KR101574443B1 - Three terminal condenser - Google Patents

Abstract

The present invention relates to a three-terminal type condenser, capable of preventing the degradation of insulation resistance between external electrodes even if an application position of the external electrodes is dislocated. An L direction length of a second external electrode is E1. An L direction of the other second external electrode is E3. An L direction length of a first external electrode is E2. A distance between the second external electrode and the first external electrode is ME1. A distance between the first external electrode and the other second external electrode is ME2. An L direction length of the condenser device is L. A width from an end edge of a third surface of a second withdrawal part to the third surface is M1L. A width from an end edge of a fourth surface of the second withdrawal part to an end edge of the second external electrode on the first surface is M1R. A width from an end edge of a third surface of a first withdrawal part to an end edge of the third surface of the first external electrode on the first surface is M2L. A width from an end edge of a fourth surface of the first withdrawal part to an end edge of the fourth surface of the first external electrode on the first surface is M2R. E1+ME2+E2+ME2+E3>L, ¦ME1-ME2¦<50μm, M2L<M2R or M1R>M1L is satisfied.

Description

[0001] THREE TERMINAL CONDENSER [0002]

The present invention relates to a three-terminal type capacitor.

2. Description of the Related Art In recent years, along with miniaturization and high capacity of electronic products, multilayer ceramic capacitors used in electronic products have also been required to be smaller in size and higher in capacity. In addition, a small multilayer ceramic capacitor of Equivalent Series Inductance (hereinafter referred to as &quot; ESL &quot;) is required due to high frequency hydration, low voltage and low power consumption of an electronic product. As a small multilayer ceramic capacitor of ESL, Terminal type ceramic capacitors are known. This three-terminal type capacitor decreases the distance between the external electrodes to reduce the current flow path, thereby reducing the inductance of the capacitor.

Japanese Patent Application Laid-Open No. 11-144996

If the distance between the external electrodes is small, there is a problem that the IR value is lowered between the external electrodes. A certain distance is required between the external electrodes. However, if the application positions of the external electrodes are deviated, the distance between the external electrodes becomes small.

Therefore, it is an object of the present invention to provide a three-terminal type capacitor capable of preventing deterioration of insulation resistance between external electrodes because the distance between the external electrodes is constant even if the application position of the external electrode is shifted.

A three-terminal capacitor of the present invention includes a first surface and a second surface extending in the longitudinal direction and the width direction, a third surface and a fourth surface extending in the width direction and the thickness direction, A capacitor element having a fifth surface and a sixth surface extending along the first surface and the second surface, the capacitor element having one end in the longitudinal direction of the first surface, A second external electrode formed on the fourth surface, the fifth surface and the sixth surface, and a second external electrode formed on the other surface in the longitudinal direction of the first surface, A first external electrode formed on the fifth surface and the sixth surface; a second external electrode formed on the first external electrode and electrically connected to the first external electrode through the first lead portion; A second conductor layer formed on the first outer conductor and a second conductor layer formed inside the capacitor element, And a plurality of second conductor layers which are electrically connected to each other through a second lead portion and are electrically connected to each other through a second lead portion, The length in the longitudinal direction of the first external electrode is denoted by E1, the length in the longitudinal direction of the other second external electrode is denoted by E3, the length in the longitudinal direction of the first external electrode is denoted by E2, ME2 is a distance between the first external electrode and the second external electrode, Me2 is a distance between the first external electrode and the second external electrode, L is a length in the longitudinal direction of the capacitor element, The width from the edge of the edge of the second external electrode on the first surface to the edge of the edge of the second external electrode on the fourth surface side is M1R , The width from the edge of the third surface of the first lead portion to the edge of the third surface of the first external electrode on the first surface is M2L and the width of the edge of the second lead- The width from the edge of the edge to the edge of the fourth surface side of the first external electrode on the first surface is M2R and the width from the edge of the edge on the fourth surface side of the second lead- Is M3R and the width from the end edge on the third surface side of the other second lead portion to the end edge of the second external electrode on the first surface is M3L, L is 1.5% or more desirable.

ME1-ME2 | <50 占 퐉, M2L <M2R and M1R> M1L, or M2L> M2R, and M1R The three-terminal type capacitors are characterized in that &lt; M1L, M1R / L, M2L / L, M2R / L and M3L /

In the three-terminal capacitor according to the present invention, the length in the longitudinal direction of one second external electrode is denoted by E1, the length in the longitudinal direction of the other second external electrode is denoted by E3, The distance in the longitudinal direction is E2, the distance between one second external electrode and the first external electrode is ME1, the distance between the first external electrode and the second external electrode is ME2, and the length of the capacitor element And the width from the edge of the third surface to the third surface is denoted by M1L and the width from the edge of the end on the fourth surface side of one of the second lead portions is denoted by M1L. A width of the first external electrode on the first surface to the edge of the end portion is denoted by M1R and a width of the end on the third surface side of the first external electrode on the first surface from the edge of the third surface TED And a width from the edge of the fourth surface of the first lead portion to the edge of the fourth surface of the first external electrode on the first surface is M2R, ME1 + ME2 + E3 &gt; L, | ME1-ME2 | <50 mu m and M2L <M2R and M1R> M1L or M2L> And the offset of the other second external electrode are always shifted to the predetermined end face side, deterioration of the insulation resistance between the external electrodes can be prevented.

M2R / L, M2L / L, M2R / L, and M2R / L are the widths from the edge of the third surface of the other second lead portion to the edge of the second external electrode on the first surface, L and M3L / L are respectively 1.5% or more, the first lead portion, the second lead portion and the second lead portion are reliably held by the first outer electrode, the one second outer electrode, and the other second outer electrode It is possible to prevent the moisture penetrating from the edge of the outer electrode end portion and to prevent deterioration of the insulation resistance between the conductive layers.

According to the present invention, it is possible to provide a three-terminal capacitor capable of preventing deterioration of insulation resistance between external electrodes because the distance between the external electrodes is constant even if the application position of the external electrode is shifted.

BRIEF DESCRIPTION OF THE DRAWINGS The above and other objects, features and advantages of the present invention will become more apparent from the following detailed description taken in conjunction with the accompanying drawings.

1 is an external perspective view showing a first embodiment of a three-terminal type capacitor according to the present invention.
Fig. 2 is a perspective view of the capacitor element shown in Fig. 1; Fig.
3 is an exploded perspective view of the capacitor element shown in Fig.
4 is an external perspective view showing a modification of the three-terminal type capacitor according to the present invention.
5 is a perspective view of a modified example of the capacitor element shown in Fig.
6 is a schematic diagram showing a lead-out portion of the internal electrode in the mounting view of the capacitor element shown in Fig. 5;
7 is an explanatory view for explaining a first internal electrode and a first lead-out portion of the capacitor element shown in FIG. 5;
8 is an explanatory view for explaining a second internal electrode and a second lead portion of the capacitor element shown in Fig. 5;
9 is a schematic cross-sectional view of a further modified example of the three-terminal type capacitor shown in Fig.
10 is a schematic front view of a fifth surface in a further modified example of the three-terminal type capacitor according to the present invention.
11 (a) is a schematic sectional view taken along a line IV-IV in Fig. 10, and Fig. 11 (b) is a schematic sectional view taken along a line V-V in Fig.
12 is a diagrammatic view showing an interface between an outermost conductor layer and an outermost dielectric layer in which a boundary layer is formed;
13 is a schematic cross-sectional view of a three-terminal type capacitor according to the present invention.
14 is an external perspective view showing a second embodiment of a three-terminal type capacitor according to the present invention.
Fig. 15 is a perspective view of the capacitor element shown in Fig. 14; Fig.
16 is an exploded perspective view of the capacitor element shown in Fig.
17 is an external perspective view showing a modified example of the three-terminal type capacitor shown in Fig.
18 is a perspective view of a modified example of the capacitor element shown in Fig.
19 is an explanatory view for explaining the first internal electrode and the first lead-out portion of the capacitor element shown in Fig. 18;
Fig. 20 is an explanatory view for explaining the second internal electrode and the second lead portion of the capacitor element shown in Fig. 18; Fig.
Fig. 21 is a schematic cross-sectional view of a further modified example of the three-terminal type capacitor shown in Fig. 14; Fig.
22 is a flow chart showing one embodiment of a method of manufacturing a three-terminal type capacitor according to the present invention.
23 is an explanatory diagram for explaining a method of calculating the R amount of the ridge line portion;
Fig. 24A is a schematic view showing a three-terminal type capacitor for explaining a signal and noise flowing path when the three-terminal type capacitor is used as the pattern 1, Fig. 24B is a schematic view showing a three- (C) is a schematic diagram of a first conductor layer for explaining a signal and a path of noise in the case of using the three-terminal capacitor as the pattern 1, Of the second conductor layer.
FIG. 25A is a schematic view of a three-terminal capacitor for explaining a signal and a path of noise when the three-terminal capacitor is used as the pattern 2, and FIG. 25B is a schematic view of a three- (C) is a schematic diagram of a first conductor layer for explaining a signal and a path of noise in the case of using the three-terminal type capacitor as the pattern 2, Of the second conductor layer.
26 is a graph showing the frequency characteristics of the insertion loss of the pattern 1 and the pattern 2 with respect to the three-terminal type capacitor.

1. Three-terminal capacitor

(1) First Embodiment

1 is an external perspective view showing a three-terminal type capacitor 100. Fig. 2 is a perspective view of the capacitor element 102 shown in Fig. 3 is an exploded perspective view of the capacitor element 102 shown in Fig.

The three-terminal capacitor 100 includes a substantially rectangular parallelepiped capacitor element 102, first external electrodes 104 and 105 formed at the center of the surface of the capacitor element 102, And second external electrodes 106, 107, 108, and 109 formed on the substrate 110.

The capacitor element 102 has a first surface 102a and a second surface 102b opposite to the first surface 102a in the thickness T direction in the up and down direction. The capacitor element 102 has a third surface 102c and a fourth surface 102d opposite to the third surface 102c in the left and right length L directions. The capacitor element 102 has a fifth surface 102e and a sixth surface 102f opposite to the fifth surface 102e in the width direction W in the front and back directions.

For example, the three-terminal capacitor 100 preferably has a dimension in the direction of the length L of 2.00 mm or more and 2.10 mm or less, preferably a dimension in the direction of the thickness T of 0.7 mm or more and 1.0 mm or less, Mm or more and 1.40 mm or less.

The dimension in the length L direction, the dimension in the thickness T direction, and the dimension in the width W direction of the three-terminal capacitor 100 can be measured using a micrometer MDC-25MX manufactured by Mitsudo.

The first external electrode 104 is formed from the central portion in the longitudinal direction of the first surface 102a to the fifth surface 102e and the sixth surface 102f. The first external electrode 105 is formed to extend from the central portion in the longitudinal direction of the second surface 102b to the fifth surface 102e and the sixth surface 102f.

The first external electrode 104 includes a first external electrode body portion 104a electrically connected to the first lead portion 132 of the first conductor layer 120 to be described later and a second external electrode body portion 104b electrically connected to the first external electrode body portion 104a, And first folding portions 104b and 104b extending from both ends of the first folding portion 104b. The first external electrode main body portion 104a is formed on the first surface 102a and the first folding portions 104b and 104b are formed on the fifth surface 102e and the sixth surface 102f Respectively.

The first outer electrode 105 includes a first outer electrode body portion 105a electrically connected to the first lead portion 133 of the first conductor layer 120 to be described later, And first folding parts 105b and 105b extending from both ends of the first and second folding parts 105a and 105a. The first external electrode main body portion 105a is formed on the second surface 102b and the first folding portions 105b and 105b are respectively formed on the fifth surface 102e and the sixth surface 102f have.

The second external electrodes 106 and 108 are formed so as to arrange the first external electrodes 104 at both the left and right ends of the first surface 102a.

More specifically, the second external electrode 106 extends from one end in the longitudinal direction of the first surface 102a to the third surface 102c, the fifth surface 102e, and the sixth surface 102f Respectively. The second external electrode 108 is formed from the other end in the longitudinal direction of the first surface 102a to the fourth surface 102d, the fifth surface 102e, and the sixth surface 102f .

The second outer electrode 106 includes a second outer electrode body portion 106a electrically connected to the second lead portion 134 of the second conductor layer 122 to be described later, Second folding portions 106b and 106b extending from both ends of the first external electrode body portion 106a and a third folding portion 106c extending from one edge of the second external electrode body portion 106a. The second external electrode main body portion 106a is formed on the first surface 102a and the second folding portions 106b and 106b are formed on the fifth surface 102e and the sixth surface 102f And the third folding portion 106c is formed on the third surface 102c.

Similarly, the second external electrode 108 includes a second external electrode main body portion 108a electrically connected to the second lead portion 136 of the second conductor layer 122 to be described later, and a second external electrode main body portion 108b 108b extending from both ends of the second external electrode body portion 108a and a third folding portion 108c extending from the other edge of the second external electrode body portion 108a. Therefore, the second external electrode main body portion 108a is formed on the first surface 102a, and the second folding portions 108b and 108b are formed on the fifth surface 102e and the sixth surface 102f And the third folding portion 108c is formed on the fourth surface 102d.

The second external electrodes 107 and 109 are formed on the left and right ends of the second surface 102b so as to dispose the first external electrode 105 therebetween.

More specifically, the second external electrode 107 extends from one end in the longitudinal direction of the second surface 102b to the third surface 102c, the fifth surface 102e, and the sixth surface 102f Respectively. The second external electrode 109 extends from the other end in the longitudinal direction of the second surface 102b to the fourth surface 102d, the fifth surface 102e, and the sixth surface 102f Respectively.

The second external electrode 107 includes a second external electrode body portion 107a electrically connected to the second lead portion 135 of the second conductor layer 122 to be described later, Second folding portions 107b and 107b extending from both ends of the first external electrode body portion 107a and a third folding portion 107c extending from one edge of the second external electrode body portion 107a. The second external electrode main body portion 107a is formed on the second surface 102b and the second folding portions 107b and 107b are formed on the fifth surface 102e and the sixth surface 102f And the third folding portion 107c is formed on the third surface 102c.

Similarly, the second outer electrode 109 includes a second outer electrode body portion 109a electrically connected to the second lead portion 137 of the second conductor layer 122, which will be described later, Second folding portions 109b and 109b extending from both ends of the first external electrode body portion 109a and a third folding portion 109c extending from the other edge of the second external electrode body portion 109. [ Therefore, the second external electrode main body portion 109a is formed on the second surface 102b, and the second folding portions 109b and 109b are formed on the fifth surface 102e and the sixth surface 102f And the third folding portion 109c is formed on the fourth surface 102d.

Therefore, either one of the first surface 102a and the second surface 102b serves as a mounting view of the three-terminal capacitor 100. [

Here, the width B of the first external electrodes 104 and 105 is set larger than the width A of the second external electrodes 106, 107, 108, and 109. More specifically, the width B of the first external electrodes 104 and 105 is 0.63 mm or more and 0.67 mm or less. The width A of the second external electrodes 106, 107, 108, and 109 is 0.35 mm or more and 0.45 mm or less.

The widths of the first external electrodes 104 and 105 and the second external electrodes 106, 107, 108 and 109 are measured by using a three-terminal capacitor 100 at a magnification of 20 times with a measuring microscope MM- It is possible to measure by projecting the first surface 102a or the second surface 102b.

The first outer electrodes 104 and 105 are formed as a thick film by applying the outer electrode paste once. Further, the second outer electrodes 106, 107, 108, and 109 are formed as a thick film by applying the outer electrode paste twice, respectively. As a result, the electrode thickness of the second external electrodes 106, 107, 108, and 109 is larger than the electrode thickness of the first external electrodes 104 and 105.

The thicknesses of the first external electrodes 104 and 105 and the second external electrodes 106 and 107 and 108 and 109 are set such that the center of the width direction from the surface of the fifth surface 102e of the three- After exposing the end faces of the first external electrodes 104 and 105 and the second external electrodes 106, 107, 108 and 109 and removing the sagging by polishing, the first external electrodes 104 and 105, 105 and the second external electrodes 106, 107, 108, and 109, respectively.

When the electrode thickness of the second external electrodes 106, 107, 108, and 109 is formed to be larger than the electrode thickness of the first external electrodes 104 and 105, the three-terminal capacitor 100 is mounted on the mounting substrate So that they can be mounted substantially parallel to each other. As a result, the three-terminal type capacitor 100 can suppress the apparent height of the mounting substrate after mounting.

4 is an external perspective view showing a modification of the three-terminal type capacitor according to the present invention.

The width B 'of the first folding portions 104b and 105b of the first external electrodes 104 and 105 is greater than the width B' of the first external electrodes 104 and 105 104a, and 105a, respectively. Similarly, the width A 'of the second folding portions 106b, 107b, 108b, and 109b of the second external electrodes 106, 107, 108, and 109 is equal to the width A' of the second external electrodes 106, 107, 2 may be formed larger than the width A of the two external electrode body portions 106a, 107a, 108a, and 109a. That is, the width B 'of the first folding portions 104b and 105b of the first external electrodes 104 and 105 and the second folding portions 106b, 107b, and 108b of the second external electrodes 106, 107, 108, And 109b of the second external electrodes 106, 107, 108, and 109 are equal to the width B of the first external electrode body portions 104a and 105a of the first external electrodes 104 and 105, And has a shape extending in the length L direction as compared with the width A of the external electrode body portions 106a, 107a, 108a, and 109a.

The width B 'of the first folding portion 104b of the first external electrode 104 is set such that the boundary 103a and the first surface 102a where the first surface 102a and the fifth surface 102e cross each other, At the boundary portion 103b where the sixth surface 102f and the sixth surface 102f intersect. Similarly, the width A 'of the second folding portions 106b and 108b of the second external electrodes 106 and 108 is largest at the boundary portion 103a and the boundary portion 103b.

The width B 'of the first folding portion 105b of the first external electrode 105 is set so that the boundary portion 103c and the second surface 102b where the second surface 102b and the fifth surface 102e cross each other, And the sixth surface 102f cross each other at the boundary 103d. Similarly, the width A 'of the second folding portions 107b and 109b of the second external electrodes 107 and 109 is largest at the boundary portion 103c and the boundary portion 103d.

The width B 'of the first folding portions 104b and 105b of the first external electrodes 104 and 105 is equal to the width B' of the first external electrode body portions 104a and 105a of the first external electrodes 104 and 105, And the width A 'of the second folding portions 106b, 107b, 108b and 109b of the second external electrodes 106, 107, 108 and 109 is greater than the width A of the second external electrodes 106, 107 and 108 The first folding portions 104b and 105b of the first external electrodes 104 and 105 and the second folding portions 104b and 105b of the first external electrodes 104 and 105 are formed to be larger than the width A of the second external electrode body portions 106a, The amount of solder wetted to the second folding portions 106b, 107b, 108b, and 109b of the second external electrodes 106, 107, 108, and 109 can be increased compared to the conventional case. Accordingly, it is possible to reduce the area of the fillet of the solder in the land of the mounting board, while securing the fixing strength between the three-terminal capacitor 100 and the mounting board. Therefore, the area of the land pattern of the mounting board can be reduced by mounting the three-terminal capacitor 100 on the mounting board.

The second external electrode 106 formed at one end in the length L direction of the first surface 102a is connected to the second folding portions 106b and 106b of the fifth surface 102e and the sixth surface 102f, And the height of the central portion in the width W direction of the third folding portion 106c of the third surface 102c is H3, the conditional expression H2> H3.

The second external electrode 108 formed on the other end of the first face 102a in the direction of the length L has the second folding portions 108b and 108b of the fifth face 102e and the sixth face 102f And the height of the central portion in the width W direction of the third folding portion 108c of the fourth surface 102d is H3 ', the height of the center portion in the length L direction is H2' Satisfies the conditional expression H2 '> H3'.

The second external electrode 107 formed at one end in the length L direction of the second surface 102b is connected to the second folding portions 107b and 107b of the fifth surface 102e and the sixth surface 102f And the height of the central portion in the width W direction of the third folding portion 107c of the third surface 102c is H3, the condition H2 > H3.

The second external electrode 109 formed on the other end of the second face 102b in the direction of the length L is connected to the second face 102b of the second face 102b, And the height of the central portion in the width W direction of the third folding portion 109c of the fourth surface 102d is H3 ' , The conditional expression H2 '> H3' is satisfied.

As described above, since the three-terminal capacitor 100 satisfying the conditional expressions H2> H3 and the conditional expressions H2 '> H3' is used, the three-terminal condenser 100 is obtained by, for example, The amount of solder that gets wet in the second folding portions 106b and 108b of the second external electrodes 106 and 108 when mounted on the mounting substrate is larger than that of the third folding portions 106c And 108c. Therefore, the displacement of the three-terminal capacitor 100 is suppressed, and the fixing strength between the three-terminal capacitor 100 and the mounting board can be secured.

The first external electrodes 104 and 105 and the second external electrodes 106, 107, 108 and 109 include Ag, Cu, Ni, Pd or an alloy of these metals. The first external electrodes 104 and 105 and the second external electrodes 106, 107, 108, and 109 are each provided with a plating film on its surface. The plated film protects the first external electrodes 104 and 105 and the second external electrodes 106 and 107 and the first external electrodes 104 and 105 and the second external electrodes 106 and 107, 108, and 109 are improved.

The first external electrodes 104 and 105 may be the ground side electrodes and the second external electrodes 106 and 107 may be the signal side electrodes and the first external electrodes 104 and 105 may be the signal side electrodes. And the second external electrodes 106, 107, 108, and 109 may be grounded electrodes.

The capacitor element 102 includes a plurality of inner layer dielectric layers 110 in the width direction W (stacking direction), a plurality of first conductor layers 120 arranged at the interface between the plurality of inner layer dielectric layers 110, The outer conductor layers 124 and 126 are disposed so as to sandwich the outermost conductor layers 124 and 126 therebetween so as to sandwich the plurality of inner dielectric layers 110 therebetween, And a dielectric layer 112 for a dielectric layer.

The first conductor layer 120 has a first opposing portion 128 and first lead portions 132 and 133 extending from the central portion of the first opposing portion 128 in the thickness T direction. The first lead portion 132 is drawn to the central portion of the first surface 102a of the capacitor element 102 and is electrically connected to the first external electrode 104. [ The first lead portion 133 is drawn to the central portion of the second surface 102b of the capacitor element 102 and is electrically connected to the first external electrode 105. [

The second conductor layer 122 includes a second opposing portion 130 and second lead portions 134 and 135 extending from the left end of the second opposing portion 130 in the thickness T direction respectively, And second extending portions 136 and 137 extending from the right end of the two opposing portions 130 in the thickness direction T in the up and down direction, respectively. The second lead portion 134 is drawn to the left end of the first surface 102a of the capacitor element 102 and is electrically connected to the second external electrode 106. [ The second lead portion 135 is drawn to the left end of the second surface 102b of the capacitor element 102 and electrically connected to the second external electrode 107. [ The second lead portion 136 is drawn to the right end of the first surface 102a of the capacitor element 102 and is electrically connected to the second external electrode 108. [ The second lead portion 137 is drawn to the right end of the second surface 102b of the capacitor element 102 and is electrically connected to the second external electrode 109. [

Here, FIG. 5 is a perspective view of a modified example of the capacitor element shown in FIG. Fig. 6 is a schematic diagram showing the lead-out portion of the internal electrode in the mounting view of the capacitor element shown in Fig. 5; 7 is an explanatory view for explaining the first internal electrode and the first lead-out portion of the capacitor element shown in Fig. 8 is an explanatory view for explaining the second internal electrode and the second lead portion of the capacitor element shown in Fig.

(I) of Fig. 7 is a cross-sectional view of the first conductor layer 120 at the position of I-I in Fig. 5 (perspective view) and Fig. 6 (front view) (132, 133). (II) of FIG. 7 shows the positions of the positions (II-II) of FIG. 5 and FIG. 6 (the position of the layer disposed at 1/4 of the width W from the outermost layer of the capacitor element 102 The first conductor layer 120 and the first lead portions 132 and 133 of the first conductor layer 120 are shown. 7 (III) shows the position in the vicinity of the position (hereinafter referred to as the center layer) disposed at 1/2 of the width W from the outermost layer of the capacitor element 102 at positions III-III in Figs. 5 and 6 The first conductor layer 120 and the first lead portions 132 and 133 of the first conductor layer 120 are shown.

The width E of the tips of the first lead portions 132 and 133 of the first conductor layer 120 disposed in the vicinity of the central layer of the capacitor element 102 is smaller than the width E of the first lead portions 132 and 133 located near the outermost layer of the capacitor element 102 1 of the conductor layers 120 are set to be larger than the width F of the tips of the first lead portions 132 and 133 of the first conductor layer 120. [ Then, the widths of the tips of the first lead portions 132, 133 gradually increase from the position near the outermost layer toward the position near the center layer.

(I) of Fig. 8 shows the second conductor layer 122 and the second lead portions 134, 135, 136, and 137 at positions I-I of Figs. 5 and 6. FIG. 8 (II) shows the second conductor layer 122 and the second lead portions 134, 135, 136, and 137 at positions II-II in FIGS. FIG. 8 (III) shows the second conductor layer 122 and the second lead portions 134, 135, 136, and 137 in the positions of III-III in FIG. 5 and FIG.

The width G of the tips of the second lead portions 134, 135, 136, and 137 of the second conductor layer 122 disposed in the vicinity of the center layer of the capacitor element 102 is smaller than the width G of the outermost layer of the capacitor element 102 135, 136, 137 of the second conductor layer 122 disposed in the second conductor layer 122. The width H of the tip of the second lead portion 134, 135, 136, Then, the width of the tips of the second lead portions 134, 135, 136, and 137 gradually increases from the position near the outermost layer toward the position near the center layer.

6, the tip ends of the second lead portions 134 and 135 of the second conductor layer 122 disposed in the vicinity of the center layer of the capacitor element 102 are connected to the ends of the capacitor element 2 And a distance C from the third surface (end surface) 102c. Similarly, the tip ends of the second lead portions 136 and 137 of the second conductor layer 122 disposed in the vicinity of the center layer of the capacitor element 102 are also connected to the fourth surface (end surface) of the capacitor element 102 102d. &Lt; / RTI &gt; The tips of the second lead portions 134 and 135 of the second conductor layer 122 disposed in the vicinity of the outermost layer of the capacitor element 102 are spaced apart from the third surface 102c of the capacitor element 102 D. The distal ends of the second lead portions 136 and 137 of the second conductor layer 122 disposed near the outermost layer of the capacitor element 2 are also spaced from the fourth surface 102d of the capacitor element 102 D. Then, the distance D is set larger than the distance C.

Here, the second lead portions 134, 135, 136, and 137 of the second conductor layer 122 disposed in the vicinity of the outermost layer of the capacitor element 102 are connected to the inclined portion 122, (129), and the position of the leading end is the center. By increasing the inclination angle of the inclined portion 129 of the second lead portions 134, 135, 136, and 137 from the position near the outermost layer toward the position near the center layer, the position of the tip becomes gradually outward have.

Table 1 shows the results of the calculation of the thicknesses of the second lead portions 134 and 135 (the second lead portion) in the position of I-I (position near the outermost layer), the position of II-II and the position of III- The distance between the tip of the second lead portion 134 (135, 136, 137) and the third surface 102c (fourth surface 102d) of the capacitor element 102, And the width of the leading end of the first lead portions 132 and 133. In the example shown in Fig. In Table 1,? Represents the distance between the tip of the second lead portions 134 and 135 (the second lead portions 136 and 137) near the center layer and the third surface 102c of the capacitor element 102 4 (102d)).

Thus, when the distance D is set to be larger than the distance C, the three-terminal type capacitor 100 in which a crack is less likely to occur in the vicinity of the outermost layer of the capacitor element 102 can be obtained.

The width G of the tips of the second lead portions 134, 135, 136, and 137 of the second conductor layer 122 disposed in the vicinity of the center layer of the capacitor element 102 is smaller than the width G of the capacitor element 102 In the vicinity of the outermost layer of the capacitor element 102 is set larger than the width H of the tips of the second lead portions 134, 135, 136 and 137 of the second conductor layer 122 disposed in the vicinity of the outer layer, Cracks are more difficult to occur.

The width E of the tips of the first lead portions 132 and 133 of the first conductor layer 120 disposed in the vicinity of the center layer of the capacitor element 102 is set near the outermost layer of the capacitor element 102 The width of the first external electrodes 104, 104 near the central layer of the capacitor element 102 is set to be larger than the width F of the ends of the first lead portions 132, 133 of the first conductor layer 120, 105 and the second external electrodes 106, 107, 108, and 109 are shortened so that the distance between the first external electrodes 104 and 105 in the vicinity of the outermost layer of the capacitor element 102, The electric distance between the electrodes 106, 107, 108, and 109 becomes approximately equal. As a result, the equivalent series inductance (ESL) is equalized and the equivalent series inductance (ESL) is reduced.

9 is a schematic cross-sectional view of a further modified example of the three-terminal type capacitor shown in Fig.

9A, the first withdrawing portion 132 is formed so that the first opposing portion 128 side is in the two directions of the second withdrawing portion 134 side and the second withdrawing portion 136 side Side inclined portion 170a inclined and the first surface 102a side may have a straight portion 170b. The first withdrawing portion 133 has both side inclining portions 171a which are inclined in two directions on the side of the second withdrawing portion 135 and the side of the second withdrawing portion 137 on the side of the first opposing portion 128 And the second surface 102b side may have a straight portion 171b.

9 (b), the second lead portion 134 has a one-side inclined portion 172a which is inclined in one direction on the first lead portion 132 side on the side of the second opposing portion 130, And the side of the first surface 102a has a straight portion 172b. The second lead portion 135 has a one side inclined portion 173a that is inclined in one direction on the first lead portion 133 side and a second side face 102b side is a straight portion 173b. The second lead portion 136 has a one side inclined portion 174a whose side of the second opposing portion 130 is inclined in one direction on the first lead portion 132 side and the side of the first face 102a is a straight portion 174b. The second lead portion 137 has a one side inclined portion 175a that is inclined in one direction on the first lead portion 133 side and a second side face 102b side is a straight portion 175b.

The first opposing portion 128 side and the second opposing portion 130 side of the first lead portions 132 and 133 and the second lead portions 134, 135, 136, and 137 are connected to the other lead portion side The electrical distance between the first external electrodes 104 and 105 and the second external electrodes 106, 107, 108 and 109 (for example, the distance between the first external electrodes 104 and 105) The distance between the first lead portion 132 and the first conductor layer 120 to the dielectric layer 110 to the second conductor layer 122 to the second lead portion 136 to the second outer electrode 108, . Therefore, the equivalent series inductance (ESL) can be lowered.

Since the first lead portions 132 and 133 and the second lead portions 134 and 135 and 136 and 137 have the linear portions 170b and 175b, when the outer shape is cut, the cut position is shifted in the thickness T direction The widths of the tips of the first lead portions 132, 133 and the second lead portions 134, 135, 136, 137 do not change and do not expand. Therefore, the tips of the first lead portions 132 and 133 and the second lead portions 134, 135, 136, and 137 are connected to the first outer electrodes 132 and 133 and the second outer electrodes 134, 135, 136, 137 are not connected to the thinner portion of the electrode thickness. As a result, in the portion where the first external electrodes 132 and 133 are formed and the second external electrodes 134, 135, 136, and 137 are formed, moisture is less likely to penetrate into the three-terminal capacitor 100, The sealing property can be ensured.

The first conductor layer 120 and the second conductor layer 122 are opposed to each other via the inner layer dielectric layer 110 including a dielectric material in the width direction. A portion of the first conductor layer 120 and the second conductor layer 122 opposed to each other via the inner layer dielectric layer 110 (the first opposing portion 128 of the first conductor layer 120 and the second conductor (The portion where the second opposing portion 130 of the body layer 122 faces). The first conductor layer 120 and the second conductor layer 122 include Ag, Cu, Ni, Pd or an alloy of these metals. The inner layer dielectric layer 110 and the outer layer dielectric layer 112 include a barium titanate-based material, a strontium titanate-based material, and the like. The first conductor layer 120 and the second conductor layer 122 have an average thickness of 1.0 mm or less. In order to ensure electrical conduction, the first conductor layer 120 and the second conductor layer 122 have an average thickness of 0.3 mm or more.

10 is a schematic front view of a fifth surface in a further modified example of the three-terminal type capacitor according to the present invention. 11 (a) is a schematic cross-sectional view taken along line IV-IV of Fig. 10, and Fig. 11 (b) is a schematic cross-sectional view taken along line V-V of Fig. 12 is a diagram showing the interface between the outer layer dielectric layer and the outermost conductor layer in which the boundary layer is formed.

The thickness of the outermost conductor layers 124 and 126 is smaller than the thickness of the first conductor layer 120 or the second conductor layer 122 located near the center with respect to the width W direction. The thickness of the outermost conductor layers 124 and 126 is 0.8 mm or less at the central portion. In addition, in order to ensure electrical conduction, the thickness of the outermost conductor layers 124 and 126 is 0.3 mm or more on average.

The coverage of the outermost conductor layers 124 and 126 tends to become gradually thinner toward the both side surfaces from the center in the width W direction. The coverage is defined by the sum of the lengths of the conductor particle cross-sections / the total length of the conductor layer cross-section, and the side (LT plane) surrounded by the length L direction and the thickness T direction of the three- And then polishing is carried out.

Preferably, the coverage of the outermost conductor layers 124, 126 is not less than 0.4 and not more than 0.85 of the first conductor layer 120 or the second conductor layer 122 in the vicinity of the center in the thickness T direction. That is, the conductor particles are intermittently gathered in this way and the coverage is lowered, so that the defective portion 126a is formed as shown in Fig. If the coverage is less than 0.4 of the first conductor layer 120 or the second conductor layer 122 in the vicinity of the center in the thickness T direction, it is difficult to secure electrical continuity. If it is larger than 0.85, the interlayer adhesion can not be sufficiently improved.

A column connecting the dielectric layers 110 with the outermost conductor layers 124 and 126 interposed therebetween is formed in the defective portion 126a. The column is composed of Si segregated Al segregation, BaTiO ₃ (barium titanate) At least one of them is included. These segregations can be observed by FE-WDX analysis.

In addition, SiO ₂ is preferably added to the inner-layer dielectric layer 110 in order to promote the formation of the column to which the inner-layer dielectric layers 110 are bonded. The inner layer dielectric layer 110 is preferably 1.3 mol% or more of Si relative to Ti, and is preferably 3.0 mol% or less in order to secure the function as a capacitor. It is preferable to add Al to the dielectric layer in order to promote the formation of the column connecting the dielectric layers. It is also preferable to add BaTiO ₃ (barium titanate) as a conductive material to the conductor layer in order to promote the formation of the column connecting the dielectric layers.

The outermost conductor layer 124 is connected to the first external electrodes 104 and 105 which are common to the adjacent first conductor layers 120 via the internal dielectric layer 110. [ The outermost conductor layer 126 is connected to the second outer electrodes 106, 107, 108, and 109 which are common to the adjacent second conductor layers 122 via the inner layer dielectric layer 110.

The boundary layer 127 adjacent to the outermost conductor layers 124 and 126 of the outermost dielectric layer includes a coexistence region of Mg-Mn-Ni formed by segregation of Mg and Mn.

Preferably, the boundary layer 127 exists in 69% or more of the boundary between the outer-layer dielectric layer 112 and the outermost conductor layers 124 and 126. (%) Of the boundary layer = (sum of the lengths of the boundary layers in which Mg and Mn exist) / (length of the conductor layer) x 100. In the expression, &quot; the length of the conductor layer &quot; is the length except for the portion where the conductor layer is missing in the void or Si segregation.

The (Mg, Mn) / Ni molar ratio of the Mg-Mn-Ni coexistence region is preferably 0.1 to 0.8, and the area ratio is preferably 30% or more, more preferably 70% or more.

When the thickness of the outermost conductor layers 124 and 126 is smaller than the thickness of the first conductor layer 120 or the second conductor layer 122 as described above, The interlaminar adhesion between the stacked dielectric layers is improved. As a result, occurrence of cracks can be prevented, and deterioration of the capacitor function can be suppressed.

When the coverage of the outermost conductor layers 124 and 126 is 0.4 or more and 0.85 or less of the conductor layer coverage near the center in the thickness T direction, As shown, a defective portion 126a is formed. Columns are formed by the dielectric layer such as barium titanate or silica on the defected portion 126a and are stacked adjacent to both sides of the outermost conductor layers 124 and 126 between the particles of the outermost conductor layers 124 and 126 The dielectric layers are easily connected, and the interlaminar adhesion is improved. As a result, generation of cracks can be prevented, and deterioration of the capacitor function can be suppressed.

The outermost conductor layer 124 is connected to the first external electrodes 104 and 105 which are common to the adjacent first conductor layers 120 via the internal dielectric layer 110. [ When the outermost conductor layer 126 is connected to the second outer electrodes 106, 107, 108, and 109 which are common to the adjacent second conductor layers 122 via the inner layer dielectric layer 110, The conductor layers 124 and 126 do not contribute substantially to the development of capacitance. Therefore, even if a crack occurs in the vicinity of the outermost conductor layers 124 and 126, deterioration of the capacitor function can be prevented.

12, in the boundary layer 127 adjacent to the outermost conductor layers 124 and 126 of the outer-layer dielectric layer 112, a coexistence region of Mg-Mn-Ni formed by segregation of Mg and Mn , The boundary layer 127 containing an oxide compound of Mg, Mn and Ni is excellent in bonding strength with the dielectric layer. As a result, occurrence of cracks can be prevented, and deterioration of the capacitor function can be suppressed. Further, the detection of the boundary layer is performed by observing the cross section including the boundary layer with the FE-WDX.

13 is a schematic cross-sectional view of a three-terminal type capacitor according to the present invention. The first external electrode 105 and the second external electrodes 107 and 109 formed on the second surface 102b side are the same as the first surface 102a and therefore will not be described.

The length of the second external electrode 106 in the length L direction is E1, the length of the first external electrode 104 in the length L direction is E2, the length of the second external electrode 106 in the length L direction of the second external electrode 108 The length is called E3. The distance between the second external electrode 106 and the first external electrode 104 is ME1 and the distance between the first external electrode 104 and the second external electrode 108 is ME2. The width from the edge of the end portion on the third surface 102c side of the second lead portion 134 to the third surface 102c is M1L and the width on the fourth surface 102d side of the second lead portion 134 The width from the edge of the edge of the second external electrode 106 to the edge of the edge of the second external electrode 106 on the first surface 102a is referred to as M1R. The width from the end edge on the third surface 102c side of the first lead portion 132 to the end edge on the third surface 102c side of the first external electrode 104 on the first surface 102a Is defined as M2L and the distance from the edge of the first face 102d side of the first lead portion 132 to the side of the fourth face 102d of the first external electrode 104 on the first face 102a The width up to the edge of the edge is referred to as M2R. The width from the end edge of the second lead portion 136 on the third surface 102c side to the edge of the second external electrode 108 on the first surface 102a is M3L and the width of the second lead- The width from the edge of the end portion on the fourth surface 102d side of the portion 136 to the fourth surface 102d is M3R. Although the dimensions of the first external electrode, the second external electrode and the third external electrode may vary in the thickness direction, the dimensions of E1, E2, E3, ME1, ME2, M1L, M1R, M2L, M2R, M3L and M3R Dimensions of each dimension shall be performed on the same cross section.

In this case, the three-terminal capacitor 100 has a dimension (hereinafter, referred to as an L-length) in the length L direction of the capacitor element E1 + ME1 + E2 + ME2 + E3, and the second external electrode 106 is a third The third folding portion 106c is formed on the fourth surface 102c and the third folding portion 108c is formed on the fourth surface 102d of the second outer electrode 108 to satisfy | ME1-ME2 | And M2L &lt; M2R, and M1R &gt; M1L, or M2L &gt; M2R, and M1R &lt; M1L.

The length of M1R / L, the length of M2L / L, the length of M2R / L, and the length of M3L / L are preferably 1.5% or more.

The dimensions of each of E1, E2, E3, ME1, ME2, M1L, M1R, M2L, M2R, M3L and M3R are measured as follows. First, the three-terminal condenser 100 is hardened in such a manner that the side (LT surface) surrounded by the length L direction and the thickness T direction of the three-terminal capacitor 100 is exposed. Then, the three-terminal condenser 100 is polished to a depth of 1/2 along the width W direction by a polishing machine to expose the first conductor layer 120 and the second conductor layer 122. The polished surface is processed so as to eliminate the sagging of the first conductor layer 120 and the second conductor layer 122 by polishing and the cross section of the polished surface is measured using an optical microscope And the respective dimensions can be measured by observing from the side of the surface 102e.

In the three-terminal type capacitor 100 having the above configuration, the first conductor layer 120 and the second conductor layer 122 are formed on the first surface 102a or the second surface 102b of the three-terminal capacitor 100 (In other words, a mounting surface), and the lamination direction is parallel to the first surface 102a or the second surface 102b (in other words, the mounting surface).

(2) Second Embodiment

14 is an external perspective view showing a three-terminal type capacitor 200 which is a multilayer ceramic electronic part. 15 is a perspective view of the capacitor element 202 shown in Fig. 16 is an exploded perspective view of the capacitor element 202 shown in Fig.

The three-terminal type capacitor 200 is a three-terminal type capacitor 100 according to the first embodiment in which the first lead portion 133 of the first conductor layer 120 and the second lead portion 133 of the second conductor layer 122 The lead portions 135 and 137 are omitted. Therefore, the three-terminal type capacitor 200 is the same as the three-terminal type capacitor 100 in which the first external electrode 105 and the second external electrodes 107 and 109 are omitted.

The three-terminal type capacitor 200 includes a substantially rectangular parallelepiped capacitor element 202, a first external electrode 204 formed at the center of the surface of the capacitor element 202, and a second external electrode 204 formed at the left and right ends of the surface of the capacitor element 202. [ And second external electrodes 206 and 208 are provided.

The capacitor element 202 has a first surface 202a and a second surface 202b facing the first surface 202a in the thickness T direction in the up and down direction. The capacitor element 202 also has a third surface 202c and a fourth surface 202d facing the third surface 202c in the left and right direction L directions. The capacitor element 202 has a fifth surface 202e and a sixth surface 202f opposite to the fifth surface 202e in the width direction W of the front and back.

For example, the three-terminal capacitor 200 preferably has a dimension in the length L direction of 2.00 mm or more and 2.10 mm or less, preferably a dimension in the thickness T direction of 0.7 mm or more and 1.0 mm or less, and a dimension in the width W direction of 1.20 Mm or more and 1.40 mm or less.

The dimension in the length L direction, the dimension in the thickness T direction, and the dimension in the width W direction of the three-terminal capacitor 200 can be measured using a micrometer MDC-25MX manufactured by Mitsudo.

The first external electrode 204 is formed over the central portion in the longitudinal direction of the first surface 202a and the fifth surface 202e and the sixth surface 202f.

The first external electrode 204 includes a first external electrode main body portion 204a electrically connected to the first lead portion 232 of the first conductor layer 220 to be described later, And first folding parts 204b and 204b extending from both ends of the first folding part 204b. The first external electrode main body portion 204a is formed on the first surface 202a and the first folding portions 204b and 204b are formed on the fifth surface 202e and the sixth surface 202f As shown in Fig.

The second external electrodes 206 and 208 are formed on both the left and right ends of the first surface 202a so as to dispose the first external electrode 204 therebetween.

More specifically, the second external electrode 206 extends from one end in the longitudinal direction of the first surface 202a to the third surface 202c, the fifth surface 202e, and the sixth surface 202f Respectively. The second external electrode 208 is formed from the other end in the longitudinal direction of the first surface 202a to the fourth surface 202d, the fifth surface 202e, and the sixth surface 202f .

The second external electrode 206 includes a second external electrode body portion 206a electrically connected to the second lead portion 234 of the second conductor layer 222 to be described later, Second folding portions 206b and 206b extending from both ends of the second external electrode body portion 206a and a third folding portion 206c extending from one edge of the second external electrode body portion 206a. The second external electrode main body portion 206a is formed on the first surface 202a and the second folding portions 206b and 206b are formed on the fifth surface 202e and the sixth surface 202f, The third folding portion 206c is formed on the third surface 202c.

Similarly, the second outer electrode 208 includes a second outer electrode body portion 208a electrically connected to the second lead portion 236 of the second conductor layer 222, which will be described later, and a second outer electrode body portion 208a, Second folding portions 208b and 208b extending from both ends of the second external electrode body portion 208a and a third folding portion 208c extending from the other edge of the second external electrode body portion 208a. The second external electrode main body portion 208a is formed on the first surface 202a and the second folding portions 208b and 208b are formed on the fifth surface 202e and the sixth surface 202f, The third folding portion 208c is formed on the fourth surface 202d.

Therefore, the first surface 202a becomes the mounting view of the three-terminal type capacitor 200. [

Here, the width B of the first external electrode 204 is set larger than the width A of the second external electrodes 206 and 208.

The first external electrode 204 is formed by applying an external electrode paste once. The second external electrodes 206 and 208 are each formed by applying an external electrode paste twice. As a result, the electrode thickness of the second external electrodes 206 and 208 is larger than the electrode thickness of the first external electrode 204.

The first outer electrode 204 and the second outer electrodes 206 and 208 are each provided with a plating film on its surface.

Here, Fig. 17 is an external perspective view showing a modified example of the three-terminal type capacitor shown in Fig.

The second surface 202b, which is the upper surface of the three-terminal capacitor 200 shown in Fig. 17, is formed such that the corners of the ridgelines 203a and 203b in the length L direction are polished in an R- . More preferably, the amount of R may be 30 占 퐉 or more and 70 占 퐉 or less.

When the amount of R of the ridge portions 203a and 203b in the length L direction of the upper surface (second surface 202b) of the three-terminal capacitor 200 is 70 mu m or less in this manner, the adsorption necessary for adsorption by the adsorption nozzle The area is surely ensured on the upper surface (second surface 202b). As a result, it is easy for the suction nozzle to adsorb the upper surface (second surface 202b) of the three-terminal type condenser 200 when mounted on a mounting substrate, and the suction mistake caused by the suction nozzle can be reduced.

When the amount of R of the ridge portions 203a and 203b in the length direction L of the upper surface (second surface 202b) of the three-terminal capacitor 200 is 30 占 퐉 or more, the ridge portions 203a and 203b are squared Therefore, even if the mechanical impact is applied to the ridgelines 203a and 203b, it is possible to prevent the ridgelines 203a and 203b from being dislocated.

The capacitor element 202 has a plurality of inner layer dielectric layers 210 and a plurality of first conductor layers 220 disposed at an interface between the plurality of innerlayer dielectric layers 210 in the width W direction The second conductor layer 222 and the outermost conductor layers 224 and 226 are disposed back and forth so that a plurality of inner layer dielectric layers 210 are sandwiched therebetween and the outermost conductor layers 224 and 226 And a dielectric layer 212 for outer layer.

The first conductor layer 220 has a first opposing portion 228 and a first lead portion 232 extending downward in the thickness T direction from a central portion of the first opposing portion 228. The first lead portion 232 is drawn to the central portion of the first surface 102a of the capacitor element 202 and is electrically connected to the first external electrode 204. [

The second conductor layer 222 includes a second opposing portion 230 and a second lead portion 234 extending downward in the thickness T direction from the left end of the second opposing portion 230, And a second lead portion 236 extending downward in the thickness T direction from the right end portion of the second lead portion 230. [ The second lead portion 234 is drawn to the left end of the first surface 202a of the capacitor element 202 and is electrically connected to the second external electrode 206. [ The second lead portion 236 is drawn to the right end of the first surface 202a of the capacitor element 202 and is electrically connected to the second external electrode 208. [

Here, Fig. 18 is a perspective view of a modified example of the capacitor element shown in Fig. 19 is an explanatory view for explaining the first internal electrode and the first lead-out portion of the capacitor element shown in Fig. 18; 20 is an explanatory view for explaining the second internal electrode and the second lead portion of the capacitor element shown in Fig.

(I) in Fig. 19 shows the first conductor layer 220 and the first lead portion 232 at the position of I-I in Fig. 18 (near the outermost layer of the capacitor element 202). 19 (II) shows the first conductor layer 220 and the first lead portion 232 at the positions II-II in Fig. 18 (near the 1/4 layer of the capacitor element 202). Fig. 19 (III) shows the first conductor layer 220 and the first lead portion 232 at the position of III-III in Fig. 18 (near the center layer of the capacitor element 202).

The width E of the tip end of the first lead portion 232 of the first conductor layer 220 disposed in the vicinity of the center layer of the capacitor element 202 is smaller than the width E of the first lead portion 232 of the first conductor layer 220 located near the outermost layer of the capacitor element 202 Is set larger than the width F of the tip end of the first lead portion 232 of the conductor layer 220. [ Then, the width of the tip of the first lead portion 232 gradually increases from the position near the outermost layer toward the position near the center layer.

Fig. 20 (I) shows the second conductor layer 222 and the second lead portions 234 and 236 at positions I-I in Fig. (II) of FIG. 20 shows the second conductor layer 222 and the second lead portions 234 and 236 at positions II-II in FIG. Fig. 20 (III) shows the second conductor layer 222 and the second lead portions 234 and 236 at positions III-III in Fig.

The width A of the tips of the second lead portions 234 and 236 of the second conductor layer 222 disposed in the vicinity of the central layer of the capacitor element 202 is disposed in the vicinity of the outermost layer of the capacitor element 202 Is set to be larger than the width B of the tip ends of the second lead portions 234 and 236 of the second conductor layer 222. Then, the widths of the tips of the second lead portions 234 and 236 gradually increase from the position near the outermost layer toward the position near the center layer.

Fig. 6 of the first embodiment described above will be usefully described. The tip end of the second lead portion 234 of the second conductor layer 222 disposed in the vicinity of the central layer of the capacitor element 202 is spaced from the third surface (end surface) 202c of the capacitor element 202 C. Similarly, the tip of the second lead portion 236 of the second conductor layer 222 disposed in the vicinity of the center layer of the capacitor element 202 is also connected to the fourth surface (end surface) 202d of the capacitor element 202, As shown in Fig. The tip end of the second lead portion 234 of the second conductor layer 222 disposed near the outermost layer of the capacitor element 2 has a distance D from the third surface 202c of the capacitor element 202 I have. The tip end of the second lead portion 236 of the second conductor layer 222 disposed near the outermost layer of the capacitor element 202 also has a distance D from the fourth surface 202d of the capacitor element 202 I have. Then, the distance D is set larger than the distance C.

The second lead portions 234 and 236 of the second conductor layer 222 disposed in the vicinity of the outermost layer of the capacitor element 202 have inclined portions 229 in order to make the distance D larger than the distance C. And the tip is located at the center. By increasing the inclination angle of the inclined portion 229 of the second lead portions 234 and 236 toward the position near the center layer from the position near the outermost layer, the position of the tip becomes gradually outward.

21 is a schematic cross-sectional view of still another modified example of the three-terminal type capacitor shown in Fig.

21 (a), the first withdrawing portion 232 is formed so that the first opposing portion 228 side is located in two directions on the second withdrawing portion 234 side and the second withdrawing portion 236 side Side inclined portion 270a inclined to the first surface 202a and the linear portion 270b on the first surface 202a side.

21 (b), the second lead portion 234 has a one-side inclined portion 272a on the side of the second opposing portion 230 which is inclined in one direction on the first lead portion 232 side, And the first surface 202a side may have a straight portion 272b. The second lead portion 236 has a one side inclined portion 274a which is inclined in one direction on the side of the first lead portion 232 side on the side of the second opposing portion 230 and the side of the first face 202a is a straight portion 274b.

The first conductor layer 220 and the second conductor layer 222 are opposed to each other via the inner layer dielectric layer 210 including the dielectric material in the width W direction. The first conductor layer 220 and the second conductor layer 222 are formed on the portion of the first conductor layer 220 opposed to the first conductor layer 220 via the inner layer dielectric layer 210 The portion where the second opposing portion 230 of the conductor layer 222 is opposed) is formed.

The thickness of the outermost conductor layers 224 and 226 is smaller than the thickness of the first conductor layer 220 or the second conductor layer 222 located near the center with respect to the width W direction. The thickness of the outermost conductor layers 224 and 226 is 0.8 mm or less in the central portion. In order to ensure electrical conduction, the thickness of the outermost conductor layers 224 and 226 is 0.3 mm or more on average.

The coverage of the outermost conductor layers 224 and 226 tends to become gradually thinner toward the both side surfaces from the center in the width direction. The coverage is also defined by the sum of the lengths of the conductor particle cross-sections / the total length of the conductor layer cross-sections.

Preferably, the coverage of the outermost conductor layers 224, 226 is less than or equal to 0.4 and less than or equal to 0.85 of the first conductor layer 220 or the second conductor layer 222 in the vicinity of the center in the thickness T direction. The column connecting the dielectric layers 210 with the outermost conductor layers 224 and 226 therebetween includes at least one of Si segregation, Al segregation, and BaTiO ₃ (barium titanate).

The outermost conductor layer 224 is connected to the first external electrode 204 common to the adjacent first conductor layers 220 via the dielectric layer 210. The outermost conductor layer 226 is connected to the second external electrodes 206 and 208 common to the adjacent second conductor layers 222 via the dielectric layer 210.

As shown in Fig. 12, the boundary layer 227 adjacent to the outermost conductor layers 224 and 226 of the outermost dielectric layer includes a coexistence region of Mg-Mn-Ni formed by segregation of Mg and Mn .

In the three-terminal capacitor 200 having the above configuration, the first conductor layer 220 and the second conductor layer 222 are formed on the first surface 202a of the three-terminal capacitor 200 (in other words, , And the stacking direction is parallel to the first surface 202a (in other words, the mounting surface).

2. Manufacturing method of 3-terminal type capacitor

Next, a method of manufacturing the three-terminal type capacitors 100 and 200 will be described. 22 is a flowchart showing a manufacturing method of the three-terminal type capacitors 100 and 200. As shown in Fig. In the following description, the method of manufacturing the three-terminal type capacitor 100 will be mainly described.

In step S1, an organic binder, a dispersant, a plasticizer and the like are added to a ceramic powder containing a barium titanate-based material or a strontium titanate-based material to prepare a slurry for sheet molding. Subsequently, the slurry for forming a sheet is formed into a ceramic green sheet for inner layer or outer layer by a doctor blade method.

Subsequently, in Step S2, a conductor layer paste containing Ag is applied on the ceramic green sheet for inner layer by a screen printing method, and a conductive paste film to be a first conductor layer 120 and a second conductor layer 122 is formed do.

Subsequently, in step S3, a plurality of the ceramic green sheets for inner layer in which the conductive paste film is formed are stacked such that the conductive paste film of the first conductor layer 120 and the conductive paste film of the second conductor layer 122 are staggered. Further, a plurality of outer ceramic green sheets are laminated and laminated so as to sandwich the laminated inner ceramic green sheets. This multilayer ceramic green sheet is cut to a size that is required to be the individual capacitor elements 102, and a plurality of unfired capacitor elements 102 are formed.

Here, if necessary, the unfired capacitor element 202 may be connected to the ridge line portion in the length L direction of the upper surface (second surface 202b) in the state in which the mounting surface (first surface 202a) (203a, 203b) are barrel polished for a predetermined time, and the amount of R of the ridgelines 203a, 203b is about 70 占 퐉. Thereafter, it is polished by sandblasting for a predetermined time until the desired amount of R is obtained.

Here, in order to determine the polishing conditions of the barrel polishing and the sandblasting, a sample of the capacitor element 202 is prepared, and the R amount is measured by the following method. The measuring instrument is the KEYENCE digital microscope VHX series.

The sample of the capacitor element 202 is hardened on the side of the mounting surface (first surface 202a) with resin. Thereafter, the ridgelines 203a and 203b in the length direction L of the upper surface (second surface 202b) are subjected to barrel polishing or sandblasting for a predetermined time.

23A, R-polished ridgelines 203a and 203b are observed with a measuring instrument, and a time point P1 and an end point P2 of R are designated. Then, a central point P3 between the time point P1 and the end point P2 is designated.

23 (b), after the circle Q passing through the viewpoint P1, the center point P3, and the end point P2 is drawn, the radius of the circle Q is measured and the amount of R is calculated.

Subsequently, in step S4, the unbaked capacitor element 102 is subjected to binder removal treatment and then fired to be a sintered capacitor element 102. [ The ceramic green sheets for inner layer and outer layer and the conductive paste film are co-fired so that the inner layer ceramic green sheet becomes the inner layer dielectric layer 110, the outer layer ceramic green sheet becomes the outer layer dielectric layer 112, 1 internal electrode 120 or second internal electrode 122. [

Subsequently, in step S5, the first external electrode paste (AgPd alloy paste) is applied to the surface of the sintered capacitor element 102. [ The first external electrode paste is applied by applying the external electrode paste of the first external electrodes 104 and 105 and the first external electrode paste of the second external electrodes 106, Lt; / RTI &gt;

When the first external electrode paste 500 of the second external electrodes 106, 107, 108, and 109 is applied to the capacitor element 102, the second external electrodes 106, 107, 108, And the center positions of the external electrode paste are spaced apart from the third surface 102c and the fourth surface 102d of the capacitor element 102, respectively, in the inward direction. By applying the external electrode paste of the second external electrodes 106, 107, 108, and 109 in this way, the second external electrodes 106, 107, 108, and 109 can satisfy the conditional expressions H2> H3 and the conditional expressions H2 ' Can be formed.

The first external electrode paste applying step is a step of applying the external electrode paste of the first external electrodes 104 and 105 and the first external electrode paste of the second external electrodes 106, For application, external electrodes are formed efficiently.

Subsequently, in step S6, the outer electrode paste of the first outer electrodes 104 and 105 applied to the capacitor element 102 and the first outer electrode paste of the second outer electrodes 106, 107, 108, and 109 are baked do. Thereby, the first external electrode portions of the first external electrodes 104 and 105 and the second external electrodes 106, 107, 108, and 109 are formed. At this time, the electrode thickness of the first outer electrodes 104 and 105 is thick and the electrode thickness of the second outer electrodes 106, 107, 108, and 109 is thin.

Step S6 may be omitted and the process may proceed directly from step S5 to step S7 and the first external electrodes 104 and 105 and the second external electrodes 106, 107, 108, and 109 may be integrally baked in step S8 .

Subsequently, in step S7, the second external electrode paste (AgPd alloy paste) is applied to the surface of the capacitor element 102. [ The application of the second external electrode paste only applies the second external electrode paste of the second external electrodes 106, 107, 108, and 109.

When the second external electrode paste 500 of the second external electrodes 106, 107, 108, and 109 is applied to the capacitor element 102, the second external electrodes 106, 107, 108, The center positions of the external electrode paste 500 are applied so as to be spaced inward from the third surface 102c and the fourth surface 102d of the capacitor element 102, respectively. By applying the external electrode paste 500 of the second external electrodes 106, 107, 108, and 109 in this manner, the second external electrodes 106, 107, 108, and 109 can satisfy the conditional expressions H2> '&Gt; H3'.

Subsequently, in step S8, the second external electrode paste of the second external electrodes 106, 107, 108, and 109 applied to the capacitor element 102 is baked. Thus, the second external electrode portion of the second external electrodes 106, 107, 108, and 109 is formed. In this way, the electrode thickness of the second external electrodes 106, 107, 108, and 109 is formed larger than the electrode thickness of the first external electrodes 104 and 105.

Next, in step S9, Ni plating and Sn plating are formed in this order on the surfaces of the first external electrodes 104 and 105 and the second external electrodes 106, 107, 108, and 109, respectively, by wet plating. Thus, three-terminal type capacitors 100 and 200 are obtained.

As described above, in the three-terminal capacitor 100 according to the first embodiment, the first external electrodes 104 and 105 are signal-side electrodes, and the second external electrodes 106, 107, 108, The first external electrodes 104 and 105 may be ground-side electrodes, and the second external electrodes 106, 107, 108, and 109 may be signal-side electrodes.

Here, the value of the insertion loss (hereinafter referred to as &quot; pattern 1 &quot;) when the first external electrodes 104 and 105 are the signal-side electrodes and the second external electrodes 106, 107, 108, and 109 are the ground- Is referred to as IL1. On the contrary, when the signal side electrode and the ground side electrode are changed, that is, when the first external electrodes 104 and 105 are the ground side electrodes and the second external electrodes 106, 107, 108, and 109 are the signal side electrodes (Hereinafter referred to as &quot; pattern 2 &quot;) is referred to as IL2. At this time, the three-terminal capacitor 100 satisfies IL1 &lt; IL2 in the vicinity of the frequency band of 10 MHz, and satisfies IL1 &gt; IL2 in the frequency band of 100 MHz. That is, when the three-terminal capacitor 100 is used as the pattern 2 in the 100 MHz band, the insertion loss value is small as compared with the case of using the three-terminal capacitor 100 as the pattern 1.

The reason why the frequency characteristics of insertion loss is different between the case of using the three-terminal capacitor 100 as the pattern 1 and the case of using the three-terminal capacitor 100 as the pattern 2 in this way is that the paths in which the signals and noise flow in the patterns 1 and 2 are different Because. Hereinafter, this will be described in detail.

Figs. 24A to 24C are schematic diagrams for explaining a signal and a path of noise when the three-terminal capacitor 100 is used as the pattern 1, Fig. 24 (b) is a schematic view of the first conductor layer 120, and Fig. 24 (c) is a schematic view of the second conductor layer 122. Fig. A solid line arrow indicates the flow of the signal, and a dashed arrow indicates the flow of the noise.

When the three-terminal capacitor 100 is used as the pattern 1, a signal input from the first external electrodes 104 and 105 to the three-terminal capacitor 100 is supplied to the three- 1 external electrodes 104 and 105 and is output from the first external electrodes 104 and 105. [ The noise generated at this time may be transmitted through the second lead portions 134, 135, 136, and 137 of the second conductor layer 122, as shown in FIGS. 24B and 24C It flows to ground.

25 (a) to 25 (c) are schematic diagrams for explaining a path through which signals and noise flow when the three-terminal capacitor 100 is used as the pattern 2. Fig. 25 Fig. 25 (b) is a schematic view of the first conductor layer 120, and Fig. 25 (c) is a schematic view of the second conductor layer 122. Fig.

When the three-terminal capacitor 100 is used as the pattern 2, as shown in Figs. 25 (a) and 25 (c), the three-terminal type capacitors 100, The signal inputted to the first external conductor 100 is outputted from the second external electrodes 108 and 109 through the second lead portions 134, 135, 136 and 137 of the second conductor layer 122. The noise generated at this time flows to the ground through the first lead portions 132 and 133 of the first conductor layer 120 as shown in FIG. 24 (b).

As a result, the inventors of the present invention have made intensive investigations. As a result, in order to utilize the fact that the frequency characteristics of the insertion loss are different when the three-terminal capacitor 100 is used as the pattern 1 and when it is used as the pattern 2, Respectively. Therefore, an experiment was conducted to confirm that a preferable insertion loss can be obtained by using one three-terminal capacitor 100 by separately using the pattern 1 and the pattern 2 in accordance with the required frequency band. Hereinafter, an experiment performed to confirm the frequency characteristics of the insertion loss when the three-terminal capacitor 100 is used as the pattern 1 and the frequency characteristics of the insertion loss when the three-terminal capacitor 100 is used as the pattern 2 will be described.

26 is a graph showing the results of this experiment, in which the abscissa indicates the frequency (MHz) and the ordinate indicates the insertion loss (dB). The pattern 1 is shown by a solid line, and the pattern 2 is shown by a broken line.

As shown in the graph of Fig. 26, at the frequency of around 10 MHz, the pattern 1 shows an excellent insertion loss as compared with the pattern 2. Therefore, when the necessary frequency is about 10 MHz, the three-terminal capacitor 100 is set to the pattern 1 (that is, the first external electrodes 104 and 105 as shown in Fig. 24 (a) , And the second external electrodes 106, 107, 108, and 109 are grounded electrodes).

On the other hand, in the frequency band of 100 MHz, the pattern 2 exhibits excellent insertion loss characteristics as compared with the pattern 1. Therefore, when the required frequency is the 100 MHz band, the three-terminal capacitor 100 is set to the pattern 2 (i.e., the first external electrodes 104 and 105 are connected to the ground electrode And the second external electrodes 106, 107, 108, and 109 are used as signal electrodes).

That is, the pattern 1 in which the first external electrodes 104 and 105 are the signal side electrodes and the second external electrodes 106, 107, 108, and 109 are the ground side electrodes in accordance with the required frequency band, By using the pattern 2 in which the external electrodes 104 and 105 are the ground side electrode and the second external electrodes 106, 107, 108 and 109 are the signal side electrodes, one three-terminal type capacitor 100 ) Can be used to obtain a desired insertion loss.

Although the description is not repeated here, the same effect as that obtained by the three-terminal condenser 100 of the first embodiment described above can be obtained for the three-terminal capacitor 200 of the second embodiment.

3. Effect of the present embodiment

E2 + ME2 + E3> is the dimension in the length L direction of the capacitor element and the second external electrodes 106 and 206 are the third faces 102c and 202c in the three-terminal capacitors 100 and 200, The third folding portions 106c and 206c are formed on the fourth surface 102d and the second external electrodes 108 and 208 are formed on the fourth surface 102d and 202d, The first external electrodes 104 and 204 and the second external electrodes 106 and 206 satisfy the following relation: &lt; 50 mu m and M2L &lt; M2R, M1R &gt; M1L, or M2L & 108, and 208 are always shifted toward the constant end face side, and deterioration of insulation resistance between the external electrodes can be prevented.

In the three-terminal capacitors 100 and 200, the dimension of the M1R / capacitor element in the length L direction, the dimension of the M2L / capacitor element in the length L direction, the dimension of the M2R / capacitor element in the length L direction, the dimension of the M3L / The first lead portions 132 and 232 and the second lead portions 134 and 234 and 136 and 236 are connected to the first external electrodes 104 and 204 more reliably when the length of the element in the L direction is 1.5% And the second external electrodes 106, 206, 108, and 208, it is possible to prevent deterioration of insulation resistance between the external electrodes.

(Experimental Example)

In the experimental example, each sample of the three-terminal type capacitor shown below was produced.

1. Preparation of samples for evaluation

In the Experimental Example, Examples and Comparative Examples for evaluation of a three-terminal type capacitor were produced on the basis of the conditions shown in Tables 2 and 3 by the manufacturing method described in the above embodiment. The three-terminal type capacitors of the embodiments and the comparative example have the same structure in terms of design except for the length L of the three-terminal type capacitor and the respective dimensions of E1, E2, E3, ME1, ME2, M1R, M2L, .

2. Evaluation of each sample

It was judged that insulation resistance deterioration occurred when the insulation resistance between the first external electrode and the second external electrode in Examples and Comparative Examples was measured and was lower than 10 ⁷ (?).

The multilayer ceramic capacitors in the examples and comparative examples were subjected to moisture resistance load tests. With respect to the three-terminal type capacitors in the examples and comparative examples, a voltage of 6.3 V was applied, and the temperature was kept at 120 캜 for 400 hours in an air atmosphere of 100% RH. After leaving, the insulation resistance IR was measured. When the insulation resistance IR satisfied the conditional expression Log (IR) &lt; 5, the failure occurred.

Evaluation of insulation resistance deterioration is shown in Table 2, and evaluation of moisture resistance is shown in Table 3.

From the results shown in Table 2, it can be understood from the results shown in Table 2 that the relationship of E1 + ME1 + E2 + ME2 + E3> L, | ME1-ME2 | <50 μm, M2L <M2R and M1R> M1L, or M2L> M2R and M1R < Is not satisfied. That is, the distance between the first external electrode and the second external electrode becomes close to each other, and the insulation resistance between both electrodes deteriorates.

From the results shown in Table 3, it can be seen that M1R / L, M2R / L, M2L / L and M3L / L are the same in the examples, while M1R / L is 0.78% and M2L / L is 1.02% Since all of them were 1.5% or more, good results were obtained with respect to the insulation resistance. The evaluation of the insulation resistance is the same as that in Table 2.

The present invention is not limited to the above-described embodiments, but may be modified in various ways within the scope of the present invention.

In the three-terminal capacitors 100 and 200 according to the present embodiment, the second external electrode 106 formed at one end in the length L direction of the first surface 102a is the fifth surface 102e, The second folding portion 106b of the sixth surface 102f and the second folding portion 106b of the sixth surface 102f have a height H2 of the center portion in the length L direction and the third folding portion 106c of the third surface 102c, And the height of the central portion in the width W direction is H3, the conditional formula H2 &gt; H3 is satisfied, but the present invention is not limited thereto.

The second external electrode 108 formed on the other end of the first surface 102a in the direction of the length L has the second folding portions 108b and 108b of the fifth surface 102e and the sixth surface 102f And the height of the central portion in the width W direction of the third folding portion 108c of the fourth surface 102d is H3 ', the height of the center portion in the length L direction is H2' Satisfies the conditional expression H2 '> H3', but is not limited thereto.

In the three-terminal capacitors 100 and 200 according to the present embodiment, the thickness of the outermost conductor layers 124, 126, 224, and 226 is set so that the thickness of the first conductor layer 120, 122, 220, and 222, but is not limited thereto.

In the three-terminal capacitors 100 and 200 according to the present embodiment, the outermost conductor layers 124 and 224 are connected to the adjacent first conductor layers 120 and 220 via the dielectric layers 110 and 210, The second external electrodes 106, 107, 108, 109, 206, and 208 may be connected to the common first external electrodes 104, 105, and 204, but not limited thereto. Similarly, the outermost conductor layers 126 and 226 are electrically connected to the second external electrodes 106, 107, and 108, which are common to the adjacent second conductor layers 122 and 222 via the internal dielectric layers 110 and 210, 109, 206, and 208, but the present invention is not limited thereto, and may be connected to the first external electrodes 104, 105, and 204.

100, 200: 3 terminal type capacitor
102, 202: Capacitor element
102a, 202a: first side
102b, 202b: a second surface
102c, 202c: third side
102d, 202d: fourth surface
102e, 202e: fifth face
102f, 202f: sixth surface
103a, 103b, 103c, and 103d:
104, 105, 204, and 205: a first external electrode
104a, 105a, and 204a: a first external electrode body portion
104b, 105b, 204b:
106, 107, 108, 109, 206, 208:
106a, 107a, 108a, 109a, 206a, and 208a:
106b, 107b, 108b, 109b, 206b, and 208b:
106c, 107c, 108c, 109c, 206c, and 208c:
110, 210: inner layer dielectric layer
112, 212: dielectric layer for outer layer
120, 220: first conductor layer
122, 222: second conductor layer
124, 126, 224, 226: Outer conductor layer
126a: defective part
127, 227: boundary layer
128, 228: first opposing portion
129, 229:
130, 230: a second opposing portion
132, 133, 232:
134, 135, 136, 137, 234, 236:
170a, 171a, and 270a:
172a, 173a, 174a, 175a, 272a, 274a:
170b, 171b, 172b, 173b, 174b, 175b, 270b, 272b, 274b:
203a and 204b:
300: dispensing device
320a, 320b:
340a, 340b:
360a, 360b, 370a, 370b: scraper
380a, 380b: transfer roller
400a, 400b: paste tank
420, 440, 480: Home
490: Carrier tape
500: external electrode paste
520: rotation axis of the application roller
600: convex portion
L: Length
T: Height
W: Width
A: width of the second external electrode
B: width of the first external electrode

Claims (6)

A third surface and a fourth surface extending in the width direction and the thickness direction, a fifth surface extending in the longitudinal direction and the thickness direction, and a third surface extending in the thickness direction, A capacitor element having six surfaces,
A second external electrode formed on one end in the longitudinal direction of the first surface, the third surface, the fifth surface, and the sixth surface;
A second external electrode formed on the other end in the longitudinal direction of the first surface, the fourth surface, the fifth surface, and the sixth surface;
A portion located between the two second external electrodes in the longitudinal direction of the first surface; a first external electrode formed on the fifth surface and the sixth surface;
A plurality of first conductor layers formed inside the capacitor element and electrically connected to the first outer electrode through a first lead portion,
And a plurality of second conductor layers formed inside the capacitor element and electrically connected to the second external electrode through a second lead portion,
The capacitor element includes:
A plurality of inner layer dielectric layers disposed between the first conductor layer and the second conductor layer,
An outermost conductor layer positioned most outward in the width direction out of the first conductor layer and the second conductor layer,
The outer layer dielectric layer adjacent to the outermost conductor layer
/ RTI &gt;
The thickness of the outermost conductor layer is smaller than the thickness of the first conductor layer or the second conductor layer located closest to the center in the width direction,
The coverage of the outermost conductor layer is defined as the sum of the lengths of the first conductor layer or the second conductor layer located near the center with respect to the width direction when the coverage is defined as the sum of the lengths of the conductor particle cross- Is less than the coverage of the second conductor layer,
A defective portion is formed in the outermost conductor layer, and the defective portion includes a column containing the inner layer dielectric layer and the outer layer dielectric layer and containing at least one of Si slab, Al slab, and BaTiO ₃
Wherein the capacitor is a capacitor. The method according to claim 1,
And a boundary layer containing Mg and Mn between the outermost conductor layer and the outer layer dielectric layer. The method according to claim 1,
A length in the longitudinal direction of the one second external electrode is denoted by E1,
A length in the longitudinal direction of the second external electrode is denoted by E3,
A length in the longitudinal direction of the first external electrode is denoted by E2,
A distance between the one second external electrode and the first external electrode is ME1,
A distance between the first external electrode and the second external electrode is ME2,
The length in the longitudinal direction of the capacitor element is L,
The width from the edge of the end portion on the third surface side of the one second drawing portion to the third surface is M1L,
And a width from an edge of the fourth surface of the one second lead portion to an edge of the second external electrode on the first surface is M1R,
The width from the edge of the third face of the first lead portion to the edge of the third face of the first external electrode on the first face is M2L,
And a width from the edge of the fourth surface of the first lead portion to the edge of the fourth surface of the first external electrode on the first surface is M2R,
2.10 mm &gt; E1 + ME1 + E2 + ME2 + E3 &gt; 2.00 mm,
ME1-ME2 &lt; 50 占 퐉,
A relation of M2L &lt; M2R and M1R &gt; M1L, or a relation of M2L &gt; M2R and M1R &
And a width from the edge of the third surface of the other second lead portion to the edge of the second external electrode on the first surface is M3L,
M1R / L, M2L / L, M2R / L and M3L / L are 1.5% or more, respectively. A third surface and a fourth surface extending in the width direction and the thickness direction, a fifth surface extending in the longitudinal direction and the thickness direction, and a third surface extending in the thickness direction, A capacitor element having six surfaces,
A second external electrode formed on one end in the longitudinal direction of the first surface, the third surface, the fifth surface, and the sixth surface;
A second external electrode formed on the other end in the longitudinal direction of the first surface, the fourth surface, the fifth surface, and the sixth surface;
A portion located between the two second external electrodes in the longitudinal direction of the first surface; a first external electrode formed on the fifth surface and the sixth surface;
A plurality of first conductor layers formed inside the capacitor element and electrically connected to the first outer electrode through a first lead portion,
And a plurality of second conductor layers formed inside the capacitor element and electrically connected to the second external electrode through a second lead portion,
The capacitor element includes:
A plurality of inner layer dielectric layers disposed between the first conductor layer and the second conductor layer,
An outermost conductor layer positioned most outward in the width direction out of the first conductor layer and the second conductor layer,
The outer layer dielectric layer adjacent to the outermost conductor layer
/ RTI &gt;
Wherein the outermost conductor layer is the first conductor layer when the conductor layer located closest to the outermost conductor layer is the first conductor layer and the conductor layer located closest to the outermost conductor layer is the first conductor layer, 2 &lt; / RTI &gt; conductor layer,
The coverage of the outermost conductor layer is defined as the sum of the lengths of the first conductor layer or the second conductor layer located near the center with respect to the width direction when the coverage is defined as the sum of the lengths of the conductor particle cross- Is less than the coverage of the second conductor layer,
A defect portion is formed in the outermost conductor layer and the defective portion includes a column which includes at least any one of Si segregation, Al segregation and BaTiO ₃ bonded to the inner layer dielectric layer and the outer layer dielectric layer 3-terminal type capacitor. 5. The method of claim 4,
And a boundary layer containing Mg and Mn between the outermost conductor layer and the outer layer dielectric layer. 5. The method of claim 4,
A length in the longitudinal direction of the one second external electrode is denoted by E1,
A length in the longitudinal direction of the second external electrode is denoted by E3,
A length in the longitudinal direction of the first external electrode is denoted by E2,
A distance between the one second external electrode and the first external electrode is ME1,
A distance between the first external electrode and the second external electrode is ME2,
The length in the longitudinal direction of the capacitor element is L,
The width from the edge of the end portion on the third surface side of the one second drawing portion to the third surface is M1L,
And a width from an edge of the fourth surface of the one second lead portion to an edge of the second external electrode on the first surface is M1R,
The width from the edge of the third face of the first lead portion to the edge of the third face of the first external electrode on the first face is M2L,
And a width from the edge of the fourth surface of the first lead portion to the edge of the fourth surface of the first external electrode on the first surface is M2R,
2.10 mm &gt; E1 + ME1 + E2 + ME2 + E3 &gt; 2.00 mm,
ME1-ME2 &lt; 50 占 퐉,
A relation of M2L &lt; M2R and M1R &gt; M1L, or a relation of M2L &gt; M2R and M1R &
And a width from the edge of the third surface of the other second lead portion to the edge of the second external electrode on the first surface is M3L,
M1R / L, M2L / L, M2R / L and M3L / L are 1.5% or more, respectively.

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