JP5570205B2 - Magnetic sintered body, composite sintered body of magnetic body and dielectric, manufacturing method thereof, and electronic component using the same - Google Patents

Description

  The present invention relates to a magnetic sintered body, a composite sintered body of a magnetic body and a dielectric, a manufacturing method thereof, and an electronic component using the same, and is used for, for example, an EMI filter for high frequency noise countermeasures of equipment. An inductor circuit is formed in a magnetic sintered body, and a capacitor circuit and an inductor circuit are formed in a composite sintered body of a magnetic body and a dielectric body, which combines the properties of a magnetic body and a magnetic body. It is suitable for electronic components.

  Conventionally, EMI (Electro Magnetic Interference) filters are often used as countermeasures for high frequency noise in electronic devices. In recent years, with the increase in the frequency of mobile communication devices such as mobile phones and wireless LANs, filter characteristics that can be used in high frequency bands of several hundred MHz to several GHz are also required for EMI filters.

  In general, EMI filters used for noise countermeasures in such electronic devices are often configured by combining capacitors and inductors individually. However, in recent years, with the miniaturization of electronic equipment, a silver electrode or the like is included in a composite laminate in which an inductor layer made of a magnetic material and a capacitor layer made of a dielectric material are laminated and integrated. A coil with a coil has been proposed. As an example, there is a noise filter in which a coil is formed with a silver or silver-palladium electrode or the like inside a composite sintered body in which a magnetic body and a dielectric are mixed and fired (see, for example, Patent Document 1).

  As a magnetic material to be used, spinel type ferrites such as Mn—Zn, Ni—Zn, and Ni—Cu—Zn, which have a high relative permeability in the range of several MHz to several hundreds of MHz, have been often used. However, since this spinel type ferrite has a low magnetic anisotropy, it causes natural resonance at a frequency of several hundred MHz and cannot exceed the frequency limit of the magnetic permeability (the limit of the snake). Since sufficient permeability cannot be obtained in the several GHz band region, it could not be applied to a filter material in a high frequency band.

  Therefore, recently, hexagonal ferrite that maintains the relative magnetic permeability up to a high frequency range exceeding the frequency limit of the spinel ferrite has been proposed as a magnetic material in the several hundred MHz to several GHz band region.

This hexagonal ferrite has a magnetization easy axis in a plane perpendicular to the c-axis, and is a magnetic material called a ferro-planar ferrite. As typical Ferroplanar ferrites, Co-substituted Z-type hexagonal Ba ferrite (3BaO · 2CoO · 12Fe ₂ O ₃ ), Co-substituted Y-type hexagonal Ba ferrite (2BaO · 2CoO · 6Fe ₂ O ₃₎ Co-substituted W-type hexagonal Ba ferrite (BaO.2CoO.8Fe ₂ O ₃ ) and the like are known.

  Among these ferro-planar ferrites, the synthesis temperature of Y-type hexagonal Ba ferrite single phase (about 1050 ° C.) is Z-type hexagonal Ba ferrite single phase (1300 ° C.) and W-type hexagonal Ba ferrite single phase ( 1200 ° C.) Since it is lower than the respective synthesis temperatures, and the Y-type hexagonal Ba ferrite has a high frequency limit of relative permeability of 3 GHz or more, a magnetic material in the region of several hundred MHz to several GHz band. Promising as a material.

  Further, a magnetic sintered body is known which is manufactured by mixing ferrite powder and borosilicate glass powder in order to increase the bending strength of ferrite (see, for example, Patent Document 2).

JP-A-2-249294 Japanese Patent Laid-Open No. 1-110708

  However, in the magnetic sintered body described in Patent Document 2, the bending strength is still as low as about 100 MPa, and when used for electronic parts such as chip parts, a large impact is generated when a large stress or dropping occurs. There was a risk of breaking.

  The same applies to electronic parts using a composite sintered body of a magnetic body and a dielectric body mainly composed of ferrite.

  Accordingly, the present invention provides a magnetic sintered body that can be used in the GHz band region and has a high bending strength, a composite sintered body of a magnetic body and a dielectric, a manufacturing method thereof, and an electronic component using them. The purpose is to do.

The magnetic sintered body according to the present invention includes at least one of a Ferroc planar type Ba ferrite and a Li—Zn—Cu—Fe—O spinel type crystal as a main crystal, and includes needle-like crystals of (Ba, Ca) ₂ SiO _4. The magnetic sintered body has a ratio of the area of the acicular crystal in the cross section of the magnetic sintered body of 10 to 15%, a bending strength of 154 MPa or more, and a relative permeability at a frequency of 1 GHz of 3. It is characterized by being 3 or more .

  Furthermore, it is preferable that the aspect ratio of the acicular crystal is 10-15.

  A composite sintered body of a magnetic body and a dielectric according to the present invention includes the magnetic sintered body and a dielectric of titanate of an alkaline earth metal.

  The electronic component of the present invention is characterized in that an inductor circuit is formed in or on the surface of the insulating base made of the magnetic sintered body.

  Furthermore, an external electrode mainly composed of silver is baked on the surface of the electronic component, and the area of the acicular crystal in the cross section of the magnetic sintered body near the external electrode is 13.0 to 18.6%. It is preferable that

  The electronic component of the present invention is characterized in that a capacitor circuit and an inductor circuit are formed inside or on the surface of an insulating base made of a composite sintered body of the magnetic material and the dielectric material.

  Furthermore, an external electrode mainly composed of silver is baked on the surface of the electronic component, and the area of the acicular crystal in the cross section of the magnetic sintered body near the external electrode is 13.0 to 18.6%. It is preferable that

The method for producing a magnetic sintered body according to the present invention is a method for producing the above-mentioned magnetic sintered body, which includes hexagonal Ba ferrite powder, Li mol in terms of Li ₂ O of 5.0 mol% or more, BaO equivalent and CaO. A glass powder containing 15.4 mol% or more of Ba and Ca in terms of total amount in terms of conversion, and 17.0 to 24.1 mol% in terms of SiO ₂ and having a softening point of 400 to 470 ° C. It mix | blends so that the said glass powder may be 10-30 volume% with respect to the total amount of a crystal | crystallization Ba ferrite powder and the said glass powder, and it bakes the shape | molded molded object, It is characterized by the above-mentioned.

A method for manufacturing a composite sintered body of a magnetic body and a dielectric according to the present invention is a method for manufacturing a composite sintered body of the above magnetic body and a dielectric, and includes a hexagonal Ba ferrite powder, alkaline earth Metal titanate powder, Li in terms of Li ₂ O in an amount of 5.0 mol% or more, BaO equivalent in terms of CaO equivalent and 15.4 mol% in terms of Ca and Ca, and SiO _{2 in} terms of 17. 0-24.
A glass powder containing 1 mol% of Si and having a softening point of 400 to 470 ° C. is added to the glass with respect to the total amount of the hexagonal Ba ferrite powder, the alkaline earth metal titanate powder, and the glass powder. It mix | blends so that powder may be 10-30 volume%, and it bakes the shape | molded molded object, It is characterized by the above-mentioned.

According to the magnetic sintered body of the present invention, at least one of a Ferroc planar type Ba ferrite and a Li—Zn—Cu—Fe—O spinel type crystal is used as a main crystal, and a needle-like crystal of (Ba, Ca) ₂ SiO _4. by the containing 10-15% at a rate of the area of the needle crystals occupying the cross-section of the magnetic sintered body, high relative magnetic permeability in the G Hz band region, and high have magnetic sintered body of flexural strength Ru can be obtained.

Further, in the magnetic sintered body of the present invention, when the aspect ratio of the acicular crystals is 10 to 15, it is possible to obtain a high have magnetic sintered body more flexural strength.

According to the composite sintered body of magnetic material and the dielectric of the present invention, by including the dielectric of the magnetic sintered body and the alkaline earth metal titanates, high have magnetic material dielectric constant and Ru can be obtained a composite sintered body of the dielectric.

According to the electronic component of the present invention, the order inductor circuit in or on the insulating base made of a magnetic sintered body is formed, along with it can be used at GHz band region, the bending strength higher Ru can have obtain an electronic parts.

Further, according to the electronic component of the present invention, it is formed capacitor circuit in addition to the inductor circuit in or on the insulating substrate made of a composite sintered body of magnetic material and the dielectric, in the GHz band region using Ri can der, it is possible to obtain a high have electronic components flexural strength.

Furthermore, in the electronic component of the present invention, an external electrode mainly composed of silver is baked on the surface of the electronic component, and the area of the acicular crystal in the cross section of the magnetic sintered body near the external electrode is 13 If it is .0～18.6 percent, it is possible to obtain a high bonding strength of the external electrodes electronic components.

According to the method for producing a magnetic sintered body of the present invention, hexagonal Ba ferrite powder and 5.0 mol% or more of Li in terms of Li ₂ O, 15.4 mol% or more in terms of the total amount of BaO and CaO. Ba and Ca, and a glass powder containing 17.0 to 24.1 mol% Si in terms of SiO ₂ and having a softening point of 400 to 470 ° C., the total amount of the hexagonal Ba ferrite powder and the glass powder The glass powder is mixed to 10 to 30% by volume, and the molded body is fired, whereby a sintered body is produced from Ferroc sprayer-type Ba ferrite or this and a glass raw material. It becomes what mainly crystal Li-Zn-Cu-Fe- O spinel crystal, between them (Ba, _Ca) 2 for needles of SiO ₄ is made form, in the GHz band region Translucency Rate is high and Ru can be obtained high have magnetic sintered body of flexural strength.

Further , according to the method for producing a composite sintered body of a magnetic body and a dielectric according to the present invention, hexagonal Ba ferrite powder, alkaline earth metal titanate powder, and 5.0 mol in terms of Li ₂ O. % Of Li, 15.4 mol% or more of Ba and Ca in terms of the total amount of BaO conversion and CaO conversion, and 17.0 to 24.1 mol% of Si in terms of SiO ₂ , and a softening point of 400 to 470 The glass powder at 0 ° C. is mixed with the hexagonal Ba ferrite powder, the alkaline earth metal titanate, and the glass powder so that the glass powder is 10 to 30% by volume, and molded. from firing was molded body, sintered ferrox planar type Ba ferrite, or this glass material and Li-Zn-Cu-Fe- O spinel crystals produced from the (Li-Zn-Cu- and e-O spinel ferrite) a main crystal comprises a crystal of alkaline earth metal titanates, between them (Ba, Ca) ₂ for needles of SiO ₄ is made form, in this case is, it is possible to obtain a composite sintered body of the relative permeability and the relative dielectric constant is high, and high have magnetic flexural strength and dielectric in the GHz band region.

(A) It is a longitudinal cross-sectional view of the EMI filter of LC composite electronic component which is one Example of the electronic component of this invention, (b) It is a longitudinal cross-sectional view of the chip coil which is one Example of the electronic component of this invention. . (A) Sample No. which is a composite sintered body of the magnetic body and dielectric of the present invention. 19 is a reflection electron microscope image of Sample No. 19 (b), which is a magnetic sintered body outside the scope of the present invention. 20 is a reflection electron microscope image of 20; It is an X-ray diffraction pattern of the magnetic sintered body of the present invention and the magnetic sintered body outside the scope of the present invention. (A) It is a longitudinal cross-sectional view of the EMI filter of LC composite electronic component with an external electrode which is one Example of the electronic component of this invention, (b) There is an external electrode which is one Example of the electronic component of this invention It is a longitudinal cross-sectional view of a chip coil.

The electronic component of the present invention includes a ferro-planar Ba ferrite as a main crystal and at least one of a Li—Zn—Cu—Fe—O spinel crystal as a main crystal, and a needle-like crystal of (Ba, Ca) ₂ SiO _4. Inductor circuit is formed inside or on the surface of an insulating base made of a magnetic sintered body containing 10 to 15% of the area of the needle-like crystal in the cross section of the magnetic sintered body, or a Ferroch sprayer type Ba ferrite is a main crystal and at least one of Li-Zn-Cu-Fe-O spinel type crystals is a main crystal, and contains an alkaline earth metal titanate dielectric, and (Ba, Ca) ₂ SiO ₄ inside or on the surface of the insulating base made of acicular crystals of a composite sintered body of magnetic material and a dielectric containing 10-15% at a rate of the area of the needle crystals occupying the cross-section of the magnetic sintered body , In which the capacitor circuit and the inductor circuit is formed.

  Note that the notation (Ba, Ca) means that both Ba and Ca are included.

  FIG. 1A is a longitudinal sectional view of an EMI filter of an LC composite electronic component which is an embodiment of the electronic component of the present invention. A plurality of composite sintered body layers 1 (hereinafter also referred to as insulator layers) of a magnetic body and a dielectric that are insulating layers are laminated, and a silver-based conductor layer 2 ( Hereinafter, it may be referred to as a conductor layer). Further, a silver-based via hole conductor (hereinafter sometimes referred to as a via-hole conductor) 3 that electrically connects the silver-based conductor layers 2 separated by the composite sintered body layer 1 penetrates the composite sintered body layer 1. Is formed.

The composite sintered body layer 1 includes at least one of a hexagonal Ba ferrite and a Li—Zn—Cu—Fe—O spinel type crystal as a main crystal, and includes an alkaline earth metal titanate dielectric, (Ba, Ca) ₂ SiO ₄ needle-like crystals are included. By using at least one of the Y-type hexagonal Ba ferrite and the Li—Zn—Cu—Fe—O spinel type crystal as the main crystal, the relative permeability in the GHz band can be increased.

  Hexagonal Ba ferrite has a hexagonal crystal structure and an easy magnetization axis. Specifically, since hexagonal ferrite has an anisotropic magnetic field that varies depending on the crystal direction, the rotational magnetization resonance frequency (fr) increases, and the a-axis in the crystal plane (c-plane) perpendicular to the c-axis is a magnetic field. The direction of magnetization changes easily following the change in the direction of the external magnetic field. For this reason, it is possible to maintain a high relative magnetic permeability even in a high frequency region (several hundred M to several GHz).

The Li—Zn—Cu—Fe—O spinel crystal has a Zn: Cu: Fe element ratio of 5: 2: 26, and the first peak in CuKα characteristic X-ray diffraction is 2θ = 35.51 ° to 35. .55 °. In the composition formula, it is approximately expressed as Li _0.20 Zn _0.43 Cu _0.17 Fe _2.20 O ₄ . In general, spinel ferrite has a relative permeability that suddenly drops at about 1 GHz. However, the ferrite of the Li—Zn—Cu—Fe—O spinel crystal has a high frequency range (several (100 M to several GHz), it is possible to maintain a high relative magnetic permeability.

  The composite sintered body layer 1 can have a high dielectric constant by including a dielectric of an alkaline earth metal titanate.

FIG. 2A is a reflected electron image of a cross section of the composite sintered body of the magnetic body and the dielectric according to the present invention, and A is a needle-like crystal A of (Ba, Ca) ₂ SiO ₄ . The needle-like crystal A of (Ba, Ca) ₂ SiO ₄ can strengthen the bond between the magnetic crystal particles and the dielectric crystal particles, and can increase the bending strength. If the area occupied in the cross-section of the sintered body of needles A is 10-15%, the bending strength Ri is higher, relative permeability and relative dielectric constant that a high. Moreover, when the average aspect-ratio of the acicular crystal | crystallization A in a cross section is 10-15, higher bending strength can be obtained.

  Here, the aspect ratio means that in the cross section, the longest straight line segment that bisects the cross sectional area of one crystal grain is the major axis of the crystal grain in the cross section, and the shortest one is the crystal in the cross section. The ratio of the major axis to the minor axis (major axis / minor axis) when the minor axis of the particle is used.

  4A is a longitudinal sectional view of an EMI filter of an LC composite electronic component which is an embodiment of the electronic component of the present invention, and external electrodes 26 which are terminal electrodes are provided on the surface of the electronic component of FIG. It is baked. A plurality of composite sintered body layers 21 (hereinafter sometimes referred to as insulator layers) of a magnetic body and a dielectric body, which are insulating layers, are laminated, and a silver-based conductor layer 22 ( Hereinafter, it may be referred to as a conductor layer). Further, a silver-based via-hole conductor (hereinafter sometimes referred to as a via-hole conductor) 23 that electrically connects the silver-based conductor layers 22 separated by the composite sintered body layer 21 penetrates the composite sintered-body layer 11. Is formed.

The external electrode 26 is applied to the outside of the fired laminated body made of the insulating layer 21, the conductor layer 22, and the via-hole conductor 23 as a conductor paste and is baked on the laminated body by firing. Is the main component. Here, the main component means that the silver content is 60% by mass or more. In order to reduce the conductor resistance, the silver content is preferably 80% or more, more preferably 90%, and particularly preferably 95% or more. The conductive paste for forming the external electrodes 26, in addition to silver, platinum, palladium, may be included, such as glass powder. Platinum and palladium are effective in suppressing migration. Glass powder can Rukoto to change the baking temperature by changing the set formed and amount.

By baking the external electrodes 26 composed mainly of silver, it is changed generation state of definitive insulator layer 21 in contact with the external electrode 26 crystals. In the process of baking progresses, (Ba, _Ca) 2 production of needle-like crystals A of SiO ₄ increases, the aspect ratio is small Kunar. And if the area ratio of the acicular crystal | crystallization A in the cross section of the insulator layer 21 shall be 13.0-18.6% , peeling strength can be raised. If the area ratio is too large, there is a tendency that the peel strength is weakened, which become stress that is closer to the portion in the gap decreases the volume by the formation of crystals is concentrated and because become starting points of fracture Conceivable.

By proceeding further generation needles in the insulator layer 21 from the interface between the external electrode 26 in the portion within 50μm of the insulating layer 21, it can strongly peel strength of the external electrodes 26. Region generation advances of needle crystals, the direction going toward the external electrode 26 to the inside of the laminate, and Ru planar direction der of the stack table surface. Since the region where the generation of the acicular crystal proceeds is also spread in the plane direction, the external electrode 26 is hardly peeled even when the stress is concentrated on the end of the external electrode 26. In a place away from the external electrode 26 by 100 μm or more, the generation state of the needle-like crystals is almost the same as that before the external electrode 26 is burned. Needle-like crystals are generated slightly in the vicinity of the silver-based conductor layer 22 formed inside, but not so much as in the vicinity of the external electrode 26. In addition, in the capacitor circuit and the inductor circuit configured by the insulator layer 21, the silver-based conductor layer 22 formed inside, and the silver-based via-hole conductor, there is no change in characteristics before baking the external electrode 26.

  FIG. 1B is a longitudinal sectional view of a chip coil which is an embodiment of the electronic component of the present invention. A plurality of magnetic sintered body layers 11 (hereinafter sometimes referred to as insulator layers), which are insulating layers, are laminated, and a silver-based conductor layer 12 (hereinafter referred to as a conductor layer) on the surface of the magnetic sintered body layer 11. May be formed). Further, a silver-based via-hole conductor (hereinafter sometimes referred to as a via-hole conductor) 13 that electrically connects the silver-based conductor layers 12 separated by the magnetic sintered body layer 11 penetrates the magnetic sintered body 11. Is formed.

The magnetic sintered body layer 11 includes at least one of a Y-type hexagonal Ba ferrite and a Li—Zn—Cu—Fe—O spinel type crystal as a main crystal, and includes needle-like crystals of (Ba, Ca) ₂ SiO ₄ . By using at least one of the Y-type hexagonal Ba ferrite and the Li—Zn—Cu—Fe—O spinel type crystal as the main crystal, the relative permeability in the GHz band can be increased.

The magnetic sintered body layer 11 includes needle-like crystals A of (Ba, Ca) ₂ SiO ₄ similar to those shown in FIG. Thereby, the acicular crystal | crystallization A can strengthen the coupling | bonding of a magnetic body crystal particle, and can raise a bending strength. If the area occupied in the cross-section of the sintered body of needles A is 10-15%, the bending strength Ri is higher, relative permeability and relative dielectric constant that a high. Further, when the aspect ratio of the acicular crystals A is 10 to 15, the bending strength can be further increased.

  FIG. 4B is a longitudinal sectional view of a chip coil which is an embodiment of the electronic component of the present invention, and an external electrode 36 which is a terminal electrode is baked on the surface of the electronic component of FIG. . A plurality of magnetic sintered body layers 31 (hereinafter sometimes referred to as insulator layers), which are insulating layers, are laminated, and a silver-based conductor layer 32 (hereinafter referred to as a conductor layer) is formed on the surface of the magnetic sintered body layer 31. May be formed). Further, a silver-based via-hole conductor (hereinafter sometimes referred to as a via-hole conductor) 33 that electrically connects the silver-based conductor layers 32 separated by the magnetic sintered body layer 31 penetrates the magnetic sintered body 31. Is formed.

Similar to the external electrode 26 in the electronic component of FIG. 4A, the external electrode 36 is applied as a conductive paste or the like to the outside of the fired laminate including the insulator layer 31, the conductor layer 32, and the via-hole conductor 33. , Which is baked into the laminate by firing, and contains silver as a main component. Then, by baking the external electrodes 36, (Ba, _Ca) 2 but the amount of needle-like crystals A of SiO ₄ is Ru increases, (Ba, _Ca) in the cross section area ratio of 2 SiO ₄ of the needles A is 13 When it is 0.01 to 18.6% , the peel strength is increased.

  Next, the method for producing the magnetic sintered body of the present invention and the composite sintered body of the magnetic body and the dielectric will be described.

In either case, first, hexagonal Ba ferrite powder is prepared. The hexagonal Ba ferrite powder is composed of, as raw materials, 57 to 63 mol% Fe ₂ O ₃ and 18 to 22 mol% MO in terms of oxides (where M is one or more selected from Co, Cu and Zn). Metal element) and BaO are mixed so as to be the balance. At this time, each raw material is not limited to this, and metal salts such as carbonates and nitrates that generate oxides by firing may be used.

  M may be a single element or a mixture of two or more elements. In the case where two or more kinds are used as M, the total mixed mol% may be 18 to 22 mol%. However, when a Li—Zn—Cu—Fe—O spinel crystal is produced by firing (main firing) described later, a material containing Cu and Zn as M is used.

The synthesis temperature of the Y-type hexagonal Ba ferrite single phase (about 1050 ° C.) is the same as the synthesis temperature of each of the Z-type hexagonal Ba ferrite single phase (1300 ° C.) and the W-type hexagonal Ba ferrite single phase (1200 ° C.). lower than, also, Y-type hexagonal Ba ferrite, since the frequency limit of the relative permeability is not more than a high 3 GHz, preferably also using a Y-type hexagonal Ba ferrite in the hexagonal Ba ferrite.

  The powder mixed at such a blending ratio is calcined in the temperature range of 900 to 1300 ° C. for 1 to 10 hours and then pulverized to obtain hexagonal Ba ferrite powder.

  When pulverizing, using a vibration mill, rotary mill, barrel mill, etc., the magnetic material can be wet using a medium such as a steel ball or ceramic ball and an organic solvent such as water or isopropyl alcohol (IPA) or methanol. it can.

  In that case, the powder used as the raw material of the hexagonal Ba ferrite has an average particle diameter of 0.1 to 5 μm, more preferably 0.1 to 1 μm, from the viewpoint of improving the sinterability at the time of calcination. The “average particle diameter” means the particle diameter d50 at which the cumulative curve becomes 50% when the cumulative curve is obtained with the total volume of the powder group as 100%. The particle size distribution of the powder can be measured using, for example, a microtrack particle size distribution measuring apparatus X-100 (manufactured by Nikkiso Co., Ltd.) using a laser diffraction / scattering method.

  The magnetic sintered body of the present invention can be obtained by mixing the hexagonal Ba ferrite powder thus obtained with the glass powder described later and firing (main firing). In addition, by mixing hexagonal Ba ferrite powder, alkaline earth metal titanate powder and glass powder described later and firing (main firing), composite sintering of the magnetic body and dielectric of the present invention is performed. The body is obtained.

Next, the glass used in the main firing will be described. The glass powder to be used is 5.0 mol% or more of Li in terms of Li ₂ O, 15.4 mol% or more of Ba and Ca in terms of BaO and CaO, and 17.0 in terms of SiO _2. It contains 24.1 mol% Si and has a softening point of 400-470 ° C. This glass can lower the firing temperature of hexagonal Ba ferrite and can increase the bending strength of the sintered body by the needle-like crystals of (Ba, Ca) ₂ SiO ₄ precipitated from this glass. . The balance of the composition is preferably B ₂ O ₃ from the viewpoint of lowering the softening point, but may be other compositions or a mixture of B ₂ O ₃ and other compositions.

When the softening point is 400 to 470 ° C. or higher, the sintering proceeds at a low temperature, and the firing proceeds at an appropriate temperature, whereby (Ba, Ca) ₂ SiO ₄ needle crystals are precipitated. If the softening point is lower than 400 ° C., although Ru Der allows sintering at low temperature, needle-like crystals will not precipitate. When the softening point is higher than 470 ° C., sintering at a low temperature becomes difficult and acicular crystals do not precipitate.

Li serves to lower the softening point of the glass and reacts with hexagonal Ba ferrite. As the glass softens and sintering proceeds, Li reacts with the hexagonal Ba ferrite, and part or most of the hexagonal Ba ferrite is changed to a Li—Zn—Cu—Fe—O spinel crystal. In addition, since Li decreases from the glass composition as this reaction proceeds, needle-like crystals of (Ba, Ca) ₂ SiO ₄ are precipitated from the remaining glass.

In order to precipitate needle-like crystals of (Ba, Ca) ₂ SiO ₄ , a glass containing 15.4 mol% or more of Ba and Ca in terms of the total amount in terms of BaO and CaO is used. In addition, in the glass with less Li than 5.0 mol% in terms of Li ₂ O, the above-mentioned acicular crystal formation hardly occurs, and even when (Ba, Ca) ₂ SiO ₄ crystals are generated, FIG. ) Is not a needle-like crystal as shown in FIG.

You generate (Ba, _Ca) acicular crystals of 2 SiO ₄ is typically _a Ba _{1.55 Ca} 0.55 SiO _4.

Moreover, when there is much Si amount in glass, the reaction which decomposes | disassembles hexagonal Ba ferrite will advance greatly at the time of baking. Since the product of this reaction has a low relative permeability, glass containing 24.1 mol% or less of Si in terms of SiO ₂ is used to suppress this reaction. Further, since SiO ₂ is an aggregate of glass and is also a base of (Ba, Ca) ₂ SiO ₄ crystal, glass containing 17.0 mol% or more of Si in terms of SiO ₂ is used.

Furthermore, in order to lower the softening point of the glass, the B amount in terms of B ₂ O ₃ is preferably 25.6 mol% or more. Moreover, since the decomposition of hexagonal Ba ferrite becomes remarkable in the firing process when B increases, the amount of B in terms of B ₂ O ₃ is preferably 43.5 mol% or less.

The addition amount of glass powder shall be 10-30 volume% in the raw material of sintered compacts other than glass powder, and glass powder. By setting the content to 10% by volume or more, the sintered body can be sufficiently sintered. By adjusting the volume to 30% by volume or less, the relative permeability or the volume of glass in the sintered body increases, and the amount of decomposition of hexagonal Ba ferrite or alkaline earth metal titanate in the firing process increases. A decrease in relative permittivity can be suppressed.

Glass powder having an average particle size of 0.3 to 2.0 μm is used. In the case of producing a composite sintered body of magnetic material and the dielectric, the use of the alkaline earth metal titanate as a dielectric, when firing the glass powder above, the dielectric during the firing process Decomposition is relatively small and a high dielectric constant can be obtained. Examples of the alkaline earth metal titanates include SrTiO ₃ , BaTiO ₃ , CaTiO ₃ and MgTiO ₃ . SrTiO ₃ is preferable to BaTiO ₃ because of its lower dielectric loss at 100 MHz. SrTiO ₃ is preferable because it has a higher dielectric constant at 100 MHz than CaTiO ₃ and MgTiO ₃ .

The dielectric is preferably composed mainly of SrTiO ₃ , and may be a mixture of BaTiO ₃ , CaTiO _3, and MgTiO ₃ . The mixing may be a mixture of the respective powders, or a raw material having a desired composition ratio synthesized by calcination or the like to form a solid solution. The ratio of SrTiO ₃ in the dielectric material is 90% by mass or more, preferably 95% by mass or more, and particularly preferably 99% by mass or more (the balance being impurities).

The average particle size of the SrTiO ₃ powder is 0.1 to 3.0 μm, more preferably 1.2 to 2.2 μm in order to increase the magnetic permeability and dielectric constant of the composite sintered body layer of the dielectric and magnetic material. It is preferable that

The addition amount of the titanium salt of an alkaline earth metal may vary depending on the relative dielectric constant and relative permeability that is required, but in order to increase the dielectric constant, in the whole raw material powder 5% by volume or more, particularly 10 volume% or more is preferable. Further, since the sinterability decreases as the addition amount of the alkaline earth metal titanate increases, it is preferably 25% by volume or less, particularly preferably 15% by volume or less in the whole raw material powder. Further, if more than 25 vol%, from the remainder of the hexagonal Ba ferrite and glass (Ba, _Ca) 2 needles of SiO ₄ is likely to generate.

If the average particle size of the SrTiO ₃ powder is too fine, the SrTiO ₃ powder is dispersed and distributed throughout the hexagonal Ba ferrite powder, and the sintering of the hexagonal Ba ferrite is inhibited, and the desired magnetic permeability cannot be obtained. become. Furthermore, such can turn so the proportion of the dielectric material to obtain a high relative permeability bur, as a method to increase the relative dielectric constant in such a state, to use a large SrTiO ₃ powder of average particle diameter It is not good. In this case, preferably 1.2~2.2μm The average grain size of the SrTiO ₃ powder during raw material mixed-.

Moreover, it is preferable that Al is not included substantially in a raw material composition. Al may be mixed as an impurity by using alumina media for pulverization after calcining synthesis when producing a magnetic material or a dielectric material. In addition, trace amounts may be contained in iron as a raw material for Y-type hexagonal Ba ferrite. When Al is contained, a composite oxide crystal containing Al (for example, ZnAl ₂ O ₄ crystal) is generated during firing of the composite sintered body layer, and at that time, Y-type hexagonal Ba ferrite or SrTiO ₃ is decomposed. Sometimes. Since this decomposition can be suppressed by reducing the amount of Al, the relative permeability at 100 MHz or the relative dielectric constant at 100 MHz can be increased. Therefore, the amount of Al in the raw material composition or the composite sintered body layer is preferably 0.05% by mass or less, particularly preferably 0.03% by mass or less in terms of Al ₂ O ₃ . Further, by reducing the amount of Al, generation of crystals having a large dielectric loss such as ZnAl ₂ O ₄ crystal can be suppressed, so that the dielectric loss of the composite sintered body layer can be reduced.

In this case , when the composite sintered body layer is measured by X-ray diffraction, the peak intensity of the crystals containing Al contained in the composite sintered body layer is determined from the crystals contained in the composite sintered body layer. It is preferable to be set to 1/100 or less of the peak intensity of the crystal having the highest peak intensity. The crystals containing ZnAl ₂ O ₄ Al other than crystal, Kotogaa contained as impurities is, reacting with Si include BaAl ₂ Si ₂ O ₈ crystal that forms the raw and.

To manufacture an electronic component using such a sintered body, as raw materials, for example, 50 to 85% by volume of Y-type hexagonal Ba ferrite powder, 5 to 25% by volume of SrTiO ₃ powder, and 10 to 30% by mass. % Glass powder is used. Here, the glass powder contains 17.0 % by mass of Si in terms of SiO ₂ , 29.2 % by mass of B in terms of B ₂ O ₃ , 21.5 % by mass in terms of CaO and 19 in terms of BaO. 84 wt%, and Li hints 12.5% by mass Li ₂ O in terms of a softening point of Ru 410 ° C. der.

  To these raw materials, an appropriate organic binder, dispersant, and solvent are added and mixed to prepare a slurry, which is formed into a sheet by a well-known doctor blade method, calendar roll method, rolling method, or press molding method. To form a green sheet having a thickness of 25 μm.

Then, after forming a through hole as desired to the above green sheet and filled with an electrically paste in the through holes.

Subsequently, a conductive paste is applied by screen printing the aforementioned green sheet is dried to form a conductor as a silver-based conductive layer. In addition, the thickness of a silver-type conductor layer is about 2-15 micrometers after baking.

Next, aligned as silver-based conductor layers of green sheets formed with a plurality of conductors Nozomu Tokoro is formed by laminating compression bonding to prepare a laminate. During low oxidizing atmosphere was or oxidizing atmosphere, after binder removal treatment at 200 to 500 ° C., and calcined at 900 to 1200 ° C. in an oxidizing atmosphere or non-oxidizing atmosphere, you produce electronic components.

The electronic component may be further formed an external electrode composed of the terminal electrodes. The terminal electrode is composed of a conductive material mainly composed of silver, such as silver, an alloy of silver and palladium, or an alloy of silver and platinum. Conventionally, a conductive paste produced using such a conductive material is applied to the surface of the laminate. was applied in a predetermined pattern by a known dipping method, screen printing, etc., formed by baking it at high temperatures. The terminal electrode may be further subjected to a plating process such as nickel plating, gold plating, tin plating, or solder plating.

In order to set the area ratio of (Ba, Ca) ₂ SiO ₄ needle crystals in the cross section of the insulator layer in contact with the external electrode to 13.0 to 18.6%, the baking temperature of the external electrode is set to 750 to 810 ° C. It is preferable to do. When the temperature is 750 ° C. or higher, generation of the needle crystal A proceeds. Moreover, although it depends on the area ratio of the needle-shaped crystal A before baking the external electrode, the generation of the needle-shaped crystal A can be suppressed by being 810 ° C. or lower.

Through the steps described above, a high magnetic permeability as described above, and which has a dielectric constant of several hundred attenuation characteristic of the noise in the high frequency band MHz~ several GHz rather high, and high bending strength An electronic component can be obtained.

  An EMI filter component, which is an electronic component manufactured as described above, will be described with reference to FIG. A plurality of composite sintered body layers 1 are laminated, and a conductor layer 2 is formed on the surface of the composite sintered body layer 1. A via-hole conductor 3 that electrically connects the conductor layers 2 separated by the composite sintered body layer 1 is formed through the composite sintered body layer 1.

  Further, an inductor portion 4 and a capacitor portion 5 are formed in a circuit inside the insulating base composed of the plurality of composite sintered body layers 1 by the conductor layer 2 and the via-hole conductor 3 to form a filter circuit.

  The inductor portion 4 is formed in a multi-layered coil shape by the conductor layer 2 and the via-hole conductor 3, but normally, in order to increase the inductance of the circuit, it is necessary to increase the number of turns of the coil. However, when a magnetic material having a high magnetic permeability such as the composite magnetic material of the present embodiment is used, it is possible to obtain a required inductance without increasing the number of turns of the coil. As a result, the number of conductor layers 2 can be reduced, so that the electronic component can be reduced in size and height.

In addition, the chip coil is an electronic component manufactured in the same manner, will be described on the basis Figure 1 (b). In this case , the magnetic sintered body layer 11 which is an insulating layer is produced using, for example, 70 to 90% by volume of Y-type hexagonal Ba ferrite powder and 10 to 30% by weight of glass powder as raw materials . Here, the glass powder contains 17.0 % by mass of Si in terms of SiO ₂ , 29.2 % by mass of B in terms of B ₂ O ₃ , 21.5 % by mass in terms of CaO and 19 in terms of BaO. 84 wt%, and Li hints 12.5% by mass Li ₂ O in terms of a softening point of Ru 410 ° C. der.

  In the chip coil of FIG. 1B, a plurality of magnetic sintered body layers 11 are laminated, and a silver-based conductor layer 12 is formed on the surface of the magnetic sintered body layer 11. A silver-based via-hole conductor 13 that electrically connects the silver-based conductor layers 12 separated by the magnetic sintered body layer 11 is formed through the magnetic sintered body 11. An inductor portion 14 is formed in the inside of the insulating base composed of the plurality of composite sintered body layers 1 by these conductor layers 12 and via-hole conductors 3 in terms of circuit.

  Such a chip coil can be used as a filter in combination with a capacitive component such as a chip capacitor.

  Examples of the present invention will be described below.

First, Fe ₂ O ₃ powder, CoO powder, CuO powder, ZnO powder and BaCO ₃ powder are used as starting materials, and the composition ratio is Ba _2.05 Zn _1.4 Cu _0.5 Co _0.05 Fe ₁₂ O _22. Formulated as follows. IPA as an organic solvent and steel balls as media are added to the prepared powder, wet-mixed, dried, calcined at 950 ° C. in the atmosphere, and further pulverized for 72 hours in a wet manner. Y-type with an average particle size of 1 μm A magnetic material having hexagonal Ba ferrite as the main crystal (relative permittivity at 100 MHz: 25, relative permeability at 100 MHz: 15) was obtained.

In addition, nickel zinc spinel ferrite (Ni, Zn) Fe ₂ O ₄ ) powder was prepared as a magnetic material used in the comparative example.

Next, SrTiO ₃ powder (average particle diameter: 0.9 μm, relative permittivity at 100 MHz: 180, relative permeability at 100 MHz: 1.0) was prepared as a dielectric material.

Next, the glass powders listed in Table 1 were prepared. The average particle diameter of the glass powder was 0.6 μm. The above powders were wet mixed using IPA as the organic solvent and steel balls as the media so as to have the mixing ratio shown in Table 1, dried, and then the relative permeability, relative permittivity, dielectric loss, bulk density and water absorption. It was press-molded so that the rate could be evaluated, and fired in the atmosphere at the temperature shown in Table 1 for 2 hours to obtain a sintered body. Sample No. No. 19 has a volume ratio of Y-type hexagonal Ba ferrite, SrTiO ₃ and glass of 60:15:25.

Further, the mixing was performed by measuring the density of each powder in advance and converting the volume ratio into the mass ratio from the density. Note that the density of the Y-type hexagonal Ba ferrite was 5.4 g / cm ³ , the density of SrTiO ₃ was 5.1 g / cm ³ , and the density of the glass used for the sample No 1 was 3.0 g / cm ³ . .

  With respect to the magnetic sintered body thus obtained or a composite sintered body of a dielectric and a magnetic body, the relative magnetic permeability, the bending strength and the water absorption were evaluated. About the relative magnetic permeability, the value in 100 MHz and 1 GHz was measured. The value of the relative permeability measured here was consistent with the evaluation result of the filter characteristics of the next manufactured child component evaluation. The relative magnetic permeability was measured by the S parameter method using a coaxial tube.

  Thereafter, among the prepared samples, those shown in Table 2 were coated with a silver-based conductor paste and baked to form external electrodes, and the peel strength of the external electrodes was measured. Sample No. 21 and 22 are sample Nos. 12 is a sample produced with the same composition and firing temperature of the insulator layer as Sample No. 12 in Table 2. 12 is a sample in which the baking temperature of the external electrode is changed.

Observation of the needle-like crystal of (Ba, Ca) ₂ SiO ₄ in the cross section of the sintered body is performed by mirror polishing of the cross section of the sintered body (polishing is performed using a # 6000 diamond paste). And the cross section was observed using a reflection electron microscope. The range of the field of view of 400 μm × 400 μm was observed at an arbitrary 10 locations at 300 times, and the average number of acicular crystals present in the field of view was determined to be no acicular crystals. The acicular crystal referred to here is a crystal having an aspect ratio of 2 or more, and the aspect ratio is the longest line segment that bisects the cross-sectional area of one crystal grain in the cross section. It is the major axis / minor axis when the major axis of the crystal grain in the cross section is taken and the shortest is the minor axis of the crystal grain in the cross section.

The observation of the needle-like crystal of (Ba, Ca) ₂ SiO ₄ in the cross section of the insulator layer at the portion where the external electrode was baked was as described above with respect to the cross section of the portion polished by 20 μm from the surface where the external electrode was baked. Performed by the method. In addition, the insulating layer in the portion where the external electrode was baked had no difference in the state of formation of the needle-like crystals before the baking of the external electrode at a location 100 μm or more away from the external electrode.

About what a needle-like crystal is observed, it measured by imaging | photography arbitrary one of what was mentioned above 10 places observation, and image-processing. In the reflection electron composition image shooting, the acceleration voltage was set to 15 kV, a magnified image of 5000 times was shot, and the area occupied by the needle-like crystal of (Ba, Ca) ₂ SiO ₄ was measured in the shot image, The aspect ratio of 10 arbitrarily selected (Ba, Ca) ₂ SiO ₄ needle crystals was measured, and the average was calculated. In the sintered body containing SrTiO ₃ as a dielectric, Sr is also present in the vicinity of the needle crystal A, but the amount of Sr is very small and cannot be identified by X-ray diffraction as being present in the crystal of the needle crystal A. It was.

Further, X-ray diffraction was performed, and the result was subjected to Rietveld analysis, and the types of crystals contained in the composite sintered body layer and their ratio to the whole contained crystals were obtained. In all samples, ferrite was the main crystal occupying 50% by mass or more, and crystals other than ferrite, SrTiO ₃ and (Ba, Ca) ₂ SiO ₄ were 10% by mass or less. Further, in the ferrite column of Table 1, 10% by mass or more of the detected ferrite is shown in descending order.

FIG. It is a reflection electron microscope image of the cross section of 19 sintered compacts, and the acicular crystal | crystallization A was observed. The acicular crystal A was Ba _1.55 Ca _0.55 SiO ₄ from the results of element identification and X-ray diffraction.

The peel strength of the external electrode is perpendicular to the center of one 1.6 mm side formed on the side of 1.6 mm x 0.5 mm of a laminate having an area of 1.6 mm x 0.8 mm and a thickness of 0.5 mm. Solder the external electrode with a width of 0.2 mm reaching the other 1.6 mm side to the electrode formed on the plastic substrate and press the upper end of the 1.6 mm × 0.8 mm surface to It was determined by measuring the peel strength.

Sample No. 1 of the present invention containing at least one of a Ferroc planar type Ba ferrite and a Li—Zn—Cu—Fe—O spinel type crystal as a main crystal and a needle-like crystal of (Ba, Ca) ₂ SiO ₄ . 1,2,5,8,11～16 and 19, the bending strength was Tsu Der more than 154MPa.

In particular, the sample No. 1 in which the ratio of the area of the acicular crystal in the cross section of the sintered body is 10 to 15%. 12 to 16, the bending strength was Tsu Der more than 166MPa.

In addition, sample No. 1 in which the average aspect ratio of the acicular crystals in the cross section of the sintered body is 10-15. 13 and 14, the bending strength was Tsu der least 181MPa.

On the other hand, sample no. 3, 4, 6, 7, 9, 10, 17, 18, and 20 did not contain needle-like crystals of (Ba, Ca) ₂ SiO ₄ and had a bending strength of 146 MPa or less.

Sample No. In 3 and 7, with decomposition Y-type hexagonal Ba ferrite, relative permeability was lower.

FIG. 3 is a CuKα characteristic X-ray diffraction diagram of Samples A and B which are sintered bodies of the present invention and Sample C which is a sintered body outside the scope of the present invention. Sample A is Sample No. 19. Samples B and C were sample Nos. 1 except that the volume ratio of Y-type hexagonal Ba ferrite, SrTiO ₃ and glass was set to 70:15:15 and 85: 15: 0, respectively. 19 is a sintered body produced in the same manner as in FIG.

In Sample C, and the sintering step, a portion of the Y-type hexagonal Ba ferrite is decomposed, Zinc spinel ferrite (ZnFe ₂ O ₄₎ is generated, (Ba, _Ca) precipitation of 2 SiO ₄ crystal It was such observed bought.

In Sample B, a portion of the Y-type hexagonal Ba ferrite reacts with the glass Li-Zn-Cu-Fe- O spinel crystals are generated, Y-type hexagonal Ba ferrite and Li-Zn-Cu-Fe Many -O spinel crystals were observed . Also , Ba _1.55 Ca _0.
55 SiO ₄ crystals were also observed. This was a needle-like crystal when the cross section was observed with a reflection electron microscope.

In sample A, the Y-type hexagonal Ba ferrite is almost a Li—Zn—Cu—Fe—O spinel crystal, and the ferrite other than the Li—Zn—Cu—Fe—O spinel crystal is a sintered body. only it was not observed 10 mass% or less in. Further, (Ba, _Ca) acicular crystals of 2 SiO ₄ had a lot precipitate than sample B.

  Note that the observed first peak of the Li—Zn—Cu—Fe—O spinel crystal was 2θ = 35.51 ° to 35.55 °. The molar ratio of Zn: Cu: Fe element was 5: 2: 26.

Among the samples in which the external electrodes are formed, sample No. 1 in which needle-like crystals of (Ba, Ca) ₂ SiO ₄ are present. In Nos. 1, 8, 11, 12, 15, 16, 21, and 22, sample Nos. With no acicular crystals exist. Peel strength of the external electrode was high than 4. In particular, sample No. 1 in which the ratio of the area of the needle-shaped crystal of (Ba, Ca) ₂ SiO ₄ occupying the cross section of the sintered body at a location 20 μm from the external electrode is 13.0 to 18.6%. In 1,8,12,15,21 and 22, peel strength of the electrode was Tsu or more and high 0.71N.

1, 21 ... Composite sintered body layer of magnetic body and dielectric 11, 31 ... Magnetic sintered body layer 2, 12, 22, 32 ... Conductor layer 3, 13, 23, 33 ...・ Via hole conductors 4, 15, 24, 35... Inductor portion 5, 25... Capacitor portion 26, 36.

Claims (9)

A magnetic sintered body comprising at least one of a Ferroc planar type Ba ferrite and a Li—Zn—Cu—Fe—O spinel type crystal as a main crystal, and containing needle-like crystals of (Ba, Ca) ₂ SiO ₄ , The ratio of the area of the acicular crystal in the cross section of the magnetic sintered body is 10 to 15%, the bending strength is 154 MPa or more, and the relative permeability at a frequency of 1 GHz is 3.3 or more. Magnetic sintered body. 2. The magnetic sintered body according to claim 1, wherein an average aspect ratio of the acicular crystals in a cross section of the magnetic sintered body is 10 to 15. Composite sintered body of magnetic material and a dielectric, characterized in that it comprises a dielectric magnetic sintered body and the alkaline earth metal titanate according to claim 1 or 2. In or on the insulating base made of a magnetic sintered body according to claim 1 or 2, electronic components, characterized in that the inductor circuit is formed. The external electrode which has silver as a main component is baked on the surface of the electronic component of Claim 4 , The area of the said acicular crystal which occupies the cross section of the magnetic sintered compact of the said external electrode vicinity is 13.0-18 Electronic parts characterized by being 6%. An electronic component, wherein a capacitor circuit and an inductor circuit are formed inside or on the surface of an insulating substrate made of a composite sintered body of a magnetic body and a dielectric body according to claim 3 . The external electrode which has silver as a main component is baked on the surface of the electronic component of Claim 6 , The area of the said acicular crystal which occupies the cross section of the magnetic sintered compact of the said external electrode vicinity is 13.0-18 Electronic parts characterized by being 6%. A method of manufacturing a magnetic sintered body according to claim 1, hexagonal Ba ferrite powder and, Li ₂ O in terms of 5.0 mol% or more of Li, in a total amount of BaO terms and terms of CaO 15.4 A glass powder containing 17.0 to 24.1 mol% of Si and ₂ mol% of Ba and Ca in terms of SiO ₂ and having a softening point of 400 to 470 ° C., the hexagonal Ba ferrite powder and the glass powder A method for producing a magnetic sintered body, comprising mixing the glass powder so as to be 10 to 30% by volume with respect to the total amount, and firing the molded body. A method of manufacturing a composite sintered body of magnetic material and the dielectric of claim 3, the hexagonal Ba ferrite powder, and titanate powder of an alkaline earth metal, 5.0 Li 2 _O in terms It comprises mol% or more of Li, BaO translation and CaO in total conversion 15.4 mol% of Ba and Ca, and 17.0 to 24.1 mol% of Si in terms of SiO _2, 400 softening point 470 ° C. glass powder is mixed with the hexagonal Ba ferrite powder, the alkaline earth metal titanate powder, and the glass powder so that the glass powder is 10 to 30% by volume. A method for producing a composite sintered body of a magnetic body and a dielectric, characterized by firing the molded body.