KR20230137153A - Method for manufacturing ceramic products using fine particulate powder mixed Taebaek soil component and Taebaek rock component - Google Patents

Abstract

The present invention relates to a method of manufacturing ceramic products using fine particle powder mixed with Taebaek clay and Taebaek rock components. Taebaek clay containing quartz, mica, chlorite and montmorillonite (bentonite) as main constituent minerals, quartz, chlorite and mica and Taebaek rock, which contains feldspar as its main constituent mineral, to produce beautiful ceramic products using fine particle powder mixed with ingredients.

Description

Method for manufacturing ceramic products using fine particulate powder mixed Taebaek soil component and Taebaek rock component}

The present invention relates to technology for manufacturing ceramic products such as pottery, and in particular, to a method for manufacturing ceramic products using fine particle powder mixed with Taebaek clay and Taebaek rock components.

Minerals have different crystal forms as well as different physical properties. The characteristic physical properties of minerals include color, streak, gloss, hardness, specific gravity, cleavage, singularity, viscosity, magnetism, luminescence, electrical properties, and thermal properties. ) properties, etc. Important elements that characterize minerals are their chemical composition and crystal structure. In general, minerals have different colors and effects depending on their chemical composition.

Geologically, the Taebaek soil and Taebaek rock layer of Taebaek, Gangwon-do are distributed in the Paleozoic Era red-spot layer (gray-green sandy shale, red sandy shale, etc.) of the Paleozoic Era and the Cretaceous macular rock layer of the Mesozoic Era. Taebaek rock contains quartz, chlorite, mica, and feldspar. It contains major minerals, and includes silicon, aluminum, iron, potassium, magnesium, and sodium in small or trace minerals.

Taebaekam is a honeycomb structure with a wide surface and numerous spaces forming a double-layer structure. In this sponge-like honeycomb space, a large amount of far-infrared rays are absorbed and stored, and when heated, they are emitted and stimulate the molecular activity of other objects. In other words, Taebaek Rock is a mineral that has been absorbing solar energy for many years, and can be said to be a solar energy reservoir for emitting far-infrared rays and negative ions.

Taebaek Rock changes into Taebaek clay through weathering over a long period of time, and in the process of changing into Taebaek clay, it acquires unique properties and colors. This Taebaek clay contains quartz, mica, chlorite, and montmorillonite (bentonite) as main constituent minerals, and also contains small or trace minerals such as silicon, aluminum, iron, potassium, magnesium, and sodium.

Monroel nonite (bentonite), which is included in Taebaek clay, has been used as an herbal mineral since ancient times, and has functions such as removing toxins, adsorbing pollution, sterilizing, and deodorizing due to its cation exchange properties. In addition, Taebaek soil contains numerous mineral nutrients and can be used as a material for various purposes.

Meanwhile, chlorite (phyllite), a natural mineral contained in Taebaek soil, is evaluated as a mysterious substance that acts as a soil activator and physiological activator at the same time. In particular, it has excellent effects such as generation of dissolved oxygen (active oxygen), adsorption of suspended substances, removal of heavy metals, deodorization, and bacteriostatic action to remove viruses and bacteria.

In addition, chlorite (phyllite) contains a variety of medicinal elements, making it highly toxic and detoxifying, showing excellent efficacy not only for the soil, but also for the plants growing on it, and even for the health of the human body and livestock. It is in the spotlight as a material for various purposes.

In this way, Taebaek soil and Taebaek rock generate a lot of dissolved oxygen due to good air circulation, have excellent humidity control ability, have excellent antibacterial effect, do not grow mold, have excellent deodorizing effect, and have excellent heavy metal removal ability. It has excellent heat dissipation effect, constant temperature capability, and high far-infrared ray radiation.

In the Republic of Korea Patent No. 10-2285051 (announced on August 3, 2021), which was previously applied for and registered by the present inventor, unique Taebaek soil containing quartz, mica, and chlorite as main constituent minerals, which can only be collected in Taebaek, Gangwon-do, and Taebaek sandstone were used. A technology for manufacturing beautiful ceramic products with gems or precious metals attached only through single firing without first or second firing was proposed.

The present inventor improved the method for manufacturing ceramic products using Taebaek clay and Taebaek sandstone presented in Republic of Korea Patent No. 10-2285051 (announced on August 3, 2021) and used quartz, mica, chlorite, and montmorillonite (bentonite) as the main constituent minerals. A study was conducted on the technology of manufacturing beautiful ceramic products using fine particle powder mixed with Taebaek clay containing Taebaek clay and Taebaek rock containing quartz, chlorite, mica and feldspar as main constituent minerals.

Republic of Korea Patent No. 10-2285051 (announced on 2021.08.03)

The present invention uses fine particle powder mixed with Taebaek clay, which contains quartz, mica, chlorite, and montmorillonite (bentonite) as main minerals, and Taebaek rock, which contains quartz, chlorite, mica, and feldspar as main minerals. The purpose is to provide a method for manufacturing ceramic products using fine particle powder mixed with Taebaek clay and Taebaek rock ingredients that can produce ceramic products.

According to one aspect of the present invention for achieving the above object, a method of manufacturing ceramic products using fine particle powder mixed with Taebaek clay and Taebaek rock components includes quartz, mica, chlorite, and montmorillonite (bentonite) as main constituent minerals. , Taebaek clay, which contains small or trace minerals such as silicon, aluminum, iron, potassium, magnesium, and sodium, and which contains quartz, chlorite, mica, and feldspar as main constituent minerals, and contains silicon, aluminum, iron, potassium, magnesium, and sodium. A powder manufacturing step of producing a fine particle powder mixed with Taebaek rock components containing small or trace minerals; A kneading step of kneading the fine particle powder mixed with Taebaek clay and Taebaek rock ingredients produced in the powder manufacturing step; A molding step of molding the fine particle powder dough mixed with Taebaek clay and Taebaek rock ingredients kneaded through the kneading step into a ceramic product body of a desired shape; An attachment step of attaching at least one gem or precious metal to a specific position of the body of the ceramic product formed by the molding step; A drying step of drying the body of the ceramic product to which at least one gem or precious metal is attached by the attachment step; It includes a single firing step of firing the dried ceramic product body in a single firing step.

According to an additional aspect of the present invention, a method for manufacturing ceramic products using fine particle powder mixed with Taebaek clay and Taebaek rock components is provided.

A method of manufacturing a ceramic product using fine particle powder mixed with Taebaek clay and Taebaek rock includes an inlay step of engraving a pattern on the main body of the molded ceramic product after the molding step; It may include at least one of the alloy coloring steps of coloring letters, pictures, etc. using alloy on the main body of the ceramic product to which at least one gem or precious metal is attached by the attachment step.

According to an additional aspect of the present invention, the method of manufacturing a ceramic product using fine particle powder mixed with Taebaek clay and Taebaek rock components may further include a glaze step of applying a glaze to the dried ceramic product body after the drying step.

According to an additional aspect of the present invention, a method of manufacturing a ceramic product using fine particle powder mixed with Taebaek clay and Taebaek rock components includes a molding attachment step of attaching a new ceramic product molding to a single fired ceramic product body; It may further include a conglomerate firing step of firing the ceramic product body to which the new ceramic product molding is attached by the molding attachment step.

According to an additional aspect of the present invention, a method of manufacturing a ceramic product using fine particle powder mixed with Taebaek clay and Taebaek rock components includes a molding additional attachment step of additionally attaching another ceramic product molding to the main body of the ceramic product after firing the conglomerate; It may further include a three-stage firing step of firing three ceramic product bodies to which another ceramic product molding is additionally attached through the additional molding attachment step.

The present invention uses fine particle powder mixed with Taebaek clay, which contains quartz, mica, chlorite, and montmorillonite (bentonite) as main minerals, and Taebaek rock, which contains quartz, chlorite, mica, and feldspar as main minerals. Since ceramic products can be manufactured, it has the effect of helping revitalize the local economy.

Figure 1 is a block diagram showing the configuration of an embodiment of a method for manufacturing ceramic products using fine particle powder mixed with Taebaek clay and Taebaek rock components according to the present invention.
Figure 2 is a block diagram showing the detailed configuration of the powder manufacturing step of the method for manufacturing ceramic products using fine particle powder mixed with Taebaek clay and Taebaek rock components according to the present invention.
Figure 3 is a copy of the main mineral test report report of the Korea Mine & Reclamation Corporation Technology Research Institute for Taebaek soil and Taebaek rock used in the production of fine particle powder mixed with Taebaek soil and Taebaek rock components.
Figure 4 is a copy of the small or trace mineral test report report of the Korea Mine & Reclamation Corporation Technology Research Institute for Taebaek soil and Taebaek rock used in the production of fine particle powder mixed with Taebaek soil and Taebaek rock components.
Figure 5 is a diagram illustrating a ceramic product manufactured by the method of manufacturing a ceramic product using a fine particle powder mixed with Taebaek clay and Taebaek rock components according to the present invention.
Figure 6 is a diagram illustrating the body of a ceramic product in which the damaged portion is repaired by firing a ceramic product using a method of manufacturing a ceramic product using a fine particle powder mixed with Taebaek clay and Taebaek rock components according to the present invention.
Figure 7 is a diagram illustrating the main body of a ceramic product manufactured by firing three sets by the method of manufacturing a ceramic product using fine particle powder mixed with Taebaek clay and Taebaek rock components according to the present invention.

Hereinafter, the present invention will be described in detail through preferred embodiments described with reference to the accompanying drawings so that those skilled in the art can easily understand and reproduce it. Although specific embodiments are illustrated in the drawings and related detailed descriptions are described, they are not intended to limit the various embodiments of the present invention to any particular form.

In describing the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the gist of the embodiments of the present invention, the detailed description will be omitted.

When a component is said to be "connected" or "connected" to another component, it is understood that it may be directly connected to or connected to the other component, but that other components may exist in between. It should be.

On the other hand, when it is mentioned that a component is “directly connected” or “directly connected” to another component, it should be understood that there are no other components in between.

Figure 1 is a block diagram showing the configuration of an embodiment of a method for manufacturing ceramic products using fine particle powder mixed with Taebaek clay and Taebaek rock components according to the present invention. As shown in Figure 1, the method for manufacturing ceramic products using fine particle powder mixed with Taebaek clay and Taebaek rock components according to this embodiment includes a powder manufacturing step (110), a kneading step (120), and a molding step (130). ), an attachment step (140), a drying step (150), and a single firing step (160).

First, in the powder manufacturing step (110), Taebaek earth containing quartz, mica, chlorite, and montmorillonite (bentonite) as main constituent minerals, and silicon, aluminum, iron, potassium, magnesium, and sodium as small or trace minerals, It manufactures fine particle powder mixed with Taebaekite components, which contain quartz, chlorite, mica, and feldspar as main constituent minerals, and contain small or trace minerals such as silicon, aluminum, iron, potassium, magnesium, and sodium.

Figure 2 is a block diagram showing the detailed configuration of the powder manufacturing step of the method for manufacturing ceramic products using fine particle powder mixed with Taebaek clay and Taebaek rock components according to the present invention. As shown in Figure 2, the powder manufacturing step 110 includes a grinding step 111, a mixing step 112, a kneading step 113, and an aging step 114.

First, in the crushing step (111), Taebaek earth, which contains quartz, mica, chlorite, and montmorillonite (bentonite) as main constituent minerals, and silicon, aluminum, iron, potassium, magnesium, and sodium as small or trace minerals, and quartz , Taebaek rock, which contains chlorite, mica, and feldspar as main constituent minerals and small or trace minerals such as silicon, aluminum, iron, potassium, magnesium, and sodium, is respectively pulverized.

For example, in the pulverizing step 111, Taebaek soil and Taebaek rock can be pulverized into 50 to 250 pieces using a rock crusher (not shown in the drawing) or/and a rock crusher (not shown in the drawing).

Figure 3 is a copy of the main mineral test report report of the Korea Mine & Reclamation Corporation Technology Research Institute for Taebaek soil and Taebaek rock used in the production of fine particle powder mixed with Taebaek soil and Taebaek rock components.

Figure 4 is a copy of the small or trace mineral test report report of the Korea Mine & Reclamation Corporation Technology Research Institute for Taebaek soil and Taebaek rock used in the production of fine particle powder mixed with Taebaek soil and Taebaek rock components.

Referring to Figures 3 and 4, among the various samples collected in Taebaek, Gangwon-do, Taebaek rock sample NO2 polar stone, NO6 white rock, NO20 blue rock, Taebaek soil sample NO12 cut-stone soil, NO14 clay bone soil, and NO17 main soil of tourist area. The constituent minerals and minor or trace minerals can be known.

Meanwhile, major constituent minerals and minor or trace minerals not included in the Taebaek soil and Taebaek rock samples illustrated in FIGS. 3 and 4 are included in other samples not shown in FIGS. 3 and 4.

Next, in the mixing step 112, the Taebaek clay powder and Taebaek rock powder pulverized in the grinding step 111 are mixed. For example, the mixing ratio of Taebaek clay powder and Taebaek rock powder mixed in the mixing step 112 may be a weight ratio, but is not limited to this.

At this time, it can be implemented to adjust the mixing ratio of Taebaek clay powder and Taebaek rock powder according to the color, gloss, strength, and efficacy of the fine particle powder produced in the mixing step 112. Meanwhile, the sizes of the Taebaek clay powder and Taebaek rock powder mixed in the mixing step 112 may be the same or different from each other.

On the other hand, before the mixing step 112, the Taebaek clay powder and Taebaek rock powder pulverized in the grinding step 111 can be separated using a sieve (not shown) to remove powder coarser than 50 grains. It is not limited to this.

Next, in the kneading step 113, the Taebaek clay powder and Taebaek rock powder mixed in the mixing step 112 are kneaded. At this time, kneading may be implemented by adding additives to change the color, gloss, strength, and efficacy of the fine particle powder produced in the kneading step (113), or by adding a catalyst to promote chemical reaction.

For example, additives for changing the color, gloss, strength, and efficacy of the fine particle powder may be iron, salt, carbon, titanium, montmonilonite (bentonite), etc. Montmonilonite (bentonite) can increase sterilization and antibacterial efficacy, iron can make the color redder, titanium can make the material lighter and stronger, salt can improve natural luster, and carbon can provide heat retention. It can affect gloss and color by increasing .

Meanwhile, the catalyst for promoting the chemical reaction may be an oxidation catalyst such as a metal chloride that promotes the oxidation reaction of iron contained in the Taebaek clay powder and Taebaek rock powder paste, but is not limited to this.

Next, in the maturation step 114, the dough mixed with Taebaek clay powder and Taebaek rock powder kneaded in the kneading step 113 is aged to produce fine particle powder containing a mixture of Taebaek clay and Taebaek rock components.

For example, in the maturation step 114, the dough mixed with Taebaek clay powder and Taebaek rock powder can be aged for 1 day to 3 years at a relative humidity of 40 to 60% and a temperature of -25 to 40 ° C. At this time, it may be implemented to age the dough mixed with Taebaek clay powder and Taebaek rock powder in an aging warehouse (not shown in the drawing) under dark room conditions.

The fine particle powder, which is a mixture of Taebaek clay and Taebaek rock ingredients manufactured through the maturation step (114), contains beneficial ingredients such as montreal nonite (bentonite) and chlorite, and the beneficial ingredients interact through the maturation process to increase efficacy. Because it is strengthened, it can be used as a raw material for various purposes.

Meanwhile, the powder manufacturing step 110 may further include a purification step 115. In the purification step 115, the fine particle powder mixed with the Taebaek clay and Taebaek rock ingredients aged in the aging step 114 is purified to remove impurities.

At this time, after the purification step 115, the fine particle powder mixed with the purified Taebaek clay and Taebaek rock components may be passed through a filter, etc. to filter out particles of a certain size or larger.

By implementing it in this way, impurities contained in the fine particle powder mixed with Taebaek soil and Taebaek rock components aged by the maturation step 114 can be removed through the purification step 115, so that pure Taebaek soil and Taebaek rock components can be removed. Mixed fine particle powder can be obtained.

Meanwhile, the powder manufacturing step 110 may further include a sieving step 105. In the mining step (105), Taebaek soil and Taebaek rock are collected before the crushing step (111). Since the collected Taebaek soil may contain rubble, the rubble contained in the Taebaek clay is removed through the sieving step (105) before the pulverizing step (111).

For example, in the sieve step 105, Taebaek soil and Taebaek rock may be passed through a sieve machine (not shown in the figure) to remove rubble with a thickness greater than 50 wood, but the method is not limited to this.

By implementing it in this way, the present invention can remove the rubble contained in Taebaek soil and Taebaek rock by collecting Taebaek soil and Taebaek rock through the sieve step 105 before the grinding step 111, so that pure Taebaek soil can be removed from Taebaek rock. so that it can be mixed with.

Monroel nonite (bentonite), which is included in Taebaek clay, has been used as an herbal mineral since ancient times, and has functions such as removing toxins, adsorbing pollution, sterilizing, and deodorizing due to its cation exchange properties. In addition, Taebaek soil contains numerous mineral nutrients and can be used as a material for various purposes.

Meanwhile, chlorite (phyllite), a natural mineral contained in Taebaek soil, is evaluated as a mysterious substance that acts as a soil activator and physiological activator at the same time. In particular, it has excellent effects such as generation of dissolved oxygen (active oxygen), adsorption of suspended substances, removal of heavy metals, deodorization, and bacteriostatic action to remove viruses and bacteria.

In addition, chlorite (phyllite) contains a variety of medicinal elements, making it highly toxic and detoxifying, showing excellent efficacy not only for the soil, but also for the plants growing on it, and even for the health of the human body and livestock. It is in the spotlight as a material for various purposes.

Next, in the kneading step 120, the fine particle powder mixed with the Taebaek clay and Taebaek rock components prepared in the powder manufacturing step 110 is kneaded. For example, in the kneading step 120, fine particle powder mixed with Taebaek soil and Taebaek rock components is placed in a stirrer (not shown in the drawing), then water is added at a specific weight ratio, and then stirred to produce fine particle powder mixed with Taebaek soil and Taebaek rock components. It can be implemented to knead.

At this time, in order to change the color and strength of the ceramic product manufactured in the kneading step 120, celadon clay, white porcelain clay, or powdered clay may be added as an additive raw material and kneaded.

Next, in the forming step 130, the fine particle powder dough mixed with Taebaek clay and Taebaek rock components kneaded in the kneading step 120 is molded into a ceramic product body of the desired shape. For example, in the molding step 130, the fine particle powder dough mixed with Taebaek clay and Taebaek rock components can be automatically or manually molded into a ceramic product body of a desired shape, such as pottery of various shapes, etc., using an electric or manual potter's wheel. there is.

Next, in the attachment step 140, at least one gem or precious metal is attached to a specific position of the ceramic product body formed in the forming step 130. The ceramic product body formed in the forming step 130 has a smooth surface because it has not yet been dried. Therefore, in the attachment step 140, at least one gem or precious metal can be easily attached to a specific position of the ceramic product body formed in the forming step 130, automatically or manually.

At this time, the gem is a natural or artificial gem such as diamond, ruby, sapphire, or crystal that does not deteriorate at the firing temperature, and the precious metal may be platinum, which does not melt at the firing temperature. Meanwhile, when attaching a gem or precious metal to the ceramic product body, the gem or precious metal may be attached so as not to penetrate the outer and inner surfaces of the ceramic product body, or may be attached so as to penetrate.

For example, when attaching a gem or precious metal to the ceramic product body in the attachment step 140, a person may attach it manually, or a device is configured to pick up the gem or precious metal, transport it, and insert it into a specific position of the ceramic product body. It can also be attached automatically.

Next, in the drying step 150, the ceramic product body to which at least one gem or precious metal is attached is dried through the attaching step 140. At this time, in the drying step 150, the body of the ceramic product to which at least one gem or precious metal is attached by the attaching step 140 can be automatically transferred using a transfer tray to a drying room, etc., or transferred manually to be dried.

For example, in the drying step 150, the body of the ceramic product to which at least one gem or precious metal is attached can be dried within 24 hours at a temperature of 300 degrees Celsius using a dryer in a drying room, so that the body of the ceramic product becomes hard.

In this drying step (150), when the ceramic product body to which at least one gem or precious metal is attached is dried, moisture evaporates from the ceramic product body and the volume is reduced, so the gem or precious metal is naturally firmly fixed to the ceramic product body. .

Next, in the single firing step (160), the ceramic product body dried in the drying step (150) is fired in one shot. Taebaek clay and Taebaek rock contain quartz as the main constituent mineral, and in the single firing step (160), quartz, which has a lower melting point than gems and precious metals, melts and seeps into the gaps of the parts where gems and precious metals are mounted, forming a molded material. As the body of the ceramic product shrinks, the gap in the area where gems and precious metals are installed is tightly filled.

For example, the ceramic product body to which the gems or precious metals are firmly fixed after being dried in the drying step 150 in the single firing step 160 is transferred to an electric kiln, a firewood kiln, a gas kiln, etc., and the ceramic product body to which the gems or precious metals are attached is It can be implemented to be fired in single batches at about 700 degrees Celsius to 1600 degrees Celsius for about 12 hours, but is not limited to this.

Meanwhile, in the single firing step (160), the main body of the ceramic product is oxidized and fired, but the oxidation firing temperature and time are varied to manufacture matte ceramic products of various colors using the thixotropic action of the fine particle powder material mixed with Taebaek clay and Taebaek rock components. It can be implemented to do so. Oxidation firing is a firing method that ensures complete combustion of fuel by appropriately adding oxygen. It quickly rises to the desired temperature, saving time and fuel.

In contrast, the ceramic product body is reduced-fired in the single firing step 160, or the reduction-fired material is changed during the oxidation-fired process, but the reduction-fired temperature and time are changed to change the thixotropic effect of the fine particle powder material mixed with Taebaek clay and Taebaek rock components. It can also be implemented to manufacture glossy ceramic products of various colors. Reduction firing is a firing method that causes incomplete combustion by injecting flames that should be smoothly discharged through the chimney into the kiln once again, resulting in a slow rise to the desired temperature, which consumes a lot of time and fuel.

Figure 5 is a diagram illustrating a ceramic product manufactured by the method of manufacturing a ceramic product using a fine particle powder mixed with Taebaek clay and Taebaek rock components according to the present invention. As shown in Figure 5, beautiful ceramic products can be manufactured in various shapes using fine particle powder mixed with Taebaek clay and Taebaek rock components.

By implementing this, the present invention is a mixture of Taebaek clay containing quartz, mica, chlorite, and montmorillonite (bentonite) as main constituent minerals, and Taebaek rock containing quartz, chlorite, mica, and feldspar as main constituent minerals. Since beautiful ceramic products can be manufactured using fine particle powder, it can help revitalize the local economy.

Meanwhile, according to an additional aspect of the invention, the method of manufacturing a ceramic product using fine particle powder mixed with Taebaek clay and Taebaek rock components may further include an inlay step (135). In the inlay step (135), a pattern is engraved on the body of the ceramic product formed after the forming step (130).

For example, in the inlay step 135, a person manually imprints an inlay stamp with a specific pattern embossed or engraved on the ceramic product body, or a device is configured to automatically imprint the inlay stamp on the ceramic product body, and a specific pattern is applied to the ceramic product body. It can be implemented to engrave an embossed or engraved pattern. By implementing it in this way, the present invention can engrave beautiful patterns on the body of a ceramic product.

Meanwhile, according to an additional aspect of the invention, the method of manufacturing a ceramic product using fine particle powder mixed with Taebaek clay and Taebaek rock components may further include an alloy coloring step (145). In the alloy coloring step (145), an alloy is used to color letters or pictures on the main body of the ceramic product to which at least one gem or precious metal is attached in the attachment step (140). By implementing it in this way, the present invention can color beautiful letters or pictures on the body of the ceramic product.

Meanwhile, according to an additional aspect of the invention, the method of manufacturing a ceramic product using fine particle powder mixed with Taebaek clay and Taebaek rock components may further include a glaze step (155). In the glaze step (155), glaze is applied to the main body of the ceramic product dried after the drying step (150).

For example, in the glaze step (155), a person can manually dip the ceramic product body into a glaze container filled with glaze and apply the glaze, or automatically implement a device that grabs and transports the ceramic product body and dips it into a glaze container filled with glaze. It can be implemented to apply a glaze. By implementing it in this way, the present invention can form a beautiful color on the body of the ceramic product.

Meanwhile, according to an additional aspect of the invention, the method of manufacturing a ceramic product using fine particle powder mixed with Taebaek clay and Taebaek rock components may further include a molded product attachment step (170) and a conglomerate firing step (180).

In the molding attachment step (170), a new ceramic product molding is attached to the single fired ceramic product body. At this time, the new ceramic product molding may be a molding for repairing a damaged part of the ceramic product body or a molding for additional attachment to the ceramic product body, and may be manufactured in the same manner as the ceramic product body manufacturing method described above. It can be.

In the conglomerate firing step (180), the ceramic product body to which the new ceramic product molding is attached is conglomerate fired in the molding attachment step (170). For example, the body of a single-fired ceramic product with a new ceramic product molding attached can be fired in multiple batches at 1600 degrees Celsius or higher for about 12 hours using an electric kiln, a wood-fired kiln, a gas kiln, etc., but is not limited to this.

At this time, in the conglomerate firing step 180, the single-fired ceramic product body to which the new ceramic product molding is attached is oxidized and fired, or the damaged part of the ceramic product body is repaired by reduction firing, or a new ceramic product body is added to the ceramic product body. Product moldings can be attached.

Since Taebaek clay and Taebaek rock contain small or trace minerals such as silicon, aluminum, iron, potassium, magnesium, and sodium, the ceramic product body is fired once at a temperature of 1600 degrees or higher, which is above the melting point of these, with a new ceramic product molding attached. When fired in batches, they melt and the single fired ceramic product body and the new ceramic product molding adhere to each other.

Figure 6 is a diagram illustrating the body of a ceramic product in which the damaged portion is repaired by firing a ceramic product using a method of manufacturing a ceramic product using a fine particle powder mixed with Taebaek clay and Taebaek rock components according to the present invention. Referring to Figure 6, it can be seen that even if a new ceramic product molding is attached to the damaged part of the single-fired ceramic product body and the ceramic product is fired in batches, it is not much different from the original product.

By implementing this, the present invention can repair the damaged part of the single-fired ceramic product body or attach a new ceramic product molding to the single-fired ceramic product body, so even if the ceramic product body is damaged, it can be reused. , a new ceramic product molding can be easily and conveniently attached to the body of a previously manufactured single fired ceramic product.

Meanwhile, according to an additional aspect of the invention, the method of manufacturing ceramic products using fine particle powder mixed with Taebaek clay and Taebaek rock components may further include a molding additional attachment step (190) and a triple firing step (195). .

In the additional molding attachment step 190, another ceramic product molding is additionally attached to the main body of the ceramic product that has been fired. At this time, another ceramic product molding that is additionally attached to the ceramic product body that has been fired at the conglomerate can be manufactured in the same manner as the ceramic product body manufacturing method described above.

In the third firing step (195), three ceramic product bodies to which another ceramic product molding is additionally attached are fired in the additional molding attachment step (190). For example, the main body of the ceramic product that has been fired with another ceramic product molding attached to it can be fired three times at 1600 degrees Celsius or higher for about 12 hours using an electric kiln, a fire kiln, a gas kiln, etc., but is not limited to this. No.

At this time, in the third firing step 195, another ceramic product molding can be attached to the ceramic product body by oxidizing or reducing firing the fired ceramic product body to which another ceramic product molding is attached.

Taebaek clay and Taebaek rock contain small or trace minerals such as silicon, aluminum, iron, potassium, magnesium, and sodium, so they are fired at a temperature of 1600 degrees or higher, which is above the melting point of these ceramic products, with another ceramic product mold attached. When the main body is fired three times, they melt and the ceramic product body that was fired three times and the new ceramic product molding adhere to each other.

Figure 7 is a diagram illustrating the main body of a ceramic product manufactured by firing three sets by the method of manufacturing a ceramic product using fine particle powder mixed with Taebaek clay and Taebaek rock components according to the present invention. Referring to Figure 7, it can be seen that a ceramic work of art was produced by attaching another ceramic product molding to the main fired ceramic product.

By implementing the present invention in this way, another ceramic product molding can be attached to the main body of a ceramic product made by firing a conglomerate, and thus another molded product of a ceramic product can be easily and conveniently attached to the main body of a previously manufactured fired ceramic product.

As described above, the present invention is a mixture of Taebaek soil containing quartz, mica, chlorite, and montmorillonite (bentonite) as main constituent minerals, and Taebaek rock containing quartz, chlorite, mica, and feldspar as main constituent minerals. Since beautiful ceramic products can be manufactured using fine particle powder, it can help revitalize the local economy.

The various embodiments disclosed in this specification and drawings are merely presented as specific examples to aid understanding, and are not intended to limit the scope of the various embodiments of the present invention.

Accordingly, the scope of the various embodiments of the present invention includes all changes or modified forms derived based on the technical idea of the various embodiments of the present invention in addition to the embodiments described herein. It should be interpreted as being

The present invention can be used industrially in the field of ceramic product manufacturing technology and application technology.

110: Powder manufacturing step
105: Separation stage
111: Grinding step
112: mixing step
113: Kneading step
114: Ripening stage
115: Purification step
120: Kneading stage
130: Forming stage
135: Inlay step
140: Attachment step
145: Alloy coloring step
150: Drying stage
155: Glaze stage
160: Single firing step
170: Molding attachment step
180: Chaebol firing stage
190: Additional molding attachment step
195: 3 firing stages

Claims (5)

It contains quartz, mica, chlorite, and montmorillonite (bentonite) as its main constituent minerals, and Taebaek clay, which contains small or trace minerals of silicon, aluminum, iron, potassium, magnesium, and sodium, and quartz, chlorite, mica, and feldspar as its main constituent minerals. A powder manufacturing step of producing a fine particle powder mixed with Taebaek rock components containing as constituent minerals and small or trace amounts of silicon, aluminum, iron, potassium, magnesium, and sodium;
A kneading step of kneading the fine particle powder mixed with Taebaek clay and Taebaek rock ingredients produced in the powder manufacturing step;
A molding step of molding the fine particle powder dough mixed with Taebaek clay and Taebaek rock ingredients kneaded through the kneading step into a ceramic product body of a desired shape;
An attachment step of attaching at least one gem or precious metal to a specific position of the body of the ceramic product formed by the molding step;
A drying step of drying the body of the ceramic product to which at least one gem or precious metal is attached by the attachment step;
A single firing step of firing the dried ceramic product body in a single firing step;
A method of manufacturing ceramic products using fine particle powder mixed with Taebaek clay and Taebaek rock ingredients. According to claim 1,
The method of manufacturing ceramic products using fine particle powder mixed with Taebaek clay and Taebaek rock ingredients is:
An inlay step of engraving a pattern on the body of the molded ceramic product after the molding step;
An alloy coloring step of coloring letters, pictures, etc. using pigment on the main body of a ceramic product to which at least one gem or precious metal is attached through an attachment step;
A method of manufacturing a ceramic product using fine particle powder mixed with Taebaek clay and Taebaek rock components containing at least one of the following. According to claim 1,
The method of manufacturing ceramic products using fine particle powder mixed with Taebaek clay and Taebaek rock ingredients is:
A glaze step of applying glaze to the dried ceramic product body after the drying step;
A method of manufacturing a ceramic product using fine particle powder containing a mixture of Taebaek clay and Taebaek rock ingredients. According to any one of claims 1 to 3,
The method of manufacturing ceramic products using fine particle powder mixed with Taebaek clay and Taebaek rock ingredients is:
A molding attachment step of attaching a new ceramic product molding to the single-fired ceramic product body;
A conglomerate firing step in which the ceramic product body to which a new ceramic product molding is attached is conglomerately fired through the molding attachment step;
A method of manufacturing a ceramic product using fine particle powder containing a mixture of Taebaek clay and Taebaek rock ingredients. According to claim 4,
The method of manufacturing ceramic products using fine particle powder mixed with Taebaek clay and Taebaek rock ingredients is:
A molding additional attachment step of additionally attaching another ceramic product molding to the ceramic product body that has been fired by Jaebeol;
A three-stage firing step of firing three ceramic product bodies to which another ceramic product molding is additionally attached through the additional molding attachment step;
A method of manufacturing a ceramic product using fine particle powder containing a mixture of Taebaek clay and Taebaek rock ingredients.