KR102549671B1 - A manufacturing method of pottery having an dark blue colour background with gray brown and white colour paints flowed down patterns formed - Google Patents

Abstract

In the present invention, a priming step (S1) of unglazing a plurality of pottery moldings pre-formed in a set shape by using a plurality of electric kilns (100) at a uniform speed up to 800 ° C. for 8 hours; and unglazed pottery. A first cooling step (S2) of taking the molded product out of the electric kiln 100 and cooling it to 25° C.; and a first glazing step (S3) of applying a first glaze to the unglazed and cooled ceramic molded product (S3); and a first glazing step (S3). A step (S4) of roasting the pottery molded articles by heating them to a temperature of 800° C. for 8 hours using a plurality of electric kilns (100); ) and cooling to 25 ° C.; and a second glazing step (S6) of applying a second glaze to the ceramic molding that has been baked and cooled; and the second glazing of the ceramic molding into one. A third step (S7) of raising the temperature to 1,250 ° C. for 30 to 35 hours using the above firewood kiln 200 and roasting it three times (S7); Including a cooling withdrawal and cooling step (S8); the first glaze includes 25% by weight of feldspar powder, 15% by weight of limestone powder, 15% by weight of silica stone powder, 10% by weight of talc powder, and 20% by weight of It contains clay powder, 12% by weight of barium powder, and 3% by weight of dark blue pigment, and the secondary glaze contains 20% by weight of feldspar powder, 15% by weight of limestone powder, 20% by weight of silica stone powder, and 10% by weight of feldspar powder. Brownish white paint and white paint flowing down on a dark blue background, characterized by containing white clay powder, 10% by weight of clay powder, 8% by weight of zinc powder, 7% by weight of titanium powder, and 10% by weight of barium powder It relates to a method for manufacturing ceramics with a pattern of.

Description

A manufacturing method of pottery having an dark blue color background with gray brown and white color paints flowed down patterns formed}

In the present invention, a priming step (S1) of unglazing a plurality of pottery moldings pre-formed in a set shape by using a plurality of electric kilns (100) at a uniform speed up to 800 ° C. for 8 hours; and unglazed pottery. A first cooling step (S2) of taking the molded product out of the electric kiln 100 and cooling it to 25° C.; and a first glazing step (S3) of applying a first glaze to the unglazed and cooled ceramic molded product (S3); and a first glazing step (S3). A step (S4) of roasting the pottery molded articles by heating them to a temperature of 800° C. for 8 hours using a plurality of electric kilns (100); ) and cooling to 25 ° C.; and a second glazing step (S6) of applying a second glaze to the ceramic molding that has been baked and cooled; and the second glazing of the ceramic molding into one. A third step (S7) of raising the temperature to 1,250 ° C. for 30 to 35 hours using the above firewood kiln 200 and roasting it three times (S7); and a cooling withdrawal and cooling step (S8), wherein the primary glaze contains 25 wt% of feldspar powder, 15 wt% of limestone powder, 15 wt% of silica powder, 10 wt% of talc powder, and 20 wt% of It contains clay powder, 12% by weight of barium powder, and 3% by weight of dark blue pigment, and the secondary glaze contains 20% by weight of feldspar powder, 15% by weight of limestone powder, 20% by weight of silica stone powder, and 10% by weight of feldspar powder. Brownish white paint and white paint flowing down on a dark blue background, characterized by containing white clay powder, 10% by weight of clay powder, 8% by weight of zinc powder, 7% by weight of titanium powder, and 10% by weight of barium powder It relates to a method for manufacturing ceramics with a pattern of.

Hereinafter, looking at the background art together with the accompanying drawings are as follows.

In general, a ceramic manufacturing process is manufactured through processes such as preparing a pottery soil, molding a ceramic product, and then drying, unglazing, glazing, and ashes. The process of preparing the sub-soil consists of finely pulverizing the sub-soil such as clay powder or sand soil, filtering out impurities through a sieve, precipitating in water, collecting only fine sediment, and drying in the shade for a certain period of time.

In addition, molding is a process of making a predetermined bowl or work shape by using methods such as wheel molding, injection molding, extrusion molding, and compression molding, and drying is a process of sufficiently drying the molded semi-finished product in the shade, prior to drying. In some cases, poetry and prose are practiced by inscribing the pattern of a semi-finished product.

The glazing is to apply the glaze to the ceramic molding, and in the process of glazing the ceramic molding and firing it in an electric kiln or a firewood kiln, the glaze components included in the glazed glaze are expressed in a specific color by the firing temperature, respectively, and then flowed By lowering, a specific pattern is created, but a method for manufacturing pottery with a pattern formed by dripping brownish white paint and white paint on a dark blue background has never been proposed.

As described above, in order to manufacture pottery in which brownish-white paint and white paint flow patterns are formed on a dark blue background, it is important to control the firing temperature when firing a pottery molding in an electric kiln or firewood kiln. Regarding the control, electric kilns are more precise than wood-fired kilns, but electric kilns have a relatively narrow internal space for pottery moldings, making mass production of ceramics difficult. There was a problem in that the control was not precise, so that the ceramics formed cracks or were damaged when firing the ceramics only with the firewood kiln.

Registered Patent No. 10-0943253 (2010.02.11.) Registered Patent No. 10-1457987 (2014.10.29.)

The method of manufacturing a pottery having a pattern in which brownish white paint and white paint flow down on a dark blue background of the present invention is intended to solve the following problems.

An object of the present invention is to perform the initial and ashes of ceramic moldings in an electric kiln to precisely control the temperature so that the temperature rises gradually, thereby preventing the ceramic moldings from cracking or breaking during the firing process. It is to provide a method for manufacturing ceramics in which a brownish-white paint and a pattern in which white paint flowed down are formed.

Another object of the present invention is to perform a large amount of roughing and assembling of ceramic moldings using a plurality of electric kilns when priming and assembling ceramic moldings, and to use a firewood kiln capable of mass input and firing of ceramics to produce ceramic moldings. By performing the three-beam work, mass production of ceramics is possible, and at the same time, the primary glaze applied to the surface of the ceramic molding through the jaebeol work is combined with the primary glaze due to the secondary glaze applied on the surface of the ceramic molding through the three-beam work. The second glaze is melted and mixed and partially flowed or spread to produce pottery with a pattern in which brown white paint and white paint flowed on a dark blue background. It is to provide a method for manufacturing patterned ceramics.

In order to solve the above problems, the method of manufacturing a pottery having a pattern in which brownish white paint and white paint flow down on a dark blue background of the present invention is formed,

A priming step (S1) of unglazing a plurality of ceramic moldings pre-formed in a set shape by using a plurality of electric kilns (100) at a uniform speed up to 800 ° C. for 8 hours; and the unglazed ceramic moldings as described above. A first cooling step (S2) of taking it out of the electric kiln (100) and cooling it to 25 ° C; and a first glazing step (S3) of applying a first glaze to the ceramic molding that has been unglazed and cooled; and the first glazed pottery. A step (S4) of roasting the molded product at a uniform speed up to 800 ° C. for 8 hours using a plurality of electric kilns (100); and taking out the baked ceramic molded product from the electric kiln (100) a second cooling step (S5) of cooling down to 25 ° C; and a second glazing step (S6) of applying a second glaze to the ceramic molded body that has been baked and cooled; and a second glazed ceramic molded body in one or more firewood kiln A third step (S7) of raising the temperature to 1,250 ° C. for 30 to 35 hours using (200) and roasting it three times (S7); and taking out the pottery molding made of three things from the firewood kiln 200 and cooling it to room temperature, and Cooling step (S8); wherein the first glaze contains 25% by weight of feldspar powder, 15% by weight of limestone powder, 15% by weight of silica stone powder, 10% by weight of talc powder, 20% by weight of clay powder, 12% by weight of barium powder and 3% by weight of dark blue pigment, and the secondary glaze contains 20% by weight of feldspar powder, 15% by weight of limestone powder, 20% by weight of silica stone powder, 10% by weight of clay powder, 10% by weight of clay powder, 8% by weight of zinc powder, 7% by weight of titanium powder, and 10% by weight of barium powder.

The firewood kiln 200 is coupled by being inserted into a bongtong 110 and a plurality of firing compartments 120, 121, 122, 123 through which heat can be sequentially transmitted through the lattice 150, and the lattice 150 , the lattice side double tube 300 forming a double tube of an inner tube 310 with both sides open and an outer tube 320 connected to the circumference of the inner tube 310 through a blocking plate, the lattice side double tube 300 ) and a remote side double tube 400 disposed at a remote location and disposed outside the inner tube 410 and the inner tube 410 and forming a double tube of the inner tube 410 and the outer tube 420 The inner tube 310 of the lattice-side double tube 300 is connected between the inner tube 410 of the remote double tube 400 to form a first flow passage L1 through which the hot air flows. The duct 151 is connected between the outer pipe 320 of the lattice-side double pipe 300 and the outer pipe 420 of the remote-side double pipe 400, and hot air flowing through the first flow passage L1 It includes an external duct 152 forming a second flow passage L2 through which it flows in, and the remote side double pipe 400 reverses the flow direction of the hot air flowing through the first flow passage L1. It includes an inverted part, and the inner duct 151 is connected in communication with the outer duct 152 so that hot air flowing along the first flow passage L1 is discharged and extends vertically upward to each firing compartment 120, 121, 122 and 123, respectively, including first to fourth preheated hot air supply pipes 411P, 412P, 413P, and 414P protruding into the inside, and the flow direction reversal part includes an inner pipe of the remote double pipe 400 ( 410) through a plurality of first connection portions 134 spaced apart from each other, and at a distance from the free end of the inner tube 410 of the remote side double tube 400 to the central axis of the inner tube 410. a disc 135 disposed perpendicularly to the inner tube 410 and concentrically disposed; and a first conical portion 136 concentrically installed on an inner surface of the disc 135 so that the spigot faces the first flow passage L1, and the diameter of the disc 135 is the remote side It is longer than the diameter of the inner pipe 410 of the double pipe 400 and smaller than the diameter of the outer pipe 420 of the remote double pipe 400, and the flow direction reversal part has the nipple facing the outside and the bottom surface a second conical portion 137 concentrically installed on the outer surface of the disk 135 so that its circumference matches the circumference of the disk 135; and a conical portion 131a connected to the outer tube 420 and having a smaller diameter as the distance increases from the outer tube 420 . A double duct 600 that extends horizontally from the free end of the conical portion 131a and further includes a flange portion 131af that can be fitted and coupled to the blower pipe 500a of the blower 500. do.

The electric kiln 100 is provided with a heating chamber 12 inside and a kiln body 10 having a plurality of ventilation windows 14 formed on the circumferential wall, and a gap adjacent to the inner wall surface of the kiln body 10 A plurality of pairs of electric heaters 2 provided inside the heating chamber 12 and a plurality of pairs provided at intervals vertically and horizontally so that the ceramic molding 4 can be placed on the inside of the heating chamber 12. A shelf 16, a circulation fan 20 provided inside the heating chamber 12 and purifying the high-temperature heat heated by the electric heater 2, and supplying a reducing agent into the heating chamber 12 It includes a reducing agent supply pipe 40, and an air supply pipe 60 (not shown) is installed in communication with the outside on one side of the heating chamber 12, and a blowing fan 70 (not shown) is installed in the air supply pipe 60 (not shown). is provided to cool the temperature inside the heating chamber 12 by supplying cold air from the outside to the inside of the heating chamber 12, and vertically on the diaphragm 30 installed on the bottom surface inside the heating chamber 12 It is installed in the gap between each pair of shelves 16 of the plurality of pairs of shelves 16, and the inlet at the top protrudes above the uppermost pair of shelves 16, and between each pair of shelves 16 It is characterized in that it further comprises an air circulation guide pipe 80 in which a plurality of through holes 61 are formed in the positioning portion.

In the roughing step (S1), the temperature of the electric heater 2 is increased at an even rate from 25° C. to 200° C. for 2 hours by putting a plurality of ceramic moldings pre-formed into a set shape into a plurality of electric kilns 100. A first heating step (S1-1) of heating; and a second heating step (S1-2) of raising the temperature of the electric heater 2 from 200° C. to 400° C. at an even rate for 2 hours; and the electric heater A third heating step (S1-3) of raising the temperature of (2) at an even rate from 400 ° C to 600 ° C for 2 hours; and the temperature of the electric heater 2 from 600 ° C to 800 ° C for 2 hours. It is characterized in that it comprises a; 4th heating step (S1-4) to raise at an equal rate.

In the consolidation step (S4), the first glazed pottery molding is put into a plurality of electric kilns 100 and the temperature of the electric heater 2 is raised at an equal rate from 25 ° C to 200 ° C for 2 hours 1 ' A secondary heating step (S4-1); and a 2' secondary heating step (S4-2) of raising the temperature of the electric heater 2 at an equal rate from 200 ° C to 400 ° C for 2 hours; and the electric heater ( 2) a 3' heating step (S4-3) of raising the temperature from 400 ° C to 600 ° C at an equal rate for 2 hours; and the temperature of the electric heater 2 from 600 ° C to 800 ° C for 2 hours It is characterized by comprising a; 4 'secondary heating step (S4-4) to raise at an equal rate.

In the third step (S7), the second glazed pottery molding is put into a plurality of firewood kiln 200, and the temperature of the heat supplied to each of the firing compartments 120, 121, 122, and 123 is 25 ° C. for 4 hours 1 "secondary heating step (S7-1) to raise the temperature from 300 ℃ at an equal rate; and the temperature of the hot air supplied to each of the firing compartments (120, 121, 122, 123) from 300 ℃ to 500 ℃ for 4 hours 2 "secondary heating step (S7-2) to raise at an even rate until the temperature of the hot air supplied to each of the firing compartments (120, 121, 122, 123) is uniformly increased from 500 ° C to 700 ° C for 4 hours. 3 "secondary heating step (S7-3) to increase the temperature at an equal rate from 700 ℃ to 950 ℃ for 8 to 10 hours; and the heat supplied to each of the firing compartments (120, 121, 122, 123) 4 "secondary heating step (S7-4) to raise the temperature of the hot air supplied to each of the firing compartments (120, 121, 122, 123) at an even rate from 950 ° C to 1,250 ° C for 10 to 13 hours It is characterized by including; 5 "secondary heating step (S7-5) to raise.

The present invention has the following effects.

First, the initial and ashes of ceramic moldings are performed in an electric kiln to precisely control the temperature so that the temperature rises gradually, so that the ceramic moldings are prevented from cracking or being damaged during firing. It has the effect of providing a manufacturing method of ceramics in which the pattern of the flowing white paint is formed.

Second, when priming and assembling ceramic moldings, a plurality of electric kilns are used to perform the preliminary and assemblage work of ceramic moldings in large quantities, and a firewood kiln capable of mass input and firing of ceramic moldings is used to perform three-layer work of ceramic moldings. By doing so, mass production of ceramics is possible, and at the same time, the primary glaze applied to the surface of the ceramic molding through the chaebol operation is the second glaze applied to the surface of the ceramic molding through the three-beam operation, so that the primary glaze and the secondary glaze are separated. Melted and mixed and partially flowed or spread to produce pottery with a pattern in which brown white paint and white paint flowed on a dark blue background. Ceramics in which a pattern in which brown white paint and white paint flowed on a dark blue background was formed It has the effect of providing a manufacturing method of.

1 is a flow chart of a method for manufacturing a pottery having a pattern in which brownish white paint and white paint flow down on a dark blue background according to an embodiment of the present invention.
FIG. 2 is a flowchart of a rough step among steps constituting the flowchart of FIG. 1 .
FIG. 3 is a flow chart of a chaebol step among the steps constituting the flowchart of FIG. 1 .
Figure 4 is a flow chart of three steps of the steps constituting the flow chart of Figure 1.
FIG. 5 is a longitudinal cross-sectional view of an electric kiln used in the initial stage and the ashes stage of the method of manufacturing ceramics in which a pattern in which brown white paint and white paint flow down on a dark blue background of FIG. 1 is formed.
FIG. 6 is a longitudinal cross-sectional view of a firewood kiln used in the third stage of the manufacturing method of pottery in which a pattern in which brownish white paint and white paint flow down on a dark blue background of FIG. 1 is formed.
FIG. 7 is a photograph of a pottery that has undergone a roughing step and a cooling step after being molded during the steps of the method of manufacturing a pottery in which a pattern of brown white paint and white paint flowed down on a dark blue background of FIG. 1 is formed.
FIG. 8 is a photograph of a pottery in which a molded pottery has gone through a three-packing process and a drawing-out and cooling process in the manufacturing method of pottery in which a brown-white paint and a white paint pattern are formed on a dark blue background of FIG. 1 .

Hereinafter, the present invention will be reviewed with reference to the accompanying drawings, and the present invention will be described in detail in consideration of preferred embodiments.

Advantages and features of the present invention, and methods of achieving them, will become clear with reference to the detailed description of the following embodiments taken in conjunction with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but may be implemented in a variety of different forms, and only the present embodiments are intended to complete the disclosure of the present invention, and are common in the art to which the present invention belongs. It is provided to fully inform the knowledgeable person of the scope of the invention, and the invention is only defined by the scope of the claims. And, like reference numerals designate like elements throughout the specification.

1 is a flow chart of a method for manufacturing a pottery having a pattern in which brown white paint and white paint flow down on a dark blue background according to an embodiment of the present invention, and FIG. 2 is a preliminary step among steps constituting the flowchart of FIG. 3 is a flow chart of the conglomerate step among the steps constituting the flow chart of FIG. 1, FIG. 4 is a flow chart of the three-step step constituting the flow chart of FIG. 1, and FIG. It is a longitudinal cross-sectional view of an electric kiln used in the initial stage and chaebol stage of the manufacturing method of ceramics in which white paint and white paint flowed down patterns are formed, and FIG. This is a longitudinal cross-sectional view of a firewood kiln used in the third stage of the manufacturing method of pottery in which the flowing pattern is formed. 8 is a photograph of a pottery that has been molded during the steps of the pottery manufacturing method and has undergone a roughening step and a cooling step, and FIG. This is a picture of the pottery that has undergone the three-stage, drawing-out, and cooling process.

Referring to FIGS. 1 to 8, the method for manufacturing ceramics* in which a pattern in which brownish white paint and white paint flow down on a dark blue background of the present invention is formed is a roughing step (S1), a first cooling step (S2), and , the first oiling step (S3), the conglomerate step (S4), the second cooling step (S5), the second oiling step (S6), the third step (S7), and the withdrawal and cooling step (S8); includes

1. Priming stage (S1)

In the priming step (S1), a plurality of porcelain moldings pre-formed in a set shape were primed by raising the temperature to 800 ° C. at a uniform speed for 8 hours using a plurality of electric kilns (100).

Here, the electric kiln 100 is provided with a heating chamber 12 inside and adjacent to the kiln body 10 having a plurality of ventilation windows 14 formed on the circumferential wall, and the inner wall surface of the kiln body 10 Electric heaters 2 provided inside the heating chamber 12 at intervals, and a plurality of porcelain moldings 4 provided at intervals vertically and horizontally between each other so that the ceramic molding 4 can be placed inside the heating chamber 12. A pair of shelves 16, a circulation fan 20 provided inside the heating chamber 12 and circulating high-temperature heat heated by the electric heater 2, and a reducing agent into the heating chamber 12 It includes a reducing agent supply pipe 40 for supplying, and an air supply pipe 60 (not shown) is installed in communication with the outside on one side of the heating chamber 12, and a blowing fan 70 (not shown) is installed in the air supply pipe 60 (not shown). Si) is provided to cool the temperature inside the heating chamber 12 by supplying cold air from the outside to the inside of the heating chamber 12, and a diaphragm 30 installed on the bottom surface inside the heating chamber 12 It is installed vertically on the top and is inserted into the gap between each pair of shelves 16 of the plurality of pairs of shelves 16, and the inlet at the top protrudes above the uppermost pair of shelves 16 and between each pair of shelves 16 An air circulation guide pipe 80 having a plurality of through holes 61 formed therebetween is further included.

According to the configuration, the air circulation guide pipe 80 is installed vertically on the diaphragm 30 installed on the bottom surface inside the heating chamber 12, and between each pair of shelves 16 of the plurality of pairs of shelves 16. It is inserted into the gap of the top and the inlet at the top protrudes above the uppermost pair of shelves 16, and a plurality of through holes 61 are formed in the portion located between each pair of shelves 16, so the circulation fan 20 ), when the high-temperature heat heated by the electric heater 2 circulates in the heating chamber 12, the heat flows laterally toward the plurality of through holes 61, and in the process, the shelf 16 Since the ceramic molding placed above flows while heating, the heating effect on the ceramic molding is immediately reflected, and as a result, the ceramic molding placed on the shelf 16 in the heating chamber 12 It is possible to prevent the ceramic molding from cracking or breaking during the firing process during unglazing by precisely controlling the rise of the heating temperature for 8 hours at an even rate and gradually.

Here, in relation to the non-explained numerals in the drawings, reference numerals 22, 24, 26, 34, and 50 denote a disk, a blade, a through hole, an exhaust passage, and a drive motor, respectively.

In a specific embodiment, in the roughing step (S1), a plurality of pottery moldings pre-formed into a set shape are put into a plurality of electric kilns 100 and the temperature of the electric heater 2 is set at 25° C. to 200° C. for 2 hours. A first heating step (S1-1) of raising the temperature to °C at an equal rate; and a second heating step (S1-1) of increasing the temperature of the electric heater 2 from 200 °C to 400 °C at an equal rate for 2 hours. 2); and a third heating step (S1-3) of raising the temperature of the electric heater 2 at an equal rate from 400 ° C to 600 ° C for 2 hours; and the temperature of the electric heater 2 for 2 hours During the fourth heating step (S1-4) of raising the temperature from 600 ° C to 800 ° C at an equal rate; In this way, a plurality of ceramic moldings pre-formed into a set shape are put into a plurality of electric kilns 100 and the temperature of the electric heater 2 is raised for 8 hours through the first to fourth heating steps (S1-1 to S1-4). By precisely adjusting the temperature of the hot air supplied gradually during the heating process to increase the heating temperature of the ceramic moldings placed on the shelf 16 in the heating chamber 12, the heating temperature of the ceramic moldings placed on the shelf 16 is gradually accurately controlled so that the ceramic moldings are fired during the unglazed firing process. Prevents ceramic moldings from cracking or breaking.

2. 1st cooling step (S2)

In the first cooling step (S2), the unglazed pottery molding was taken out of the electric kiln 100 and cooled to 25°C. In this way, when the ceramic molding is cooled to room temperature of 25° C., the risk of injury to a worker in the process of moving the ceramic molding is reduced.

3. 1st oiling step (S3)

In the first glazing step (S3), the first glaze was applied to the unglazed and cooled ceramic molding.

The primary glaze contains 25% by weight of feldspar powder, 15% by weight of limestone powder, 15% by weight of silica stone powder, 10% by weight of talc powder, 20% by weight of clay powder, 12% by weight of barium powder, and 3% by weight. contains dark blue pigments of

The feldspar powder is white, and if it is more than 25% by weight, it is sufficient to help the first glaze to fuse, but the chemical resistance of the first glaze applied to the surface of the unglazed pottery after the first glazing is lowered and the gloss deteriorates, and if it is less than 25% by weight, it is insufficient to play a role in helping the primary glaze to fuse to the surface of the unglazed ceramics, so that the primary glaze is not fused to the surface of the unglazed ceramics. Since this may partially occur, the weight of the feldspar powder is preferably 25% by weight.

The limestone powder is white, has an emulsifying action, imparts viscosity, and gives a soft feel. When the proportion of the limestone powder in the secondary glaze exceeds 15% by weight, the coefficient of thermal expansion of the secondary glaze increases and oil level cracking may occur, and the proportion of the limestone powder in the secondary glaze is 15% by weight If less than that, the hardness and abrasion resistance of the secondary glaze are lowered, so the content of limestone powder in the secondary glaze is preferably 15% by weight.

The silica powder is silica SiO ₂ as a main component to form glass and is mixed with the primary glaze so that the oil surface of the primary glaze is glossy when fired. If the silica powder content is less than 15% by weight, the primary glaze is It has no luster, flows easily, and cracks occur. If the content of silica powder exceeds 15% by weight, the viscosity of the primary glaze becomes too high and does not flow well when fired by conglomerate work, so that the desired pattern cannot be obtained on the surface of the pottery. The silica powder preferably has a specific gravity of 15% by weight in the primary glaze.

The talcum powder is used in the primary glaze and serves to give a gray color, and when the proportion in the primary glaze exceeds 10% by weight, the opacity and glossiness of the primary glaze increase, expressing transparency and rugged properties. It is not suitable for use in ceramics, and if it is less than 10% by weight, the primary glaze may shrink and cause cracks, so the use of the talcum powder is preferably 10% by weight.

Since the white clay powder does not contain iron, it is white when used in the first glaze and fired. When the white clay powder is less than 20% by weight in the first glaze, the first glaze is formed on the surface of the pottery. The glaze composition may be dried or peeled off due to failure to adhere, and when the amount of the white clay powder exceeds 20% by weight, the transparency of the first glaze is lowered, so that the color of the parts due to the components of the first glaze excluding the white clay powder is reduced. not clearly visible

The barium powder is included to make an opaque glaze. Barium powder has low reactivity and high fire resistance, so if the content is high, the oil surface does not melt, so it is preferable that the content occupied in the first glaze is 12% by weight. Specifically, when the barium powder is included in less than 12% by weight, the melting point becomes high and the oil surface becomes rough, and when it is included in more than 12% by weight, there is a problem in that bubbles are generated.

The dark blue pigment is used in the first glaze and serves to make the background color dark blue when fired by chaebol work, and is preferably 3% by weight excluding the components described above among the components of the first glaze.

As such, the primary glaze applied to the surface of unglazed pottery through the primary glazing is an important factor in determining the color and feel of pottery, and serves as a cloth, and at the same time, the primary glaze is applied to the surface of unglazed pottery to glass it. Nitriding prevents leakage and improves durability.

4. Chaebol Stage (S4)

In the consolidation step (S4), the first glazed pottery molded article was roasted at an even rate up to 800° C. for 8 hours using a plurality of electric kilns (100).

According to the above configuration, in the plurality of electric kilns 100, the air circulation guide tubes 80 are installed vertically on the diaphragm 30 installed on the bottom surface inside the heating chamber 12, so that the plurality of pairs of shelves 16 It is inserted into the gap between each pair of shelves 16, the inlet at the top protrudes above the uppermost pair of shelves 16, and a plurality of through holes 61 located between each pair of shelves 16 Since this is formed, when the high-temperature heat heated by the electric heater 2 is circulated in the heating chamber 12 by the circulation fan 20, the heat moves laterally toward the plurality of through holes 61. In the process, the ceramic molding placed on the shelf 16 flows while heating, so the heating effect on the ceramic molding is immediately reflected. As a result, through the precise control of the electric heater 2, the shelf in the heating chamber 12 16), it is possible to prevent the ceramic molding from cracking or being damaged during the firing process at the time of baking by precisely controlling the rise in heating temperature for the ceramic molding disposed at a gradual rate for 8 hours. .

In a specific embodiment, in the consolidation step (S4), the first glazed pottery molding is put into a plurality of electric kilns 100 and the temperature of the electric heater 2 is uniformly set from 25 ° C to 200 ° C for 2 hours. A 1st heating step (S4-1) of raising the temperature at one rate; and a 2nd heating step (S4-2) of raising the temperature of the electric heater 2 from 200°C to 400°C at an equal rate for 2 hours. ); and a 3rd heating step (S4-3) of raising the temperature of the electric heater 2 at an equal rate from 400 ° C to 600 ° C for 2 hours; and the temperature of the electric heater 2 for 2 hours A 4' heating step (S4-4) of raising the temperature from 600 ° C to 800 ° C at an equal rate during the process.

In this way, the first glazed pottery molding is put into a plurality of electric kilns 100 and the temperature of the electric heater 2 is raised for 8 hours through the 1st to 4th heating steps (S4-1 to S4-4). By precisely adjusting the temperature of the gradually supplied hot air to rise, the heating temperature of the ceramic moldings placed on the shelf 16 in the heating chamber 12 is precisely controlled so that the heating temperature rises gradually for 8 hours, so that the ceramic moldings are Prevents cracking or damage of ceramic moldings during the firing process.

In addition, when firing the ceramic molded article in the ashesive step (S4) by baking, in the first glaze applied first, the dark blue pigment forms a dark blue background color at the bottom of the inner surface of the ceramic molded article, As shown in Fig. 8, a pattern in which brownish white paint and white paint flow down on a dark blue background that creates beauty as a whole is formed on the surface of the ceramic molding, and as the white clay powder and feldspar powder flow down, the white paint is formed. A flow-like pattern is formed, and a pattern in which white paint flows down on a dark blue background is primarily formed on the surface of the pottery as a whole during chaebol roasting in the chaebol stage (S4).

5. Second cooling step (S5)

In the second cooling step (S5), the pottery molded product, which has been baked, is taken out of the electric kiln 100 and cooled to 25°C. In this way, when the ceramic molding is cooled to room temperature of 25° C., the risk of injury to a worker in the process of moving the ceramic molding is reduced.

6. Second oiling step (S6)

In the second glazing step (S6), a second glaze was applied to the ceramic molding that was baked and cooled.

The secondary glaze contains 20% by weight of feldspar powder, 15% by weight of limestone powder, 20% by weight of silica stone powder, 10% by weight of clay powder, 10% by weight of clay powder, 8% by weight of zinc powder, and 7% by weight of clay powder. of titanium powder, 10% by weight of barium powder.

The feldspar powder is white, and if it exceeds 20% by weight in the secondary glaze, it is sufficient to help the secondary glaze fuse, but after the secondary glazing, it is applied to the surface of the baked pottery. The chemical resistance of the secondary glaze is lowered and the gloss is deteriorated, and if it is less than 20% by weight in the secondary glaze, it is insufficient to help the secondary glaze to be fused to the surface of the baked pottery, so that the secondary glaze Since a portion that is not fused to the surface of the jaebeol-fired pottery may partially occur, it is preferable that the weight of the feldspar powder is 20% by weight in the second glaze.

The limestone powder is white, has an emulsifying action, imparts viscosity, and gives a soft feel. When the proportion of the limestone powder in the secondary glaze exceeds 15% by weight, the coefficient of thermal expansion of the secondary glaze increases and oil level cracking may occur, and the proportion of the limestone powder in the secondary glaze is 15% by weight If less than that, the hardness and abrasion resistance of the secondary glaze are lowered, so the content of limestone powder in the secondary glaze is preferably 15% by weight.

The silica powder is silica SiO ₂ as the main component, so it occupies the main part of the secondary glaze, serves as a framework, and forms glass to be mixed with the secondary glaze to make the oil surface of the secondary glaze shiny when fired, In the secondary glaze, if the content of silica powder is less than 20% by weight, the secondary glaze is not glossy and easily flows down and cracks occur, and if the content of silica powder exceeds 20% by weight, the limestone powder has viscosity, so the secondary glaze Since the viscosity of the glaze is so high that it does not flow down well during roasting and it is not possible to obtain a desired pattern on the ceramic surface, the content of the silica stone powder in the secondary glaze is preferably 20% by weight.

Since the white clay powder does not contain iron, it is white when used in the secondary glaze and fired. When the white clay powder is less than 10% by weight in the secondary glaze, the secondary glaze is formed on the surface of the pottery The glaze composition may be dried or peeled off due to lack of adhesion, and when the amount of the white clay powder exceeds 10% by weight, the transparency of the second glaze is lowered, so that the color of parts due to the components of the second glaze excluding the white clay powder is reduced. not clearly visible

If the clay powder is more than 10% by weight, it can increase the dry strength of the glaze, and has viscosity, that is, adhesion. The use of the powder is preferably 10% by weight.

In the zinc powder, zinc usually uses a lot of zinc oxide, but when a small amount of zinc oxide is added to the high-degree porcelain oil, the melting temperature is lowered and a more complete glaze surface is formed. When 8% by weight of the zinc powder is used in the secondary glaze, it has good fire resistance and whiteness and helps the secondary glaze to adhere to the ceramic molding, so that the content of the zinc powder in the secondary glaze is 8% by weight. desirable. However, when the zinc powder is used in excess of 8% by weight in the secondary glaze, glaze curling, that is, crawling or cracking, occurs in the secondary glaze because zinc has a high shrinkage rate in a wide temperature range. When zinc powder is used in an amount of less than 8% by weight in the secondary glaze, the melting temperature of the secondary glaze is lowered.

The titanium powder plays a role in making a white glaze, and if it is less than 7% by weight, a pattern in which the white paint flows down may not be formed when the secondary glaze is fired by triple-grilling. When the titanium content exceeds 7% by weight, a pattern in which white paint flows down is well formed, but the gloss of the secondary glaze may be deteriorated.

The barium powder is included to make an opaque glaze, and when it is included in the secondary glaze at less than 10% by weight, the melting point becomes high and the oil surface becomes rough, and when it is included in more than 10% by weight, bubbles are generated. Since there is, it is preferable to include it at 10% by weight.

7. The third step (S7)

In the trimming step (S7), the second glazed pottery molding was triple-roasted by raising the temperature to 1,250 ° C. for 30 to 35 hours using one or more firewood kiln 200.

The firewood kiln 200 is coupled by being inserted into a bongtong 110 and a plurality of firing compartments 120, 121, 122, 123 through which heat can be sequentially transmitted through the lattice 150, and the lattice 150 , the lattice side double tube 300 forming a double tube of an inner tube 310 with both sides open and an outer tube 320 connected to the circumference of the inner tube 310 through a blocking plate, the lattice side double tube 300 ) and a remote side double tube 400 disposed at a remote location and disposed outside the inner tube 410 and the inner tube 410 and forming a double tube of the inner tube 410 and the outer tube 420 The inner tube 310 of the lattice-side double tube 300 is connected between the inner tube 410 of the remote double tube 400 to form a first flow passage L1 through which the hot air flows. The duct 151 is connected between the outer pipe 320 of the lattice-side double pipe 300 and the outer pipe 420 of the remote-side double pipe 400, and hot air flowing through the first flow passage L1 It includes an external duct 152 forming a second flow passage L2 through which it flows in, and the remote side double pipe 400 reverses the flow direction of the hot air flowing through the first flow passage L1. It includes an inverted part, and the inner duct 151 is connected in communication with the outer duct 152 so that hot air flowing along the first flow passage L1 is discharged and extends vertically upward to each firing compartment 120, 121, 122 and 123, respectively, including first to fourth preheated hot air supply pipes 411P, 412P, 413P, and 414P protruding into the inside, and the flow direction reversal part includes an inner pipe of the remote double pipe 400 ( 410) through a plurality of first connection portions 134 spaced apart from each other, and at a distance from the free end of the inner tube 410 of the remote side double tube 400 to the central axis of the inner tube 410. a disc 135 disposed perpendicularly to the inner tube 410 and concentrically disposed; and a first conical portion 136 concentrically installed on an inner surface of the disc 135 so that the spigot faces the first flow passage L1, and the diameter of the disc 135 is the remote side It is longer than the diameter of the inner tube 410 of the double tube 400 and smaller than the diameter of the outer tube 420 of the remote double tube 400, and the flow direction reversal part has the nipple facing the outside and the bottom surface a second conical portion 137 concentrically installed on the outer surface of the disk 135 so that its circumference matches the circumference of the disk 135; and a conical portion 131a connected to the outer tube 420 and having a smaller diameter as the distance increases from the outer tube 420 . A double duct 600 that extends horizontally from the free end of the conical portion 131a and further includes a flange portion 131af that can be fitted and coupled to the blower pipe 500a of the blower 500.

According to the configuration of the firewood kiln 200, the hot air flowing along the first flow passage L1 formed in the internal duct 151 hits the first conical portion 136 and flows laterally to the disc 135 Since the collision occurs in an oblique line, the hot air cannot escape to the outside, that is, to the right side of FIG. to flow in a flow direction opposite to the flow direction of the hot air flowing along the first flow passage L1 through the second flow passage L2 formed between the inner duct 151 and the outer duct 152 The flow direction of the hot air is reversed so that the hot air flowing along the second flow passage L2 forms an insulating layer of the hot air flowing along the first flow passage L1 to prevent heat loss, thereby preventing the first through fourth preheating Disposed in each firing compartment (120, 121, 122, 123) by supplying even heat to the inside of each firing compartment (120, 121, 122, 123) through the heat supply pipe (411P, 412P, 413P, 414P) It makes the three-piece roasting of the pottery molding evenly.

In the third step (S7), the second glazed pottery molding is put into a plurality of firewood kiln 200, and the temperature of the heat supplied to each of the firing compartments 120, 121, 122, and 123 is 25 ° C. for 4 hours 1 "secondary heating step (S7-1) raising at an equal rate from 3300 ℃; and the temperature of the hot air supplied to each of the firing compartments (120, 121, 122, 123) from 300 ℃ to 500 for 4 hours 2" secondary heating step (S7-2) that rises at an even rate to ° C; and the temperature of the hot air supplied to each of the firing compartments (120, 121, 122, 123) is uniformly increased from 500 ° C to 700 ° C for 4 hours. 3 "secondary heating step (S7-3) to raise at one speed; and the temperature of the hot air supplied to each of the firing compartments (120, 121, 122, 123) is uniformly increased from 700 ° C to 950 ° C for 8 to 10 hours. 4 "secondary heating step (S7-4) to increase the temperature at an even rate from 950 ℃ to 1,250 ℃ for 10 to 13 hours; and the heat supplied to each of the firing compartments (120, 121, 122, 123) 5 "secondary heating step (S7-5) to raise to; includes.

In this way, the second glazed pottery molding is put into each firing compartment 120, 121, 122, 123 of the firewood kiln 200, and the 1" to 5" heating steps (S7-1 to S7-5) By adjusting the temperature of the hot air supplied for 30-35 hours to gradually rise through the 30-35 It is precisely controlled so that it is done gradually over time to prevent cracking or damage of the ceramic molding during the firing process of the ashes.

In one embodiment, the second glazed pottery molding is put into each firing compartment 120, 121, 122, 123 of the firewood kiln 200, 1" to 5" heating step (S7-1 to S7 -5) to gradually increase the temperature of the heat supplied for 35 hours, thereby increasing the heating temperature of the ceramic moldings disposed in each firing compartment (120, 121, 122, 123) of the firewood kiln (200). It was confirmed that the ceramic molding was cracked or damaged during the firing process at the time of jaebeol roasting.

In addition, when the pottery molded article is fired by triple firing in the third step (S7), the second glaze applied secondly is fused with the feldspar powder, resulting in chemical resistance and gloss of the second glaze. This is improved, and the occurrence of oil surface cracks and the decrease in hardness and wear resistance of the secondary glaze are prevented by the limestone powder, and the gloss is imparted to the secondary glaze by the silica stone powder, and at the same time, the phenomenon of easily flowing down and cracking The zirconium powder prevents the decrease in whiteness and heat resistance and the occurrence of glaze curling, and the zinc powder makes the secondary glaze have good refractory and whiteness, and at the same time, the occurrence of glaze curling and Generation of cracks is prevented, and the melting point of the secondary glaze is maintained at 1,250° C. by the frit powder.

8. Take-out and cooling step (S8)

In the fetching and cooling step (S8), the pottery molded product, which was baked in three pieces, was taken out from the firewood kiln 200 and cooled to room temperature.

As such, when the ceramic molded article is cooled to room temperature of 25° C., the risk of injury to workers in the process of packaging, displaying, or moving the ceramic molded article for sale is reduced.

The present invention described above has been described with reference to the embodiments shown in the drawings, but this is only exemplary, and those skilled in the art can make various modifications and equivalent other embodiments therefrom. will have to clarify Therefore, the true technical protection scope of the present invention should be construed by the appended claims, and all technical ideas within the equivalent range should be construed as being included in the scope of the present invention.

2. Electric heater 4. Ceramic molding
10. Kiln body 12. Heating chamber
14. Ventilation window 16. Shelf
20. Circulation fan 30. Diaphragm
40. Reducing agent supply pipe 60. Air supply pipe
61. Through hole 70. Blowing fan
80. Air circulation guide pipe 100. Electric kiln
110. Bongtong 120, 121, 122, 123. Soseongkan
131a. Cone 131af. Flange part
134. First connection part 135. Disc
136. First cone part 137. Second cone part
150. lattice 151. internal duct
152. Exterior duct 200. Wood kiln
300. Double pipe on the lattice side 310, 410. Inner pipe
320, 420. Outer pipe 400. Remote side double pipe
411P, 412P, 413P, 414P. Preheat hot air supply line
500. Blower 500a. blow pipe
600. Duplex duct L1. first flow passage
L2. Second flow passage S1. initial stage
S1-1. 1st heating step S1-2. 2nd heating step
S1-3. Third heating step S1-4. 4th heating step
S2. 1st cooling step S3. 1st oiling stage
S4. Chaebol Stage S4-1. 1st heating step
S4-2. 2' heating step S4-3. 3' heating step
S4-4. 4' heating step S5. 2nd cooling step
S6. 2nd glazing step S7. three steps
S7-1. 1" primary heating stage S7-2. 2" primary heating stage
S7-3. 3" primary heating stage S7-4. 4" primary heating stage
S7-5. 5" primary heating step S8. Withdrawal and cooling step

Claims (6)

A priming step (S1) of priming a plurality of ceramic moldings pre-formed in a set shape by using a plurality of electric kilns 100 to increase the temperature to 800 ° C. at a uniform speed for 8 hours; and
A first cooling step (S2) of taking out the unglazed ceramic molding from the electric kiln 100 and cooling it to 25 ° C;
A first glazing step (S3) of applying a first glaze to the ceramic molding that has been unglazed and cooled; and
A chaebol step (S4) of roasting the first glazed pottery molding by using a plurality of electric kilns (100) at a uniform speed to a temperature of 800 ° C. for 8 hours; and
A second cooling step (S5) of taking out the pottery molded product that has been baked from the electric kiln 100 and cooling it to 25 ° C;
A second glazing step (S6) of applying a second glaze to the ceramic molding that has been baked and cooled; and
A third step (S7) of roasting the secondly glazed ceramic molding by raising the temperature to 1,250 ° C. for 30 to 35 hours using one or more firewood kiln 200; and
A withdrawal and cooling step (S8) of taking out the pottery molding, which has been roasted in three pieces, from the firewood kiln 200 and cooling it to room temperature;
The primary glaze contains 25% by weight of feldspar powder, 15% by weight of limestone powder, 15% by weight of silica stone powder, 10% by weight of talc powder, 20% by weight of clay powder, 12% by weight of barium powder, and 3% by weight. Contains dark blue pigments of,
The secondary glaze contains 20% by weight of feldspar powder, 15% by weight of limestone powder, 20% by weight of silica stone powder, 10% by weight of clay powder, 10% by weight of clay powder, 8% by weight of zinc powder, and 7% by weight of clay powder. A method for producing a pottery pattern in which brownish white paint and white paint flow down on a dark blue background, characterized in that it contains titanium powder and 10% by weight of barium powder. According to claim 1,
The firewood kiln 200,
Bongtong 110 and a plurality of firing compartments 120, 121, 122, 123 through which heat can be sequentially transmitted through the lattice 150; and
The double tube 300 on the lattice side forming a double tube of an inner tube 310 inserted into and coupled to the lattice 150 and open on both sides and an outer tube 320 connected to the circumference of the inner tube 310 through a blocking plate. ), disposed at a position remote from the lattice-side double pipe 300, disposed outside the inner pipe 410 and the inner pipe 410, and the double pipe of the inner pipe 410 and the outer pipe 420 The first flow through which the hot air is introduced and flows is connected between the inner tube 310 of the remote double tube 400 formed, the inner tube 310 of the lattice side double tube 300 and the inner tube 410 of the remote double tube 400 The first flow is connected between the inner duct 151 forming the passage L1 and the outer pipe 320 of the lattice-side double pipe 300 and the outer pipe 420 of the remote-side double pipe 400. and an external duct 152 forming a second flow passage L2 through which hot air flowing through the passage L1 is introduced and flows, and the remote side double pipe 400 is a source of hot air flowing through the first flow passage L1. It includes a flow direction reversal unit that reverses the flow direction, and the inner duct 151 is connected in communication with the outer duct 152 so that hot air flowing along the first flow passage L1 is discharged and extends vertically upward. It includes first to fourth preheating hot air supply pipes 411P, 412P, 413P, and 414P protruding into each firing compartment 120, 121, 122, and 123, respectively, and the flow direction reversal unit includes the remote side It is connected to the inner tube 410 of the double tube 400 through a plurality of first connection parts 134 spaced apart from each other, and the inner tube is spaced apart from the free end of the inner tube 410 of the remote side double tube 400. a disc 135 disposed perpendicular to the central axis of the tube 410 and disposed concentrically with the inner tube 410; and a first conical portion 136 concentrically installed on an inner surface of the disc 135 so that the spigot faces the first flow passage L1, and the diameter of the disc 135 is the remote side It is longer than the diameter of the inner tube 410 of the double tube 400 and smaller than the diameter of the outer tube 420 of the remote double tube 400, and the flow direction reversal part has the nipple facing the outside and the bottom surface a second conical portion 137 concentrically installed on the outer surface of the disk 135 so that its circumference matches the circumference of the disk 135; and a conical portion 131a connected to the outer tube 420 and having a smaller diameter as the distance increases from the outer tube 420 . A double duct 600 that extends horizontally from the free end of the conical portion 131a and further includes a flange portion 131af that can be fitted and coupled to the blower pipe 500a of the blower 500. A method of manufacturing pottery in which a pattern in the form of flowing brown and white paint is formed on a dark blue background. According to claim 1,
The electric kiln 100 is provided with a heating chamber 12 inside and a kiln body 10 having a plurality of ventilation windows 14 formed on the circumferential wall, and a gap adjacent to the inner wall surface of the kiln body 10 A plurality of pairs of electric heaters 2 provided inside the heating chamber 12 and a plurality of pairs provided at intervals vertically and horizontally so that the ceramic molding 4 can be placed on the inside of the heating chamber 12. A shelf 16, a circulation fan 20 provided inside the heating chamber 12 and purifying the high-temperature heat heated by the electric heater 2, and supplying a reducing agent into the heating chamber 12 It includes a reducing agent supply pipe 40, and an air supply pipe 60 (not shown) is installed in communication with the outside on one side of the heating chamber 12, and a blowing fan 70 (not shown) is installed in the air supply pipe 60 (not shown). is provided to cool the temperature inside the heating chamber 12 by supplying cold air from the outside to the inside of the heating chamber 12, and vertically on the diaphragm 30 installed on the bottom surface inside the heating chamber 12 It is installed in the gap between each pair of shelves 16 of the plurality of pairs of shelves 16, and the inlet at the top protrudes above the uppermost pair of shelves 16, and between each pair of shelves 16 Manufacture of pottery formed with a pattern in which brownish white paint and white paint flowed down on a dark blue background, characterized in that it further comprises an air circulation guide pipe 80 in which a plurality of through holes 61 are formed in the positioning portion method. According to claim 3,
The rough step (S1),
1st heating step (S1- 1); with
A second heating step (S1-2) of raising the temperature of the electric heater 2 at an even rate from 200 ° C to 400 ° C for 2 hours; and
A third heating step (S1-3) of raising the temperature of the electric heater 2 at an even rate from 400 ° C to 600 ° C for 2 hours; and
A fourth heating step (S1-4) of raising the temperature of the electric heater 2 at an equal rate from 600 ° C to 800 ° C for 2 hours; brownish white paint and white paint on a dark blue background, characterized in that it comprises A method of manufacturing pottery in which this flowing pattern is formed. According to claim 3,
In the chaebol step (S4),
A 1st heating step (S4-1) of putting the first glazed pottery molding into a plurality of electric kilns 100 and raising the temperature of the electric heater 2 at an equal rate from 25 ° C to 200 ° C for 2 hours ;and
A 2' heating step (S4-2) of raising the temperature of the electric heater 2 at an equal rate from 200 ° C to 400 ° C for 2 hours; and
A 3' heating step (S4-3) of raising the temperature of the electric heater 2 at an even rate from 400 ° C to 600 ° C for 2 hours; and
A 4' heating step (S4-4) of raising the temperature of the electric heater 2 at an equal rate from 600 ° C to 800 ° C for 2 hours; A method of manufacturing pottery with a pattern of dripping paint. According to claim 3,
The third step (S7),
The secondly glazed pottery molding is put into a plurality of firewood kiln 200, and the temperature of the heat supplied to each firing compartment (120, 121, 122, 123) is raised at an even rate from 25 ° C to 300 ° C for 4 hours 1 "secondary heating step (S7-1); and
A 2" secondary heating step (S7-2) of raising the temperature of the hot air supplied to each of the firing compartments (120, 121, 122, 123) at an equal rate from 300 ° C to 500 ° C for 4 hours; and
A 3" secondary heating step (S7-3) of raising the temperature of the hot air supplied to each of the firing compartments (120, 121, 122, 123) at an equal rate from 500 ° C to 700 ° C for 4 hours; and
A 4" secondary heating step (S7-4) of raising the temperature of the hot air supplied to each of the firing compartments (120, 121, 122, 123) at an equal rate from 700 ° C to 950 ° C for 8 to 10 hours; and
A 5" secondary heating step (S7-5) of raising the temperature of the hot air supplied to each of the firing compartments (120, 121, 122, 123) at an equal rate from 950 ° C to 1,250 ° C for 10 to 13 hours; including A method of manufacturing ceramics in which a pattern of brownish white paint and white paint flowed down on a dark blue background is formed.

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