KR101122353B1 - Manufacturing method of artificial casting stone for construction exterior decoration - Google Patents

Abstract

The present invention relates to a method for manufacturing cast stone for building exterior, which can realize the texture of natural limestone and natural sandstone for building using inorganic ceramic raw materials as a main material.

An object of the present invention is non-combustible, does not burn, does not generate toxic gas harmful to the human body due to combustion, lighter than natural stone can be easily and quickly precise construction can reduce the construction time and construction cost, Various colors can be expressed using natural inorganic raw materials and the color does not change, and the natural texture of natural stone is expressed by matching the air bubbles and wrinkled surface properly distributed according to the molding method and surface processing method It is possible to grind and polish used in natural stone, and manufacture cast-casting stone for building exterior that can replace natural limestone (limestone) and natural sandstone by manufacturing casting products of various shapes using various shapes of molds. To provide a way.

Manufacturing method of cast stone for exterior building

Description

MANUFACTURING METHOD OF ARTIFICIAL CASTING STONE FOR CONSTRUCTION EXTERIOR DECORATION

The present invention relates to a method for manufacturing cast stone for building exterior, and more particularly, to a method for manufacturing cast stone for building exterior which can realize the texture of natural limestone and natural sandstone for building using inorganic ceramic raw materials as main materials.

As a method of manufacturing a conventional artificial stone of this kind, it is disclosed in Korean Patent Publication No. 94-005072 (published date; June 10, 1994).

In the method of manufacturing artificial stone disclosed in Korean Patent Publication No. 94-005072, stone powder, pigment and thermoplastic resin are dissolved and mixed on the outer surface of a wooden board to apply colored stone powder dough to prepare artificial stone in an uncured state. Put the stone powder dough in the mold, and place the mold inclined or inclined the uncured artificial stone to form a pattern by the viscosity and self-weight of the stone powder dough, and put the uncured stone powder dough in the mold After molding, the resin was cured and then separated to complete the artificial stone.

However, the artificial stone prepared as described above is coated with colored stone powder dough by dissolving and mixing stone powder, pigment, and thermoplastic resin on the outer surface of wood board, so that the shrinkage force of the wood board and stone powder dough is different according to the use time. In addition to this problem, there is a problem that can not be precise construction by changing the dimensions.

In addition, since the artificial stone uses a thermoplastic resin, there are various problems such as not only burning on fire but also generating a combustion gas harmful to a human body at the time of combustion.

An object of the present invention is to provide a method for producing a cast stone for building exterior which is nonflammable and does not burn, and does not generate toxic gases harmful to the human body due to combustion.

Another object of the present invention is to provide a method for manufacturing a cast stone for building exterior which is lighter than natural stone can be easily and quickly precise construction can reduce the construction time and the construction cost.

Still another object of the present invention is to provide a method for manufacturing a cast stone for building exterior which can express various colors using natural inorganic raw materials and does not change its color.

Another object of the present invention is to express the natural texture of natural stone by matching the air bubbles and wrinkled surface properly distributed according to the molding method and surface processing method, or polishing (grinding and polishing) used in natural stone for construction, It is possible to trim (rough rough, fine and fine) work and manufacture various types of cast products using molds of various shapes to replace natural limestone (limestone) and natural sandstone. It is to provide a method for manufacturing the exterior cast stone.

In order to achieve the above object, the present invention provides a method for manufacturing the building exterior casting stone of 2.23 parts by weight to 2.60 parts by weight of cement, 7.64 parts by weight to 8.09 parts by weight of sand, 1.22 parts by weight to 1.35 parts by weight of limestone, and 0.09 parts by weight to 0.11 parts by weight. Part lightweight aggregate, 1.33 parts by weight to 1.46 parts by weight of gypsum, 0.01 parts by weight to 0.03 parts by weight of reaction accelerator, 0.02 parts by weight to 0.04 parts by weight of fluidizing agent, 0.01 parts by weight to 0.03 parts by weight of retardant, 0.19 parts by weight to 0.22 parts by weight For the dry surface material produced in the manufacturing step (step S1) and the ceramic dry mixture manufacturing step for the surface material (step S1) for producing a ceramic dry mixture for the surface material by stirring the inorganic pigment evenly in a stirrer. 1.62 parts by weight to 1.89 parts by weight of water was added to the ceramic mixture, and the mixture was stirred evenly in a stirrer to mix the ceramic mixture dough for the surface material. The release agent application process (step S3) which apply | coats a mold release agent to the inner peripheral surface of a shaping | molding die after the ceramic mixing dough manufacturing process for surface materials to manufacture (step S2), and the ceramic mixing dough production process for manufacturing a surface material (step S2), and the said surface materials for The ceramic mixture layer lamination process (step S4) for laminating a ceramic mixture layer for the surface material by squeezing the ceramic mixture dough for the surface material manufactured in the ceramic mixing dough manufacturing process (step S2) to a specific thickness on the inner circumferential surface of the mold; Reinforcing fiber layer lamination step of laminating a reinforcing fiber layer by laying a reinforcing fiber layer of 0.51 parts by weight to 0.69 parts by weight of a mesh type shape on the surface of the ceramic mixture layer lamination step (step S4). ), 18.37 parts by weight to 21.00 parts by weight of cement, 42.85 parts by weight to 46.15 parts by weight of sand after the reinforcing fiber layer lamination step (step S5), 4.87 parts Parts to 5.39 parts by weight of limestone, 3.83 parts by weight to 4.23 parts by weight of gypsum, 0.06 parts by weight to 0.08 parts by weight of reaction accelerator, 0.21 parts by weight to 0.23 parts by weight of fluidizing agent, 0.03 parts by weight to 0.05 parts by weight of retardant, 1.19 parts by weight to 1.27 parts by weight of the inorganic pigment is stirred in an agitator evenly to mix the ceramic dry mixture for the backing material ceramic dry mixture manufacturing process (step S6) and the backside material mixed in the ceramic dry mixture manufacturing process (step S6). 9.23 parts by weight to 10.76 parts by weight of water (H ₂ O) is added to the ceramic dry mixture and stirred evenly in a stirrer to prepare a ceramic mixing dough for the backing material (step S7), and The back surface manufactured in the ceramic mixing dough manufacturing process for the back surface material (step S7) on the reinforcing fiber layer laminated in the reinforcing fiber layer lamination step (step S5). The ceramic mixture layer laminating step (step S8) for laminating the ceramic mixture layer for the backing material by laminating the ceramic mixture kneading material to a specific thickness and the ceramic mixture layer laminating step for the backing material (step S8). A drying step (step S9) of drying the ceramic mixture layer for backing material laminated in the ceramic mixture layer stacking step (step S8) for the backing material at a temperature of from 30 ° C. to 30 ° C., and the semi-finished product dried in the drying step Demolding step (step S10) for demolding the cast stone of the mold from the mold, and the cast stone of the semi-finished product demolded in the demolding step (step S10) is maintained at a humidity of 60% to 95% and a temperature of 60 ℃ to 80 ℃ Polishing and polishing of the curing step (step S11) and the cast stone of the semi-finished product cured in the curing step (step S11), which is left to cure for 40 to 50 hours in the curing room maintained at the Polishing / Trimming / Washing Process (Step S12) to Clean / Turn / Clean Semi-Finished Cast Stone Surface by Washing Up and After, and Cast Stone Surface of Semi-Finished Product Stone in the Polishing / Trimming / Washing Process (Step S12) A cutting process (step S13) for cutting the polished / washed cast stone to a specific size, and a coating process for coating a surface of the cast stone of the semi-finished product cut to a specific size in the cutting process (step S13) (step S14). Characterized in that it comprises a.

As described above, according to the manufacturing method of the cast stone for building exterior of the present invention, because it is incombustible and does not burn, it does not generate toxic gas harmful to the human body due to combustion, and is lighter than natural stone, so it can be easily and quickly precisely installed. It can shorten the construction time and reduce the construction cost, and can express various colors using natural inorganic raw materials, and the color does not change, and the air bubbles and corrugated surface properly distributed according to the molding method and the surface processing method can be used. It is possible to express the natural texture of natural stone or to grind (grind and polish) and trim (rough, fine, fine) work that is used in natural stone for building. Formed cast molded products to replace natural limestone (limestone) and natural sandstone It can have that effect.

Next, the cast stone for building exterior of the present invention will be described in detail with reference to Examples 1 to 3.

1 is a perspective view schematically showing a building exterior cast stone according to an embodiment of the present invention, Figure 2 is a longitudinal cross-sectional view showing a state of the building exterior cast stone stacked in a molding frame according to an embodiment of the present invention. 3 is a flowchart showing a manufacturing procedure of the cast stone for building exterior according to an embodiment of the present invention.

Hereinafter, the manufacturing method of the cast stone for building exterior according to the embodiment of the present invention.

Example 1

2.23 parts by weight of cement, 8.09 parts by weight of sand (sand having a particle size of 18 to 30 mesh and No. 6 sand of 31 to 80 mesh in a 6: 4 volume ratio), and 1.35 parts by weight of limestone And 0.09 parts by weight of light aggregate, 1.46 parts by weight of gypsum, 0.02 parts by weight of reaction accelerator (Li ₂ CO ₃ ), 0.02 parts by weight of fluidizing agent, 0.03 parts by weight of retardant, and 0.19 parts by weight of inorganic pigment After stirring, the ceramic dry mixture for the surface material is mixed (the ceramic dry mixing step for the surface material; step S1 (S denotes Step)), and then proceeds to step S2 for the surface material mixed in the ceramic dry mixing step for the surface material. ceramic dry mixture to 1.62 parts by weight of water (H ₂ O) was added and it was stirred uniformly in a stirrer to prepare a surface damper ceramic kneading water (surface water re-dissolved ceramic mixed dough making process), and the surface of the ceramic mix damper After the bamboo salt producing step, the process proceeds to step S3 and the mold release agent (carry (K)) is applied to the inner peripheral surface of the mold 1 (release agent applying process), and then the process proceeds to step S4 for the surface material prepared in the ceramic mixing dough production process for the surface material. The ceramic mixture dough was chopped to a specific thickness on the inner circumferential surface of the mold 1 to which the release agent was applied in the release agent applying step to laminate the ceramic mixture layer 3 for the surface material (ceramic mixture layer lamination step for the surface material).

Next, the process proceeds to step S5 to laminate the reinforcing fiber layer 5 by laying 0.51 parts by weight of mesh-type reinforcing fiber on the surface-mixing ceramic mixture layer 3 in the surface material ceramic mixture layer laminating step (reinforcing fiber layer laminating step). After the reinforcing fiber layer lamination process, the process proceeds to step S6, where 18.37 parts by weight of cement and 46.15 parts by weight of sand (No. 5 sand having a particle size of 18 to 30 mesh and No. 6 sand of 31 to 80 mesh are 6: 4). Sand, mixed with a volume ratio of 5.39 parts by weight of limestone, 4.23 parts by weight of gypsum, 0.06 parts by weight of reaction accelerator, 0.23 parts by weight of fluidizing agent, 0.05 parts by weight of retardant, and 1.19 parts by weight of inorganic pigment Stirring to prepare a ceramic dry mixture for the backing material (manufacturing process for the ceramic dry mixture for the backing material), and proceed to step S7 to produce the ceramic dry mixture for the backing material. 9.23 parts by weight of water was added to the prepared ceramic dry mixture for the backing material, and then stirred evenly in a stirrer to prepare a ceramic mixing dough for the backing material (manufacturing process for the ceramic mixing dough for the backing material), and after the ceramic mixing dough manufacturing process for the backing material In step S8, the ceramic mixture dough for the backing material prepared in the ceramic mixing dough for the backing material prepared in the manufacturing process for the backing material is laminated on the reinforcing fiber layer 5 laminated in the reinforcing fiber layer stacking step 7. ) Was laminated (ceramic mixture layer lamination step for backing material).

Next, the process proceeds to step S9 and the ceramic mixture layer 7 for backing material laminated in the ceramic mixture layer laminating step for the backing material is dried at a temperature of 15 ° C to 30 ° C for 30 minutes (drying step). Further, the cast stone of the semi-finished product dried in the drying step is demolded from the forming mold 1 (de-molding step), and the process proceeds to step S11 to maintain the cast stone of the semi-finished product demolded in the demolding process at a humidity of 60% to 95% or more. And curing (curing process) for 40 hours to 55 hours in a curing chamber maintained at a temperature of 50 ° C. to 70 ° C., and proceed to step S12 to cast stone surface of the semi-finished product cured in the curing process (the ceramic mixture layer for the surface material) After polishing / polishing / washing (polishing / polishing / washing processing) to wash the surface of (3) after the polishing and polishing operation, proceed to step S13 in the polishing / polishing / washing processing process. After cutting the cast stone of the semi-finished product to a specific size (cutting process), go to step S14 to be coated with a waterproofing agent (including a permeable waterproofing agent) on the surface of the cast stone of the semi-finished product cut to a specific size in the cutting process to be waterproof. Step) to produce a cast stone 10 for building exterior of the present invention.

The building exterior cast stone 10 of the present invention manufactured as described above was manufactured in accordance with the provisions of KS 5105-87 to form a test piece by molding the width × length × height to 50mm × 50mm × 50mm in a molding frame. 7 days later, specific gravity, water absorption, compressive strength, flexural strength, and resistance to freeze-thaw (100 cycles) were tested.

As a result of measuring specific gravity and water absorption according to KSF2518-'80, specific gravity was 1.85, water absorption was 3.2%, and compressive strength was measured according to KSL5105-'87. Compressive strength was 46.9 N / mm ² The flexural strength was 5.2 N / mm ^{2 according} to the provisions of KSF2476-'02, and the resistance to freeze-thawing (100 cycles) was determined according to the KSF2456-'93, and there were no cracks or cracks.

Therefore, it was found that the cast stone 10 for building exterior according to the present invention is suitable as a building exterior material.

Example 2

2.48 parts by weight of cement, 7.76 parts by weight of sand (sand mixed with No. 5 sand having a particle size of 18 to 30 mesh and No. 6 sand of 31 to 80 mesh in a volume ratio of 6: 4), and 1.29 parts by weight of limestone And 0.1 parts by weight of light aggregate, 1.4 parts by weight of gypsum, 0.01 parts by weight of reaction accelerator, 0.03 parts by weight of fluidizing agent, 0.01 parts by weight of retardant, and 0.21 parts by weight of inorganic pigments in a stirrer, and agitated evenly. After mixing the dry mixture (surface ceramic dry mixing step; step S1), proceed to step S2 and add 1.81 parts by weight of water to the ceramic dry mixture for surface material mixed in the ceramic dry mixing step for the surface material and stir evenly in a stirrer. To prepare a ceramic mixture dough for the surface material (manufacturing process of the ceramic mixture dough for the surface material), and proceed to step S3 after the ceramic mixture dough material manufacturing process for the surface material. After the release agent (carrying (K)) is applied to the inner circumferential surface of the molding die 1 (release agent applying step), the process proceeds to step S4 and the ceramic mixture dough for surface material prepared in the ceramic mixing dough preparation process for the surface material is subjected to the release agent. In the coating process, the ceramic mixture layer 3 for surface materials was laminated | stacked (cutting the ceramic mixture layer lamination process for surface materials) by compacting it in the inner peripheral surface of the shaping | molding die 1 to which the mold release agent was apply | coated to specific thickness.

Next, the process proceeds to step S5 and the reinforcing fiber layer 5 is laminated by laying 0.60 parts by weight of mesh type reinforcing fibers on the surface-mixing ceramic mixture layer 3 in the surface material ceramic mixture layer laminating step (reinforcing fiber layer laminating step). After the step of laminating the reinforcing fiber layer, the process proceeds to step S6, where 20.00 parts by weight of cement, 43.95 parts by weight of sand (No. 5 sand having a particle size of 18 to 30 mesh and No. 6 sand of 31 to 80 mesh are 6: 4). Sand, mixed with a volume ratio of 5.13 parts by weight of limestone, 4.03 parts by weight of gypsum, 0.07 parts by weight of reaction accelerator, 0.22 parts by weight of glidant, 0.04 parts by weight of retardant, and 1.21 parts by weight of inorganic pigment After stirring, the ceramic dry mixture for the backing material is mixed (process for preparing the ceramic dry mixture for the backing material), and the process proceeds to step S7 in the process for producing the ceramic dry mixture for the backing material. 10.25 parts by weight of water is added to the prepared ceramic dry mixture for the backing material, and then stirred evenly in a stirrer to prepare a ceramic mixing dough for the backing material (manufacturing process for the ceramic mixing dough for the backing material), and after the ceramic mixing dough manufacturing process for the backing material. In step S8, the ceramic mixture dough for the backing material prepared in the ceramic mixing dough for the backing material prepared in the manufacturing process for the backing material is laminated on the reinforcing fiber layer 5 laminated in the reinforcing fiber layer stacking step 7. ) Was laminated (ceramic mixture layer lamination step for backing material).

Next, the process proceeds to step S9 and the ceramic mixture layer 7 for backing material laminated in the ceramic mixture layer laminating step for the backing material is dried at a temperature of 15 ° C to 30 ° C for 30 minutes (drying step). Further, the cast stone of the semi-finished product dried in the drying step is demolded from the mold 1 (de-molding step), and the flow proceeds to step S11 to maintain the cast stone of the semi-finished product demolded in the demolding process at a humidity of 60% to 95%. And curing (curing process) for 40 hours to 55 hours in the curing room maintained at a temperature of 50 ℃ to 70 ℃, go to step S12 and the surface of the cast stone of the semi-finished product cured in the curing process (ceramic mixture layer for the surface material (3) After polishing / polishing / cleaning (polishing / polishing / washing processing) to clean the surface of the surface) after polishing and polishing, the process proceeds to step S13 and the semi-finished product in the polishing / polishing / washing processing After the cast stone is cut to a specific size (cutting step), the process proceeds to step S14, where the surface of the cast stone of the semi-finished product cut to the specific size in the cutting process (specifically, the surface of the ceramic mixture layer 3 for the surface material) The coating (coating step) of a waterproofing agent (including an impervious waterproofing agent) was prepared on the cast stone 10 for building exterior of the present invention.

The building exterior cast stone 10 of the present invention manufactured as described above was manufactured in accordance with the provisions of KS 5105-87 to form a test piece by molding the width × length × height to 50mm × 50mm × 50mm in a molding frame. 7 days later, specific gravity, water absorption, compressive strength, flexural strength, and resistance to freeze-thaw (100 cycles) were tested.

As a result of measuring specific gravity and water absorption according to KSF2518-'80, specific gravity was 1.83, water absorption was 2.8%, and compressive strength was measured according to KSL5105-'87. Compressive strength was 46.1 N / mm ² was, KSF2476-'02 As a result of measuring the bending strength by the terms of the bending strength 5.3N / mm ² was, by the terms of KSF2456-'93 deoni done resistance (100 cycles) for the freezing and thawing test, and cracking etc. keulraek There was no.

Therefore, it was found that the cast stone 10 for building exterior according to the present invention is suitable as a building exterior material.

Example 3

2.60 parts by weight of cement, 7.64 parts by weight of sand (sand mixed with No. 5 sand having a particle size of 18 to 30 mesh and No. 6 sand of 31 to 80 mesh in a volume ratio of 6: 4), and 1.22 parts by weight of limestone And 0.11 parts by weight of light aggregate, 1.33 parts by weight of gypsum, 0.03 parts by weight of reaction accelerator, 0.04 parts by weight of fluidizing agent, 0.02 parts by weight of retardant, and 0.22 parts by weight of inorganic pigment by stirring in an agitator evenly. After mixing the dry mixture (surface ceramic dry mixing step; step S1), the process proceeds to step S2, and 1.89 parts by weight of water is added to the ceramic dry mixture for surface material mixed in the ceramic dry mixing step for the surface material and evenly mixed in a stirrer. The mixture was stirred to produce a ceramic mixture dough for surface materials (process of producing ceramic mixture dough for surface materials), and the step step S3 after the ceramic mixture dough preparation process for surface materials. After applying the release agent (carry (K)) to the inner peripheral surface of the mold 1 (release agent applying step), the process proceeds to step S4 and the ceramic mixture dough for the surface material prepared in the ceramic mixing dough production process for the surface material In the release agent applying step, the ceramic mixture layer 3 for the surface material was laminated (cut the ceramic mixture layer lamination step for the surface material) by compacting it into a specific thickness on the inner peripheral surface of the mold 1 to which the release agent was applied.

Next, the process proceeds to step S5 to laminate the reinforcing fiber layer 5 by laying 0.69 parts by weight of mesh-type reinforcing fibers on the surface-mixing ceramic mixture layer 3 laminated in the surface material ceramic mixture layer laminating step (reinforcing fiber layer lamination). Step) After the step of laminating the reinforcing fiber layer, go to step S6, 61.00 parts of cement, 42.85 parts by weight of sand (No. 5 sand having a particle size of 18 to 30 mesh and No. 6 sand of 31 to 80 mesh) Sand mixed at a volume ratio of 4), 4.87 parts by weight of limestone, 3.83 parts by weight of gypsum, 0.08 parts by weight of reaction accelerator, 0.21 parts by weight of glidant, 0.03 parts by weight of retardant, and 1.27 parts by weight of inorganic pigment After stirring uniformly to mix the ceramic dry mixture for the backing material (mixing process of the ceramic dry mixture for the backing material), the process proceeds to step S7 and the mixing in the ceramic dry mixing step for the backing material. 10.76 parts by weight of water was added to the ceramic dry mixture for the backing material, and stirred evenly in a stirrer to prepare a ceramic mixing dough for the backing material (manufacturing process for the ceramic mixing dough for the backing material), followed by the ceramic mixing dough for the backing material. In step S8, the ceramic mixed dough for the backing material prepared in the ceramic mixing dough for the backing material prepared in the manufacturing process of the ceramic mixed dough for the backing material is chopped to a specific thickness on the reinforcing fiber layer 5 laminated in the reinforcing fiber layer laminating process (7). ) Was laminated (ceramic mixture layer lamination step for backing material).

Next, the process proceeds to step S9 and the ceramic mixture layer 7 for backing materials laminated in the ceramic mixture layer laminating step for the backing material is dried for 60 minutes to 90 minutes at a temperature of 15 ° C to 30 ° C (drying step). Further, the cast stone of the semi-finished product dried in the drying step is demolded from the mold 1 (de-molding step), and the flow proceeds to step S11 to maintain the cast stone of the semi-finished product demolded in the demolding process at a humidity of 60% to 95%. And curing (curing process) for 40 hours to 55 hours in a curing chamber maintained at a temperature of 50 ℃ to 70 ℃, and proceeds to step S12 the cast stone surface of the semi-finished product cured in the curing process (the ceramic mixture layer for the surface material ( 3) after polishing and polishing, and then polished / polished / washed (grinded / polished / washed processing steps) of the cast stone surface of the semi-finished product, and then proceeds to step S13 to perform the above-mentioned After the cast stone of the semi-finished product is cut (cutting step) to a specific size in the flattening / washing process, the process proceeds to step S14 and the surface of the cast stone of the semi-finished product cut to the specific size to be waterproof (the ceramic mixture layer for the surface material) The surface of 3)) was coated (coating step) with a waterproofing agent (including a permeable waterproofing agent) to manufacture the cast stone 10 for building exterior of the present invention.

The building exterior cast stone 10 of the present invention manufactured as described above was manufactured in accordance with the provisions of KS 5105-87 to form a test piece by molding the width × length × height to 50mm × 50mm × 50mm in a molding frame. 7 days later, specific gravity, water absorption, compressive strength, flexural strength, and resistance to freeze-thaw (100 cycles) were tested.

As a result of measuring specific gravity and water absorption according to KSF2518-'80, specific gravity was 1.84, water absorption was 3.5%, and compressive strength was measured according to KSL5105-'87, and the compressive strength was 44.4 N / mm ^2. was, KSF2476- results of the measurement of the bending strength by the terms of 2002, the bending strength 5.2N / mm ² was, by the terms of KSF2456-'93 deoni done resistance (100 cycles) for the freezing and thawing test, and cracking etc. keulraek There was no.

Therefore, it was found that the cast stone 10 for building exterior according to the present invention is suitable as a building exterior material.

Comparative example

3.01 parts by weight of cement, 6.84 parts by weight of sand (sand mixed with No. 5 sand having particle sizes of 18 to 30 mesh and No. 6 sand of 31 to 80 mesh in a volume ratio of 6: 4), and 8.84 parts by weight of limestone After mixing uniformly with 0.68 parts by weight of light aggregate and 0.68 parts by weight of gypsum and stirrer to mix the ceramic dry mixture for surface material (ceramic dry mixing step for surface material; step S1), the process proceeds to step S2 and the ceramic dry type for surface material. The ceramic dry mixture for the surface material, which was mixed in the mixing step, was stirred equally with 0.03 parts by weight of the reaction accelerator, 0.04 parts by weight of the fluidizing agent, 0.05 parts by weight of the retardant, and 0.16 parts by weight of the inorganic pigment in an agitator. After mixing (ceramic dry mixing process for surface material), 3.52 parts by weight of water is stirred evenly with a stirrer to prepare a ceramic mixture dough for surface material (ceramic for surface material) MIX mixing dough manufacturing process), and the release agent (carrying (K)) is applied to the inner peripheral surface of the mold 1 (release agent coating step), then the ceramic mixing dough for the surface material prepared in the ceramic mixing dough manufacturing process for the surface material Water was chopped to a specific thickness on the inner circumferential surface of the mold 1 to laminate the ceramic mixture layer 3 for the surface material (the ceramic mixture layer lamination step for the surface material).

Next, the reinforcing fiber layer 5 was laminated (reinforcing fiber layer lamination step) by laying 0.51 parts by weight of mesh type reinforcing fiber on the surface-mixing ceramic mixture layer 3 in the surface material ceramic mixture layer lamination step. Parts by weight of cement, 31.32 parts by weight of sand (sand having a particle size of 18 to 30 meshes and No. 6 sands of 31 to 80 meshes at a volume ratio of 6: 4), 4.69 parts by weight of limestone, , 3.38 parts by weight of gypsum, 0.03 parts by weight of reaction accelerator, 0.21 parts by weight of fluidizing agent, 0.27 parts by weight of retardant, and 1.70 parts by weight of inorganic pigment, by stirring in a stirrer and mixing the ceramic dry mixture for backing material Dry mixing process) and then 19.52 parts by weight of water is equally stirred in a stirrer to the ceramic dry mixture for the backing material mixed in the ceramic back mixing process for the backing material. A ceramic dry mix for the backing material manufactured in the ceramic dry mixing dough for the backing material is manufactured on the reinforcing fiber layer 5 laminated in the reinforcing fiber layer lamination step, and manufactured a kneaded material (a ceramic mixing kneading step for the backing material). The dough was chopped to a specific thickness to laminate the ceramic mixture layer 7 for the backing material (the ceramic mixture layer laminating step for the backing material).

Next, in order to cure after the ceramic mixture layer lamination process for the backing material, it is dried at a temperature of 15 ° C to 30 ° C for 30 minutes to 90 minutes (drying step), and the cast stone of the semi-finished product dried in the drying step is formed in the molding frame ( (1) demolding from 1), the cast stone of the semi-finished product demolded in the demolding process is maintained at a humidity of 60% to 95% or more and maintained at a temperature of 60 ℃ to 70 ℃ for 45 hours to 50 hours It is left in the shade to cure (cure process), and after the polishing and polishing of the semi-finished cast stone cured in the curing process, the surface of the cast stone of the semi-finished product is polished / refined / washed (polishing / refining / washing process) In the polishing / refining / washing process, the surface of the cast stone of the semifinished product is cut (cutting process) into a specific size of the polished / refined / washed semi-finished cast stone, and then the waterproofing The cast stone for building exterior of the comparative example was coated (coated) with a waterproofing agent (including a permeable waterproofing agent) on the cast stone surface (specifically, the surface of the ceramic mixture layer 3 for surface material) cut to a specific size in the process. Was prepared.

In accordance with the provisions of KS 5105-87, the cast stone for building exterior manufactured by the comparative example manufactured in this way was molded into a width × length × height of 50 mm × 50 mm × 50 mm in a molding frame to manufacture test pieces, 7 days later, specific gravity, water absorption, compressive strength, flexural strength, and resistance to freeze-thaw (100 cycles) were tested.

As a result of measuring specific gravity and water absorption according to KSF2518-'80, specific gravity was 1.87, water absorption was 2.5%, and compressive strength was measured according to KSL5105-'87, and the compressive strength was 48.9 N / mm ² was, KSF2476-'02 by the terms of the results of the measurement of the bending strength, the bending strength was 4.8N / mm ^2, deoni by the terms of KSF2456-'93 done resistance (100 cycles) for the freezing and thawing test, and cracking keulraek There was a back.

The cast stone for building exterior materials according to the comparative example produced in this way has a high content of light weight aggregates, so that the surface is too smooth like tiles in the freeze-thawing test, so it does not look like natural stone, which is unsuitable for high value-added exterior materials, and also has a low gypsum content. The hardness was high and the breakage rate was high, which was unsuitable for the exterior material.

In the above description, the lightweight aggregate is preferably used vermiculite or pearlite.

The inorganic pigments include titanium dioxide (white pigment), ferric dioxide (red pigment), ferric trioxide (yellow pigment), sodium aluminum sulfosilicate (blue pigment), oxide iron green (green pigment) and carbon black (black pigment). For example, these pigments may be used alone, but by adjusting the content of two or more pigments, the surface color of the cast stone 10 for building exterior materials of the present invention can be easily changed to various colors.

In the above description, as a water repellent coating agent to be coated on the surface of the ceramic mixture layer 3 for surface material, a permeable sealant of colorless, odorless, and harmless transparent color which is easily chemically combined with each component of the present invention is used. When the waterproofing agent is coated on the cast stone surface of the semi-finished product (specifically, the surface of the ceramic mixture layer 3 for the surface material), the surface is prevented from erosion and neutralization, the surface is strengthened, neutralization is prevented, durability is increased, Prevent contamination

In the production of the above-mentioned ceramic dry mixture, when the cement content is more than 2.60 parts by weight, cracking is not preferable, and when the cement content is less than 2.23 parts by weight, the strength is lowered, which is not preferable, and the production cost increases, which is not preferable. If it contains more than 8.09 parts by weight of sand, the cost is low but the strength is poor, and if it contains less than 7.64 parts by weight of sand, the content of other components increases, which increases the strength but increases the manufacturing cost, which is undesirable. When the content is more than 1.35 parts by weight, the compressive strength is not preferable, and when the content is less than 1.22 parts by weight, the bending strength is not preferable. When the content is less than 0.11 part by weight, the surface roughness (a large number of Concave grooves appear on the surface) to increase the appearance of natural stone If it contains less than 0.09 parts by weight of lightweight aggregate, the surface is too smooth and does not look like natural stone. If it contains more than 1.46 parts by weight of gypsum, the hydration reaction occurs well and the strength is high. If it contains less than 1.33 parts by weight of gypsum, the strength deteriorates, and if it contains more than 0.03 parts by weight of the reaction accelerator, the curing rate is increased and workability is poor. If less than 0.01 part by weight of the reaction accelerator, the workability is improved, but the curing rate is poor, which is not preferable.

In addition, in the preparation of the above-mentioned ceramic dry mixture for the surface, when the fluidizing agent is contained in an amount exceeding 0.04 parts by weight, the fluidity is good and the workability is improved, but the strength is too high, which is not preferable. It is poor in fluidity and consumes a lot of moisture, and is not preferable because of poor workability. If it contains more than 0.03 parts by weight of a retardant, the hydration reaction is delayed and the curing rate is slowed. If contained, the rate of hydration reaction is increased and the curing rate is increased, which is not preferable. If the inorganic pigment is contained in an amount exceeding 0.22 parts by weight, the color becomes white, and other components are lacking to obtain required exterior material properties. It is not preferable because it is not preferable, and if it contains less than 0.19 parts by weight of the inorganic pigment, It is not preferable because it cannot be obtained, and when water is contained in an amount exceeding 1.89 parts by weight, the viscosity is increased and workability is inferior, and when water is contained in an amount of less than 1.62 parts by weight, the viscosity is poor and workability is good, but adhesion is poor. I can't.

In addition, when the mesh type reinforcing fiber is contained in an amount exceeding 0.69 parts by weight, the tensile strength is increased but other components are insufficient, which is not preferable. When the mesh type reinforcing fiber is contained in less than 0.51 part by weight, the tensile strength is not preferable.

In the production of the above-mentioned ceramic dry mixture for the back surface, when the cement is contained in an amount of more than 21.00 parts by weight, cracking is not preferable. When the cement is contained in an amount of less than 18.37 parts by weight, the strength is not preferable, and the production cost increases, which is not preferable. If it contains more than 46.15 parts by weight of sand, the cost is low but the strength is poor, and if it contains less than 42.85 parts by weight of sand, the content of other components increases, the strength increases, but the production cost increases, which is undesirable. When the content is more than 5.39 parts by weight, the compressive strength is not preferable, and when the content is less than 4.87 parts by weight, the bending strength is not preferable. When the content is more than 4.23 parts by weight, the hydration reaction occurs well and the strength Is strong, but it may be damaged during construction or transportation. If less than 3.83 parts by weight of gypsum is contained, the strength is deteriorated, which is not preferable. If the content of the reaction accelerator is more than 0.08 parts by weight, the curing rate is increased and the workability is poor. If less than this, the workability is improved, but the curing rate is poor, which is not preferable.

In addition, in the production of the above-mentioned ceramic dry mixture for the back side, when the fluidizing agent is contained in an amount exceeding 0.23 parts by weight, the fluidity is good and the workability is improved, but the strength is too high, which is not preferable. It is not preferable because of poor fluidity and poor moisture, which is poor in workability, and when it contains more than 0.05 parts by weight of retardant, the hydration reaction is delayed and the curing rate is slowed. If contained, the rate of hydration reaction is increased and the curing rate is increased, which is not preferable. If the inorganic pigment is contained in an amount of more than 1.27 parts by weight, the color becomes white, and other components are insufficient to obtain the required exterior material properties. Unfavorable because it is less than 1.19 parts by weight of the inorganic pigment, the required color It is not preferable because it is not preferable, and if it contains more than 10.76 parts by weight of water, the viscosity is increased and the workability is poor, and if it is contained less than 9.23 parts by weight, the viscosity is poor and the workability is good but the adhesion is preferable. I can't.

In the above description, the lightweight aggregate is preferably used vermiculite or pearlite.

The inorganic pigments include titanium dioxide (white pigment), ferric dioxide (red pigment), ferric trioxide (yellow pigment), sodium aluminum sulfosilicate (blue pigment), oxide iron green (green pigment) and carbon black (black pigment). For example, these pigments may be used alone, but by adjusting the content of one or more pigments, the surface color of the cast stone 10 for building exterior materials of the present invention can be easily changed to various colors.

Preferably, the reaction promoter is lithium carbonate (Li ₂ CO ₃ ), the fluidizing agent is preferably a water reducing agent, and the reinforcing fiber is preferably a mesh type reinforcing fiber.

In the above description, the water-repellent coating agent coated on the surface of the ceramic mixture layer 3 for surface material is coated with a colorless, odorless, harmless transparent color permeable sealant which chemically bonds with the raw material, and penetrates the surface. Prevents crusting, hardens surfaces, prevents neutralization, increases durability, and prevents contamination.

Therefore, the present invention is not combustible and does not burn, and does not generate toxic gas harmful to the human body due to combustion, and is lighter than natural stone so that it can be easily and quickly precisely installed, thereby reducing construction time and reducing construction cost. It can express various colors by using natural inorganic raw materials, and it does not change its color, and expresses the natural texture of natural stone by matching air bubbles and wrinkled surface properly distributed according to molding method and surface processing method or It is possible to grind (water grind and polish) used in natural stone, and to trim (coarse, fine and fine) and to produce various types of cast molding products using various shapes of molds. It can replace stone (limestone) and natural sandstone.

In the above description, the specific embodiments have been shown and described, but the present invention is not limited thereto, for example, by those skilled in the art without departing from the concept of the present invention. Of course, the design can be changed in various ways.

1 is a perspective view schematically showing a cast stone for building exterior according to an embodiment of the present invention.

Figure 2 is a longitudinal cross-sectional view showing a state in which the cast stone for building exterior according to an embodiment of the present invention is laminated in the molding die.

Figure 3 is a flow chart showing the manufacturing procedure of the building exterior cast stone according to an embodiment of the present invention.

Description of the Related Art

1: Molding mold (molding) 3: Ceramic mixture layer for surface material

5: Reinforcing fiber layer 7: Ceramic mixture layer for backing material

Claims (5)

2.23 parts by weight to 2.60 parts by weight of cement, 7.64 parts by weight to 8.09 parts by weight of sand, 1.22 parts by weight to 1.35 parts by weight of limestone, 0.09 parts by weight to 0.11 parts by weight of light aggregate, 1.33 parts by weight to 1.46 parts by weight of gypsum for the surface material Ceramic dry mixing process (step S1) for the surface material which mixes a ceramic dry mixture, 0.01 parts by weight to 0.03 parts by weight of lithium carbonate, 0.02 parts by weight to 0.04 parts by weight of a fluidizing agent, 0.01 parts by weight to 0.03 parts by weight of a retardant to the ceramic dry mixture for surface materials mixed in the ceramic dry mixing step for surface material (step S1), A ceramic mixing dough preparation process for surface materials (step S2), in which 0.19 parts by weight to 10.22 parts by weight of an inorganic pigment and 1.62 parts by weight to 1.89 parts by weight of water are added and stirred uniformly in a stirrer to prepare a ceramic mixture dough for surface materials. , A releasing agent applying step (step S3) of applying a releasing agent to the inner peripheral surface of the molding die 1 after the ceramic mixing dough production step (step S2) for the surface material; Surface material ceramic for laminating the ceramic mixture dough for surface material prepared in the step of manufacturing the ceramic mixture dough for surface material (step S2) to a specific thickness on the inner circumferential surface of the molding die 1 to laminate the ceramic mixture layer 3 for surface material. Mixture layer lamination step (step S4), Reinforcing fiber layer lamination for laminating the reinforcing fiber layer 5 by laying a mesh type shape reinforcing fiber on the surface of the ceramic mixture layer 3 laminated in the surface material ceramic mixture layer stacking step (step S4). Process (step S5), After the reinforcing fiber layer lamination step (step S5), 18.37 parts by weight to 21.00 parts by weight of cement, 42.85 parts by weight to 46.15 parts by weight of sand, 4.87 parts by weight to 5.39 parts by weight of limestone, 3.83 parts by weight to 4.23 parts by weight of gypsum, and 0.06 parts by weight to 0.08 parts by weight of lithium carbonate, 0.21 parts by weight to 0.23 parts by weight of a fluidizing agent, 0.03 parts by weight by 0.05 parts by weight of a retardant, 1.19 parts by weight by 1.27 parts by weight of an inorganic pigment is stirred in an stirrer to mix the ceramic dry mixture for the backing material Ceramic dry mixing process for back material (step S6), 9.23 parts by weight to 10.76 parts by weight of water is added to the ceramic dry mixture for the back material mixed in the ceramic dry mixing process for the back surface material (step S6) and stirred evenly in a stirrer to prepare the ceramic mixed dough for the back material. Mixed dough production process (step S7); On the reinforcing fiber layer 5 laminated in the reinforcing fiber layer stacking step (step S5), the ceramic dry mixing kneading material for the backing material prepared in the manufacturing step of ceramic dry mixing dough for the backing material (step S7) is chopped to a specific thickness. Ceramic mixture layer lamination process for back surface material which laminates the ceramic mixture layer 7 for materials (step S8), After the ceramic mixture layer stacking step (step S8) for the backing material, the ceramic mixture layer 7 for backing material laminated in the ceramic mixture layer stacking step (step S8) for 60 minutes to 95 minutes at a temperature of 15 ° C to 30 ° C. Drying step (step S9) of drying the A demolding step (step S10) of demolding the cast stone of the semi-finished product dried in the drying step (step S9) from the mold 1; Curing step of curing by leaving the cast stone of the semi-finished product demolded in the demolding step (step S10) for 40 to 50 hours in a curing chamber maintained at a humidity of 60% to 95% and maintained at a temperature of 60 ℃ to 80 ℃ (Step S11), Polishing / Trimming / Washing process (Step S12) of washing / refining / washing the cast stone surface of the semi-finished product by washing after polishing and trimming the cast stone of the semi-finished product cured in the curing step (Step S11), A cutting step (step S13) of cutting the cast stone of the semi-finished product whose surface of the cast stone is polished, trimmed, or washed in the polishing / refining / washing step (step S12); And a coating step (step S14) of coating a waterproofing agent on the surface of the cast stone of the semi-finished product cut to a specific size in the cutting step (step S13). The cast stone for building exterior use according to claim 1, wherein the sand is a mixture of sand having a particle size of 18 to 30 mesh and sand having a particle size of 31 to 80 mesh at a volume ratio of 6: 4. Manufacturing method. delete According to claim 1, wherein the cement is a manufacturing method of the cast stone for building exterior, characterized in that using one selected from aluminum salt cement or aluminum sulfate cement. delete

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