JP4689961B2 - Conductive paste and ceramic electronic component manufacturing method - Google Patents

Description

  The present invention relates to a conductive paste for forming electrodes, wirings, and the like in ceramic electronic components and the like, and a method for manufacturing a ceramic electronic component using the same.

  Usually, this type of conductive paste is composed of a noble metal or base metal component (conductive component), an organic solvent in which the metal component is dispersed, and a resin component for viscosity adjustment. For example, when manufacturing a ceramic electronic component having an internal electrode, the conductive paste is applied to the surface of the green sheet in a predetermined pattern to form an electrode paste film, and the green sheet and the conductive paste film are integrated. The internal electrodes are simultaneously formed on the ceramic substrate by firing.

  By the way, in order to increase the density or super multilayer of multilayer ceramic electronic components, it is required to make the electrode film thinner. Conventionally, however, spherical metal fine particles have been used for the above metal component, so that there has been a limit to the reduction in the thickness of the electrode film. In other words, the film thickness formed by the application of the conductive paste mainly depends on the metal component having a large particle size in the paste component, but in the current metal particle generation technology, a metal having a predetermined spherical diameter or less is used. It is difficult to produce fine particles inexpensively and in large quantities. On the other hand, since it is necessary to use metal powder for paste with a predetermined spherical particle size as an industrial material at the manufacturing site, the film thickness cannot be reduced below the spherical diameter of the metal component in the production process of ceramic electronic parts and the like. It was causing the problem. For example, as disclosed in Japanese Patent Application Laid-Open No. 10-308118 of Patent Document 1, a general silver powder for electrode metal having an average particle diameter of about 1 μm is used. It was difficult to make the film thickness 1 μm or less.

  Next, in addition to the problem of thinning factor that depends on the paste metal component described above, there is a problem of heat shrinkage of the metal film in the firing process especially in the manufacturing process of ceramic electronic parts. Detailed description.

  First, in green sheet molding, ceramic powder is kneaded with an organic binder and a solvent to form a slurry, and the slurry is formed into a sheet to form a green sheet. Next, when the green sheet is fired, the organic component is removed, and the green sheet is changed into a ceramic substrate while contracting. At the same time, the conductive paste film also changes to an electrode film while shrinking due to removal of organic components. If there is a large difference in the firing shrinkage rate between the green sheet and the conductive paste film, there is a risk that the electrode film is peeled off from the ceramic substrate, or the electrode film is locally spheroidized by firing and the electrode film is interrupted.

  In general, since the metal fine particles have a relatively low melting point, they are melt-bonded to each other deep in the surface of the particles by firing, and the film made of the metal fine particles changes into a dense metal film while greatly contracting. On the other hand, since ceramic particles have a higher melting point than metal particles, they only cause surface melting even when fired, and their shrinkage rate is smaller than that of metal particles even when sintered together. For this reason, the firing shrinkage rate of the conductive paste film is generally larger than the firing shrinkage rate of the green sheet, the electrode film is easily peeled off from the ceramic substrate, and the electrode film is likely to be discontinuous.

  Therefore, it is necessary to make the firing shrinkage rates of the green sheet and the conductive paste film as close as possible. As one of the methods, a technique of mixing a dielectric powder with a conductive paste has been developed. This technique is disclosed as an example of the prior art in Japanese Patent Application Laid-Open No. 2001-291634. The composition of the dielectric powder is substantially the same as that of the main component of the ceramic constituting the green sheet, and this added dielectric powder is called a co-material.

  When the dielectric powder is mixed in the conductive paste, the dielectric fine particles are interposed between the metal fine particles in the conductive paste film. When this conductive paste film is baked, the dielectric fine particles inhibit the fusion bond between the metal fine particles, so that the effect of suppressing the sintering of the metal fine particles appears. The action of suppressing the sintering of the metal fine particles immediately produces an effect of reducing the contraction rate of the electrode film. As described above, when the dielectric powder is added to the conductive paste, the sintering suppression effect of the conductive paste film, that is, the shrinkage suppression effect is exhibited.

The dielectric powder is set to the same composition as the ceramic main component of the green sheet. This is because the firing shrinkage rate of the conductive paste film is as close as possible to the firing shrinkage rate of the green sheet. For example, when the ceramic main component of the green sheet is BaTiO ₃ , BaTiO ₃ powder is similarly selected as the dielectric powder of the conductive paste. By the addition of such dielectric powder, the conductive paste film approximates the composition of the green sheet, and the firing shrinkage characteristics of the conductive paste film and the green sheet approximate to prevent peeling of the electrode film. .

  As described above, when the dielectric powder is added to the conductive paste, the firing shrinkage rate of the conductive paste film is surely lowered. According to recent research, the reduction in firing shrinkage due to the forced addition of dielectric powder is effectively manifested at higher firing temperatures. However, even if the dielectric powder is added, a certain degree of firing shrinkage always occurs, and it is impossible to completely prevent the firing shrinkage only by adding the dielectric powder. In particular, it has been understood that when the firing temperature is low, the firing shrinkage rate is not sufficiently reduced only by the addition of dielectric powder. This means that even if dielectric powder is added, it is not a countermeasure for suppressing shrinkage in low-temperature firing even if it is a countermeasure for high-temperature firing.

  Moreover, even if it says high temperature baking, it is actually baked by passing through various temperature processes until reaching a high temperature. For example, even when firing at 1300 ° C., the temperature rises from room temperature to reach 1300 ° C., so that it is already fired even at an intermediate temperature between room temperature and 1300 ° C. before being fired for a long time at 1300 ° C. . Even if there is a shrinkage suppressing effect at 1300 ° C., if there is no shrinkage suppressing effect even when firing at an intermediate temperature of 500 ° C. or 1000 ° C. (low temperature firing), when subjected to high shrinkage at the low temperature firing stage, Inhibition of shrinkage is considered to be half the effect.

  The shrinkage phenomenon due to the low firing temperature must be determined for another reason. When the firing temperature is low, melting of the metal fine particles is suppressed, and it is considered that the surface of the metal fine particles is melted in the same manner as the ceramic particles, and the metal fine particles are partially melt-bonded between the surfaces. In the low-temperature firing, in the conductive paste film, the metal fine particles separated through the small gaps are brought close to each other by the firing and bonded at the surfaces, and shrinkage occurs due to the absence of the gap. Preventing shrinkage due to the disappearance of minute gaps results in suppression of shrinkage due to low-temperature firing.

  It is clear that shrinkage due to the disappearance of such a minute gap cannot be prevented by the presence of dielectric fine particles. In other words, if the size of the gap is equal to or larger than the particle size of the dielectric fine particles, it is possible to prevent the metal fine particles from being sintered by interposing the dielectric fine particles. However, when the size of the gap is smaller than the particle size of the dielectric fine particles, it becomes impossible to interpose the dielectric fine particles in the gap itself, and other means must be taken to prevent shrinkage.

  In addition, research is being conducted to reduce the particle size of the dielectric fine particles. In this method, the particle size of the dielectric fine particles is reduced to fill the gaps between the metal fine particles with the dielectric fine particles. However, when the particle size of the metal fine particles becomes small, the particle size of the dielectric fine particles for preventing sintering tends to be inevitably small. At present, nanosize is required as the particle size, and for example, development of dielectric ultrafine particles is required for ultrafine metal particles.

  FIG. 6 is a schematic diagram illustrating the relationship between the metal fine particle diameter D and the three pocket diameter d. In order to ensure the conductivity of the electrode film, it is required to set the density of the electrode film large. The electrode film density is maximized when the metal fine particles 2 are closely packed, and in this close-packed structure, the three pockets 4 are formed by the three metal fine particles 2 that are in contact with each other.

  The three pocket diameter d is defined by the maximum diameter of the particles that can enter the three pocket 4. If the dielectric fine particles 6 can be filled in the three pockets 4, it should be possible to maximize the electrode film density and suppress the sintering. In other words, it is necessary to design the diameter of the dielectric fine particles 6 to be not more than the three pocket diameter d. The relationship between the metal fine particle diameter D and the three pocket diameter d is shown in Table 1.

<Table 1> Relationship between metal fine particle diameter D and three pocket diameter d <Number><Metal fine particle diameter D><Three pocket diameter d>
No. 1 0.6μm 0.0929μm
No. 2 0.4μm 0.0618μm
No. 3 0.2μm 0.0309μm
No. 4 0.1μm 0.0154μm

An example in which Ni fine particles are used as the metal fine particles 2 and BaTiO ₃ fine particles are used as the dielectric fine particles will be described. In the conductive paste conventionally used, 0.1 μm BaTiO ₃ fine particles are mixed with 0.6 μm Ni fine particles. In this case, since the three pocket diameter d is 0.0929 μm, the 0.1 μm BaTiO ₃ fine particles are almost well filled into the three pockets.

On the other hand, as described above, in order to realize high density or super multi-layering of multilayer ceramic electronic parts, there is a demand for further thinning of the electrode film. Therefore, although it is in the experimental research stage, for example, it has been attempted to use Ni fine particles having a diameter D of 0.4 μm or 0.2 μm. At this time, the three pocket diameter d is as extremely small as 0.0618 μm or 0.0309 μm. In order to fill the three pockets 4 with dielectric fine particles, BaTiO ₃ fine particles having a diameter of 0.06 μm or 0.03 μm are required. Such dielectric fine particles are called nanometer-sized BaTiO ₃ ultrafine particles, which are still under study but are still difficult to put into practical use.

  As described above, when using a conductive paste in which metal fine particles and dielectric fine particles are mixed, if the diameter of the metal fine particles is reduced, the three pocket diameter is drastically reduced, and there is a limit to the diameter of the usable dielectric fine particles. There was a weak point to do. Thus, when the metal fine particles are close to each other, dielectric fine particles that fill the small gap cannot be expected at present.

Also, the firing temperature varies depending on the type of ceramic electronic component, and it is necessary to suppress shrinkage in both high temperature firing and low temperature firing. Furthermore, as described above, even if high-temperature firing is performed, a temperature history from low temperature to high temperature is passed. Therefore, not only measures against high temperature shrinkage but also measures against low temperature shrinkage need to be taken at the same time. In particular, at the manufacturing site, in order to save energy and extend the life of the firing furnace, the temperature for firing ceramics tends to gradually decrease. Therefore, it is extremely important to solve the prevention of shrinkage of minute gaps that cannot be filled with current dielectric fine particles.
JP-A-10-308118 JP 2001-291634 A

  As described above, a first object of the present invention is to provide a conductive paste that can realize thinning of an electrode film suitable for high density or super multi-layering of ceramic electronic parts and the like. In addition to this, the second object is to provide a conductive paste capable of suppressing shrinkage in high-temperature firing by adding dielectric powder, and also realizing shrinkage suppression in low-temperature firing by supplementing and adding a new substance. It is what. It is another object of the present invention to provide a conductive paste that can handle both high-temperature firing and low-temperature firing with a single conductive paste, and that provides an optimum sintering suppression curve even for firing through any temperature history. . Finally, the present invention provides a novel method for manufacturing a ceramic electronic component in which a conductive paste film is formed on a green sheet using such a conductive paste, and an electrode film is formed on a ceramic substrate by firing. With the goal.

  This invention is made | formed in order to solve the said subject, and the 1st form of this invention is the electrically conductive paste which contains at least the scaly metal powder containing dielectric material powder as an electroconductive component.

  The second aspect of the present invention is a conductive paste comprising at least a scale-like metal powder containing a dielectric precursor, an organic solvent for uniformly dispersing the scale-like metal powder, and a viscosity adjusting resin. .

  The 3rd form of this invention is an electroconductive paste in which the said scale-like metal powder consists of a base metal atom.

  A fourth aspect of the present invention is a conductive paste in which the scaly metal powder is composed of noble metal atoms.

  A fifth aspect of the present invention is a conductive paste in which the dielectric precursor is an organometallic resinate.

  The 6th form of this invention is an electroconductive paste whose content of the said dielectric material powder is 0.1-30 mass% with respect to the whole quantity of the said scale-like metal powder.

  A seventh aspect of the present invention is a conductive paste in which the total metal content of the dielectric precursor is 0.1 to 10% by mass with respect to the total amount of the scaly metal powder.

  An eighth aspect of the present invention is a conductive paste configured such that the composition of the dielectric powder corresponds to the main component of the dielectric forming the green sheet.

  A ninth aspect of the present invention is a conductive paste configured such that the composition of the dielectric precursor corresponds to the main component of the dielectric forming the green sheet.

  In a tenth aspect of the present invention, a conductive paste film is formed on a green sheet using the conductive paste, and the green sheet and the conductive paste film are integrally baked to remove organic components. This is a method for manufacturing a ceramic electronic component in which an electrode film having a desired pattern is formed on a ceramic substrate.

  An eleventh aspect of the present invention is a method for manufacturing a ceramic electronic component, wherein the ceramic electronic component is a ceramic circuit board, a ceramic capacitor, a ceramic inductor, a ceramic piezoelectric element, or a ceramic actuator.

  The scaly metal powder in the present invention is obtained by processing spherical metal particles into a scaly powder using a scaly processing machine such as a ball mill, a stamp mill, a sand mill, or a vibration mill. For example, flaky nickel obtained by processing nickel Ni metal particles having an average particle diameter of 0.4 to 0.5 μm into a flat shape having a thickness of 0.1 μm or less by a scaly machine.

  According to the conductive paste of the first or second form of the present invention, since the scaly metal powder is included as the conductive component, the scaly metals overlap each other when the paste is applied to form a coating film. An electrode film, a wiring film, etc. thinner than the metal sphere diameter of the paste containing spherical metal powder can be obtained. For example, in a conventional paste using nickel Ni metal particles having an average particle diameter of 0.4 to 0.5 μm, an electrode film thinner than the average particle diameter cannot be formed in the coating process, but in this embodiment, the thickness is 0.1 By using a flat scaled nickel having a thickness of not more than μm, a thin nickel metal film having a thickness of about 0.3 μm can be formed, and high density and super multilayering of ceramic electronic parts can be realized. In addition, the scale-like nickel powder can be obtained simply by scaling the spherical nickel Ni metal particles, which is a prefabricated material, so that a thin-film metal film can be formed at a low cost and the cost of the super multilayer ceramic electronic component can be reduced. Contribute.

  In particular, the first form is a mixture of scaly metal powder and dielectric powder, and this dielectric powder is composed of dielectric fine particles, preferably the same as the ceramic substrate obtained by firing the green sheet. Use ceramic fine particles. By adding the dielectric powder to the paste, the dielectric fine particles are interposed between the fine metal pieces of the scaly metal powder by kneading the paste. Therefore, the dielectric fine particles become fine metal during firing of the conductive paste film. Sintering between pieces is suppressed, and the shrinkage ratio due to firing is reduced.

The second form is a mixture of scaly metal powder and a dielectric precursor, and is characterized in that it contains a dielectric precursor. Concerning the shrinkage problem during firing described above, filling the dielectric fine particles into large gaps between the metal components (conductive components) can prevent firing shrinkage between the metal components, but small gaps between the metal components not filled with the dielectric fine particles. On the other hand, it has succeeded in preventing the firing shrinkage between the metal components by filling the molecular dielectric precursor. The dielectric precursor is a compound that forms a dielectric (ceramics) when fired, and is selected from various metal compounds such as organometallic compounds, organometallic complexes, and organometallic resinates. The metal of these substances means a metal element constituting a dielectric. For example, when you select BaTiO ₃ as a dielectric, Ba and Ti is the metal, and the precursor compound of BaTiO _3, means a compound which forms a BaTiO ₃ by baking. For example, when titanium octylate and barium octylate are baked in an oxidizing atmosphere, organic substances are removed by combustion, and finally a dielectric of BaTiO ₃ is formed. In the conductive paste state, since the dielectric precursor is molecular, any small gaps between the metal fine particles are densely filled with the dielectric precursor. A minute nano-sized three pocket formed by nano-sized metal ultrafine particles can be filled with a dielectric precursor. When the conductive paste film is baked, the dielectric precursor becomes a dielectric in a filled state, and a dielectric can be formed in a gap of an arbitrary shape. Therefore, in particular, by adding dielectric fine particles, it is possible to give an optimum sintering suppression curve for a wide range of temperature history from low temperature to high temperature received during firing, and the conductive paste film is in the process of firing temperature history. The effect of preventing the shrinkage as much as possible is obtained. In addition, even when the firing temperature varies depending on the type of electronic component, a universal conductive paste that can be used in a wide range of firing temperatures from low temperature firing to high temperature firing can be configured.

  In addition, according to the second embodiment, it is possible to reduce the thickness of the electrode film by using the scaly metal powder, and to obtain an optimum sintering suppression curve for a wide range of temperature history from the low temperature to the high temperature received during the firing. A universal conductive paste that can be applied and can be used in a wide range of firing temperatures can be provided. In addition, by adding an appropriate amount of resin for adjusting the viscosity, the viscosity of the conductive paste can be freely adjusted, and it is possible to respond freely to market demands from high viscosity paste to low paste.

  In the third embodiment of the present invention, by using base metal atoms such as copper and nickel as the raw material in the scale-like metal powder, for example, a conductive paste suitable for thinning internal electrodes and external electrodes of ceramic electronic components Can be provided.

  Further, in the fourth embodiment of the present invention, by using noble metal atoms such as gold, silver, platinum, palladium as the material for the scale-like metal powder, for example, thinning of internal electrodes and external electrodes of ceramic electronic components A conductive paste suitable for the above can be provided.

  The present invention also includes the use of an alloy such as silver / palladium.

In the fifth embodiment of the present invention, an organometallic resinate is optimal as the dielectric precursor contained in the conductive paste. The organometallic resinate is an organometallic resinate, and a higher fatty acid metal salt is a representative substance. Examples of organometallic resinates include naphthenates, octylates, stearates, oleates, palmitates, laurates, myristates, benzoates, paratoylates, n-decanoates, metals Alkoxides, metal acetylacetonates and the like are used. By firing these organometallic resinates, any of BaTiO ₃ , Ba (Ti / Zr) O ₃ , (Ba / Ca) (Ti / Zr) O ₃ , SrTiO ₃ , Pb (Ti / Zr) O _3, etc. A dielectric having a composition can be easily formed.

  According to the sixth aspect of the present invention, since the content of the dielectric powder is added in an amount of 0.1 to 30% by mass with respect to the total amount of the scaly metal powder, the shrinkage rate of firing is reduced even in high-temperature firing, which is good An electrode film having excellent conductivity can be formed. If it is less than 0.1% by mass, the high-temperature sintering is not sufficiently suppressed, and if it exceeds 30% by mass, the conductive properties of the electrode film are affected. By adjusting the range of the scale-like metal powder in the range of 0.1 to 30% by mass, an electrode film having advanced characteristics required for ceramic electronic parts can be formed. Just by adding an appropriate amount of dielectric powder to the metal component for electrode formation as in this embodiment, an electrode film having a small firing shrinkage ratio and high density and high surface smoothness can be formed even at high temperature firing.

  According to the seventh aspect of the present invention, the metal content of the dielectric precursor is added in an amount of 0.1 to 10% by mass with respect to the total amount of the scaly metal powder, so the firing shrinkage rate is reduced even at low temperature firing. In addition, an electrode film having good conductivity can be formed. The dielectric precursor is usually a metal oxide, and when it is adjusted to a range of 0.1 to 10% by mass of the scaly metal powder, a high-level electrode film required for ceramic electronic parts can be formed. If the amount is less than 0.1% by mass, the low-temperature sintering is not sufficiently suppressed. If the amount is more than 10% by mass, the conductive performance of the electrode film is affected. Just by adding a small amount of a dielectric precursor to the electrode-forming metal component as in this embodiment, a dense electrode film can be formed with a low firing shrinkage rate even at low temperature firing.

  According to the eighth or ninth aspect of the present invention, since the composition of the dielectric powder or the dielectric precursor is configured to correspond to the main component of the dielectric forming the green sheet, the conductive paste film It is possible to match the firing shrinkage ratio of the green sheet with that of the green sheet as much as possible. The green sheet is a material formed into a sheet shape by kneading dielectric powder, resin, and other components, and changes to a ceramic substrate made of a dielectric material by firing. The dielectric precursor becomes a dielectric upon firing, and the dielectric powder does not change even when fired, and remains a dielectric. Since these dielectric compositions are composed of the same composition as the main component of the dielectric forming the green sheet, the firing shrinkage rate of the electrode film can be approximated to the firing shrinkage rate of the green sheet. Therefore, even if baked, the electrode film does not peel from the green sheet (ceramic substrate), and a stable electrode film can be excellently formed. In addition, since the molecular dielectric precursor does not interfere with the behavior of the metal components during firing, the metal components can be reliably sintered together, and there is an advantage that a stable and uniform electrode film can be formed even at low temperature firing.

  According to the 10th form of this invention, the ceramic electronic component provided with the electrode thinned can be formed by forming a conductive paste film | membrane using the said conductive paste on a green sheet.

  In particular, the electrode film is formed using the conductive paste of the present invention to which the dielectric powder and the dielectric precursor shown in the first or second embodiment are added, so that high temperature firing or low temperature firing can be performed. By any firing, it is possible to form a good quality electrode thin film on a ceramic electronic component. In this case, the firing temperature is determined by the temperature at which the ceramic sintering of the green sheet can be performed, and it is possible to provide an epoch-making method for manufacturing a ceramic electronic component that can cope with the selection of the sintering temperature with a single conductive paste. Even if the electrode film formed by firing is an ultra-thin film, the conductivity is extremely high, and the firing shrinkage rate of the electrode film and the green sheet is almost the same, so an excessive stress acts between the electrode film and the ceramic substrate. Therefore, a long-life ceramic electronic component having high density and high conductivity can be provided.

  The eleventh aspect of the present invention provides a method for manufacturing a ceramic electronic component of a ceramic circuit board, a ceramic capacitor, a ceramic inductor, a ceramic piezoelectric element, or a ceramic actuator using the conductive paste of the present invention. In addition, the present invention can be used in a method of manufacturing a ceramic electronic component that can cope with the ceramicization of many other electronic components, and the conductive paste in the present invention can be applied to internal electrodes and external electrodes of ceramic electronic components. It is also applicable as a wiring forming material on an insulating substrate. And, by making the electrode film of the present invention thinner, it is possible to realize super-multilayering and super-high density of ceramic electronic parts, which can contribute to further miniaturization of electronic devices and personal computers, particularly mobile phones.

  Hereinafter, embodiments of a method for producing a conductive paste and a ceramic electronic component according to the present invention will be described in detail with reference to the accompanying drawings.

  FIG. 1 is a schematic explanatory view of a conductive paste 1 according to the present invention. A conductive paste 1 is prepared in the container 3. Metal powder made of scale-like fine metal particles 2, dielectric powder made of dielectric fine particles 6, dielectric precursor 8 having the same composition as the dielectric powder, and these materials 2, 6, 8 are uniformly dispersed. The conductive paste 1 is formed by kneading the organic solvent 10 and the resin 12 for adjusting the viscosity. The conductive paste 1 is configured so that the above-mentioned five kinds of substances are uniformly mixed and stirred to have an appropriate viscosity.

  The scaly metal fine particle 2 may be at least one kind or two kinds of single noble metal fine particles made of Ir, Os, Rh, Pd, Ru, Au, Pt, Ag, alloy noble metal fine particles, or base metal fine particles made of other transition metals. But it ’s okay. In recent years, from the viewpoint of cost reduction of semiconductors and electronic materials and cost stabilization, conversion from noble metal materials to base metal materials has been attempted, and Ni, Cu, and the like are being used as electrode metal materials instead of noble metals. Therefore, the cost of the conductive paste 1 can be greatly reduced by using base metal fine particles such as Cu fine particles and Ni fine particles in the present invention. Moreover, the market price of Cu and Ni is more stable than that of precious metals, and can contribute to price stabilization of the conductive paste 1.

  As shown in FIG. 2, the flaky metal fine particles 2 used in the present invention are formed into flaky powder using a conventional spheroidizing machine such as a ball mill, a stamp mill, a sand mill, or a vibration mill. It has been processed. In this embodiment, nickel Ni spherical metal fine particles having an average particle diameter of 0.4 to 0.5 μm are pulverized or placed by a scaly machine, so that the thickness T is 0.1 μm or less and the plane size is long. Scale-like nickel fine particles processed into a flat shape with D of 1 μm or less are used. In the present invention, the plane size length D may be fine metal particles of the order of μm or ultrafine metal particles of the order of nm.

  In particular, since the molecular dielectric precursor 8 is used in the present invention, the molecular dielectric precursor is filled even in the micro-gaps / ultra-gaps formed by nano-sized flaky metal ultrafine particles. Can do. When scale-like metal ultrafine particles of 0.1 μm or less are used for the conductive paste 1, an electrode film with a nano-size film thickness can be formed, and the structure is such that the minute gaps of the scale-like metal ultrafine particles are filled with a dielectric. It can realize ultra-thin film and contribute to high density and miniaturization of ceramic electronic parts.

In the present embodiment, a dielectric powder composed of dielectric fine particles 6 is added to the conductive paste 1. The dielectric fine particles 6 are fine ceramic fine particles and are made of the same material as the ceramic substrate formed by firing the green sheet. For example, if the main component of the ceramic substrate is BaTiO ₃ , BaTiO ₃ ceramic fine particles are selected as the dielectric fine particles 6. From this point of view, the dielectric fine particles 6 are BaTiO ₃ , Ba (Ti / Zr) O ₃ , (Ba / Ca) (Ti / Zr) O ₃ , SrTiO ₃ , (Ba / Sr) TiO ₃ , Pb (Ti / Zr). ) O ₃ and other dielectrics.

  When the dielectric fine particles 6 are added to the conductive paste 1, the dielectric fine particles 6 are interposed between the scale-like metal fine particles 2 and 2 by kneading the paste. Even when the conductive paste film is fired, the dielectric fine particles 6 suppress the sintering of the scaly metal fine particles 2 and 2 and reduce the shrinkage rate due to the firing. Further, when the dielectric fine particles 6 are made of the same material as the main component of the green sheet, the shrinkage rate due to the firing of the conductive paste film approaches the shrinkage rate of the green sheet, and peeling of the electrode film can be prevented.

  Further, the dielectric fine particle 6 may have a cross-sectional diameter (particle diameter) of μm order dielectric fine particles or nm order dielectric ultrafine particles. More specifically, the present invention is not limited to 1 to 10 μm micron-sized dielectric fine particles and 0.1 to 1 μm submicron-sized dielectric fine particles, and 1 to 100 nm nano-sized dielectric ultrafine particles can also be used in the present invention. . In particular, in the case of dielectric fine particles of 0.05 to 0.3 μm, the material acquisition is relatively simple, and the production of the conductive paste of the present invention is easy.

  Furthermore, in this embodiment, the dielectric precursor 8 is added to the conductive paste 1. The dielectric precursor 8 means a molecular raw material compound that generates a dielectric by firing. Since the dielectric precursor 8 is a molecule, its particle size is extremely small and can enter any local region. Moreover, the material of the dielectric precursor 8 is set to the same composition as the main component of the dielectric constituting the green sheet, as with the dielectric fine particles 6.

The ceramic fine particles constituting the green sheet are dielectric fine particles. This dielectric includes, for example, barium titanate (BaTiO ₃ , abbreviation BT), barium zirconate titanate, strontium titanate (SrTiO ₃ , abbreviated ST), barium strontium titanate ((Ba / Sr) TiO ₃ ), There are lead zirconate titanate (Pb (Ti / Zr) O ₃ ), calcium titanate, barium zirconate, lithium niobate, lithium tantalate, zinc oxide, alumina, zirconia, aluminum nitride, silicon nitride, and the like. Among these, the main component of the ceramic capacitor green sheet is often barium titanate (BT).

  The dielectric precursor 8 is a molecular compound, and its size is extremely small as described above. That is, the dielectric precursor 8 easily enters the minute gap / ultra gap formed by the scaly metal fine particles 2 and functions to fill such a minute region. Further, it is considered that a thin coating film of the dielectric precursor 8 is formed on the surface of the scaly metal fine particles 2. Accordingly, when fired, the dielectric precursor 8 acts to suppress the sintering of the scaly metal fine particles 2 while being transformed into a dielectric. Further, since the composition of the dielectric precursor 8 is set to the same composition as the main component of the green sheet, it has the effect of bringing the firing shrinkage rate of the conductive paste film close to the firing shrinkage rate of the green sheet. Therefore, the dielectric precursor 8 together with the dielectric fine particles 6 prevents the electrode film from peeling off from the ceramic substrate.

  The sintering inhibiting action of the dielectric fine particles 6 and the dielectric precursor 8 on the scaly metal fine particles 2 will be described. The present inventors consider that the dielectric fine particles 6 are responsible for sintering suppression at high temperatures, and the dielectric precursor 8 is responsible for sintering inhibition at low temperatures. When the conductive paste 1 contains both the dielectric fine particles 6 and the dielectric precursor 8, it is considered that the conductive paste has a sintering suppressing effect against a wide range of firing temperatures such as high temperature and low temperature. Since the firing temperature or firing profile is variously changed according to the material of the ceramic material or ceramic electronic component, the conductive paste of the present invention is effective. In addition, since the conductive paste undergoes a wide range of temperature changes from a low temperature to a high temperature even in one firing process, the conductive paste has an effect of exhibiting a sintering suppressing action in the entire process of the temperature change.

  The micro mechanism of sintering suppression is considered as follows. The dielectric fine particles 6 are interposed between the scale-like metal fine particles 2 and 2, and the dielectric precursor 8 fills the fine gaps / ultra fine gaps or thinly covers the surfaces of the fine metal particles 2. At high temperature, the scaly metal fine particles 2 may melt to the deep surface, and the dielectric fine particles 6 inhibit the joining of the melted metal fine particles and suppress sintering. Further, at low temperature, the scaly metal fine particles 2 melt at the shallow surface, so that the peritoneum by the dielectric precursor 8 inhibits the joining of the scaly metal fine particles and suppresses sintering. Due to such a double sintering inhibiting action, the conductive paste of the present invention exhibits sintering inhibition both for high temperature firing and for low temperature firing. Therefore, by using the dielectric fine particles 6 and the dielectric precursor 8 in combination, it is possible to smoothly sinter the conductive paste in the temperature range from the low temperature firing region to the high temperature firing region, and to realize the sintering suppression control. A conductive paste can be provided.

The dielectric precursor 8 is a raw material compound that generates the above-described dielectric by firing, and any compound that can form a dielectric by firing can be used. As this dielectric precursor, metal compounds such as organometallic compounds, organometallic complexes, organometallic resinates, metal oxides, and metal carbonates can be used. Here, the metal means a metal atom constituting a dielectric, such as BaTiO ₃ of BaTiO ₃ , Sr and Ti of SrTiO ₃ , Pb, Ti and Zr of Pb (Ti / Zr) O ₃ , etc. is there.

Methods for producing the main dielectric BaTiO ₃ include mixed melting of TiO ₂ and BaO or BaCO ₃ , thermal decomposition of barium oxalate titanate, sol-gel method of titanium alkoxide and barium alkoxide, titanium hydroxide and hydroxylation There are various methods such as polycondensation of barium, baking of titanium naphthenate and barium naphthenate, baking of titanium octylate and barium octylate, and hydrothermal synthesis. Therefore, the raw material components of these methods, that is, TiO ₂ and BaO or BaCO ₃ , barium oxalate titanate, titanium alkoxide and barium alkoxide, titanium hydroxide and barium hydroxide, titanium naphthenate and barium naphthenate, titanium octylate And a raw material compound such as barium octylate constitutes the dielectric precursor 8.

  If these dielectric precursors 8 are classified, an organic metal compound in which a metal atom and a carbon atom are directly bonded, an organic metal complex in which a ligand is bonded to a metal atom, a higher fatty acid metal salt having viscosity, and the like are included. It is composed of inorganic resin compounds such as metal resinates, metal oxides and metal carbonates. Among these, organometallic resinates are suitable as the dielectric precursor 8 of the present invention. Examples of organometallic resinates include naphthenates, octylates, stearates, oleates, palmitates, laurates, myristates, benzoates, paratoylates, n-decanoates, metals Alkoxides, metal acetylacetonates and the like are used.

  As the organic solvent 10, any solvent that can uniformly disperse the dielectric precursor 8 can be used. For example, alcohol, acetone, propanol, ether, petroleum ether, benzene, ethyl acetate, mineral spirit, other petroleum solvents, terpineol, dihydroterpineol, terpineol acetate, butyl carbitol, cellosolves, aromatics, diethyl phthalate, etc. Can be used. When the dielectric precursor 8 is completely dispersed (dissolved), the solution is colored and transparent.

  First, in this embodiment, an intermediate solution in which the dielectric precursor 8 is uniformly dispersed and dissolved is prepared. After confirming that this solution is in a colored transparent state, it is determined that the dielectric precursor 8 is uniformly dispersed and dissolved in the organic solvent in the molecular state. When an organometallic resinate is used as the dielectric precursor 8, this intermediate solution is referred to as a resinate solution.

  When the flaky metal fine particles 2 and the dielectric fine particles 6 are uniformly dispersed in the intermediate solution, the intermediate solution develops a metal color peculiar to the flaky metal fine particles 2 depending on the amount of the flaky metal fine particles 2 added. To do. By this metal color spreading evenly throughout the solution, it can be determined that the scale-like metal fine particles 2 are uniformly dispersed in the solution.

  The resin 12 used in the present invention is an organic resin that can adjust the viscosity of the conductive paste 1, and is a material that can uniformly knead the scaly metal fine particles 2, the dielectric fine particles 6, the dielectric precursor 8, and the organic solvent 10. Is preferred. For example, ethyl cellulose, nitrocellulose, butyral, acrylic copay balsam, dammar and the like can be used. Such a resin is kneaded with the solution to give the conductive paste an appropriate viscosity.

  In the conductive paste 1, the dielectric powder is added in an amount of 0.1 to 30% by mass with respect to the total amount of the metal powder. If it is 0.1% by mass or less, sintering suppression at a high temperature becomes insufficient, and if it is 30% by mass or more, a problem tends to occur in the conductivity of the electrode film formed by firing the conductive paste. Further, the dielectric precursor 8 is added in an amount of 0.1 to 10% by mass with respect to the total amount of the metal powder. If it is 0.1% by mass or less, sintering suppression at low temperatures is insufficient, and if it is 10% by mass or more, there is a problem in the conductivity of the electrode film. Within these ranges, appropriate amounts of dielectric powder and dielectric precursor 8 are added to the conductive paste 1.

  FIG. 3 is a process diagram for manufacturing the ceramic electronic component 22 by firing. In (3A), the electrode paste film 16 is formed in a predetermined shape on the green sheet 14. First, a ceramic powder composed of ceramic fine particles, an organic binder, and an organic solvent are kneaded to form a slurry. The slurry is formed into a sheet shape to form a green sheet 14. An electrode paste film 16 is formed by screen printing the conductive paste 1 on the surface of the green sheet 14.

  In (3B), organic substances are removed by firing, the green sheet 14 changes to the ceramic substrate 18, and the electrode paste film 16 changes to the electrode film 20. More specifically, in the green sheet 14, all organic substances are removed by firing, and the ceramic fine particles are sintered together to form the ceramic substrate 18. Moreover, in the electrode paste film | membrane 16, all the organic substances are removed by baking and the scaly metal fine particle 2 mutually sinters, and the conductive electrode film | membrane 20 is formed.

FIG. 4 is a partially enlarged cross-sectional view of the electrode paste film 16. The scale-like metal fine particles 2 are stacked so as to overlap each other, and dielectric fine particles 6 such as BaTiO ₃ particles and dielectric precursors 8 such as BaTiO ₃ resinate are interposed between the particles, and the electrode film thickness is extremely thin. The thickness is 0.3 μm. On the other hand, FIG. 5 shows an electrode paste formed by the same printing method as in the present embodiment, using a conventional conductive paste using the above-mentioned spherical metal powder (nickel Ni metal particles having an average particle diameter of 0.4 to 0.5 μm). It is a partial expanded sectional view of a film. In the case of FIG. 5, the metal particles 50 overlap each other via the BaTiO ₃ particles 51, and the total electrode film thickness is 1 μm. Therefore, comparing these, it can be seen that the conductive paste using the scaly metal fine particles 2 of the present embodiment is an extremely effective material for reducing the thickness of the electrode film.

The dielectric fine particles 6 are interposed in the minute gaps between the scale-like metal fine particles 2 and 2, whereas the dielectric precursor 8 is dispersed in the extremely minute gaps, and the electrode paste film 16 has an ultrathin film thickness. Can be realized. The organic solvent 10 and the resin 12 that are not shown are dispersed throughout. When this electrode paste film 16 is baked, it is considered that these distribution states are sintered while being contracted as a whole, and the dielectric precursor 8 changes to BaTiO _{3 in the} distribution state. The dielectric fine particles 6 also change to BaTiO ₃ while being sintered with each other. The scaly metal fine particles 2 undergo sintering suppression and sinter in a state where they are laminated to each other and change into the electrode film 20.

The green sheet 14 becomes a BaTiO ₃ ceramic substrate 18 while shrinking due to firing removal and sintering of the organic matter. The dielectric fine particles 6 and the dielectric precursor 8 are also ceramicized into BaTiO ₃ to form the electrode film 20. Since the ceramic component is common to BaTiO ₃ , the firing shrinkage rates of the electrode paste film 16 and the green sheet 14 are close to each other. Therefore, it is possible to prevent the electrode film 20 from being peeled off from the ceramic substrate 18 or being spheroidized and interrupted in the middle.

  Supplementing with reference to FIG. 3, the ceramic electronic component 22 is constituted by the electrode film 20 and the ceramic substrate 18. Since there is no peeling of the electrode film 20, the lifetime of the ceramic electronic component 22 can be extended. Further, a plurality of green sheets 14 on which the electrode paste film 16 is formed are stacked, and the whole is fired. As a result, the plurality of green sheets 14 and the electrode paste film 16 are changed to the ceramic substrate 18 and the electrode film 20 by firing, and a multilayer ceramic electronic component is manufactured. The ceramic electronic parts targeted by the present invention include ceramic circuit boards, ceramic capacitors, ceramic inductors, ceramic piezoelectric elements, and ceramic actuators.

  The present invention is not limited to the above-described embodiment, and it goes without saying that various modifications and design changes within the technical scope of the present invention are included in the technical scope. .

  When the first and second embodiments of the present invention are used, the electrode film can be made thinner than the conductive paste of the spherical metal powder by containing the scaly metal powder as the conductive component. In addition, when the first embodiment is used, in addition to the effect of thinning, a conductive paste imparted with a high-temperature sintering inhibiting action by the contained dielectric fine particles (powder) in the paste can be obtained. Furthermore, when the second form is used, it is possible to provide a conductive paste imparted with a low-temperature sintering suppressing action by the dielectric precursor contained in the paste, and the combination of the dielectric fine particles of the first form Can provide a universal conductive paste that suppresses sintering in the temperature range, and can maintain the sintering suppression effect in the entire temperature range for a wide range of temperature changes from low to high during firing. The dramatic improvement effect can be obtained. In addition, when the firing temperature is changed depending on the type of electronic component, that is, the same conductive paste for ceramic electronic components manufactured by low temperature firing and ceramic electronic components manufactured by high temperature firing. And can reduce the cost and improve the electrode characteristics in the electronic component industry using the conductive paste.

  Furthermore, if the 3rd and 4th form of this invention is used, the thin film of the electrode film suitable for ceramic electronic components is realizable with the scaly metal powder which consists of a base metal or a noble metal atom.

  If the 5th form of this invention is used, the electrically conductive paste which uses organometallic resinate as a dielectric precursor containing paste can be provided. The organometallic resinate is an organometallic resinate, and a higher fatty acid metal salt is a representative substance. The organometallic resinate contains many kinds of metal compounds, and it is very easy to change the metal species and the molecular size, and has an advantage of providing various conductive pastes ranging from noble metals to base metals.

  If the 6th form of this invention is used, the electrically conductive paste which prepared the metal content of dielectric powder in the range of 0.1-30 mass% with respect to the whole quantity of a scaly metal powder can be provided. If the metal content of the dielectric powder is changed within this range, the conductive paste that can adjust the degree of high-temperature sintering suppression while maintaining good conduction characteristics of the electrode film and satisfy the market requirements freely There is an advantage that can provide.

  If the 7th form of this invention is used, the electrically conductive paste which prepared content of the dielectric precursor in the range of 0.1-10 mass% with respect to the whole quantity of metal powder can be provided. By changing the content of the dielectric precursor within this range, it is possible to adjust the degree of low-temperature sintering suppression while maintaining good conduction characteristics of the electrode film, and to satisfy various market demands freely. There is an advantage that a paste can be provided.

  When the eighth and ninth embodiments of the present invention are used, the composition of the dielectric powder or the dielectric precursor is configured to correspond to the main component of the dielectric forming the green sheet, and the firing shrinkage rate of the green sheet is increased. A conductive paste film that is very close can be formed. When the firing shrinkage rate approximates, the electrode film does not peel from the ceramic substrate, and the electrode film does not crack, so that there is an advantage that a dense electrode film having high conduction performance can be formed.

By using the tenth and eleventh aspects of the present invention, it is possible to reduce the thickness of the electrode film of the ceramic electronic component. The downsizing of ceramic electronic parts depends on the reduction in the thickness of the electrode film, and according to the present invention, it is possible to realize super multi-layer and super high density of ceramic electronic parts. Therefore, it is possible to contribute to further miniaturization of electronic devices and personal computers, particularly mobile phones, and to the realization of an advanced mobile society. Moreover, in addition to reducing the thickness of the electrode film, it is possible to provide an epoch-making method for manufacturing a ceramic electronic component that can be handled with a single conductive paste when the firing temperature is selected according to the type of ceramic electronic component. . Unlike the prior art, since many types of conductive paste are not prepared for each firing temperature, it is possible to contribute to the reduction of the manufacturing cost of the ceramic electronic component. Examples of the ceramic electronic component include a ceramic circuit board, a ceramic capacitor, a ceramic inductor, a ceramic piezoelectric element, and a ceramic actuator. In addition, there is an advantage that the present invention can be used in a method for manufacturing a new ceramic electronic component that will appear in the future.

It is a schematic explanatory drawing of the electrically conductive paste 1 which concerns on this invention. 1 is an external view of one fine particle piece of a scale-like metal powder 2 used for a conductive paste 1. FIG. FIG. 4 is a process diagram for manufacturing a ceramic electronic component 22 using a conductive paste 1. 3 is a partial enlarged cross-sectional view of an electrode paste film 16. FIG. It is a partial expanded sectional view of the conventional nickel conductive paste film. It is the schematic explaining the relationship between the metal fine particle diameter D and the three pocket diameter d.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Conductive paste 2 Scale-like metal microparticle 3 Container 4 Three pocket 6 Dielectric particle 8 Dielectric precursor 10 Organic solvent 12 Resin 14 Green sheet 16 Electrode paste film 18 Ceramic substrate 20 Electrode film 22 Ceramic electronic component

Claims (9)

A dielectric powder, a dielectric precursor, a scaly metal powder, an organic solvent that uniformly disperses the scaly metal powder, and a viscosity adjusting resin, wherein the total metal content of the dielectric precursor is the scaly 0.1 to 10% by mass with respect to the total amount of the Jo metal powder is, a conductive paste in which the dielectric powder is characterized by comprising the dielectric fine particles having a particle size of 1Nm～10myuemu. The conductive paste according to claim 1, wherein the scaly metal powder comprises a base metal atom. The conductive paste according to claim 1 or 2, wherein the scaly metal powder is composed of noble metal atoms. Dielectric precursor organometallic resinate a is claim 1 in any crab described conductive paste. The conductive paste according to any one of claims 1 to 4, wherein a content of the dielectric powder is 0.1 to 30% by mass with respect to a total amount of the scaly metal powder. The electrically conductive paste in any one of Claims 1-5 comprised so that the composition of the said dielectric material powder may respond | correspond to the main component of the dielectric material which forms a green sheet. The electrically conductive paste in any one of Claims 1-6 comprised so that the composition of the said dielectric precursor may correspond to the main component of the dielectric material which forms a green sheet. A conductive paste film is formed on a green sheet using the conductive paste according to any one of claims 1 to 7, and the green sheet and the conductive paste film are integrally fired to remove organic components. A method for producing a ceramic electronic component, comprising: forming an electrode film having a desired pattern on a ceramic substrate by the method described above. The method of manufacturing a ceramic electronic component according to claim 8, wherein the ceramic electronic component is a ceramic circuit board, a ceramic capacitor, a ceramic inductor, a ceramic piezoelectric element, or a ceramic actuator.

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