KR101764564B1 - powder added to glaze, manufacturing method for powder added to glaze and manufacturing method for pottery - Google Patents

Abstract

The present invention relates to a powdered glaze additive. According to an embodiment of the present invention, the powdered glaze additive which is added into glaze in an attempt to produce potteries on which crystal patterns are formed is produced by pulverizing a transfer paper-like base material. The transfer paper-like base material is obtained by applying a pulverization solution onto background transfer paper having a specific size, and then drying the same thereafter.

Description

A method for producing glazed ground powder, a method for manufacturing glazed ground powder, and a method for manufacturing ceramics. {powder added to glaze, manufacturing method for powder added to glaze and manufacturing method for pottery}

The present invention relates to a glaze-added ground product, a method for manufacturing a glaze-added ground product, and a method for manufacturing a ceramics. More specifically, the present invention relates to a glaze-added ground product, .

Generally, ceramics can be produced in the order of a stool step, a molding step, a drying step, a priming step, a sapling step, a chaebol step and an excavation step.

The stoichiometric stage is the operation of working the soil, so that the air bubbles in the soil are removed and the moisture contained in the soil can be evenly distributed in the soil. In the forming step, the basic shape of the pottery can be made by using the earth in which the stool steps have been advanced. In the drying step, the soil (hereinafter referred to as a "material") that has undergone the forming step may be dried to maintain the shape of the pottery. At this time, the pattern may be engraved on the object. At the preliminary stage, the dried material can be baked in a kiln at about 700 ° C for the advanced material. In the metering step, the glaze can be dried after the glaze is finished. In the chaebol stage, the above-mentioned material that has undergone the above-mentioned refining step can be baked in a kiln at about 1300 ° C. At the excavation stage, the kiln is cooled to cool the object (hereinafter referred to as " porcelain ") after completion of the chaebol process, and the porcelain can be excavated by opening the kiln door after sufficient cooling.

Conventionally, in order to express a crystal pattern on the surface of ceramics, Iron powder was added to the glaze. The iron powder adhered to the article and was conquered like the article. The iron powder became chaebol so that the surface of the ceramics had a crystal pattern. However, when the iron powder is added to the glaze due to its high density, there is a problem of sinking into the glaze. Therefore, the pottery maker had to continuously stir the glaze added with the iron powder. Further, the color of the crystal pattern using the iron powder was only realized as the color of the iron powder, black or brown. Further, when the articles are churned at a temperature higher than the temperature at which the iron powder reacts, the iron powder is vaporized and the crystal pattern is not formed on the surface of the pottery. Therefore, there was.

An object of the present invention is to provide a glaze-added pulverized product, a method for producing glazed pulverized product, and a method for manufacturing ceramics, which can be added to glaze instead of iron powder to express a crystal pattern on the surface of a ceramic .

The glaze-added ground product according to an embodiment of the present invention is a glaze-added ground product added to a glaze to produce a ceramic represented by a crystal pattern, wherein the glaze-added ground product is obtained by pulverizing Wherein the transfer substrate is formed by applying a pulverizing liquid to a base transfer sheet having a predetermined size and drying the same.

In the glaze-added pulverized product according to an embodiment of the present invention, the base material in the form of a transfer paper is impregnated with water in the base transfer material coated with the pulverizing liquid, dried, and dried from the base transfer material, And then dried and separated.

In the glaze-added pulverized product according to an embodiment of the present invention,

When the grains are added to the glaze, they are uniformly distributed in the glaze.

A method for manufacturing a glaze-added ground product according to an embodiment of the present invention is a method for manufacturing a glaze-added ground product to produce a glaze-added ground product added to a glaze, Providing a first matrix including a background transfer sheet of the first substrate; Applying a pulverizing liquid to the first matrix to implement the crystal pattern; Drying the first matrix coated with the pulverizing liquid so that the pulverizing liquid is processed into a second matrix in the form of a transfer paper on the first matrix; Impregnating the first matrix processed with the transfer-type second matrix with water to separate the second matrix of the transfer-sheet form on the first matrix; Drying the separated second matrix of the transfer paper type; And grinding the dried second substrate of the transfer paper type to obtain a glaze-added pulverized product to be added to the glaze for realizing the crystal pattern.

The method for producing glazed pulverized material according to one embodiment of the present invention is characterized in that the pulverizing liquid contains a pigment for determining the color of the crystal pattern, a magicting agent for controlling the melting point of the pigment, The oil is produced by mixing.

The method for producing glazed pulverized material according to an embodiment of the present invention is characterized in that the step of applying the pulverizing liquid and drying the first matrix are performed in order to increase the thickness of the second matrix in the form of the transfer paper on the first matrix , And repeatedly proceeding.

The glaze added pulverized product manufacturing method according to an embodiment of the present invention is characterized in that before the second mother body is separated, the pulverized liquid applied on the first mother body and dried is processed into the second mother body, Coating one side of the substrate; And further comprising:

In the method for producing glazed pulverized material according to an embodiment of the present invention, the glaze-added pulverized material is realized in a flat form due to the pulverization of the second matrix of the transfer paper type, and when added to the glaze, And the like.

According to another aspect of the present invention, there is provided a method of manufacturing a pottery, the method comprising the steps of: preparing a glaze; Adding a glazed ground powder to the glaze; And a metering step of immersing the glaze-added article in the glaze to which the glaze-added ground product is added, and attaching the glaze-added ground product to the article, wherein the glaze-added ground product is obtained by pulverizing Wherein the transfer substrate is formed by applying a pulverizing liquid to a base transfer sheet having a predetermined size and drying the same.

In the ceramics manufacturing method according to an embodiment of the present invention, the base of the transfer paper type is implemented by being separated from the base transfer paper by impregnating the dried base transfer paper coated with the pulverizing liquid and dried in water have.

Industrial Applicability According to the present invention, it is possible to reduce the labor required in the fermentation step by using the glaze-added ground product, the glaze-added ground product, and the ceramics production method.

Further, according to the present invention, it is possible to shorten the time required in the fueling step.

In addition, according to the present invention, crystal patterns of various colors can be embodied in ceramics.

Further, according to the present invention, crystal patterns can be embodied in ceramics that are baked at various temperatures.

Further, according to the present invention, the crystal pattern can be embodied in one part of the ceramics.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a flow chart of a method for manufacturing a glazed ground powder according to an embodiment of the present invention. FIG.
Fig. 2 is a view for explaining the step of applying the pulverizing liquid according to Fig. 1; Fig.
Figure 3 is a view of the matrix according to Figure 1;
FIG. 4 is a view for explaining a second matrix separation step and a second matrix drying step according to FIG. 1; FIG.
FIG. 5 is a view for explaining the step of obtaining a pulverized product according to FIG. 1; FIG.
6 is a flow chart of a method of manufacturing a pottery according to an embodiment of the present invention.
7 is a view for explaining the step of adding the glaze-added pulverized product according to FIG.
8 is a diagram for explaining the reference step according to FIG. 6;
Fig. 9 is a view for explaining another embodiment of the referencing step according to Fig. 6; Fig.
FIG. 10 is a photograph of products of ceramics illustratively made by the method of manufacturing a ceramic according to FIG.

Hereinafter, specific embodiments of the present invention will be described in detail with reference to the drawings. It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the inventive concept. Other embodiments falling within the scope of the inventive concept may readily be suggested, but are also considered to be within the scope of the present invention.

The same reference numerals are used to designate the same components in the same reference numerals in the drawings of the embodiments.

1 is a flowchart illustrating a method of manufacturing a glaze-added pulverized product according to an embodiment of the present invention.

Referring to FIG. 1, a method of manufacturing a glazed ground product for manufacturing a glazed ground product 30 (see FIG. 5) to be added to a glaze to produce a ceramics in which a crystal pattern is expressed, S10), a pulverized liquid application step (S20), and a first matrix drying step (S30). A second matrix separation step (S40), a second matrix drying step (S50), and a pulverized material acquisition step (S60).

The glaze added pulverized product 30 added to the glaze can be produced by the above-described steps.

The matrix may include a first matrix 10 (see FIG. 3) and a second matrix 20 (see FIG. 3).

The second mother body 20 may be disposed on one side of the first mother body 10.

For example, the first matrix 10 may be a base transfer sheet of a predetermined size.

Here, the background transfer sheet may be a paper sheet on which pigment, dye or the like is not printed.

Here, the background transfer paper may be made of at least one material such as starch, ceramics, and silicone.

However, the background transfer sheet is not limited thereto, and may include any material that can be used at a level that is obvious to a person skilled in the art.

Referring to the description of the background of the invention, it can be said that the soil in which the basic shape of the ceramics is realized by the molding step. In addition, the above-mentioned material having passed through the chaebol step can be referred to as a ceramic.

The first matrix providing step S10 may be a step of preparing the first matrix 10 to perform the steps described later.

That is, the first matrix providing step S10 may be a step of providing a first matrix 10 including a background transfer sheet of a predetermined size.

Fig. 2 is a view for explaining the step of applying the pulverizing liquid according to Fig. 1;

Referring to Fig. 2, in order to carry out the pulverizing liquid application step (S20), the pulverizing liquid (f) may be first prepared.

The pulverizing liquid (f) may be prepared by mixing a pigment for determining the color of the crystal pattern, a magic agent for controlling the melting point of the pigment, and an oil for easily mixing the pigment and the magenta agent.

However, the pulverizing liquid (f) may be formed by mixing various materials in addition to the pigment, the antistatic agent, and the oil at a level that is obvious to a person skilled in the art.

The pigment may have various colors other than brown or black.

For example, the pigment may be a dried color paint.

For example, the pigment may be a colorless powder that is insoluble in water. The pigment may be at least one selected from the group consisting of cadmium, cadmium, selenium, vanadium, cobalt, chromium, copper , iron oxide (FeO), zinc (Zn), manganese (Mn), and alumina (Al 2 O 3) .

However, the pigment may be any kind of pigment that can be used in the production of ceramics, at a level that is obvious to a person skilled in the art.

The anticaking agent may be a fusing agent.

The above-mentioned antistatic agent can appropriately melt the pigment through the control of the melting point of the composition, so that the crystal shape can be smoothly realized on the surface of the ceramics.

The above-mentioned antistatic agent can control the melting point of the components contained in the glaze.

For example. The above-mentioned antistatic agent may be formed by mixing at least one of glass raw materials such as frit, silica sand, boric acid and borax.

Here, the melting point of the glazed powder 30 may be lowered as the amount of the antistatic agent added to the pulverizing liquid is increased.

In addition, for example, the antistatic agent may be a mineral having a high melting point such as alumina.

Here, the melting point of the glazed powder 30 may be increased as the amount of the antistatic agent added to the pulverizing liquid increases.

For reference, when the above-mentioned antistatic agent is added to the glaze, the melting point of the glaze can be controlled.

For example, when the above-mentioned antioxidant is made of one of the glass raw materials, the melting point of the glaze may be lowered as the amount of the antioxidant added to the glaze increases.

However, the present invention is not limited thereto, and the above-mentioned antistatic agent may include all the fluxes used in manufacturing the ceramics at a level that is obvious to the ordinary artisan.

The oil may allow easy and even mixing of the pigment and the tackifier.

If the oil is omitted in the process of mixing the pigment and the antistatic agent, the pigment and the antistatic agent can not be uniformly mixed, so that the control of the melting point by the antistatic agent can not be precisely controlled.

Here, the composition ratios of the pigment, the flavoring agent and the oil can be variously changed in consideration of the production process of ceramics, the purpose of producing ceramics, and the like.

For example, if the chaebol process is carried out at high temperatures to produce pottery for tableware, the proportion of ingredients in the antioxidant can be reduced. In addition, if the chaebol process is carried out at a low temperature to produce decorative ceramics, the content ratio of the anticorrosive agent can be increased.

In addition, the pulverizing liquid (f) may be added with a pigment corresponding to the hue of the crystal to be expressed in the ceramics.

In order to carry out the pulverized solution applying step (S20), the filtering section 51, the frame section 52 and the application device 53 may be required.

The filtering section 51 may have fine through-holes.

As an example, the filtering section 51 may be a fabric, a silk or a film.

The inside of the frame part 52 can be penetrated so that the pulverizing liquid f can be received.

The application device 53 may transfer the pulverizing liquid f from the container containing the pulverizing liquid f to the frame 52 and apply the pulverizing liquid f.

The pulverized liquid application step (S20) may be performed in the following process.

And the filtering section 51 can be attached to one surface of the frame section 52. The frame 52 to which the filtering unit 51 is attached may be disposed on one side of the first mother body 10.

That is, the frame portion 52 is disposed on one side of the screening portion 51, and the first matrix 10 is disposed on the other side of the screening portion 51.

Thereafter, the applying unit 53 applies the pulverizing liquid f to one side of the filtering unit 51 after the pulverizing liquid f stored in the container is applied to the first matrix 10, (F).

The pulverizing liquid f may flow out of the application device 53 and be applied to the first matrix 10 through the fine holes of the screening portion 51.

The applicator 53 can repeatedly reciprocate the penetrating portion formed in the frame portion 52 so that the pulverizing liquid f is uniformly applied to the first mother body 10. [

Figure 3 is a view of the matrix according to Figure 1;

3 (a) and 3 (b), the matrix may include a first matrix 10, a second matrix 20, and the like.

Here, FIG. 3 (b) is exaggeratedly shown for convenience of explanation.

The first matrix drying step (S30) is a step of drying the first matrix 10 coated with the pulverized liquid (f). The pulverized liquid (f) may be dried to form a pulverized liquid layer (21) on one side of the first mother body (10).

In other words, the first mother drying step S30 is performed in such a manner that the pulverizing liquid f is applied to the second mother body 20 in the form of a transfer paper on the first mother body 10, 1 may be a step of drying the matrix 10.

Herein, the pulverizing liquid applying step (S20) and the first mother drying step (S30) are repeatedly performed to increase the thickness of the second mother body (20) on the first mother body (10) . By controlling the thickness of the second matrix 20, the density or specific gravity of the glaze added ground substance 30 can be controlled, and when the glaze added ground substance 30 is added to the glaze, And the area of distribution of the glaze added powder 30 in the glaze can be controlled.

The pulverizing liquid f applied on the first mother body 10 dried before the second mother body 20 is separated, that is, before the second mother separating step S40 proceeds, A step of coating one side of the pulverizing liquid f may be performed so as to be processed into the second matrix 20.

Here, the coating step may be such that the pulverized liquid layer 21 implemented by the pulverized liquid f applied to one surface of the first mother body 10 is not contaminated from the external environment.

Here, the coating step may facilitate separation of the pulverized liquid layer 21 from the first matrix 10.

The coating layer 22 may be formed on one surface of the pulverized liquid layer 21 through the coating step and the coating layer 22 may be formed on at least a portion of the first matrix 10.

In other words, the coating layer 22 is formed only on one surface of the pulverizing liquid layer 21 and on one surface of the first mother body 10, but is not limited thereto.

For example, the coating layer 22 may be formed on only one surface of the second mother body 20, and may be formed on the entire surface of the second mother body 20 and on the entire surface of the first mother body 10 .

When the coating step is performed, the second matrix 20 may be in the form of a transfer paper having a pulverized liquid layer 21 and a coating layer 22.

However, if the coating step is not carried out, the second matrix 20 may have only the pulverized liquid layer 21.

Since the second matrix 20 may include the coating layer 22, it is possible to maintain a flat polygonal shape even if the second matrix 20 is pulverized by the pulverized material acquisition step S60.

In addition, since the second mother body 20 can include the coating layer 22, the glaze added crushed material 30 produced by the manufacturing method according to the present invention can maintain a flat polygonal shape even when added to the glaze .

The second mother body 20 may be formed on a portion of one surface of the first mother body 10 in the form of a transfer paper.

Here, although the second matrix 20 is shown in blue, the hue of the second matrix 20 may be varied according to the material of the pigment.

On the other hand, the second mother body 20 in the form of a transfer sheet can be manufactured in various types by adjusting the amount of the above-mentioned antistatic agent on the basis of the temperature at which it becomes chaebol.

For example, the component ratio of the magentic agent in the pulverizing liquid (f) implemented by the second matrix 20 may be small for use in a material to be conglomerated at 1200 ° C. In addition, in order to use for a material to be enriched at 400 DEG C, the ratio of ingredients of the magentic agent in the pulverizing liquid (f) may be large.

In addition, the second matrix 20 may be manufactured in various types based on colors.

For example, the pigment added to the pulverizing liquid (f) is blue, and the second matrix 20 may be blue as shown in the drawing. Further, the pigment added to the pulverizing liquid (f) may be red, and the second matrix 20 may be red.

The user can manufacture various kinds of second mother bodies 20 based on the temperature, and thus, various types of glazed pulverized material 30 can be manufactured.

Further, the user can manufacture various kinds of second mother bodies 20 having different colors from each other, and thus, various types of glazed crushed material 30 can be manufactured.

Accordingly, the user can add various kinds of glaze-added crushed material 30 having various melting points and various colors to the glaze in response to the ceramics manufacturing process, thereby realizing various crystal patterns in the ceramics.

4 is a view for explaining the second matrix separation step and the second matrix drying step according to FIG.

4 (a), 4 (b), and 4 (c), the second matrix separating step S40 is a step in which the matrix is immersed in water w, 2 mother body 20 can be separated.

4 (a) and 4 (b), the first mother body 10 processed with the second mother body 20 of the transfer paper type is impregnated with water w.

4 (c), after the first mother body 10 and the second mother body 20 have been sufficiently separated from each other by an external force, The first mother body 10 and the second mother body 20 can be separated from each other by an external force after the mother body 20 is taken out from the water w.

That is, the first mother body 10 processed with the transfer-type second mother body 20 is impregnated with water w to separate the second mother body 20 of the transfer-type from the first mother body 10 .

Here, if the coating layer 22 is formed by the coating step, when the first matrix 10 is impregnated with the water w, the second matrix 20 can easily be removed from the first matrix 10 It can be separated.

More specifically, the coating layer 22 is coated on the first matrix 10 and applied to the dried matrix f and the first matrix 10, To be bonded to the first mother body (10). That is, the coating layer 22 may be adhered to the first matrix 10 and the crushed liquid layer 21. Therefore, the coating layer 22 can integrate the pulverized liquid layer 21 and the first matrix 10.

However, when the coating layer 22 is impregnated with the water w, the adhesion with the crushed liquid layer 21 is not weakened, but the adhesion with the first mother body 10 may be weakened. Therefore, when the first mother body 10 is impregnated with the water w, the coating layer 22 can be easily separated from the first mother body 10 by the small external force together with the crushed liquid layer 21 have.

Referring to FIG. 4 (d), in the second mother matrix drying step (S50), the separated second mother matrix 20 may be dried

FIG. 5 is a view for explaining the step of obtaining the pulverized material according to FIG. 1. FIG.

In the pulverized material obtaining step (S60), the dried second granular material (20) may be pulverized to obtain the glaze added pulverized material (30) added to the glaze to realize the crystal pattern.

Here, the second matrix 20 can be pulverized by the pulverizer to obtain the glaze-added pulverized product 30.

Here, since the second mother body 20 is present in the form of a transfer paper, the glazed powder 30 may have a flat and polygonal shape.

In addition, the second matrix 20 may be pulverized into various sizes to obtain various kinds of glaze-added pulverized materials 30 having different sizes.

For example, in order to obtain a pattern having a large crystal shape, the second matrix 20 may be crushed to a large size. Similarly, in order to obtain a pattern of a crystal shape with a small size, the second matrix 20 may be pulverized to a small size.

The user can grind the second matrix 20 and obtain various types of glazed grindstones 30 on the basis of the size. Accordingly, the user can selectively use the glazed powder 30 in consideration of various purposes such as the purpose of producing ceramics, the use environment, and the like.

Also, since the second mother body 20 includes the coating layer 22, the process of grinding the glazed ground material 30 to have a flat and polygonal shape can be easily performed.

The method for manufacturing the glazed ground product 30 will now be described briefly from the point of view of the glazed ground product 30.

The glaze added grindstone 30 added to the glaze is manufactured by grinding a matrix of the transfer paper type and the matrix of the transfer paper type is formed by grinding a base paper of a predetermined size f) may be applied and dried.

Here, the matrix of the transfer sheet type may correspond to the second matrix 20 of the transfer sheet type separated on the first matrix 10 realized by the second matrix drying step (S50) described with reference to FIG.

That is, the mother paper in the form of a transfer paper is obtained by impregnating the base transfer paper coated with the pulverizing liquid (f) and drying the paper into water, separating the dried pulverizing liquid (f) from the base transfer paper, The second mother body 20 may be a transfer base paper.

FIG. 6 is a flowchart illustrating a method of manufacturing a ceramic according to an embodiment of the present invention, FIG. 7 is a view for explaining a step of adding glaze added ground water according to FIG. 6, FIG. 8 is a view FIG. 9 is a view for explaining another embodiment of the sewing step according to FIG. 6, and FIG. 10 is a photograph of products of a porcelain which is illustratively manufactured by the porcelain manufacturing method according to FIG.

Referring to FIG. 6, the method for manufacturing a pottery includes the steps of preparing a glaze (step S100), preparing a glaze (step S200), adding glazed ground water (step S300) S600). However, the flowchart in Fig. 6 is an example, and the order can be changed. As an example, the glaze preparation step may be performed before the priming step.

The preliminary step (SlOO) may be a step of pruning the object from the kiln.

The glaze preparation step (S200) may be a step of preparing a glaze corresponding to the purpose of the ceramics to be produced.

For example, if the article is to be subjugated at high temperatures, a solidifying glaze may be prepared which is fired at 1230 ° C to 1370 ° C.

For example, the glaze (g) may include feldspar, silica, limestone clay, talc, clay, titanium, calcium phosphate and the like.

The glaze (g) may be any kind of glaze (g) that can be used on the ceramics at a level that is obvious to a general practitioner in consideration of the purpose of producing the ceramics and the use environment .

Referring to FIG. 7, the step of adding the glaze added pulverized product (S300) is a step of adding the glaze added grinding product 30 obtained by proceeding with the steps described with reference to FIG. 1 to FIG. 5 to the glaze (g) .

At this time, the glaze added pulverized product 30 corresponding to the color of the crystal to be expressed on the ceramic can be added to the glaze g.

For example, if a blue crystal pattern is to be embodied in the ceramics, the glaze powder 30 obtained by pulverizing the second matrix 20 embodied by the pulverized liquid (f) (g). < / RTI >

Further, the glaze added pulverized product 30 may be added to the glaze (g) in correspondence with the temperature at which the article is to be conglomerated.

For example, if the temperature at which the article is to be conglomerated is high, the glaze powder 30 in which the second matrix 20 containing the proportion of the corresponding antistatic agent is pulverized may be added to the glaze (g) have.

Further, the glaze-added pulverized product 30 may be added to the glaze (g) in correspondence with the color of the crystal pattern expressed in the ceramics.

For example, if a crystal pattern of red is to be expressed on the ceramics, the glaze powder 30 obtained by grinding the second mother body 20 having a red color may be added to the glaze g.

For example, if a crystal pattern of various colors is to be expressed in the ceramics, various kinds of glazed crushed material 30 having different colors may be added to the glaze f.

In the step S400, the article may be immersed in the glaze g to apply the glaze g to the article.

That is, in the step of S400, the glaze (g) to which the glaze additive 30 is added may be immersed in the glaze, and the glaze additive 30 may be attached to the glaze.

8, the glaze-added pulverized product 30 is realized in a flat form due to the pulverization of the second matrix 20 in the form of a transfer paper, and when the glaze is added to the glaze g, 0.0 > g). < / RTI >

Here, the uniform distribution means that the number of particles of the glaze added pulverized product 30 in the unit volume of the glaze (g) is not only the same but also exists within a predetermined error range have.

In addition, since the glaze added ground product 30 is formed in a flat shape, the glaze added ground product 30 may not sink in the glaze g. It may not be necessary to continue stirring the glaze g to prevent the glaze powder 30 from sinking into the glaze g.

In addition, the coating layer 22 of the glaze-added ground product 30 may maintain the shape of the glaze-added ground product 30.

When the article 1 is immersed in the glaze g (Figs. 8A and 8B), the article 1 is coated with the glaze g, 30 can be attached. (Fig. 8 (c)).

Referring to FIG. 9, the reference step may be implemented differently from FIG.

If the pulverized liquid (f) is applied to the first mother body 10 several times in the pulverized liquid application step (S20), the thickness of the pulverized liquid layer (21) may become thick. Accordingly, the thickness of the second matrix 20 can be increased.

At this time, when the glaze powder 30 obtained by grinding the second mother body 20 having a large thickness is added to the glaze g, the glaze powder 30 may be added to the glaze g And can be densely positioned from the middle portion to the lower portion.

Here, the glaze g may be contained in a glazing container that provides a storage space.

Here, the direction of the paper in the glaze bottle may be referred to as the lower part of the glaze g, the direction opposite to the paper surface as the upper part of the glaze g, and the lower part and the upper part as the middle part of the glaze g.

At this time, since the glaze added powder 30 is a flat polygon, it can be positioned not only at the lower part of the glaze g but also up to the middle part.

9 (a) and 9 (b)), the glaze (g) is applied to the whole of the article 1, and the article 1 The glaze added pulverized product 30 can be attached to a part of the glaze added product (Fig. 9 (c)).

The manufacturer may immerse the article (1) in the glaze (g) in consideration of a portion of the ceramic article to express the crystal pattern.

This can have the advantage of being able to implement only the desired location of the crystal pattern of the pottery

For example, if a crystal pattern is to be displayed only on the lower part of the ceramic, only the lower part of the article 1 may be immersed in the glaze g in which the glaze additive 30 is located.

9, the glaze added pulverized product 30 is attached only to the lower part of the product 1, but the glaze added product 30 attached to the product 1 1) can be varied in various ways.

For example, in order to express a crystal pattern only on the upper part of the ceramic, only the upper part of the article 1 may be immersed in the glaze g in which the glaze additive 30 is located.

FIG. 10 (a) is a photograph of a ceramics (100) in which a crystal pattern produced through a chaebol step of enchanting a material having undergone the sewing step according to FIG. 8 and a ceramics obtaining step excavated from a kiln.

Here, the color of the crystal pattern may be varied in various ways according to the pigment described above, and the size and shape of the crystal pattern may be determined by a person skilled in the art, such as the ratio of the magenta agent in the pulverizing liquid (f) It can be variously changed at one level.

When the chaebol step is carried out, the coating layer 22 of the glaze added pulverized product 30 is burned and only the pulverized liquid layer 21 of the glaze added pulverized product 30 is fired on the surface of the product 1 A crystal pattern can be formed.

FIG. 10 (b) is a photograph of a pottery 200 expressing a crystal pattern produced through a chaebol step of enchanting the object on which the fermentation step according to FIG. 9 has been performed and a pottery obtaining step excluded from the kiln.

 10 (a), a crystal pattern may be formed only on the lower portion of the ceramic body 200.

Here, the color of the crystal pattern may be variously changed according to the pigment described above, and the size and shape of the crystal pattern may be variously changed at a level that is obvious to a general technician such as the temperature of the magic agent or the conglomerate.

Likewise, when the chaebol step proceeds, the coating layer 22 of the glazed ground product 30 is burnt and only the ground layer 21 of the glaze added ground product 30 is exposed on the surface of the product 1 A crystal pattern can be formed.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, It will be apparent to those skilled in the art that changes or modifications may fall within the scope of the appended claims.

1: article 10: first matrix
20: second matrix f: pulverized liquid

Claims (10)

In order to produce a pottery in which a crystal pattern is expressed, in the glaze-added ground powder added to the glaze,
The glaze-added pulverized product,
It is implemented by crushing the matrix of the transfer paper type,
The transfer sheet type mother body may be formed by,
Characterized in that the pulverized liquid is applied to a base transfer paper of a predetermined size and dried.
The method according to claim 1,
The transfer sheet type mother body may be formed by,
Wherein the primer is applied by impregnating the base transfer paper coated with the pulverized liquid and dried in water, separating the dried pulverized liquid from the base transfer paper, and then drying the pulverized liquid.
3. The method of claim 2,
The glaze-added pulverized product,
Characterized in that it is realized in a flat form due to the pulverization of the matrix of the transfer paper type and is uniformly distributed in the glaze when added to the glaze.
A method for manufacturing a glaze-added ground product for producing a glaze-added ground product added to a glaze to produce a ceramics in which a crystal pattern is expressed,
Providing a first matrix including a base transfer paper of a predetermined size;
Applying a pulverizing liquid to the first matrix to implement the crystal pattern;
Drying the first matrix coated with the pulverizing liquid so that the pulverizing liquid is processed into a second matrix in the form of a transfer paper on the first matrix;
Impregnating the first matrix processed with the transfer-type second matrix with water to separate the second matrix of the transfer-sheet form on the first matrix;
Drying the separated second matrix of the transfer paper type; And
And grinding the dried second grains in the form of a transfer paper to obtain a glaze-added pulverized product added to the glaze to realize the crystal pattern.
5. The method of claim 4,
The above-
A pigment for determining the color of the crystal pattern, a coloring agent for adjusting the melting point of the pigment, and an oil for easily mixing the pigment and the coloring agent.
6. The method of claim 5,
The step of applying the pulverizing liquid and drying the first matrix may further comprise:
Characterized in that the process is repeatedly carried out to increase the thickness of the second matrix in the form of a transfer sheet on the first matrix.
5. The method of claim 4,
Further comprising the step of coating one side of the pulverized liquid so that the pulverized liquid applied on the first mother and dried before the second mother is separated is processed into the second mother, ≪ / RTI >
5. The method of claim 4,
The glaze-added pulverized product,
Characterized in that it is realized in a flat form due to the pulverization of the second matrix of the transfer paper type and is uniformly distributed in the glaze when added to the glaze.
A method of manufacturing a pottery for producing a pottery in which a crystal pattern is expressed,
Preparing a glaze;
Adding a glazed ground powder to the glaze; And
And a metering step of immersing the glaze in the glaze to which the glaze added pulverized product has been added and attaching the glaze added powder to the product,
The glaze-added pulverized product,
It is implemented by crushing the matrix of the transfer paper type,
The transfer sheet type mother body may be formed by,
Wherein the pulverizing liquid is applied to the base transfer paper of a predetermined size and dried to realize the ceramics.
10. The method of claim 9,
The transfer sheet type mother body may be formed by,
Wherein the base transfer sheet is formed by separating the base transfer sheet from the base transfer sheet by impregnating the dried base transfer sheet with water.

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