composition of the upper protective part and the upper part of the lower protective part are the same,
The composition of the upper protective part and the composition of the upper part of the lower protective part are different from the composition of the dielectric layer,
Wherein the composition of the lower portion excluding the upper portion of the lower protective portion is different from the composition of the upper protective portion, the composition of the upper portion of the lower protective portion, and the composition of the dielectric layer.
KR1020140113790A 2013-08-30 2014-08-29 Multilayer ceramic capacitor KR101647772B1 (en)
JPJP-P-2013-179361 2013-08-30
JP2013179361 2013-08-30
JPJP-P-2014-153566 2014-07-29
JP2014153566A JP5897661B2 (en) 2013-08-30 2014-07-29 Multilayer ceramic capacitor
KR20150026954A KR20150026954A (en) 2015-03-11
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KR1020140113790A KR101647772B1 (en) 2013-08-30 2014-08-29 Multilayer ceramic capacitor
US (1) US20150062775A1 (en)
JP (1) JP5897661B2 (en)
KR (1) KR101647772B1 (en)
CN (1) CN104425128B (en)
TW (1) TWI541846B (en)
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