KR102493103B1 - Tile construction to prevent cracks in civil engineering and building structures - Google Patents

Abstract

The present invention relates to a tile installation technique for preventing cracks caused by uneven subsidence and temperature variations in water treatment facility structures. If tiles installed on the floor or walls of water treatment facilities such as sewage treatment plants, water purification plants, drainage ponds, swimming pools, and the like are damaged or cracked due to uneven subsidence, shaking of the structure, or damage to the structures, the damage or cracks tend to propagate throughout the structures. To prevent this, expansion joint lines are created and installed at regular intervals in spaces where tiles are installed so that even when a crack occurs in any area, the crack is blocked in an expansion hole, allowing repairs to be performed only on a portion of the damaged section of the corresponding line. Therefore, the tile installation for preventing cracks in water treatment facility structures may minimize maintenance costs.

Description

Tile construction to prevent cracks in civil engineering and building structures}

The present invention relates to tile construction for preventing cracks due to water temperature change and antifreeze settlement of civil and architectural structures and water treatment facility structures, and more particularly, to civil and architectural structures and water treatment facilities such as sewage treatment plants, water purification plants, reservoirs, and swimming pools. If the tiles or bricks installed on the floor or wall of the back are damaged or cracked due to the floating settlement of the structure, shaking or damage of the structure, etc., cracks occur throughout the structure. Even if a crack occurs in one part by manufacturing and constructing it, it is possible to minimize maintenance costs by blocking the crack in the expansion hole so that only a part of the damaged part line can be repaired, and the wall or floor of the structure and water treatment facility, It relates to tile construction for preventing cracks in civil engineering and architectural structures that enhance designs by forming various letters, pictures, marks, figures, etc. on ceilings.

In general, a water treatment facility is a process of treating water cleanly, and consists of a series of processes including water intake, chemical treatment, coagulation, precipitation, filtration, disinfection, and storage.

In the concrete water tank, which is one of the above water treatment facilities, concrete is injected into formwork tiles forming the water tank on the enclosure and cured. After the concrete is cured, tile or epoxy paint is applied or stainless steel lining is applied.

However, the concrete structure as described above is maintained by the delamination phenomenon in which tiles or synthetic resin sheets are separated from the inner wall surface of the concrete tank due to dew condensation caused by water penetration into the concrete, cracks in the structure, or water temperature difference in winter. There was a difficult problem, and there is a sanitary problem due to the inherent risk of microbial growth and detection of endocrine disruptors due to the nature of resins, which are synthetic resin sheets. The process of frequently repairing the surface was complicated, resulting in excessive maintenance costs and difficulties in construction.

As for the conventional prior art related to tile construction as described above, Korean Patent Registration No. 10-0955346 stainless steel tile and its construction method are a stainless plate material that is compressed with a press to form a flange on the four sides and a constant on the flange of the stainless plate material. A joint member mounted so that the protrusion inside the bar protrudes more than the flange of the stainless plate and the coupling hole and the wedge inlet hole passing through at a distance and the coupling hole facing the stainless plate and the stainless plate applied to the inside of the stainless plate to fix the joint It is a technology characterized in that it comprises an adhesive and a bonding inducing member applied to the surface of the adhesive to increase the adhesive force with the inner wall surface of the concrete structure, and domestic patent registration number 10-1607680 manufactures porcelain tiles for water treatment and A concrete structure waterproof method construction method using this has been proposed, but the method for manufacturing a porcelain tile for water treatment includes a rectangular porcelain tile having a predetermined width and thickness as a whole and an inclined surface formed to have a certain gradient downward at the edge of the rectangular porcelain tile and the above It consists of protrusions formed to have a constant thickness vertically and horizontally on the back side of the square porcelain tile and pockets formed to have a certain shape inward at the end of the square porcelain tile, and the porcelain tile contains 30.18% by weight of kaolin, 32.25% by weight of clay, and 8.85% by weight of silica stone. A method of manufacturing a porcelain tile for water treatment comprising 28.72% by weight and 28.72% by weight of feldspar, comprising: pulverizing raw materials of kaolin, clay, silica, and feldspar constituting the porcelain tile for water treatment; Blending the pulverized raw material with fine raw materials and coarse raw materials at a constant ratio, but the particle size adjustment mixing ratio is 39% by weight of the fine raw material, 10% by weight of the intermediate raw material, and 51% by weight of the coarse raw material; A wet molding blending step of preparing a porcelain tile raw material filling for filling a refractory mold by adding 16 to 20% by weight of water to the pulverized porcelain tile raw material mixed with the particle size adjustment; Preparing a porcelain tile raw material filling by wet molding and mixing the porcelain tile raw material filling and then dehydrating the porcelain tile raw material mixture to a moisture content of 10% by weight; Preparing a refractory mold for forming a porcelain tile; preparing a porcelain tile molding by filling the refractory mold with a porcelain raw material filler and press-forming at a constant pressure; Placing the manufactured porcelain tile molding on a bogie and passing through a tunnel-type kiln with a kiln fire temperature of 1,300 to 1,450° C. to bisque-roast the porcelain tile; a temperature lowering step of lowering the unglazed porcelain tile to a predetermined temperature; applying a glaze to the surface of the lowered unglazed porcelain tile; Placing the unglazed porcelain tile coated with the glaze on a bogie, and passing the unglazed porcelain tile through a tunnel-type kiln with a kiln fire temperature of 1,300 to 1,450° C. to ash-fire the porcelain tile; a temperature lowering step of lowering the baked porcelain tile to a predetermined temperature; Separating the baked porcelain tile from the refractory mold; Disclosed is a technology characterized in that it consists of cutting the edge of the separated porcelain tile in a U shape.

However, since environmental pollution is more and more serious from the past to the present, it is easy to maintain and manage the floors and walls of sewage treatment plants, water purification plants, reservoirs, swimming pools, etc. The present invention was completed by forming a tile construction that enhances the design by forming a.

The present invention was invented to solve and supplement the problems of the prior art, and the present invention provides a tile construction space constructed on the floor or wall of civil engineering and building structures and water treatment facilities, such as sewage treatment plants, water purification plants, reservoirs and swimming pools, at regular intervals. It is possible to minimize maintenance, repair, and management costs of water treatment facilities by constructing and constructing a new planning line for each part so that when a crack occurs in one part, it is configured to repair only the cracked section instead of repairing the whole as before. The purpose is to provide tile construction to prevent cracks in civil engineering and architectural structures that enhance the design by forming bells, pictures, marks, figures, etc.

As a solution to tile construction for preventing cracks in civil engineering and building structures according to the present invention, the expansion planning line part 200 is installed on the outer surface of the concrete structure 300 using the set anchor bolt 400 and the welding joint 450. After bonding and fixing, the tile joint mortar part 500 is formed on the outer surface of the concrete structure 300 at half the height of the expansion plan line part 200 using tile joint mortar, and the tile joint mortar part 500 ), and a tile joint 150 is formed in the space between the tile 100 and another tile 100.

The expansion and contraction line portion 200 convex the central portion of the plate material to form an expansion and contraction convex 210, and vertically form both side surfaces of the expansion and contraction convex and convex 210 to form an inner side opposite to the expansion and contraction convex and convex 210 An extension hole 220 is formed, and the structure joint surface 230 is formed by forming the outer surface so as to be perpendicular to the vertically formed surface, and the tile joint 150 is formed between the tile 100 and another tile 100. ), joint cement 550 is used, and silicon 170 is used between the tile 100 and the expansion plan line portion 200.

The width of the tile joint 150 is in the range of 2 to 5 mm in length, the material of the expansion and contraction planning line part 200 is selected from stainless steel or aluminum, and the short length is in the range of 3 to 50 mm in length. , the long length vertical ranges from 50 to 5,000 mm in length.

Civil and architectural structures and water treatment facility structures, such as sewage treatment plants, water purification plants, reservoirs, swimming pools, etc., have their walls and bottom surfaces evenly trimmed with a grinder, etc. After marking with ink lines, etc., prior to installing the expansion planning line part 200, use a set anchor bolt 400 to firmly fix the area marked with laser horizontal, vertical or ink lines, etc., and expand expansion planning line It is fixed by welding to both sides of the bottom of the part 200 and the set anchor bolt 400, and the protruding set anchor bolt 400 is cut with a grinder, etc. to form a welded joint 450, cleaned with air, etc., and then tiled. In order to form the bonding mortar part 500, the tile bonding mortar is diluted and the tile 100 is bonded to the concrete structure 300 to which the tile 100 is to be attached by pressing and gluing, and the expansion planning line part 200 ) and the size of the tile 100 do not match, the space between the tile 100 and another tile 100 and between the tile 100 and the expansion and contraction line part 200 is formed by cutting with a cutter, etc. 170) or after forming the tile joint 150 by securing a space in the range of 2 to 5 mm in length so that the joint cement 550 can be inserted, the tile 100 is bonded.

The production of the expansion planning line part 200 and the corner-shaped expansion planning line part 250 is made of a plate material of rust-free material such as stainless steel or aluminum and has a thickness of about 0.5 ~ 5 mm in the length range of a certain standard horizontal length of 3 ~ 50 mm. It is cut to a standard of 50 mm and a vertical length of 50 to 5000 mm, and after forming the expansion and contraction irregularities 210 in a bending machine, after flipping it in the opposite direction, an expansion and contraction hole 220 is formed, and the concrete structure 300 shown in FIG. In order to bond with the set anchor bolt 400, the structure joint surface 230 is formed, and since the material is thin, safety accidents may occur during work, so the finish is neatly performed so that safe construction can proceed at the site.

In addition, various letters, pictures, marks, figures, etc. are formed on walls, floors, ceilings, etc. of structures and water treatment facilities to enhance the design.

That is, one or more of letters, pictures, figures, or marks may be selected and formed on the outer surface of the tile 100 .

The tile construction method for preventing cracks in civil engineering and building structures of the present invention is a water treatment facility such as a sewage treatment plant, a water purification plant, a reservoir, a swimming pool, etc. If damage or cracks occur throughout the structure, in order to prevent this, an expansion planning line is manufactured and installed at regular intervals in the tile construction space. It has the effect of minimizing maintenance cost by allowing only part of the repair, and it has the effect of enhancing the design by forming various letters, pictures, marks, figures, etc. on the walls, floors, ceilings, etc. of structures and water treatment facilities. .

1 is a block diagram of tile construction for crack prevention of civil engineering and building structures according to the present invention.
2 is a cross-sectional view of tile construction for preventing cracks in civil engineering and building structures according to the present invention.
3 is a configuration diagram showing a cross-section of tile construction for crack prevention of civil engineering and building structures according to the present invention.
Figure 4 is a perspective view of the expansion planning line of tile construction for crack prevention of civil engineering and building structures of the present invention.
5 is a view showing an embodiment of tile construction for preventing cracks in civil engineering and building structures according to the present invention.
6 is a view showing another embodiment of tile construction for preventing cracks in civil engineering and building structures according to the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings, and in the following description of the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the gist of the present invention. , the detailed description is omitted.

In addition, terms to be described later are terms defined in consideration of functions in the present invention, which may vary according to the intention or custom of a user or operator. Therefore, the definition should be made based on the contents throughout this specification.

Figure 1 is a configuration diagram of the present invention, Figure 2 is a cross-sectional view of the present invention, Figure 3 is a configuration diagram showing a cross-section of the present invention, Figure 4 is a perspective view of the expansion plan line of the present invention, Figure 5 is the present invention It is a diagram showing an embodiment of, and FIG. 6 is a diagram showing another embodiment of the present invention,

In detail with reference to Figure 1,

In order to minimize the maintenance cost of civil engineering and building structures and water treatment facility structures, the tiles 100 are partially configured in the form of 3 x 3, and the nine tiles 100 are grouped into another bundle of tiles 100 An expansion and contraction line part 200 is formed between another set of tiles 100 to be divided.

That is, a tile joint 150 is formed between one tile 100 and another adjacent tile 100, and the 9 tiles 100 are formed into 3 horizontally and 3 vertically.

A set of nine tiles 100 is formed, and an expansion and contraction line portion 200 is formed between one set of tiles 100 and another set.

As described above, when the expansion and contraction line part 200 is formed to distinguish one set of tiles 100 from another set, even if a part of the tile 100 is damaged or damaged, the entire tile 100 is not repaired, but the corresponding tile Maintenance, repair, and management are easy if the expansion and contraction line part 200 of the part where 100 is located is repaired.

In detail with reference to Figure 2,

Looking at the configuration of the tile 100, the expansion and contraction line part 200, the tile joint mortar part 500, and the concrete structure 300, the concrete structure 300, which is a structure of a water treatment facility, is formed.

The expansion plan line part 200 is firmly bonded and fixed to a part of the concrete structure 300 using a set anchor bolt 400 and a welding joint 450.

After that, in order to join the tiles 100, the tile joint mortar portion 500 is stacked on the upper surface of the concrete structure 300, and the tile 100 is firmly bonded to the upper surface of the tile joint mortar portion 500.

A tile joint 150 is formed in the space between the tiles 100 bonded to the upper surface of the tile joint mortar 500, and silicon 170 and joint cement 550 are applied to the upper layer of the tile joint 150. Form and finish

More specifically, after evenly trimming the walls and bottom surfaces of concrete structures 300 such as civil and architectural structures and water treatment facilities such as sewage treatment plants, water purification plants, reservoirs, and swimming pools with a grinder, certain standards are set and partitioned, and wall and After marking the bottom surface with an ink line, etc., prior to installing the expansion planning line part 200, use a set anchor bolt 400 to firmly fix the marked part with a laser level, vertical system or ink line, etc. It is welded and fixed to both sides of the lower end of the expansion planning line part 200 and the set anchor bolt 400, and the protruding set anchor bolt 400 is cut with a grinder, etc. to form a welded joint 450, and cleans with air, etc. After that, to form the tile joint mortar part 500, the tile joint mortar is diluted and the tile 100 is bonded to the concrete structure 300 to which the tile 100 is to be attached by pressing and attaching, and the expansion planning line If the specifications of the part 200 and the tile 100 do not match, the space between the tile 100 and another tile 100 and between the tile 100 and the expansion and contraction line part 200 is cut with a cutter or the like. After forming the tile joint 150 by securing a space in the range of 2 to 5 mm in length so that the silicon 170 or joint cement 550 can be inserted, the tile 100 is bonded.

After a certain period of time has elapsed, before the joint cement 550 is applied, the tile joint mortar portion 500 is dug out with an awl, etc., and then cleaned with air, etc., and then the joint cement 550 is applied to the tile 100 and another tile. It is inserted between the tiles 100 and stretchable silicone 170 is inserted into the space between the tile 100 and the expansion plan line part 200 to secure elasticity so that when damage or cracking of the tile 100 occurs, it expands and contracts. The construction of the tile 100 is completed when the construction is performed to block the progression of the damaged portion by the expansion and contraction of the division line portion 200 and the expansion and contraction of the silicone 170 and then is finished.

The extension planning line part 200 can be constructed by driving the set anchor bolt 400 into the surface of the concrete structure 300, but concrete nails, knife blocks, or screws can be used.

In addition, a material such as rubber may be used instead of silicon, which is the material of the silicon 170 formed in the space between the expansion and contraction line portion 200 and the tile 100.

In detail with reference to Figure 3,

Civil and architectural structures and water treatment facilities, such as sewage treatment plants, water purification plants, reservoirs, and swimming pools, are evenly trimmed with a grinder, etc., and then partitioned by setting a certain standard, and then applied to the wall or floor. In order to mark with an ink line, etc. and install the corner-shaped stretch plan line part 250 at the corner, set anchor bolts 400 are firmly fixed by driving the marked part with ink line, etc., and then the corner-shaped stretch plan line part 250 After welding and fixing to the set anchor bolt 400, the protruding set anchor bolt 400 is cut with a grinder, etc., cleaned with air, and then the tile joint mortar is diluted to form the tile joint mortar portion 500 After applying the tile 100 evenly and sufficiently to the concrete structure 300 to be attached, the tile 100 is joined, and if the specifications of the corner-shaped expansion planning line part 250 and the tile 100 do not match, they are cut with a cutter or the like. By doing so, the space between the tile 100 and the corner-shaped expansion planning line part 250 is secured in the range of 2 to 5 mm in length, and the tile 100 is bonded and constructed.

In addition, after a certain period of time has elapsed, before the joint cement 550 is applied, the tile joint mortar portion 500 is dug out with an awl, etc., cleaned with air, etc., and then the joint cement 550 is applied to the tile 100 and corner type expansion and contraction. If the tile 100 is damaged or cracked by inserting it between the partitioning line parts 250 or by inserting the elastic silicone 170 to secure elasticity, the corner-shaped expansion and contraction line parts 250 will not stretch and contract. The construction of the tile 100 is completed when the construction is performed to block the progression of the damaged portion due to the expansion and contraction action of the silicon 170 and then finished.

In detail with reference to Figure 4,

The manufacturing of the expansion planning line part 200 and the corner-shaped expansion planning line part 250 uses a plate material of rust-free material such as stainless steel or aluminum with a thickness of about 0.5 ~ 5 mm in the length range of a certain standard horizontal length of 3 ~ After cutting to a standard of 50 mm and a vertical length of 50 to 5000 mm, forming the expansion and contraction convex 210 in a bending machine, flipping it in the opposite direction, and concave the expansion hole 220 on the inner side of the opposite side of the expansion and contraction convexity 210. In order to form and join the set anchor bolt 400 to the concrete structure 300 shown in FIG. 2, a structure joint surface 230 is formed, and safety accidents may occur during work due to the thin material, so safe construction can proceed at the site Make sure the finish is neat.

The materials used for the tile 100, the tile joint mortar part 500, the joint cement 550, and the silicon 170 have generally been developed on the market, so that various products can be used according to the field conditions.

If described in detail with reference to Figure 5,

It is a brick and tile construction method that allows the design of a structure to stand out by configuring and forming various letters, pictures, or mark shapes and figures that are designs (201) on the walls of civil engineering or building structures and water treatment facilities.

In detail with reference to Figure 6,

Designs (201) on the walls of civil engineering or building structures and water treatment facilities are composed and formed of various letters, pictures or mark shapes and figures to make the design of the structure stand out on general plastering or epoxy painted walls or floors or ceilings (800). It is a design construction method that is formed so that

The above embodiment in the present invention is an example, and the present invention is not limited thereto. Anything that has substantially the same configuration as the technical concept described in the claims of the present invention and achieves the same effect is included in the technical scope of the present invention.

100. Tiles
150. Tile joints
170. Silicon
200. New Construction Planning Line Department
201. Design
210. Stretching irregularities
220. New Hall
230. Joint
250. Corner type expansion plan line part
300. Concrete structures
400. Set Anchor Bolts
450. Weld joints
500. Tile joint mortar part
550. Joint cement
800. Ceiling

Claims (6)

In the construction of tiles constructed in civil and architectural structures and water treatment facilities,
The expansion planning line part 200 is joined and fixed to the outer surface of the concrete structure 300 using the set anchor bolt 400 and the welding joint 450, and the expansion planning line part 200 is attached to the outer surface of the concrete structure 300. The tile joint mortar portion 500 is formed using tile joint mortar at half the height of the portion 200, the tile 100 is bonded to the upper surface of the tile joint mortar portion 500, and the tile 100 and A tile joint 150 is formed in the space between another tile 100,
The expansion and contraction planning line part 200 convex the central part of the plate material to form an expansion and contraction convex 210, and forms both side surfaces of the expansion and contraction convex and convex 210 vertically to form an inner side opposite to the expansion and contraction convex and convex 210 An expansion hole 220 is formed, and a structure bonding surface 230 is formed by forming an outer surface so as to be perpendicular to the vertically formed surface,
The material of the expansion and contraction line part 200 is selected from stainless steel or aluminum, and the short length is in the range of 3 to 50 mm, and the long length is in the range of 50 to 5,000 mm. Tiles for preventing cracks in civil engineering and construction structures. delete The method of claim 1,
For the tile joint 150, joint cement 550 is used between the tile 100 and another tile 100, and silicon 170 is used between the tile 100 and the expansion planning line part 200. Tile for preventing cracks in civil and architectural structures, characterized in that for use. The method of claim 3,
Tile for preventing cracks in civil engineering and building structures, characterized in that the width of the tile joint 150 is in the range of 2 to 5 mm in length. delete The method of claim 1,
A tile for preventing cracks in civil engineering and building structures, characterized in that formed by selecting one or more of letters, pictures, figures, or marks on the outer surface of the tile (100).

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