JPH1155058A - Layered ceramic composite part - Google Patents

Abstract

PROBLEM TO BE SOLVED: To obtain a composite part which does not warp nor crack by covering a layered body which is formed by layering at least two ceramics which are selected from magnetic material ceramics, high dielectric constant dielectric ceramics and low dielectric constant dielectric ceramics from both sides with insulating ceramics that has a reduction ratio which is different from at least the two ceramics. SOLUTION: A low dielectric constant dielectric ceramics sheet 11 and a magnetic material ceramics sheet 12 are formed by mixing low dielectric constant dielectric ceramics material in which barium oxide, aluminium oxide and powder of silica are main materials and magnetic material ceramics material in which iron oxide, niobium oxide and powder of zinc oxide are main materials, binder, plasticizing agent and solvent. After layered body 13 is formed by layering them, a mold body 15 is acquired by covering the body 13 from both sides with blocks 23 that comprising, ceramic sintering material on the like, through insulating ceramics 14 that is constituted of alumina sheet whose reduction rate is small and performing pressure sintering.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to a laminated ceramic composite part, and more particularly to a laminated ceramic composite part obtained by laminating and integrating different ceramics.

[0002]

2. Description of the Related Art In recent years, due to demands for miniaturization of electronic devices and the like, the integration of electronic components has been progressing. These composite components include, for example, a laminated LC filter combining an inductor and a capacitor. This LC filter is
Generally, it is manufactured as follows. That is, after the molded body obtained by laminating the magnetic green sheets on which the coil electrode patterns are formed and the molded body obtained by laminating the low dielectric constant green sheets on which the capacitor electrode patterns are formed, By firing, a sintered body in which the magnetic body and the low dielectric constant dielectric are integrated is obtained. Thereafter, an external electrode is baked on a portion of the sintered body where the coil electrode and the capacitor electrode are exposed to obtain an LC filter. As a ceramic material for obtaining a magnetic green sheet and a low dielectric constant dielectric green sheet, a ceramic material that can be sintered at 950 ° C. or lower is used. This is because a low-resistivity silver-based electrode is used for the purpose of reducing the DC resistance of the coil formed in the magnetic material. As the raw material, as the low dielectric constant dielectric material, a material obtained by adding a glass component to a raw material obtained by calcining and pulverizing a starting raw material powder is used.

[0003]

However, in the above-mentioned laminated ceramic composite part, since the coprecipitated raw material obtained by the wet synthesis method has fine particles and is rich in activity, the raw material obtained by calcining the starting raw material powder and pulverizing the raw material has a glass component. The firing shrinkage is remarkably large as compared with the case of adding. For this reason, when the molded body serving as the inductance and the molded body serving as the capacitor are stacked and fired, there is a problem that the sintered body is warped or peeled due to the difference in firing shrinkage.

[0004] The present invention has been made to solve such problems, and an object of the present invention is to provide a laminated ceramic composite component free from warpage or cracking.

[0005]

In order to solve the above-mentioned problems, the laminated ceramic composite part of the present invention comprises at least one selected from magnetic ceramics, high dielectric constant dielectric ceramics and low dielectric constant dielectric ceramics. A laminate formed by laminating two ceramics is sandwiched between insulating ceramics having a shrinkage rate different from that of the at least two ceramics and integrated.

Further, the laminate is formed by laminating the at least two ceramics via the insulator ceramics.

According to the multilayer ceramic composite component of the present invention, when a laminated body formed by laminating at least two ceramics is integrated, it has a smaller shrinkage ratio than at least two ceramics constituting the laminated body. Since they are integrated by being sandwiched and pressed by the insulating ceramics, the shrinkage rate of at least two ceramics constituting the laminate can be made equal to the shrinkage rate of the insulating ceramics sandwiching the laminate.

[0008]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 shows a perspective view of a first embodiment of a multilayer ceramic composite component according to the present invention. The multilayer ceramic composite component 10 includes a laminate 13 including a low dielectric constant dielectric ceramic 11 containing a capacitor (not shown) and a magnetic ceramic 12 containing a coil (not shown). A molded body 15 sandwiched between insulating ceramics 14 and 14 having a smaller shrinkage ratio than the low dielectric constant dielectric ceramics 11 and the magnetic ceramics 12 is provided. External terminals 16, 16 and a ground terminal 17 are provided on the side surface of the molded body 15.

A method of manufacturing the multilayer ceramic composite component 10 shown in FIG. 1 will be described with reference to FIGS.

First, barium oxide, aluminum oxide,
Silica powder as the main material, low dielectric constant dielectric ceramic material with sintering temperature around 900 ° C by adding boric acid, and iron oxide, niobium oxide, zinc oxide powder as the main material, and glass added 850-900 sintering temperature
The binder, plasticizer, solvent and the like are kneaded at a predetermined ratio with the magnetic ceramic material at a temperature of 100 ° C., and a low dielectric constant dielectric ceramic sheet 11 a is formed by a doctor blade method or the like.
To 11d and magnetic ceramic sheets 12a to 12d
To form

Next, the low dielectric constant dielectric ceramic sheets 11b to 11d and the magnetic ceramic sheet 12
After forming a via hole in a and 12b by punching, copper, silver, silver / palladium,
A via-hole electrode 18 is formed by filling a paste-like conductive material made of tungsten, platinum, or the like.

Next, the low dielectric constant dielectric ceramic sheets 11b and 11c and the magnetic ceramic sheet 12
A paste-shaped conductor made of copper, silver, silver / palladium, tungsten, platinum, or the like is printed on screens b and 12c by screen printing, and the capacitor electrode 19, the ground electrode 20, the coil electrodes 21, 21 and the extraction electrodes 22, 22 is formed.

Next, the low dielectric constant dielectric ceramic sheets 11a to 11d and the magnetic ceramic sheet 12a
After forming the laminate 13 by laminating the laminates 13 to 12d, as shown in FIG. 3, the laminate 13 has a lower shrinkage than the low dielectric constant dielectric ceramic sheets 11a to 11d and the magnetic ceramic sheets 12a to 12d. It is sandwiched between blocks 23 made of a ceramic sintered body or the like via insulating ceramics 14 made of a small alumina sheet. Next, the molded body 15 is obtained by pressing the laminated body 13 from both main surface directions by the block 23 and sintering the laminated body 13 at a temperature of about 900 ° C.

Next, although not shown, external terminals 16 and 1 connected to the extraction electrode 22 are provided on the side surface of the molded body 15.
6. By forming the ground terminal 17 connected to the ground electrode 20, the multilayer ceramic composite component 10 is completed.

In the 1 cm square laminated ceramic composite component 10 having the above-described configuration, the shrinkage in the x, y, and z directions (FIG. 1) was measured. As a result, the x direction: 2%, the y direction: 2%,
In the z direction: 40%, the warpage was about 10 μm. Further, in the thermal shock test at −55 ° C., + 85 ° C., and 1000 cycles, no crack was observed in all 100 pieces.

On the other hand, in the 1 cm square laminated ceramic composite part 50 having the conventional configuration, the shrinkage in the x, y, and z directions is 16% in the x direction, 16% in the y direction, and 16 in the z direction.
%, The warpage was about 100 μm. -55 ° C,
In a thermal shock test at + 85 ° C. and 1000 cycles, 100
Cracks occurred in 37 of the pieces from the interface between the low dielectric constant dielectric ceramic layer and the magnetic ceramic layer.

According to the first embodiment, when a laminate formed by laminating a low dielectric constant dielectric ceramic and a magnetic ceramic is integrated, the low dielectric constant dielectric ceramic constituting the laminate is formed. In order to integrate by pressing and pressing between insulating ceramics having a smaller shrinkage ratio than magnetic ceramics, the shrinkage ratio of the low dielectric constant dielectric ceramics and the magnetic ceramics constituting the laminated body is reduced by sandwiching the laminated body. It can be made equal to the contraction rate of the insulating ceramics.

Therefore, warpage due to a difference in shrinkage between the low dielectric constant dielectric ceramics and the magnetic ceramics constituting the laminate can be suppressed, and as a result, the interface between the low dielectric constant dielectric ceramics and the magnetic ceramics can be suppressed. Cracks can be prevented.

FIG. 4 is a perspective view of a second embodiment of the multilayer ceramic composite component according to the present invention. The multilayer ceramic composite component 20 is different from the multilayer ceramic composite component 10 of the first embodiment in that a low dielectric constant dielectric ceramic 11 having a built-in capacitor (not shown) and a magnetic material having a coil (not shown) built-in. And a ceramic body 12 laminated with an insulator ceramic 14 having a smaller shrinkage ratio than the dielectric ceramic 11 having a lower dielectric constant and the magnetic ceramic 12. , 14 are provided.

The multilayer ceramic composite part 20 is manufactured by the same method as the method for manufacturing the multilayer ceramic composite part 10 shown in FIG. 1 (FIGS. 2 and 3). That is, in FIG. 2, the insulating ceramics 14 may be inserted between the low dielectric constant dielectric ceramics sheet 11d and the magnetic ceramics sheet 12a.

In the 1 cm square laminated ceramic composite component 20 having the above-described configuration, the shrinkage in the x, y, and z directions (FIG. 1) was measured.
z direction: 40%, warpage is about 10 μm,
The shrinkage in the xy direction, that is, in the plane direction, is reduced by about 1% as compared with the laminated ceramic composite component 10 of the embodiment (FIG. 1).

According to the second embodiment, the low dielectric constant dielectric ceramics and the magnetic ceramics are laminated via the insulating ceramics having a smaller shrinkage than the low dielectric constant dielectric ceramics and the magnetic ceramics. Since the laminate is formed in this manner, the difference in the shrinkage in the plane direction between the low dielectric constant dielectric ceramic and the magnetic ceramic can be absorbed by the insulating ceramic.

Therefore, warpage due to a difference in shrinkage between the low dielectric constant dielectric ceramics and the magnetic ceramics constituting the laminate can be further suppressed, and as a result, the interface between the low dielectric constant dielectric ceramics and the magnetic ceramics can be reduced. Cracks can be further prevented.

In the first and second embodiments described above,
Although a case has been described where the multilayer ceramic composite component is made of a magnetic ceramic and a low dielectric constant dielectric ceramic, the present invention is not limited to only these.
In other words, the magnetic ceramics and the high dielectric constant dielectric ceramics, the high dielectric constant dielectric ceramics and the low dielectric constant dielectric ceramics, and the magnetic ceramics, the high dielectric constant dielectric ceramics and the low dielectric constant dielectric ceramics are also included. Similar effects can be obtained.

[0025]

According to the laminated ceramic composite component of the first aspect, when a laminate formed by laminating at least two ceramics is integrated, shrinkage different from that of at least two ceramics constituting the laminate is required. Since it is integrated by being sandwiched and pressed by insulating ceramics having a specific modulus, the shrinkage of at least two ceramics constituting the laminate can be made equal to the shrinkage of the insulator ceramic sandwiching the laminate. .

Therefore, warpage due to a difference in shrinkage of at least two ceramics constituting the laminate can be suppressed, and as a result, cracking at the interface between at least two ceramics can be prevented.

According to the laminated ceramic composite component of the second aspect, at least two ceramics are laminated via the insulating ceramics having a different shrinkage rate from the at least two ceramics to form a laminated body. The difference in shrinkage in the plane direction of at least two ceramics is
It can be absorbed by insulating ceramics.

Therefore, warpage due to a difference in shrinkage of at least two ceramics constituting the laminate can be further suppressed, and as a result, cracking at the interface between at least two ceramics can be further prevented.

[Brief description of the drawings]

FIG. 1 is a perspective view of a first embodiment of a multilayer ceramic composite component according to the present invention.

FIG. 2 is an exploded perspective view of a laminate constituting the multilayer ceramic composite component of FIG.

FIG. 3 is a perspective view showing a method of manufacturing a molded body constituting the multilayer ceramic composite component of FIG.

FIG. 4 is a perspective view of a second embodiment of the multilayer ceramic composite component of the present invention.

[Explanation of symbols]

10, 20 laminated ceramic composite parts 11, 12 ceramics (low dielectric constant dielectric ceramics, magnetic ceramics) 13 laminated bodies 14 insulating ceramics

Claims (2)

[Claims] 1. A laminated body formed by laminating at least two ceramics selected from magnetic ceramics, high dielectric constant dielectric ceramics, and low dielectric constant dielectric ceramics, the laminated body being different from the at least two ceramics. A multilayer ceramic composite part characterized by being sandwiched and integrated by insulating ceramics having a shrinkage rate. 2. The laminated ceramic composite part according to claim 1, wherein the laminated body is formed by laminating the at least two ceramics via the insulating ceramic.