KR102380382B1 - Swimming pool with carbon fiver panels and, construction method thereof - Google Patents

Abstract

The present invention relates to a water tank of a swimming pool using a carbon fiber panel and a construction method thereof. An objective of the present invention is to provide a water tank of a swimming pool using a carbon fiber panel and a construction method thereof, which form a carbon fiber panel layer by continuously installing a plurality of carbon fiber panels on the inner wall of a water tank of a swimming pool by a dual packing structure, form a carbon fiber tile layer by fitting and attaching a plurality of carbon fiber tiles to edge tiles and groove tiles, and improve the waterproofing and constructability for the water tank of the swimming pool by a dual waterproof layer structure of the carbon fiber panel layer and the carbon fiber tile layer. According to the present invention, a plurality of carbon fiber panels are continuously installed on the inner wall of a water tank of a swimming pool by a dual packing structure via a support body to be separated from the bottom surface and the wall surface of the water tank of the swimming pool to form a carbon fiber panel layer, and a plurality of carbon fiber tiles are fitted and attached to edge tiles and groove tiles to form a carbon fiber tile layer. The waterproofing and constructability for the water tank of the swimming pool are improved by a dual waterproof layer structure of the carbon fiber panel layer and the carbon fiber tile layer.

Description

Swimming pool using carbon fiber panels and their construction method {Swimming pool with carbon fiver panels and, construction method thereof}

The present invention relates to a swimming pool water tank using carbon fiber panels and a construction method thereof, wherein a plurality of carbon fiber panels are connected and installed by a double packing structure to form a panel layer, and carbon fiber tiles integrally attached to the panel layer It relates to a swimming pool water tank using a carbon fiber panel and its construction method, in which leakage is prevented by a waterproof layer consisting of a double structure of a panel layer and a tile layer by forming a tile layer by

In general, swimming pools are for freshwater purposes, and are used for various purposes such as swimming, water play, aqua aerobics for aerobics, and underwater walking for patient treatment.

In such a swimming pool, after the water tank is waterproofed by waterproofing using paint film (urethane, polyurea)/waterproofing using stainless/waterproofing using FRP, etc., tiles or membranes are installed as finishing materials. The most widely used water tank method is urethane waterproofing + silica sand + base plaster + tile.

However, the waterproof layer formed by the coating film (urethane, polyurea) series is filled in the swimming pool and the water pressure caused by water generating wave waves, people, water playground equipment, etc. There was a problem in that, due to this, a water leakage phenomenon occurred, and repair work for the waterproofing layer was frequently generated.

In addition, in the conventional swimming pool, the surface of the concrete structure is waterproofed and primed (ground plaster), and then pressed cement is applied to attach the tile as a finishing material to the wall or floor of the swimming pool. In the case of tile construction, not only does the tile peeling occur due to the lifting phenomenon between the waterproofing layer and the rough plastering cement, but also the vibration generated by the movement of water in the swimming pool creates a crack between the compressed cement and the tile. This peeling phenomenon has occurred. As such, when the tile is peeled off, the water quality is deteriorated due to the backside of the tile and the residue of the pressed cement, and thus there is a problem in that the maintenance cost is increased according to the improvement of the water quality.

In addition, if the tile is peeled off or leakage occurs due to this, the water in the water tank is discarded for reattachment of the tile, and various processes such as waterproofing of the swimming pool tank, priming, applying compressed cement, and attaching the tile are re-installed. Therefore, there was a problem that not only the repair cost and the required manpower increase, but also the repair work period becomes longer, making the swimming pool unusable for a long period of time.

In particular, the durability of the swimming pool tank consisting of a waterproofing film waterproofing layer (urethane waterproofing) + silica sand + plastering + tiles is only about 7 to 10 years, so there are many defects due to water leakage and tile peeling (periodic repair). The remodeling of the swimming pool has been widely carried out.

In addition, in the case of waterproofing using stainless steel/waterproofing using FRP, most of the products imported from abroad are applied, so not only the construction cost increases, but also, in the case of the stainless (S/STEEL) system, corrosion by chlorine and , leakage defects are occurring due to thermal fusion of the membrane, and in the case of FRP, environmental problems (when discarded). There were several problems that occurred.

Registered Patent Publication No. 10-2215829 (2021.02.08) Registered Patent Publication No. 10-1383218 (2014.04.02)

It is an object of the present invention to provide a swimming pool water tank using carbon fiber panels in which a plurality of carbon fiber panels are continuously installed on the inner wall of the swimming pool water tank by a double packing structure, and improved waterproofness and workability for the swimming pool water tank, and a construction method thereof .

An object of the present invention is to provide a double waterproof layer structure by a panel layer made of a plurality of carbon fiber panels and a tile layer made of a plurality of carbon fiber tiles, and a swimming pool water tank using a carbon fiber panel with improved overall waterproofness and its construction to provide a way

In the present invention, a plurality of carbon fiber panels are continuously installed on the inner wall of the swimming pool tank by a double packing structure through a support so as to be spaced apart from the wall surface and the bottom surface of the swimming pool tank to form a carbon fiber panel layer, and a plurality of carbon fiber tiles The frame tile and the concave tile are fitted and attached to form a carbon fiber tile layer, and the double waterproof layer structure of the carbon fiber panel layer and the carbon fiber tile layer improves the waterproofness and workability of the swimming pool tank.

The present invention has a double waterproof layer structure of a carbon fiber panel layer connected by a double packing structure and a carbon fiber tile layer connected by fitting and attaching a rim tile and a concave tile, so that it has excellent waterproof properties.

When the present invention is applied to a swimming pool, it is possible to reduce the weight of the building structure compared to other construction methods, and since the double waterproof layer structure is spaced apart from the wall surface and the floor surface of the water tank, the effect of reducing the defects of the waterproof layer due to building cracks there is

The present invention has an effect that the waterproof layer is made of carbon fiber panel and carbon fiber tile, so that corrosion by moisture and chlorine does not occur.

The carbon fiber panel according to the present invention has an effect that the flange fixed to the support has a step difference from the body, so that the strength and durability are improved, thereby preventing the occurrence of deformation due to water pressure.

The carbon fiber panel layer according to the present invention is made of a plurality of carbon fiber panels having a step along the circumference of the body and integrally formed with a flange, so that the water pressure transmitted to the body is distributed to the support through the flange, and thus This has the effect of increasing the overall rigidity of the swimming pool tank.

According to the present invention, a plurality of carbon fiber panels are connected by a double packing structure according to the first and second packing materials and the side carbon fiber panels, so that not only water leakage is prevented, but also the carbon fiber panels are elastically made against the water pressure in the swimming pool. It has the effect of preventing leakage while responding.

According to the present invention, the carbon fiber tile layer is formed by continuously arranging a plurality of carbon fiber tiles without gaps by fitting, close contact, and attachment of the edge tile and the concave tile, so that the strength and supporting power of the carbon fiber tile layer are only improved. Rather, the water leakage phenomenon is prevented, so that water in the water tank is prevented from penetrating in the direction of the carbon fiber panel layer through the carbon fiber tile layer.

According to the present invention, a plurality of carbon fiber tiles are connected without joint construction by fitting, close contact, and attachment between the edge tile and the concave tile. It works.

1 is an exemplary view showing a configuration according to the present invention;
2 is an exemplary view showing the construction state of the carbon fiber panel layer and the carbon fiber tile layer according to the present invention;
3 is an exemplary view showing a waterproofing layer construction process according to the present invention;
4 is an exemplary view showing a waterproof layer construction state according to the present invention;
5 is an enlarged view of part 'A' of FIG.
6 is an exemplary view showing the configuration of a carbon fiber panel according to the present invention;
7 is an exemplary view showing the configuration of a carbon fiber tile according to the present invention;

Figure 1 is an exemplary view showing the configuration according to the present invention, Figure 2 is an exemplary view showing the construction state of the carbon fiber panel layer and the carbon fiber tile layer according to the present invention, Figure 3 is a waterproof layer construction process according to the present invention 4 is an exemplary view showing the construction state of the waterproofing layer according to the present invention, FIG. 5 is an enlarged view of the 'A' part of FIG. 4, and FIG. 6 is an example showing the configuration of a carbon fiber panel according to the present invention 7 is an exemplary view showing the configuration of the carbon fiber tile according to the present invention,

In the swimming pool water tank using the carbon fiber panel according to the present invention, a plurality of carbon fiber panels are continuously installed on the inner wall of the swimming pool water tank by a double packing structure through a support so as to be spaced apart from the wall surface and the bottom surface of the swimming pool water tank. A layer is formed, and a plurality of carbon fiber tiles are fitted and attached to the edge tile and the concave tile to form a carbon fiber tile layer. and constructability is improved.

That is, the swimming pool water tank 100 according to the present invention,

A support unit 110 formed by fixing the support body 10 to the wall surface 101 and the bottom surface 102 of the swimming pool tank at regular intervals;

a carbon fiber panel layer 120 formed by having a plurality of carbon fiber panels 20 fixedly installed on the support portion so that the wall surface 101 and the bottom surface 102 of the swimming pool tank are covered;

A carbon fiber tile layer 130 formed by continuously attaching and installing a plurality of carbon fiber tiles 30 on the exposed surface of the carbon fiber panel 120 layer;

The waterproof layer 140 of the double structure comprising the carbon fiber panel layer 120 and the carbon fiber tile layer 130 is formed to be spaced apart from the wall surface 101 and the bottom surface 102 of the swimming pool tank.

The support unit 110 is for spaced apart installation of the carbon fiber panel layer 120, and a plurality of supports 10 are provided to correspond to the shape of the carbon fiber panel 20. The wall surface 101 and the bottom surface of the swimming pool tank ( 102) is fixed at regular intervals to be fixed to the carbon fiber panel (20).

For example, when the carbon fiber panel 20 is formed of a square panel, the support unit 110 may be formed in a checkerboard shape or a grid shape by a plurality of supports 10 .

At this time, the support 10 may be a square pipe or a square wood made of a material having a predetermined strength, such as aluminum, stainless steel, titanium, aluminum alloy, and corrosion treatment or corrosion resistance. Since the fixed installation of the support 10 is made by known techniques such as bolts, a detailed description thereof will be omitted.

The carbon fiber panel layer 120 is provided with a first waterproof layer function, and as shown in FIGS. 3 and 4 , a first packing material 40 installed on the support body 10 of the support part; The carbon fiber panel 20 is installed so that the flange 22 is in close contact with the first packing material 41 and is fixedly installed to the support body by the first coupler 71; a second packing material 50 installed on the flange 22 between adjacent carbon fiber panels so that the flange 22 of the carbon fiber panel is not exposed to the outside; Including,;

A plurality of carbon fiber panels 20, the first and second packing materials 40 and 50 and the side carbon fiber panel 60 are integrally connected by a double packing structure.

The first packing material 40 is installed between the carbon fiber panel 20 and the support body 10 to maintain watertightness, and a rubber packing material (rubber gasket) or a silicone packing material may be used. At this time, the width (V4) of the first packing material (40) is installed to have the same width or a wider width with respect to the width (V1) of the support body, preferably the flange of the carbon fiber panel is the first 1 is formed larger than the width (V1) of the support so as to be in close contact on the packing material (40). In addition, the first packing material 40 having self-adhesive strength may be used.

In addition, the first packing material 40 is further formed with a plurality of grooves 41 in the longitudinal direction on one surface in contact with the flange 22 of the carbon fiber panel, so that the carbon fiber panel 20 and the first packing material ( 40) Even if moisture penetrates between the grooves 41, the moisture is gradually introduced and transferred into the grooves 41, so that moisture penetration into the wall surface 101 and the bottom surface 102 of the swimming pool is prevented.

In addition, the first packing material 40 provided with the plurality of grooves 41 as described above may be made of a water-expandable resin (rubber) having a predetermined elastic force and sealing force, and is made of a water-expandable resin (rubber) as described above. When it loses, when moisture flows into the groove 41, the groove 41 expands and the inflow of moisture itself is blocked.

The carbon fiber panel 20 is a panel including carbon fiber, and as shown in FIG. 6 , a body 21 and a step along the periphery of the body 21 are provided, are integrally formed, and a plurality of fastening holes It is adapted to include a flange 22 provided with 22a.

That is, the carbon fiber panel 20 is provided with side surfaces 21a on the slopes of the body 21, and has a structure in which the flange 22 is integrally formed at the end of the side surface 21, so that the flange 22 ) is provided with a step along the circumference of the body 21 and is formed integrally.

The flange 22 is formed to have a predetermined width W22 along the end circumference of the side surface 21a of the body 21, and a plurality of fastening holes 22a for fastening with the support 10 are formed. there is.

In addition, the thickness of the carbon fiber panel (d 20), that is, the body 21 and the flange 22 is about 1.0 mm to 2.5 mm thick, preferably about 1.0 mm to 2.0 mm, more preferably about 1.0 mm to 1.5 It consists of a thin sheet type with a thickness of mm.

In addition, the step D between the body 21 and the flange 22 is such that a step does not occur between the body 21 and the side carbon fiber panel 60, that is, the second packing material 50 on the flange 22. ) and the side carbon fiber panel 60 are laminated and installed, the body 21 and the side carbon fiber panel 60 are formed to have a predetermined depth so that a step does not occur.

The carbon fiber panel 20 configured as described above is, for example, made of a plate shape having a thickness (t 20) of about 1.0 mm, and the body 21 is 500 mm × 500 mm (total width × length) or 1,000 mm × It is configured in a square shape of 1,000 mm (total width × length), and the flange 22 may be formed to have a width (W22) of about 20 mm to 40 mm along the body circumference.

In addition, when the thickness (d5) of the second packing material is 3mm and the thickness (d6) of the side carbon fiber panel is 1.5mm, the step D between the body 21 and the flange 22 is about 4.0 to 4.5 mm may be provided.

The carbon fiber panel 20 configured as described above may be formed so that the body 21 and the flange 22 are integrated while having a thin plate shape by press working. For example, the carbon fiber panel may be molded into a thin plate-like structure by compression molding and drying of a press by lamination of carbon fibers impregnated with a binder resin, and preferably, a laminate of carbon fiber grids impregnated with a resin binder. And it can be made into one panel by compression molding and drying of the press. At this time, since the binder resin uses a known resin used for press molding of the panel, a detailed description thereof will be omitted.

The second packing material 50 is installed between the flange 22 of the carbon fiber panel and the side carbon fiber panel 60, and a rubber packing material (rubber gasket) or a silicone packing material may be used. At this time, the width W5 of the second packing material 50 is preferably formed so that both ends are in contact with the side surface 21a of the body of the adjacent carbon fiber panel. In addition, the second packing material 50 having self-adhesive strength may be used.

In addition, the second packing material 50 is further formed with a plurality of grooves 51 in the longitudinal direction on one surface in contact with the flange 22 of the carbon fiber panel, so that the carbon fiber panel 20 and the second packing material ( 50), even if moisture penetrates through, it may be configured to prevent moisture from penetrating in the direction of the first packing material 40 by allowing the moisture to flow in and transfer step by step into the plurality of grooves 51 .

In addition, the second packing material 50 provided with the plurality of grooves 51 as described above may be made of a water-expandable resin (rubber) having a predetermined elasticity and sealing force. When it loses, when moisture flows into the groove 51, the groove 51 expands and the inflow of moisture itself is blocked.

The side carbon fiber panel 60 is made of the same material and thickness as the carbon fiber panel 20, and has a shape corresponding to the size of the second packing material, that is, on the side surface 21a of the body of the adjacent carbon fiber panel, the side carbon Both ends 60b of the fiber panel are formed to have a predetermined width W6 so that they are in contact with or close to each other. At this time, the width (V6) of the side carbon fiber panel (60) is preferably formed to be the same as the width (W5) of the second packing material.

In addition, a plurality of fastening holes 60a for fastening the second coupler 72 are formed in the side carbon fiber panel 60, and the fastening holes 60a are formed between adjacent carbon fiber panels. When the fiber panel is installed, the fastening hole 22a provided in the flange of the carbon fiber panel is deviated from the position, that is, the fastening hole 22a and the fastening hole 60a are displaced from each other and assembled to be installed.

The carbon fiber tile layer 130 is made of a plurality of carbon fiber tiles 30 attached to and installed on the carbon fiber panel layer 120, as shown in FIGS. 1 to 4, and the body 21 of the carbon fiber panel. And the carbon fiber tiles 30 are attached to the side carbon fiber panel 60 so as to be continuously arranged.

As shown in FIG. 7 , the carbon fiber tile 30 includes a body tile 31 and an upper step 32a on two adjacent sides of the body tile 31 and an integrally protruding edge tile 32 . ), and a concave tile 33 formed to have a lower step 33a on two adjacent sides of the body tile and into which the edge tile 32 of the adjacent carbon fiber tile is inserted and supported in contact.

That is, the carbon fiber tile 30 has an upper step 32a so that the bottom surface 31b of the body tile and the bottom surface 32b of the edge tile are integrally formed, and the edge tile 32 is the body tile. (31) is integrally formed on two adjacent sides of the body tile and has a lower step (33a) so that the upper surface (31c) of the body tile and the upper surface (33c) of the concave tile are integrally extended, and the concave tile (33) It is integrally formed on the other two sides adjacent to this body tile (31).

As such, in the carbon fiber tile 30, the edge tile 32 is formed to extend from the bottom surface 31b of the body tile, and is predetermined toward the bottom surface 31b of the body tile so that the edge tile 32 can be fitted. The concave tile 33 is formed so that a groove of

One tile floor 30b is formed by the bottom surface 31b of the body tile and the bottom surface 32b of the edge tile, and by the top surface 31c of the body tile and the top surface 33c of the concave tile One tile upper end face 30c is formed, the edge tile 32 has an upper stepped 32a to have a step with respect to the tile upper end face 30c, and the concave tile 33 is a tile floor face 30b. ) is stepped so that the lower step (33a) is provided.

At this time, the width of the border tile, that is, the upper step width W32, is the width of the concave tile, that is, the lower portion of the carbon fiber tile 30 so that a gap is not generated between the carbon fiber tile 30 and another adjacent carbon fiber tile 30 ′. The width (W33) of the step is the same as the width (W33) of the upper step, or the width (W32) of the upper step is larger than the width (W33) of the lower step. Preferably, the width (W32) of the upper step of the edge tile is the lower part of the concave tile. It is formed to be larger than the width (W33) of the step.

In addition, the carbon fiber tile 30 is formed so that the step height of the upper step 32 and the step height of the lower step 33 are the same, so that the edge tile 32 of one side of the carbon fiber tile is placed on the edge of the other carbon fiber tile. When the concave tile 33 is installed to overlap, a step is not generated in the body tile of the adjacent carbon fiber tile.

For example, in the carbon fiber tile, with respect to a body tile having a width of 100 to 150 mm and a length of 200 to 300 mm, a rim tile and a concave tile are respectively formed to have an upper/lower step width of 30 to 10 mm, and the rim tile The upper step of the tile is formed to have a step of about 1 to 2 mm with respect to the top surface of the tile, and the lower step of the concave tile is formed to have a step of about 1 to 2 mm with respect to the bottom of the tile. may be configured to be the same. That is, the carbon fiber tile may have a thin plate-like structure with a thickness (thickness from the tile top surface to the tile floor surface) of about 2 to 4 mm.

In this way, the carbon fiber tile 30 according to the present invention is provided with a border tile 32 on two adjacent sides of the body tile 31, and a concave tile 33 is provided on two other adjacent sides. 3 and 4, the edge tile 32 of one carbon fiber tile is adjacent to another carbon so that the lower step 33a' of the concave tile is in close contact with the upper step 32a of the edge tile. By being continuously installed by being inserted into the concave tile 33' of the fiber tile, one carbon fiber tile layer 130 is formed.

In addition, the carbon fiber tile 30 has rounded edges, that is, the edges of the body tile, the edge tile, and the concave tile, so that a safety accident due to a sharp edge is prevented in advance.

8 relates to a method for constructing a swimming pool water tank using a carbon fiber panel according to the present invention;

A support installation step in which the support is installed on the wall surface and the bottom surface of the swimming pool tank to form the support;

A panel installation step in which a plurality of carbon fiber panels are continuously arranged and installed to be supported by a support unit to form a carbon fiber panel layer;

A tile installation step in which a carbon fiber tile layer is formed by attaching and installing a plurality of carbon fiber tiles to be sequentially arranged on the carbon fiber panel layer;

The panel installation step is

A first packing material installation step in which the first packing material is installed on the support;

A panel fixing step in which the flanges of the adjacent carbon fiber panels are arranged so as to be in close contact with the support, and the support, the first packing material, and the flange are integrally fixed and installed by the first coupler;

A second packing material installation step in which a second packing material is installed so that the flange of the adjacent carbon fiber panel fixed to the support is wrapped;

A packing processing step in which the side carbon fiber panel is arranged so that the side carbon fiber panel is in close contact with the body of the adjacent carbon fiber panel so that the second packing material is wrapped, and the flange is fixedly installed to the side carbon fiber panel and the second packing material by the second coupling hole; including,

Carbon fiber panels are installed on the wall and bottom surfaces of the swimming pool tank, and a plurality of carbon fiber panels are integrally connected and installed by a double packing structure by first and second packing materials and side carbon fiber panels to prevent leakage. it is not meant to be.

In the support installation step, with respect to the wall surface and the bottom surface of the swimming pool tank, a plurality of supports are provided so that the carbon fiber panel layers are arranged spaced apart from each other by a predetermined interval, and the carbon fiber panel layers are supported. fixed at regular intervals.

The panel installation step is a step in which the carbon fiber panel layer is formed through the support part, and a plurality of carbon fiber panels are arranged on the support part at regular intervals and have a double packing structure by the first and second packing materials and the side carbon fiber panel. are sequentially arranged by

In the first packing material installation step, as shown in FIGS. 3 and 4 , the first packing material is installed on the upper surface of the support. In this case, the first packing material may be disposed to be seated on the upper surface of the support, attached by self-adhesive force, or partially adhered to the upper surface of the support by a separate adhesive.

In the panel fixing step, a plurality of carbon fiber panels are arranged on the support part so that the flange of the carbon fiber panel is seated on the first packing material, and then fixed and installed by the first coupler. At this time, as shown in FIG. 3 , the flanges of the adjacent carbon fiber panels are spaced apart from each other by a predetermined distance on the first packing material so that the interval G is maintained. For example, the adjacent carbon fiber panels are spaced apart by a predetermined distance so that the flanges seated on the first packing material are spaced apart from each other by a distance (G) of about 1 to 5 mm, preferably about 2 to 3 mm.

Such spaced arrangement of the carbon fiber panel not only facilitates the arrangement of the carbon fiber panel and the installation of the second packing material and the side carbon fiber panel, but also when an excessive load is generated on the carbon fiber panel, the carbon fiber Water leakage is prevented without lifting the panel layer, and when the carbon fiber panel expands and contracts according to the water temperature, damage to the carbon fiber panel layer is prevented.

In addition, the carbon fiber panel arranged as described above is fixedly installed on the support body by the first coupling hole inserted and coupled into the fastening hole provided in the flange. The first coupler may be formed of a known bolt such as a piece bolt, a screw bolt, or the like.

That is, in the panel fixing step, after the flanges of the carbon fiber panels adjacent to the first packing material disposed on the support are spaced apart by a predetermined distance, the flange and the first packing material are fixed to the support by the first coupler. has been

In this way, when a plurality of carbon fiber panels are sequentially spaced apart/fixed, the second packing material and the side are between the carbon fiber panel on one side and another carbon fiber panel adjacent thereto due to the step difference between the body and the flange of the carbon fiber panel. A packing groove 80 in which the carbon fiber panel is installed is formed. That is, the packing groove 80 includes a gap G, and means a space between the side surface of one carbon fiber panel and the side surface of another carbon fiber panel adjacent thereto.

The second packing material installation step is, as shown in FIGS. 3 and 4, on the flange of the neighboring carbon fiber panel, that is, into the packing groove so that the flange of the carbon fiber panel fixedly installed by the first coupler is wrapped around it. 2The packing material is inserted and installed. In this case, the second packing material may be disposed (or installed) so that it is inserted into the packing groove and seated on the flange upper surface, attached by self-adhesive force, or partially adhered to the flange upper surface by a separate adhesive.

In addition, the second packing material is installed so that both ends are in close contact with or close to the side surface of the adjacent carbon fiber panel, preferably is installed so as to be in close contact with the side surface of the carbon fiber panel.

In the packing processing step, as shown in FIGS. 3 and 4, the side carbon fiber panel is inserted into the packing groove in which the second packing material is installed, and the second packing material and the side carbon fiber panel are carbon fiber by the second coupling hole. It is fixedly installed to the flange of the panel or the flange of the carbon fiber panel and the first packing material.

At this time, the side carbon fiber panel is inserted and installed into the packing groove, and not only has a function of flattening the surface of the carbon fiber panel layer without a step, but also has a second packing material and a flange of the carbon fiber panel by a second coupling hole. It has a function of adhering so that the watertightness is maintained. That is, the side carbon fiber panel is installed by pressing the second packing material so as not to generate a step difference with the body of the carbon fiber panel by the second coupling hole.

In addition, the side carbon fiber panel and the carbon fiber panel are made of the same material and thickness, and the side carbon fiber panel has the same width as the second packing material and is formed to correspond to the shape and length of the packing groove.

In the carbon fiber panel layer 120 installed by the configuration as described above, the flange 22 and the first packing material 40 of the carbon fiber panel are formed while the interval G is maintained between the adjacent carbon fiber panels. It is fixed to the support body 30 by the first coupler 71, and the side carbon fiber panel 60 and the second packing material 50 are connected to the flange 22 of the carbon fiber panel by the second coupler 72 or Since it is bound to the flange 22 and the first packing material 40, even if an expansion and contraction action occurs in the carbon fiber panel, damage such as lifting does not occur to the carbon fiber panel layer, as well as the first and second coupling holes The flange and the first packing, the side carbon fiber panel and the second packing have an independent watertight structure while having a double packing structure, thereby preventing water leakage.

The tile installation step is a step in which a plurality of carbon fiber tiles are attached to and installed on the carbon fiber panel layer to form a carbon fiber tile layer, and any carbon fiber tiles are attached and installed on the carbon fiber panel layer by an adhesive such as epoxy. , After the adhesive such as epoxy is applied to the tile floor of another carbon fiber tile or the tile floor and the lower step of the concave tile, the lower step is optional on the tile floor of the carbon fiber tile. It is attached and installed so as to be in close contact with the upper step provided on the edge tile of the tile.

That is, as shown in FIGS. 3 to 5 , the edge tile 32 of one carbon fiber tile and the body tile 31 ′ of another carbon fiber tile adjacent thereto have a gap G1, and one side Carbon fiber tiles 30 and 30' are installed so that the body tile 31 of the carbon fiber tile and the concave tile 33 ′ of another carbon fiber tile adjacent thereto have a gap G2 between them, one side carbon fiber The upper step (32a) provided on the edge tile of the tile and the lower step (33a′) provided on the concave tile of another carbon fiber tile adjacent thereto overlap and are continuously installed while in close contact.

At this time, the spacing G1 is set to be smaller than or equal to the spacing G2, and preferably, the spacing G1 between the adjacent carbon fiber tiles 30 and 30' so that the contact area of the needles is uniform. and carbon fiber tiles are continuously installed while maintaining the interval (G2) between them.

The gap G1 and the gap G2 have a function of preventing deformation in the carbon fiber tile layer in response to the expansion and contraction action of the carbon fiber tile by water temperature and water pressure.

According to the present invention, a carbon fiber tile layer is formed on the carbon fiber panel layer without a separate joint construction by overlapping, fitting, and attaching a plurality of carbon fiber tiles to the edge tiles and the concave tile.

In addition, in the present invention, the carbon fiber tile layer can be formed without joint construction by overlapping the edge tile and the concave type, but the joint construction operation using the gap G2 may be further performed.

The present invention made as described above can be applied not only to a swimming pool tank, but also to a structure having a purpose of desalination, such as a large storage tank in which living water is stored, a bathroom, a large pipeline, and the like.

The present invention is not limited to the specific preferred embodiments described above, and various modifications can be made by anyone with ordinary skill in the art to which the invention pertains without departing from the gist of the invention as claimed in the claims. Of course, such modifications are intended to be within the scope of the claims.

In addition, since the terms described in the present invention are for distinguishing one component from other components and helping the understanding of the present invention, the components of the present invention are not limited by the described terms.

(10): support (20): carbon fiber panel
(21): body (21a): side
(22): flange (22a): fastener
(30): carbon fiber tile (30b): tile floor
(30c): tile top surface (31): body tile
(31b): bottom surface (31c): top surface
(32): border tile (32a): upper step
(32b): floor (33): concave tile
(33a): lower step (33c): upper surface
(40): first packing material (50): second packing material
(60): side carbon fiber panel (60a): fastening hole
(60b): both ends (71): first coupler
(72): second coupling hole (80): packing groove
(100): swimming pool tank (101): wall surface
(102): bottom

Claims (15)

A support unit 110 formed by fixing the support body 10 to the wall surface 101 and the bottom surface 102 of the swimming pool tank at regular intervals; a carbon fiber panel layer 120 formed by having a plurality of carbon fiber panels 20 fixedly installed on the support portion so that the wall surface 101 and the bottom surface 102 of the swimming pool tank are covered; A carbon fiber tile layer 130 formed by continuously attaching and installing a plurality of carbon fiber tiles 30 on the exposed surface of the carbon fiber panel 120 layer; including,
The carbon fiber panel layer 120 includes a first packing material 40 installed on the support 10 of the support; The carbon fiber panel 20 is installed so that the flange 22 is in close contact with the first packing material 41 and is fixed to the support body by the first coupler 71; a second packing material 50 installed on the flange 22 between adjacent carbon fiber panels so that the flange 22 of the carbon fiber panel is not exposed to the outside; The side carbon fiber panel 60 is fixed to the flange 22 by the second coupler 72 so as to be in close contact with the second packing material 50;
The carbon fiber tile 30 includes a body tile 31, an upper step 32a on two adjacent sides of the body tile 31, and an integrally protruding edge tile 32, and a body tile (31). A body tile 31 and The edges of the border tile 32 and the concave tile 33 are all configured to be rounded,
A plurality of carbon fiber panels 20 are spaced apart while maintaining an interval G, and are integrally connected and installed in a double packing structure by the first and second packing materials 40 and 50 and the side carbon fiber panels 60 fiber panel layer 120; The edge tile 32 of one carbon fiber tile and the body tile 31 ′ of another carbon fiber tile adjacent thereto have a gap G1 between them, and the body tile 31 of one carbon fiber tile and the adjacent body tile 31 . Another carbon fiber tile concave tile 33 ′ is provided with carbon fiber tiles 30 and 30 ′ to have a gap G2 between them, and the upper step 32a provided on the edge tile of one carbon fiber tile and The carbon fiber tile layer 130 continuously installed while overlapping and in close contact with the lower step (33a`) provided on the concave tile of another carbon fiber tile adjacent to this; A swimming pool tank using a carbon fiber panel, characterized in that it is formed to be spaced apart from the wall surface 101 and the bottom surface 102.
delete The method of claim 1 ;
The first packing material 40 and the support body have the same width, or the width W4 of the first packing material is formed to be wider than the width V1 of the support body, so that the flange of the carbon fiber panel is the first packing material 40 ) is configured to be in close contact with the
The second packing material (50) is a swimming pool using a carbon fiber panel, characterized in that it is formed to have a predetermined width (V5) so that both ends are in contact with the side surface (21a) of the body of the adjacent carbon fiber panel.
The method of claim 1 ;
The first packing material 40 is further formed with a plurality of grooves 41 in the longitudinal direction on one surface in contact with the flange 22 of the carbon fiber panel,
The second packing material (50) is a swimming pool using a carbon fiber panel, characterized in that a plurality of grooves (51) are further formed in the longitudinal direction on one surface in contact with the flange (22) of the carbon fiber panel.
The method of claim 1 ;
The carbon fiber panel 20 has a body 21 and a step along the circumference of the body 21 and is integrally formed and includes a plurality of fastening holes 22a for fastening the first coupler 71 . including a flange (22)
The side carbon fiber panel 60 is formed with a plurality of fastening holes 60a for fastening the second coupler 72,
A swimming pool using a carbon fiber panel, characterized in that the fastening hole (60a) of the side carbon fiber panel and the fastening hole (22a) provided in the flange of the carbon fiber panel are formed to be shifted from each other.
6. The method of claim 5;
The step between the body 21 and the flange 22 is, when the second packing material 50 and the side carbon fiber panel 60 are laminated on the flange 22, the body 21 and the side carbon fiber panel 60 ) A swimming pool tank using carbon fiber panels, characterized in that it is formed with a predetermined depth so as not to cause a step difference between them.
delete The method of claim 1 ;
In the carbon fiber tile 30, the edge tile 32 is formed to extend from the bottom surface 31b of the body tile, and a predetermined groove is formed toward the bottom surface 31b of the body tile so that the edge tile 32 can be fitted. The concave tile 33 is formed so as to be formed,
One tile floor 30b is formed by the bottom surface 31b of the body tile and the bottom surface 32b of the edge tile, and by the top surface 31c of the body tile and the top surface 33c of the concave tile One tile top surface 30c is formed,
The edge tile 32 has an upper step 32a formed to have a step with respect to the tile upper end surface 30c, and the concave tile 33 has a lower step 33a with respect to the tile floor surface 30b. Swimming pool tank using carbon fiber panel, characterized in that the step is formed.
9. The method of claim 1 or 8;
In the carbon fiber tile 30, the width of the upper step (V32) of the edge tile and the width (V33) of the lower step of the concave tile are the same, or the upper step width (V32) of the edge tile is the width of the lower step of the concave tile (V33) ) A swimming pool tank using carbon fiber panels, characterized in that it is formed to be larger than that.
The method of claim 1 ;
The carbon fiber panel 20 and the carbon fiber tile 30 are formed into a thin plate-like structure by compression molding of a press.
delete A support installation step in which the support is installed on the wall surface and the bottom surface of the swimming pool tank to form the support; A panel installation step in which a plurality of carbon fiber panels are continuously arranged and installed to be supported by a support unit to form a carbon fiber panel layer; A tile installation step in which a carbon fiber tile layer is formed by attaching and installing a plurality of carbon fiber tiles to be sequentially arranged on the carbon fiber panel layer;
The panel installation step may include: a first packing material installation step in which a first packing material is installed on a support; A panel fixing step in which the flanges of the adjacent carbon fiber panels are arranged so as to be in close contact with the support, and the support, the first packing material, and the flange are integrally fixed and installed by the first coupler; A second packing material installation step in which a second packing material is installed so that the flange of the adjacent carbon fiber panel fixed to the support is wrapped; A packing processing step in which the side carbon fiber panel is arranged so that the side carbon fiber panel is in close contact between the bodies of the adjacent carbon fiber panels so that the second packing material is wrapped, and the flange is fixedly installed to the side carbon fiber panel and the second packing material by a second coupling hole; Including, a plurality of carbon fiber panels on the wall surface and the bottom surface of the swimming pool tank are spaced apart while maintaining a gap (G), and are integrally connected and installed by the double packing structure by the first and second packing materials and the side carbon fiber panels. A carbon fiber panel layer is formed,
The carbon fiber tile 30 includes a body tile 31, an upper step 32a on two adjacent sides of the body tile 31, and an integrally protruding edge tile 32, and a body tile 31. It is formed to have a lower step (33a) on the other two adjacent sides of the tile and includes a concave tile (33) into which the edge tile (32) of the adjacent carbon fiber tile is inserted and supported in contact with the body tile (31) and The edges of the border tile 32 and the concave tile 33 are all rounded,
A concave tile 33 of another carbon fiber tile is superimposed on the edge tile 32 of one carbon fiber tile, and the edge tile 32 of one carbon fiber tile and the body tile 31 of another carbon fiber tile adjacent thereto ) is provided with a spacing G1, and the body tile 31 of one carbon fiber tile and the concave tile 33' of another carbon fiber tile adjacent thereto have a spacing G2, and the adjacent carbon A method of constructing a swimming pool water tank using a carbon fiber panel, characterized in that the carbon fiber tile layer is formed so as not to cause a step difference in the body tile of the fiber tile to prevent leakage.
delete 13. The method of claim 12;
The carbon fiber panel 20 has a body 21 and a step along the circumference of the body 21 and is integrally formed and includes a plurality of fastening holes 22a for fastening the first coupler 71 . A swimming pool water tank construction method using a carbon fiber panel, characterized in that it includes a flange (22).
13. The method of claim 12;
Carbon fiber tile, after an arbitrary carbon fiber tile is attached to the carbon fiber panel layer by an adhesive, and the adhesive is applied to the tile floor of another carbon fiber tile or the tile floor and the lower step of the concave tile, The tile bottom surface of the carbon fiber tile coated with adhesive is closely attached to the carbon fiber panel layer, and the lower step of the carbon fiber tile coated with adhesive is attached to the upper step of the carbon fiber tile attached to the carbon fiber panel layer. Became,
A swimming pool water tank construction method using a carbon fiber panel, characterized in that the carbon fiber tile layer is integrally formed on the carbon fiber panel layer without a separate joint construction by overlapping the edge tile and the concave tile.

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