JP2005272231A - Solid for hygiene porcelain glaze and manufacturing method of ceramic ware - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a solid for hygiene porcelain glaze enabling long time storage and enhancing transport efficiency, and a method of manufacturing a ceramic ware. <P>SOLUTION: This solid for porcelain glaze is obtained by wet-pulverizing a porcelain glaze material comprising a silica sand, feldspar, clay, etc., with water in a ball mill, etc., and after regulating particle diameter and viscosity, of the slurry, etc., dehydrating and/or heating and drying. In this manufacturing method of a porcelain, this solid for porcelain glaze is again made into slurry and applied to the surface of moldings of a crude ceramic ware. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a sanitary ware (ceramics) glaze solid, a method for producing ceramics, a method for adjusting various properties when reslurrying the ceramic glaze solids, and the like.

  2. Description of the Related Art Conventionally, in the production of tiles among ceramics, a green body is formed by a dry method by extrusion molding using a plastic forming clay (for example, see Patent Document 1). Also, the glaze is applied by using a dry powder obtained by drying a glaze slurry and dropping it onto a tile raw material. (For example, refer to Patent Document 2). On the other hand, among ceramics, especially sanitary ware, most of the products are large and irregularly shaped. Therefore, a method of forming a molded body wet by casting a base slurry and a spray coating of glaze slurry. A wet glazing method is usually used. Therefore, the base and glaze slurry prepared by adding an appropriate amount of water to the sanitary ware base material or sanitary ware glaze raw material as described above to give fluidity and mixing and pulverizing with a ball mill or the like is used as it is. Until now, in the glaze applied to sanitary ware, the glaze slurry has not been dehydrated and dried to be once solid.

JP-A-8-40777 (page 2-5) JP-A-8-133869 (page 2-4)

  The glaze for sanitary ware has a large change in properties over time when it is in a slurry state, and has many disadvantages for long-term storage. If the raw materials for glaze such as silica sand, feldspar, clay etc. are in the accepting state, there is no problem in long-term storage, but in this state, the slurry particle size and viscosity are adjusted so that they can be used in the glazing process. Therefore, a lot of time is required, and there is a problem that it is not possible to immediately cope with a sudden increase in demand. Moreover, since the moisture content is usually 40 to 60% in the slurry state, when the transfer is attempted, a large amount of water is carried, and the transfer efficiency is poor. In many cases, water is also available at the destination site.

  An object of the present invention is to provide a solid material for sanitary ware glaze and a method for producing a ceramic that can be stored for a long period of time and can improve transfer efficiency. In particular, it is to provide a solid material for a ceramic glaze that can efficiently prepare a glaze slurry suitable for wet glazing.

  In the present invention, in order to solve the above-mentioned problems, water is added to the glaze raw material for sanitary ware, wet pulverized by a ball mill to obtain a glaze slurry, and then dehydrated and / or dried to obtain a moisture content of 0 to 25. The present invention provides a solid for sanitary ware glaze characterized by being a solid in weight percent.

  The solid material for sanitary ware glaze obtained as described above is adjusted in particle size, viscosity, etc. so that it can be directly applied to the surface of the sanitary ware base molded body in the state of slurry before solidification. Therefore, even a slurry obtained by adding water to dissolve is suitable because it can be used without any problem in the glazing process. As the glaze material for ceramics, a glaze material for ceramics that forms various glazes such as transparent glaze (base glaze), opaque glaze (colored glaze), matte glaze, raster glaze, and aventurine glaze can be used.

  If the ceramic glaze raw material is stored in a slurry state, the solid content in the slurry precipitates when left standing, causing a problem of so-called “sitting”. In order to avoid this problem, it is possible to constantly stir the slurry. However, not only is the equipment and power for stirring required, but the cost is high, and the concentration of the slurry is likely to change. Before use in the glazing process, the concentration and viscosity must be adjusted again. On the other hand, the sanitary ware (ceramics) glaze solids as described above are slurry dehydrated and dried products, so that problems related to long-term storage such as “sitting” can be solved.

  Furthermore, since the dehydrated / dried material can be reduced and reduced in weight to about 70% of the original slurry volume and weight, it is preferable because the transfer efficiency can be increased when the transfer of solids is required.

In a preferred embodiment of the present invention, the sanitary ware glaze solids contain an emulsion and / or a color former.
As a sanitary ware (ceramics) glaze raw material, transparent glaze (base glaze) using the minimum required clay, aggregates such as alumina, and feldspar etc. When applied, there is no problem, but if it is a single layer, the surface of the sanitary ware base cannot be concealed, so usually a coloring agent such as an emulsion or pigment is applied. In addition, when applying the color former, an emulsion such as zirconium silicate (zircon) or tin oxide is often required, so the basic glaze is obtained by adding an emulsion to the above-mentioned aggregate or melt. As a sanitary ware, if it is manufactured using a glaze slurry that has been re-slurried by adding water to the sanitary ware glaze solids obtained, Only sanitary ware with a glaze layer will be obtained. Due to diversification of user demand, the glaze layer of sanitary ware is required to have various colors. At this time, the color tone is added to the solid material for sanitary ware glaze obtained from the basic glaze slurry and reslurried with water, and the desired color tone is obtained by stirring and dissolving at the same time. This is preferable because post-adjustment becomes possible. By doing in this way, it becomes much more efficient than manufacturing and storing a plurality of sanitary ware glaze solids containing different color formers. Moreover, conveyance and reslurry of a solid can be performed effectively by making the moisture content of the solid for sanitary ware glaze into 0 to 25 weight%.

  In a preferred embodiment of the present invention, the slurry is dehydrated by a filter press, and the water content of the solid after dehydration is 15 to 25% by weight.

Here, the moisture content represents the moisture content in a solid containing moisture, and is represented by a fraction of the moisture content relative to the total weight. When the mass of the sample before drying is W (g) and the mass of the sample after drying at 110 ° C. for 24 hours is W _D (g), the moisture content Z (%) can be calculated by the following equation 1. .

  The filter press machine is a machine that applies a pressure to the slurry using the filter cloth as a filter and dehydrates and concentrates it. However, if the press pressure is increased, a great burden is placed on the filter cloth and the machine. Therefore, it is desirable that the water content of the solid after dehydration is 15 to 25% by weight. Here, when the moisture content is larger than 25% by weight, it can be obtained only as a large solid body, so that the workability during storage and the solubility during reslurry become worse, requiring a lot of time. Many. Therefore, the workability can be improved and the reslurry time can be shortened by adjusting the shape of flakes or noodles by passing the press cake through a pelleter or the like. In addition, the above flaky or noodle-like solid can be further reduced in weight and weight by lowering the water content by drying at room temperature or by heating, which is preferable because the efficiency during transfer or transportation can be increased. . The water content after drying is preferably 0 to 15% by weight, more preferably 1 to 10% by weight. In the drying step, the solid matter is further separated, which contributes to an improvement in efficiency during transfer or transportation.

  In a preferred embodiment of the present invention, the slurry is dried by a spray dryer, and the moisture content of the solid after drying is 0 to 15% by weight, preferably 2 to 10% by weight.

  The use of a spray dryer makes it possible to considerably reduce the moisture content of the solids. However, when the moisture content is 0 to 1% by weight, dust tends to be generated when the particle size of the solid is small. Further, when the moisture content is less than 2% by weight, the viscosity of the slurry before solidification tends to be considerably higher at the time of reslurry. Furthermore, when the moisture content exceeds 10% by weight, the yield value due to the reslurried slurry tends to increase. Therefore, it can be used if the moisture content of the solid is in the range of 0 to 15% by weight, but it can be suitably used in the range of 2 to 10% by weight. Spray drying is a desirable solidification method for reslurry because it can prevent the loss of soluble salts such as peptizers and flocculants contained in the slurry as much as possible compared to the filter press.

  In a preferred embodiment of the present invention, the particle size of the solid material for sanitary ware glaze obtained after drying the slurry is in the range of 0.1 to 10 mm.

  When the spray dryer is used, it is possible to adjust the particle size of the solid matter to some extent. However, if the particle size is smaller than 0.1 mm, dust is likely to be generated, and not only the recovery rate but also the work environment is reduced. Since it leads to deterioration, it is not preferable. Moreover, since the workability | operativity at the time of a transfer or reslurry will fall when the said particle size becomes larger than 10 mm, it is unpreferable.

  In the present invention, a process for obtaining a ceramic glaze solid material by adding water to a ceramic glaze material and performing wet pulverization with a ball mill to obtain a glaze slurry, followed by dehydration and / or drying, the ceramic glaze Reslurry process to add solid to water and return to glaze slurry, molding process to obtain ceramic molded body, glazing process to apply the reslurried glaze to the molded body, firing the glazed molded body There is provided a method for manufacturing a ceramic, which is manufactured through a firing step.

An amount of water calculated from the water content of the solid material is added to the ceramic glaze solid material so as to obtain a predetermined slurry concentration (for example, a water content of 40 to 60%), and a stirrer, a stirrer or the like By performing the mixing / stirring operation (reslurry), the slurry can be used in the glazing process.
The molded body can be obtained by extrusion using a plastic molding clay like a tile, or it may be obtained as a calcined body, but in sanitary ware, it is cast with slurry gypsum or resin for sanitary ware bodies. A green body is obtained by pouring into a mold and demolding after fleshing, and the green body is dried to obtain a green body. A sanitary ware is manufactured by applying the re-slurried glaze slurry to a necessary portion of the obtained molded body and firing it at 1000 to 1300 ° C.

In a preferred embodiment of the present invention, the reslurry step includes a step of adding a powder raw material in order to adjust the melt viscosity and the melt distance during firing.
Among ceramics, especially in the manufacture of sanitary ware, the melt viscosity and melting distance of the glaze during firing are important factors. That is, there is no problem when glazing and firing on a horizontal surface such as a tile. However, in the case of a complicated shape having a vertical surface such as sanitary ware, the uneven flow of the molten glaze during firing is not possible. It leads to surface defects such as. In addition, when the glaze slurry before solidification and the re-slurry of the sanitary ware glaze solid material are fired in the same kiln and under the same conditions, the melt viscosity and the melt distance are almost constant. Never become. However, it may be considered that the solid is transferred to another place and fired in a kiln having different conditions. Therefore, in the step of reslurrying the solid matter, it is preferable that the powder viscosity is post-added to adjust the melt viscosity and the melt distance during firing. The melting distance refers to a distance in which the glaze flows after the flat molded body is partially glazed and then the flat molded body is tilted and fired in that state.
In addition, the same state as the glaze solid for sanitary ware described above can be applied to the glaze solid for ceramics. That is, the moisture content range and the particle size range of the sanitary ware glaze solids can be similarly applied.

In a preferred embodiment of the present invention, the powder raw material is at least one selected from feldspar, limestone, zinc white, dolomite, nepheline, and frit having substantially the same composition as the ceramic glaze solid material.
Because feldspar, limestone, zinc white, dolomite, nepheline, etc. play a role as a melt in the glaze raw material, by adding them later when reslurrying the ceramic glaze solids, The slurry obtained after the addition has a low melting start temperature at the time of firing, so that it can be adjusted to an appropriate melt viscosity and melt distance in a kiln having a low kiln temperature. Further, when comparing non-frit glazes and frit glazes having the same composition, generally, the frit glaze tends to have a lower melting start temperature under the same firing conditions. Therefore, it is preferable to add a frit having substantially the same composition as that of the solid material for a ceramic glaze since the melting distance can be adjusted with almost no change in the glaze composition. In order to shorten the adjustment time for reslurry, it is desirable to pulverize these powders in advance to a state close to the particle size in the final glaze slurry.

In a preferred embodiment of the present invention, the powder raw material is at least one selected from silica sand, alumina, kaolin, clay, zirconium silicate, and tin oxide.
Since silica sand, alumina, kaolin, etc. play a role as a bone agent in the glaze raw material, a slurry obtained after addition is obtained by adding them later when reslurrying the ceramic glaze solids. Since the melting start temperature becomes high at the time of firing, it can be adjusted to an appropriate melt viscosity and melt distance in a kiln having a high kiln temperature. Further, zirconium silicate and tin oxide used as an emulsifying agent are crystalline components that do not dissolve in glass even after ceramic firing, and when this component increases, the melt viscosity tends to increase at the same firing temperature. Therefore, it is preferable to add zirconium silicate or tin oxide to the solid material for ceramic glaze since the melt viscosity can be adjusted. In order to shorten the adjustment time for reslurry, it is desirable to pulverize these powders in advance to a state close to the particle size in the final glaze slurry.

  In a preferred aspect of the present invention, the powder raw material is 0.01 to 20 parts by weight with respect to 100 parts by weight of the ceramic glaze solid material.

  When the powder raw material added after reslurry exceeds 20 parts by weight with respect to 100 parts by weight of the ceramic glaze solids, the influence on other glaze characteristics such as thermal expansion coefficient cannot be ignored. Therefore, it is unsuitable. Further, if the amount of the powder raw material to be added after re-slurry is very small, the effect of adjusting the melting start temperature cannot be obtained, so it is necessary to make it 0.01 parts by weight or more.

  In a preferred embodiment of the present invention, the reslurry step includes a step of adding a color former in order to adjust the color tone of the glaze layer after firing.

The color tone of the glaze layer after firing is greatly affected even by slight variations in firing conditions. In order to keep the color tone of the glaze layer within a certain control range even if the firing conditions fluctuate, the glaze slurry obtained by re-slurrying the solid material is applied to the surface of the ceramic molded body as it is and fired. Conduct a pilot test. The target color tone from the color difference ΔE ^* value calculated based on the L ^* , a ^* , b ^* color system color space measured with a spectrocolorimeter to measure the color tone of the glaze fired in the preliminary test Find the gap with. Here, it is preferable to add a color former so as to eliminate the above-mentioned deviation when reslurrying the ceramic glaze solid material, so that the glaze color of the target color tone can be corrected.

  In a preferred embodiment of the present invention, the color former is an easily dispersible pigment.

  Usually, the color pigment used as a color former has a high cohesiveness because of fine particles, and when mixed with water, the pigment particles drain into water and become agglomerates, so the dispersibility is poor, and this agglomeration is lost. In addition, it was necessary to use a mixing / stirring apparatus having a grinding ability such as a ball mill. The easily dispersible pigment is obtained by holding an inorganic electrolyte, an anionic surfactant or a water-soluble polymer on the surface of the colored pigment particles. When added to water or slurry, the water-soluble polymer absorbs surrounding water and swells, and gradually dissolves in water to promote dispersion of the colored pigment particles in water or slurry. . Further, the anionic surfactant has a function of charging the adsorbed particles to minus (−) and electrically repelling and dispersing the colored pigment particles. Furthermore, the inorganic electrolyte acts to increase the dispersibility immediately after addition by acting an ion antagonism between the ions that are first dissolved and released when added to water or slurry and the colored pigment particles having a dispersing group. have. Due to the synergistic effect of the above action, the mixing / stirring operation (reslurry) can be performed in a short time by a stirrer such as a stirrer or a blanker having no grinding ability.

  In a preferred embodiment of the present invention, the color former is added in an amount of 0.01 to 20 parts by weight with respect to 100 parts by weight of the ceramic glaze solid.

  The pigment or the like used as the color former is a crystalline component that does not dissolve in the glass even after the ceramic baking, and 20 color formers are added after reslurry to 100 parts by weight of the ceramic glaze solids. Exceeding parts by weight is not suitable because the influence on other glaze characteristics such as the coefficient of thermal expansion cannot be ignored. Further, if the amount of the color former added after re-slurry is too small, the effect of correcting the color tone cannot be obtained, so it is necessary to make it 0.01 parts by weight or more.

  In a preferred embodiment of the present invention, the reslurry step includes a step of adding 0.001 to 5.0 parts by weight of a peptizer or a flocculant in order to adjust the viscosity of the slurry.

The peptizer acts as a dispersing agent because it is adsorbed on the glaze raw material particles in the slurry and has an electric charge to generate an electric repulsion between the particles. Accordingly, the peptizer has a function of reducing the viscosity. On the other hand, the flocculant has an effect of promoting the bonding between the particles by adsorbing to the glaze raw material particles in the slurry, depriving the electric charge and preventing electric repulsion. Therefore, the flocculant has a function of increasing the viscosity. It is preferable to add these after re-slurrying the ceramic glaze solids, because the viscosity of the slurry obtained after the addition can be adjusted to either the low side or the high side.
If the amount of peptizer or flocculant added after re-slurry is over 5.0 parts by weight with respect to 100 parts by weight of the ceramic glaze solids, the composition of the glaze will be affected. is there. Further, if the amount of the peptizer or flocculant added after re-slurry is too small, the effect of adjusting the viscosity cannot be obtained, so it is necessary to make it 0.001 part by weight or more.

  In a preferred embodiment of the present invention, the reslurrying step includes a step of adding 0.001 to 10 parts by weight of a binder and / or a corrosion inhibitor.

The binder has a viscosity adjusting function in water and a binder function for improving the strength of the glaze layer when the glaze slurry is dried. Further, the corrosion inhibitor has a function of preventing the organic components contained in the glaze slurry from becoming nutrients and the propagation of bacteria such as bacteria.
If the amount of binder and / or corrosion inhibitor added after re-slurry exceeds 10 parts by weight with respect to 100 parts by weight of the ceramic body solids, the composition of the glaze is affected. is there. In addition, if the amount of binder and / or corrosion inhibitor added after re-slurry is too small, the effect of increasing viscosity and / or the effect of preventing corrosion cannot be obtained, so 0.001 part by weight or more It is necessary to.

  ADVANTAGE OF THE INVENTION According to this invention, the manufacturing method of the solid substance for sanitary ware glaze which can enable long-term preservation | save and can raise transfer efficiency, and a ceramic can be provided.

  As the ceramic glaze material in the present invention, known ceramics for silica sand, soda feldspar, potash feldspar, lithium feldspar, limestone, alumina, clay, talc, sodium carbonate, barium carbonate, borax, zinc white, dolomite, wollastonite, etc. A glaze raw material can be used, and these sanitary ware glaze raw materials can be appropriately blended and used as necessary. Moreover, in order to make the glaze obtained after baking into a colored layer, a color former or the like can be added as necessary. Examples of color formers include metal oxides such as iron oxide, copper oxide, manganese oxide, cobalt oxide, zirconium oxide, chromium oxide, titanium oxide, and antimony oxide, zirconium silicate (zircon) as an emulsion, tin oxide, and the like. Can be used as appropriate. Furthermore, Table 1 shows a preferable range of the glaze raw material composition.

  Water as a dispersion medium is preferably added so that the water content of the slurry is 40 to 60% by weight. In addition, a peptizer or a flocculant can be added as necessary. Here, examples of the peptizer or flocculant include soda ash, potassium carbonate, sodium silicate, sodium hydroxide, potassium hydroxide, calcium chloride, calcium sulfate, magnesium sulfate, ammonium carbonate, sodium polycarboxylate, and polyacrylic. Ammonium acid can be used.

The glaze slurry is prepared by adding a predetermined amount of water and, if necessary, a color former and a peptizer or a flocculant to the ceramic glaze raw material, and using a known pulverizer such as a cylinder mill, a ball mill, a bead mill, etc. (D ₅₀ : indicates the particle size of particles when the cumulative amount of fine particles from the fine particle side reaches 50% in the particle size distribution measurement data measured using a laser diffraction particle size distribution meter) to be 1 to 10 μm. Prepare to.

  The glaze slurry is usually added with a predetermined amount of water and, if necessary, a color former, a peptizer or a flocculant to the sanitary ware glaze raw material, and the viscosity is usually 200 to 1000 mPa · s so as to be suitable as a glaze slurry. Adjust so that Further, the yield value is adjusted to be 10 to 30 dPa.

  The obtained glaze slurry is dehydrated with a filter press or the like to obtain a press cake having a water content of 15 to 25% by weight. The filter press, as its name suggests, separates the slurry into solids and moisture using a filter.For the purpose of preventing clogging and clumping of the filter and removing the press cake from the filter easily, The peptizer or flocculant is preferably a soluble salt. As other dehydrating means, a centrifugal separator or the like can be used.

  The obtained glaze slurry is dried by a spray dryer or the like to obtain a powder having a water content of 0 to 20% by weight. Rather than obtaining a powder with a water content of 0 to 20% by weight from a water content of 40 to 60% by weight of the slurry at once, a water content to maintain fluidity by dehydrating the slurry through a filter press. You may make it obtain a powder with a moisture content of 0-20 weight% by reducing to 20-30 weight%, and passing this through a spray dryer after that.

  As a drying method, not only spray dryers but also sun drying, hot air drying, freeze drying and the like can be used. However, spray drying is suitable in that the drying rate is fast, the productivity is high, and the particle size of the powder obtained after drying can be adjusted.

  In addition, the moisture content of the powder obtained after drying may fluctuate somewhat during storage and storage, but the moisture content fluctuation is not a major problem because it will be adjusted again in reslurry. Is suitable for long-term storage.

By adding water and, if necessary, the above-described peptizer, aggregating agent and the like to the above powder, the slurry is made into a slurry for glaze according to the conditions of the firing kiln to be used. It is desirable that the water used here does not contain a large amount of ions that cause aggregation / precipitation such as chloride ions (Cl ⁻ ) and sulfate ions (SO ₄ ²⁻ ). According to the object of the present invention, when the ceramic glaze solid material is used by being transferred to a distant place, it may be difficult to obtain water satisfying the above conditions. When such water is not available, distilled water or ion exchanged water after distillation or ion exchange is used. These peptizers, flocculants, binders described later, corrosion inhibitors, and the like may be added in advance as a raw material for the glaze slurry before forming the solid material to form a solid material. .

  When the above-mentioned powder before reslurry does not contain a color former, by adding an easily dispersible pigment and stirring, it becomes possible to obtain a desired colored wrinkle in a simple operation and in a short time. . Here, the easily dispersible pigment is one in which a dispersion having the property of being dispersed in an aqueous solvent is held on the surface of the pigment particles of the various metal oxides or composite oxides. Examples of the dispersion include an inorganic electrolyte composed of an alkali metal salt and the like, and a water-soluble polymer such as a cellulose, polyacrylate, and polyethylene oxide, or an anionic surfactant such as a sulfate ester salt and a sulfonate. Those using at least one of these are preferred. In addition, when applying a normal pigment as a color former, separately from the container for reslurry of the ceramic glaze solid, separately using the pigment and the inorganic electrolyte, anionic surfactant or water-soluble polymer, The same effect as that of the easily dispersible pigment can be expected by applying a pretreatment for improving dispersibility and then putting it into a reslurry container.

  When reslurry by stirring the powder and water, a binder and a corrosion inhibitor may be added as necessary. In the present invention, the binder refers to an organic substance having two functions: a viscosity adjusting function in water and at least a binder function capable of improving the strength of the glaze layer when the glaze slurry is dried. Specifically, PVA (polyvinyl alcohol), sodium alginate, CMC (carboxymethyl cellulose) sodium salt, CMC ammonium salt, methyl cellulose, cellulose sodium salt, sodium polyacrylate, polyethylene oxide, PVP (polyvinyl pyrrolidone), starch, dextrin, Various natural rubbers are preferably used. In the present invention, the term “corrosion inhibitor” refers to a drug that has an effect of killing or suppressing the growth of microorganisms such as bacteria or bacteria in glazes, such as triazine compounds, triiodoallyl alcohol (TIAA), silver powder, and the like. Can be suitably used. The viscosity is adjusted to 200 to 1000 mPa · s in the same range as before solidification.

  The glaze slurry whose concentration and viscosity have been adjusted as described above is passed through a refining facility such as a vibrating sieve or a iron remover as necessary to remove foreign matter and undissolved binder, and then arced. Move to a glaze storage facility such as a large container. Thereafter, the glaze slurry in the glaze storage facility is supplied to the glaze facility and applied to the surface of the sanitary ware body by a method such as flow coating, spray coating, dip coating, curtaining, or brushing. The sanitary ware molded article after the glazing is appropriately dried and baked in a temperature range of 1000 to 1300 ° C. in an electric furnace, roller hearth kiln, shuttle kiln, tunnel kiln or the like to obtain sanitary ware products.

(Comparative Example 1)
2 kg of the glaze material having the composition shown in Table 2, 1 kg of water and 4 kg of cobblestone are put into a pot of 6 liter earthenware, and the particle size measurement result of the glaze slurry after pulverization using a laser diffraction particle size distribution meter is 10 μm or less. A glazed slurry A of pastel ivory (# SC1: Totoki equipment color number, the same shall apply hereinafter) is pulverized by a ball mill for about 65 μm and a 50% average particle size (D ₅₀ ) of about 6.5 μm. Got. The water content of the glaze slurry A obtained here was 48% by weight, and the yield value obtained by calculation from the viscosity measured with a B-type viscometer was 16.1 dPa. The time required from the start of the preparation of the glaze raw material to the glaze slurry that can be used in the glazing process was about 24 hours.
Also, by replacing with a different pigment from the glaze slurry A, a pastel yellow (same as # SD1) glaze slurry B and ivory (same as # 54R) glaze slurry C were prepared by the same method.

A ceramic body slurry made of porcelain stone, feldspar, clay, etc. is poured into a gypsum mold and cast to form a plate-shaped body of length × width × thickness = 150 × 70 × 7 mm. The glaze slurries A, B and C obtained as described above were applied to the surface of the dried molded body by spray coating, and baked at 1100 to 1200 ° C. for 24 hours. A sample was obtained. The glaze surface of the sample obtained by applying the glaze slurry A was measured by a spectrophotometer (CM-3700d manufactured by Minolta) using a measurement diameter φ of 25.4 mm and a d / 8 SCI method based on JIS-Z8722 condition c. However, L ^* = 86.841, a ^* = 0.792, and b ^* = 7.721. When the color was measured in the same manner, the glaze slurry B samples were L ^* = 85.012, a ^* =-3.403, b ^* = 26.835, and the glaze slurry C sample was L ^* = 84. .401, a ^* = − 0.305, b ^* = 11.109.

(Comparative Example 2)
Part of the glaze slurry A prepared in Comparative Example 1 was withdrawn and dried by heating at an atmospheric temperature of 110 ° C. for about 24 hours to obtain a solid powder of glaze material. The water content of this powder was measured and found to be 0% by weight. Water was added to the obtained powder so that the water content was 48% by weight, and it was reslurried by mixing and stirring with a blanker for about 5 hours. With respect to the obtained slurry, the yield value was calculated from the viscosity measured with a B-type viscometer, and it was 10.8 dPa. Compared with the glaze slurry before solidification, the yield value was greatly reduced, and the glaze slurry was not suitable for application by spray coating. The reason why the yield value greatly decreased after solidification was that the temperature during drying was too high, and the organic polymer as a binder was decomposed, resulting in a decrease in viscosity after reslurry. This is probably due to the fact that

(Example 1)
Part of the glaze slurry A prepared in Comparative Example 1 was withdrawn and dried by heating at an atmospheric temperature of 80 ° C. for about 24 hours to obtain a solid powder of glaze material. The water content of this powder was measured and found to be 3.7% by weight. Water was added to the obtained powder so that the water content was 48% by weight, and it was reslurried by mixing and stirring with a blanker for about 3 hours. The glaze slurry obtained here is referred to as glaze D. It was 20.2 dPa when the yield value was calculated from the viscosity measured with the B-type viscometer about the glaze D. Although the yield value is slightly higher than that of the glaze slurry before solidification, it is in a range where there is no problem in application by spray coating.
In the same manner as in Comparative Example 1, a plate-like molded body of a ceramic body having a length × width × thickness = 150 × 70 × 7 mm was prepared, and this molded body was dried at 45 ° C. overnight and obtained as described above. A sample was obtained by applying the glaze D to the surface of the dried molded body by spray coating and firing at 1100 to 1200 ° C. for 24 hours. When the glaze surface of the obtained sample was measured in the same manner as in Comparative Example 1 using a spectrocolorimeter (same as above), L ^* = 87.059, a ^* = 0.949, b ^* = 7.777. When compared with the sample obtained from the glaze slurry A of Example 1, the color difference ΔE ^* = 0.275, and the color tone was very small and there was no problem. If the color difference is within a range of ± 1, the color difference is regarded as a level at which the color difference cannot be recognized visually.

(Example 2)
Part of the glaze slurry A prepared in Comparative Example 1 was extracted and dried by heating at an ambient temperature of 60 ° C. for about 24 hours to obtain a solid powder of glaze material. The water content of this powder was measured and found to be 15.2% by weight. Water was added to the obtained powder so that the water content was 48% by weight, and it was reslurried by mixing and stirring with a blanker for about 1 hour. The glaze slurry obtained here is referred to as glaze E. It was 21.0 dPa when the yield value was calculated from the viscosity measured with the B-type viscometer about glaze E. Although the yield value is slightly higher than that of the glaze slurry before solidification, it is in a range where there is no problem in application by spray coating.
In the same manner as in Comparative Example 1, a plate-like molded body of a ceramic body having a length × width × thickness = 150 × 70 × 7 mm was prepared, and this molded body was dried at 45 ° C. overnight and obtained as described above. A sample was obtained by applying the glaze E to the surface of the dried molded body by a spray coating method, followed by baking at 1100 to 1200 ° C. for 24 hours. When the glaze surface of the obtained sample was measured with a spectrocolorimeter in the same manner as in Comparative Example 1, L ^* = 86.989, a ^* = 0.851, b ^* = 7.760. Compared with the sample obtained from the glaze slurry A, the color difference ΔE ^* = 0.164, and there was no problem regarding the color tone.

(Example 3)
Part of the glaze slurry A prepared in Comparative Example 1 was extracted and dried by heating at an ambient temperature of 30 ° C. for about 24 hours to obtain a solid powder of glaze material. The water content of this powder was measured and found to be 20.8% by weight. Water was added to the obtained powder so that the water content was 48% by weight, and it was reslurried by mixing and stirring with a blanker for about 30 minutes. The glaze slurry obtained here is referred to as glaze F. It was 21.7 dPa when the yield value was calculated from the viscosity measured with the B-type viscometer about glaze F. Although the yield value is slightly higher than that of the glaze slurry before solidification, it is in a range where there is no problem in application by spray coating.
In the same manner as in Comparative Example 1, a plate-like molded body of a ceramic body having a length × width × thickness = 150 × 70 × 7 mm was prepared, and this molded body was dried at 45 ° C. overnight and obtained as described above. A sample was obtained by applying the glaze F to the surface of the dried molded body by spray coating and firing at 1100 to 1200 ° C. for 24 hours. The glaze surface of the obtained sample was measured with a spectrocolorimeter in the same manner as in Comparative Example 1. As a result, L ^* = 87.011, a ^* = 0.877, b ^* = 7.735. Compared with the sample obtained from the glaze slurry A, the color difference ΔE ^* = 0.191, and there was no problem regarding the color tone. Table 3 summarizes the evaluation results.

(Comparative Example 3)
The particle size measurement result of the glaze slurry after pulverization using a laser diffraction particle size distribution meter was placed in a ceramic pot with a volume of 6 liters, 2 kg of glaze material with a composition excluding the pigment from Table 2 and 1 kg of water and 4 kg of cobblestone. A white glaze slurry was obtained by pulverizing for about 18 hours by a ball mill so that 10 μm or less was 65% and the 50% average particle diameter (D ₅₀ ) was about 6.5 μm. The white glaze slurry was dried by heating at an ambient temperature of 80 ° C. for about 24 hours to obtain solidified glaze powder. The water content of this powder was measured and found to be 5.8% by weight. By adding water and Pr-based yellow, Fe-based brown, and Co-based blue pigment to the powder so that the water content is 48% by weight, mixing and stirring with a blanker for about 30 minutes to reslurry An attempt was made to prepare a glaze slurry G of pastel yellow (same as # SD1). In the same manner as in Comparative Example 1, a plate-like molded body of a ceramic body having a length × width × thickness = 150 × 70 × 7 mm was prepared, and this molded body was dried at 45 ° C. overnight and obtained as described above. The obtained glaze slurry G was applied to the surface of the dried molded body by a spray coating method, and baked at 1100 to 1200 ° C. for 24 hours to obtain a sample. When the glaze surface of the obtained sample was measured with a spectrocolorimeter in the same manner as in Comparative Example 1, L ^* = 84.484, a ^* = − 1.803, b ^* = 28.312, and Comparative Example 1 When compared with the sample obtained from the glaze slurry B, the color difference was ΔE ^* = 2.219, and it was confirmed that the color tone was greatly deviated visually. This is probably because the mixing and stirring time of the pigment was short and the pigment partially aggregated.
Similarly, by adding water, Pr-based yellow, Fe-based brown, and Si-Ni-Zr-Co-based gray regular pigment to the powder, mixing and stirring with a blanker for about 30 minutes to reslurry. An attempt was made to prepare glaze slurry J of ivory (# 54R) color. Similarly, the glaze slurry J obtained as described above was applied to the surface of the dried molded body by a spray coating method, and baked at 1100 to 1200 ° C. for 24 hours to obtain a sample. The glaze surface of the obtained sample was measured with a spectrocolorimeter in the same manner as in Comparative Example 1. As a result, L ^* = 84.892, a ^* = 0.906, b ^* = 9.063. Compared with the sample obtained from the glaze slurry C, the color difference ΔE ^* = 2.428, and it was confirmed that the color tone was greatly deviated visually. This is probably because the mixing and stirring time of the pigment was short and the pigment partially aggregated.

Example 4
To the powder obtained from the white glaze slurry prepared in Comparative Example 3, an easily dispersible pigment obtained by subjecting water and Pr-based yellow, Fe-based brown, and Co-based blue surface treatment to a water content of 48% by weight The mixture was mixed and stirred with a blanker for about 30 minutes and reslurried to prepare a pastel yellow (same as # SD1) glaze slurry K. A plate-like molded article of sanitary ware body having a length x width x thickness = 150 x 70 x 7 mm was prepared in the same manner as in Comparative Example 1, and this molded article was dried at 45 ° C overnight and obtained as described above. The obtained glaze slurry K was applied to the surface of the dried molded body by a spray coating method, and baked at 1100 to 1200 ° C. for 24 hours to obtain a sample. When the surface of the glaze of the obtained sample was measured with a spectrocolorimeter in the same manner as in Comparative Example 1, L ^* = 85.271, a ^* = − 3.564, b ^* = 27.035, and Comparative Example 1 When compared with the sample obtained from the glaze slurry B, the color difference ΔE ^* = 0.364, and the deviation in color tone was very small and there was no problem.
Further, in the same manner, water and a readily dispersible pigment subjected to surface treatment of Pr yellow, Fe brown, and Si—Ni—Zr—Co gray are added to the powder, and mixed and stirred for about 30 minutes by a blanker. Then, an attempt was made to prepare an ivory (# 54R) glaze slurry L by reslurry. Similarly, the glaze slurry L obtained as described above was applied to the surface of the dried molded body by a spray coating method, and baked at 1100 to 1200 ° C. for 24 hours to obtain a sample. When the glaze surface of the obtained sample was measured with a spectrocolorimeter in the same manner as in Comparative Example 1, L ^* = 84.688, a ^* = − 0.531, b ^* = 11.381, and Comparative Example 1 When compared with the sample obtained from the glaze slurry C, the color difference ΔE ^* = 0.456, and the color tone was very small and there was no problem. Tables 4 and 5 summarize the evaluation results.

Claims (16)

It is characterized by adding water to the glaze raw material for sanitary ware and performing wet pulverization with a ball mill to obtain a glaze slurry, followed by dehydration and / or drying to obtain a solid having a water content of 0 to 25% by weight. Sanitary ware glaze solids. The sanitary ware glaze solid according to claim 1, wherein the sanitary ware glaze solid contains an emulsion and / or a color former. 3. The solid material for sanitary ware glaze according to claim 1 or 2, wherein the slurry is dehydrated by a filter press, and the water content of the solid material after dehydration is 15 to 25% by weight. 3. The sanitary ware glaze solid according to claim 1, wherein the slurry is dried by a spray dryer, and the moisture content of the dried solid is 0 to 15% by weight. 3. The solid material for sanitary ware glaze according to claim 1 or 2, wherein the slurry is dried by a spray dryer, and the moisture content of the solid material after drying is 1 to 10% by weight. The solid material for sanitary ware glaze according to claim 1 or 2, wherein the particle size of the solid material for sanitary ware substrate obtained after drying the slurry is in the range of 0.1 to 10 mm. A step of obtaining a ceramic glaze solid by adding water to a ceramic glaze raw material and performing wet pulverization with a ball mill to obtain a glaze slurry, followed by dehydration and / or drying, the ceramic glaze solid Reslurry process to return to a glaze slurry state by adding water, a molding process to obtain a ceramic molded body, a glazing process for applying the reslurried glaze to the molded body, and a firing process for firing the glazed molded body A method for producing ceramics, characterized by being manufactured through The method for producing a ceramic according to claim 7, wherein the reslurry step includes a step of adding a powder raw material in order to adjust a melt viscosity and a melt distance during firing. 9. The ceramic according to claim 8, wherein the powder raw material is at least one selected from feldspar, limestone, zinc white, dolomite, nepheline, and a frit having substantially the same composition as the solid for ceramic glaze. Manufacturing method. The method for producing a ceramic according to claim 8, wherein the powder raw material is at least one selected from silica sand, alumina, kaolin, clay, zirconium silicate, and tin oxide. The ceramic powder according to any one of claims 8 to 10, wherein an amount of the powder raw material is 0.01 to 20 parts by weight with respect to 100 parts by weight of the ceramic glaze solids. Manufacturing method. The method for producing a ceramic according to claim 7, wherein the reslurry step includes a step of adding a color former in order to adjust the color tone of the glaze layer after firing. The method for producing a ceramic according to claim 12, wherein the color former is an easily dispersible pigment. The method for producing a ceramic according to claim 12 or 13, wherein an amount of the color former is 0.01 to 20 parts by weight with respect to 100 parts by weight of the solid for ceramic glaze. The porcelain according to claim 7, wherein the reslurry step includes a step of adding 0.001 to 5.0 parts by weight of a peptizer or a flocculant to adjust the viscosity of the slurry. Manufacturing method. The method for producing ceramics according to claim 7, wherein the reslurrying step includes a step of adding 0.001 to 10 parts by weight of a binder and / or a corrosion inhibitor.