JPH05229880A - Production of porous ceramic product - Google Patents

Abstract

PURPOSE:To provide a method for producing a porous ceramic product capable of increasing the porosity and simultaneously uniformizing the pore diameter. CONSTITUTION:The objective method is characterized by mixing calcined ceramic powder prepared by calcining a ceramic raw material with unburned ceramic powder obtained by aggregating and granulating the ceramic raw material with an organic substance, then forming the resultant mixture into a prescribed shape and burning the formed mixture.

Description

Detailed Description of the Invention

[0001]

FIELD OF THE INVENTION The present invention relates to a method for producing a porous ceramic product.

[0002]

2. Description of the Related Art Conventionally, a porous ceramic product in which pores are dispersed in a ceramic that is a matrix phase is, for example,
It is used as an electronic component such as a microwave dielectric, and as a material for forming pores in such a porous ceramic product, an organic simple substance such as a cellulose resin that decomposes at a temperature below the sintering temperature of the ceramic raw material is used. It is generally used. That is, in manufacturing this type of porous ceramic product, first,
A ceramic raw material that has been preliminarily tempered to have a predetermined composition is prepared, and a powdery cellulose resin which is an organic simple substance and a vinyl acetate binder are added to the ceramic raw material and mixed to form a slurry (mud). After obtaining the soybean), the slurry is formed into a predetermined shape such as a substrate, and then the formed body is fired in an air atmosphere.

[0003]

However, the above-described method for producing a porous ceramic product has the following disadvantages. That is, the sintering temperature of the ceramic raw material is often 1000 ° C. or higher, whereas the organic simple substance such as a cellulose resin is carbonized at a temperature of 300 to 400 ° C. and then at a temperature of 400 to 900 ° C. It is usually decomposed. Therefore, in the conventional method, since the sintering of the ceramic raw material starts after the pores are formed due to the decomposition of the organic simple substance, the pores that have been formed once are the particles during the sintering of the ceramic raw material. It may collapse or disappear due to growth. As a result, the porosity of the porous ceramic product is reduced, or the pore diameters are not uniform.

Since the specific gravity of the organic simple substance is lighter than the specific gravity of the ceramic raw material, the doctor blade method or the like is adopted even though the organic simple substance is added to the ceramic raw material and sufficiently mixed. When the slurry is molded by the above method, the organic simple substance floats in the ceramic raw material. Therefore, as a result of non-uniform dispersion of the organic simple substance in the molded body, non-uniform dispersion of pores in the matrix ceramic.

The present invention was devised in view of such inconveniences, and an object thereof is to provide a method for producing a porous ceramic product capable of increasing the porosity and at the same time making the pore diameters uniform. There is.

[0006]

In order to achieve such an object, a method for producing a porous ceramic product according to the present invention comprises a calcined ceramic powder obtained by calcining a ceramic raw material, and the ceramic raw material. Is mixed with an unsintered ceramic powder formed into agglomerated particles by an organic material such as a binder or a resin, which is then molded into a predetermined shape and then sintered. That is, in this method, the unsintered ceramic powder functions as a pore-forming material, and the pores are formed by the decomposition of the organic material obtained by agglomerating the ceramic raw material into agglomerated particles.

[0007]

According to the above construction, since the calcined ceramic powder and the unsintered ceramic powder are made of the same ceramic raw material, the specific gravities of the two become equal, and even if they are mixed, they are separated. Cannot happen. Further, the sintering of the calcined ceramic powder and the unsintered ceramic powder in this manufacturing method is performed at the same time, and the unsintered ceramic powder has pores formed by the decomposition of the organic material that has agglomerated the ceramic raw material. Grains are grown by sintering while being encapsulated.

[0008]

EXAMPLES A method for manufacturing a porous ceramic product according to the present invention will be described below. In this example, the porous ceramic product is made of BaTi ₄ O ₉ which is a well-known microwave dielectric.

First, the purity is 99% or more and the average particle size is 1 μm.
m of BaCO ₃ and TiO ₂ having a purity of 99% or more and an average particle size of 1 μm are prepared in a required amount, and each of them has a molar ratio of BaCO ₃ / TiO ₂ = 1/4. As described above, ethyl alcohol is added and wet-mixed to obtain a slurry.
Then, the slurry thus obtained is dried and then dry pulverized to obtain a mixed powder as a ceramic raw material that is conditioned to have a predetermined composition, and then the obtained mixed powder is Divide into two.

Then, one of the two divided powders is calcined in an air atmosphere at a temperature of 1150 ° C. for 2 hours to obtain a BaTi ₄ O ₉ powder, that is, a calcined ceramic powder. In addition, 3 g of PVB (polyvinyl butyral) binder was added to 100 g of the other mixed powder of the two halves, the mixture was wet-mixed with ethyl alcohol, and the obtained slurry was dried and then dry-ground. As a result, an unfired ceramic powder having an average particle size of about 1.5 μm is obtained.
That is, the unfired ceramic powder obtained at this time is
The ceramic raw material is made into agglomerated particles by a PVB-based binder which is an organic material. The organic material used when the ceramic raw material is agglomerated into particles is not limited to the PVB-based binder, but may be a resin such as an acrylic binder.

Further, B which is a calcined ceramic powder
75g aTi ₄ O ₉ powder and 25g unfired ceramic powder
On the other hand, by adding 7 g of vinyl acetate-based binder, 2 g of plasticizer, 1 g of dispersant and 70 cc of pure water to obtain a slurry by wet-mixing, the doctor blade method is used to form the slurry. Thickness 100μ
A green (raw) sheet designated as m is formed. And
A plurality of green sheets thus formed are stacked on each other and pressed to form a block body, and then the block body is cut using a diamond cutter or the like, for example, length 20 mm × width A molded body having a size of 10 mm and a thickness of 5 mm is obtained.

Subsequently, the temperature raising / lowering rate is 200 ° C./hr.
In addition, by firing each of the molded bodies for 2 hours in air or N ₂ atmosphere in which the firing temperature is 1230 ° C., a porous ceramic product that is a sintered body is obtained. And in this embodiment,
A porous ceramic product fired in an air atmosphere is referred to as a sample A for a characteristic test, and a porous ceramic product fired in an N ₂ atmosphere is referred to as a sample B.

Next, in order to compare the method of this example with the method of the conventional example, an organic simple substance as a material for forming pores, that is, a powdery cellulose resin having an average particle size of 15 μm is prepared. Then, the prepared cellulose resin was added to a ceramic raw material that was tempered in the same manner as in the present example, mixed under the same conditions, and molded and fired to obtain a porous ceramic that was a sintered body. Get the product. And among these porous ceramic products,
What was baked in an air atmosphere was designated as sample C, and N
₂ Sample D is a porous ceramic product fired in an atmosphere
And

Then, the samples A to
When the porosity and the average pore diameter in each of D were measured, the measurement results shown in Table 1 were obtained. In addition,
In Table 1, D50 means that particles having a particle diameter of D50 or less occupy 50% of the whole, and D90 means that particles having a particle diameter of D90 or less occupy 90% of the whole.

[0015]

[Table 1]

Comparing the porosity and the average pore diameter D50 in Table 1, in comparison with the porosities of the samples C and D manufactured by the conventional method, the samples A and B manufactured by the method of this example are compared. It can be seen that the porosity is higher. At the same time, the average pore diameter D50
It is understood from the comparison between D90 and D90 that the pore diameters of Samples A and B are broader than those of Samples C and D, and the distribution of pores is uniform.

By the way, in the above description, the porous ceramic product is made of BaTi ₄ O ₉ and BaCO ₃ and TiO ₂ are used as the ceramic raw material, but the invention is not limited to these. The raw material may be any of oxides, carbonates, nitrides, carbides and borides of ceramic constituent elements. For example, when titanium is taken as an example, TiN, TiC, TiB ₂ or the like is used. Further, the atmosphere during firing of the molded body is not limited to air or N ₂ , and it is needless to say that O ₂ , CO ₂ , Ar or the like or a mixed gas thereof is used if necessary.

[0018]

As described above, in the method of the present invention, the calcined ceramic powder obtained by calcining the ceramic raw material and the ceramic raw material of the same quality are agglomerated into particles by an organic substance such as a binder or a resin to form pores. A porous ceramic product is to be manufactured by using an unfired ceramic powder as a forming material. Therefore, even if the calcined ceramic powder and the non-fired ceramic powder having the same specific gravity are mixed, they cannot be separated from each other, and
The unsintered ceramic powder grows while encapsulating the pores formed by the decomposition of the organic material that has agglomerated the ceramic raw material.

As a result, according to the method of the present invention, it is possible to obtain the effect that the porosity of the porous ceramic product can be increased and the pore diameters can be made uniform. When the porous ceramic product manufactured in this way is used as an electronic component, not only the thermal shock resistance thereof can be improved, but also the specific surface area can be increased and the electrical characteristics can be improved. ..

Claims (1)

[Claims] 1. A calcined ceramic powder obtained by calcining a ceramic raw material and an unsintered ceramic powder obtained by agglomerating the ceramic raw material with an organic substance are mixed, shaped into a predetermined shape, and then calcined. A method for producing a porous ceramic product, comprising: