KR20240059424A - A reinforcement method for concrete surface using tube sheet rolls - Google Patents

Abstract

The present invention relates to a method of reinforcing a concrete floor surface to prevent defects in the concrete floor surface. Specifically, in reality, a tube is used to cover the entire concrete floor surface so that the sealing liquid can penetrate deeply without evaporating from the concrete surface. This relates to improved reinforcement methods for concrete floor surfaces.

Description

Concrete floor reinforcement method using tube sheet rolls {A REINFORCEMENT METHOD FOR CONCRETE SURFACE USING TUBE SHEET ROLLS}

The present invention relates to a method of reinforcing the concrete floor surface to prevent defects in the concrete floor surface. Specifically, in reality, the entire concrete floor surface is reinforced so that moisture diluted in the sealing liquid can penetrate deeply without evaporating from the concrete surface. This relates to an improved reinforcement method for concrete floors using covering tube sheet rolls.

The floors of most buildings, such as factories, warehouses, parking lots, logistics centers, building rooftops, hotels, officetels, shopping malls, and buildings, are formed by pouring concrete. Then, apply a coating-type floor finishing material such as epoxy or urethane on the concrete floor, or use an inorganic compound-based penetrating surface strengthener to strengthen the surface.

As shown in Figure 1, the concrete floor is usually subjected to press plastering (mechanical plastering) after pouring. The keystone sinks due to its weight, and a dense mortar layer of 5 to 10 mm deep made of cement and sand is formed on the floor surface. . The mortar layer formed in this way has high density (density) and appears neat and tidy in appearance, but the lower part of the mortar layer is a concrete layer with many pores and low density, so it has different properties from the upper mortar layer, so the mortar layer deteriorates over time. Small cracks occur and separation from the lower concrete layer occurs. Therefore, even if a floor finishing material or surface reinforcement agent is applied to the concrete floor, this only protects the surface from external impacts, etc., and the concrete floor cannot solve the problem of defects in the mortar layer as shown in FIG. 2. In other words, the problem of ordinary concrete floors recurring over time is that defects such as separation of the mortar layer occur and require re-construction.

In order to solve this problem, the prior art presented is based on removing the mortar layer from the concrete floor surface and infiltrating the sealing liquid as a surface reinforcement into the concrete surface from which the mortar layer has been removed.

However, in the prior art, in order for the sealing liquid (agent) to penetrate deeply into the concrete surface, the sealing liquid must remain wet on the concrete surface for a long time. However, at construction sites, buildings are usually exposed to the external environment without walls, so sealing is required. Even if the liquid was sprayed on the entire concrete surface, it was easily evaporated by sunlight or wind and the sealing liquid quickly hardened on the surface, so there was a problem in that it could not penetrate deeply. Generally, the sealant is sprayed with a sprayer, but in this case, the safety of the worker cannot be guaranteed because the dispersed chemical flows into the worker's respiratory tract, and it is difficult to maintain a wet state for more than 2 hours with this method, and the sealing fluid Even if you pour it on the floor, since the floor is not 100% completely level, it will be tilted to one side, so the worker must continue to spread the sealing liquid evenly on the surface, which is not realistic.

Accordingly, the inventor of the present invention came up with a realistic and effective concrete surface strengthening method that can strengthen the concrete surface by keeping the sealing liquid wet on the concrete floor surface for a long time using an easily installed tube sheet.

Prior literature: Republic of Korea Patent 10-2016387 (registered on August 26, 2019)

The purpose of the present invention is to provide a realistic and effective concrete surface strengthening method that can strengthen the concrete surface by maintaining the sealing liquid on the concrete floor surface in a wet state for a period of time suitable for work requirements.

The concrete floor reinforcement method using tube sheet roll of the present invention to solve the above technical problems is,

A step of grinding to remove the mortar layer and clean the dust by grinding the concrete surface (S 1);

Installing a roll-shaped tube sheet on one end of the concrete floor and injecting water through the injection port to spread the tube sheet (S 2);

Injecting the sealing liquid into the injection port of the tube sheet, applying the sealing liquid to the concrete surface, and absorbing and curing (S 3);

A step of chamfering the concrete surface to remove and clean the sealing layer on the surface (S 4);

A step of generating dust on the concrete floor by grinding after applying the grouting liquid and filling the porous interior of the concrete floor with a mixture of the grouting liquid and dust (S 5); and

A concrete floor reinforcement method comprising the step of grinding the concrete floor surface (S 6),

The tube sheet 100 installed in step (S 2) is wound in a roll shape,

An upper sheet 101 and a lower sheet 102 are provided, and the upper and lower sheets are glued at predetermined intervals in an overlapping state to form a tube in the longitudinal direction, and both ends are provided to apply a load to the tube sheet. Support tubes (100L, 100R) are provided, and one or more sealing liquid tubes (100M) for injecting sealing liquid are provided between the support tubes (100L, 100R) at both ends,

The rear ends of the sealing liquid tube 110M and the support tubes 100L and 100R are provided with respective injection ports 110i, and the distal ends are sealed.

In order to prevent layer separation that occurs during the pouring and mechanical plastering of concrete, the present invention removes the mortar layer on the concrete floor, which is a source of damage, and deeply seals the pores formed in the porous concrete surface using a sealing liquid. It is done.

The present invention completes a hard and smooth foundation floor by filling air holes (pinholes) in the concrete surface from which the mortar layer has been removed by mixing grouting liquid and dust using a grouting method.

In the present invention, the wet state can be maintained for a long time because the sealing liquid is supplied through a tube in wetting the concrete floor surface.

Furthermore, in the present invention, when the tubes provided at both ends are filled with water or sealing liquid through the inlet, the weight prevents the tube sheet from blowing away in the wind after covering the concrete surface, making work possible even on windy days. .

Figure 1 is a photograph of the cross-sectional structure of a typical concrete floor.
Figure 2 is a photograph of the concrete floor where separation of the mortar layer occurred.
Figure 3 is a flowchart of the concrete floor reinforcement method according to the present invention.
Figure 4 is a photograph of the main stages of the concrete floor reinforcement method according to the present invention.
Figure 5 is a conceptual diagram of a tube sheet roll according to the present invention
Figure 6 is a conceptual diagram of the unfolding principle of the tube sheet roll according to the present invention
Figure 7 is a view showing a method of overlapping use of adjacent tube sheet rolls according to the present invention.

Hereinafter, the present invention will be described in detail through preferred embodiments. However, the present embodiments should be understood as illustrative so that the present invention can be better understood, and the terms or words used should not be construed as limited to their usual or dictionary meanings, and the inventor has used his invention in the best possible way. In order to explain the method, it should be interpreted as meaning and concept consistent with the technical idea of the present invention based on the principle that the concept of the term can be appropriately defined, and the present invention should not be understood to be limited thereto.

The present invention is limited to a concrete floor on which a mortar layer is formed on the concrete surface through mechanical or hand plastering after pouring the concrete (S 0); As shown in S 0 in Figure 4, the concrete mortar surface is smooth and beautiful, but has a very vulnerable structure.

- A step of chamfering the concrete surface by grinding to remove the mortar layer and clean the dust (S 1);

Typically, mechanical plastering is performed on the concrete floor after pouring. Since the keystone sinks due to its weight, a dense mortar layer of cement and sand 5 to 10 mm deep is formed on the surface. However, while the mortar layer formed in this way has high density (density), the inner concrete layer has low density (density) and has many pores. As time passes, small cracks occur in the mortar layer and the inner concrete layer Separation from the layer occurs.

In the present invention, the mortar layer generated by concrete pouring and pressing plaster is fundamentally removed by scraping it off through primary grinding. With the removal of the mortar layer, the surface with pores is revealed in the concrete layer.

In addition, dust on the mortar layer and concrete surface layer generated in the process of removing the mortar layer by grinding must be thoroughly removed with a vacuum cleaner, etc. On the concrete surface from which dust has been removed, as shown in S 1 of FIG. 4, porous grooves are exposed on the concrete surface.

- Installing a tube sheet roll in which the support tube and the sealing liquid tube are wound in a roll (S 2);

The concrete surface from which the mortar layer has been removed in step S 1 must absorb the sealing liquid as a whole and allow the sealing liquid to penetrate deeply in order for the concrete surface to harden to a predetermined depth. The present invention uses a tube sheet wound in a roll form to solve the problem of the sealing liquid not being able to penetrate deeply.

The tube sheet used in the present invention is a double tube sheet in which a tube is formed in the longitudinal direction and wound into a roll. It is placed on one end of the concrete floor and then goes through the process of unfolding.

Specifically, the tube sheet of the present invention is shown in Figure 5.

The tube sheet 100 is,

In a state where the upper sheet 101 and the lower sheet 102 are overlapped, the upper and lower sides are bonded at predetermined intervals in the width direction by the adhesive portion 120 to form a longitudinal tube ( 110) is formed so that at least one tube 110 is formed in the longitudinal direction from the front end of the tube sheet to the rear end. In the present invention, the meaning of the adhesive portion 120 includes not only fusion by heating but also adhesion by adhesive. Here, the 'rear end' refers to the part of the tube sheet roll where the tube sheet begins to unwind, and the 'front end' refers to the part wound around the center of the tube sheet roll, the part where the tube sheet roll is unwound and unfolds last. says

Preferably, the tube sheet roll of the present invention is a tube sheet wound in a roll shape, and a plurality of tubes are provided in the longitudinal direction, and the tubes are separated by an adhesive portion. Each adhesive portion serves as a connecting means to connect each tube. The tube sheet includes at least one support tube L (110L) at the left end and at least one support tube R (110R) at the right end.

Each of the support tubes is provided with an inlet through which water can be injected, and the rear end inlet of the tube 110 provided on the roll-shaped tube sheet 10 is connected to an external water supply pipe 210. do.

The tube sheet of the present invention is a tube sheet wound in the form of a roll, and is used in the state of being wound in the form of a roll to have a certain width and a long length. The preferred width of the tube sheet is approximately 1 to 3 m. It can be a little longer or shorter than this, but if it is too long, it will be inconvenient to transport or handle, and if it is too short, the efficiency of construction will decrease. The length of a tube sheet ranges from several meters to tens of meters. It is desirable to match the length of the tube sheet to the length of the concrete floor surface requiring covering work.

The tube sheet used in the present invention has an upper sheet and a lower sheet that overlap, and are glued or fused at a predetermined interval between them to form a tube in the tube sheet. The front end of the tube sheet is rolled in a sealed state, and the rear end is provided with an injection port so that the sealing liquid can be injected by being coupled to a supply pipe that supplies the sealing liquid from the outside. To facilitate connection between the tube inlet and the supply pipe, a one-way injection valve, etc. may be optionally added. Since the means for connecting the supply pipe and the inlet is known technology, detailed description thereof will be omitted. The tube does not necessarily have to be straight from the rear end toward the front end, but is configured from the rear end toward the front end in a zigzag or wave shape.

When supplied to the support tube L and support tube R provided at both ends through the inlet at the rear end, it is possible to prevent the tube sheet from being blown away by strong winds due to a sufficient load. In addition, a plurality of additional tubes may be further provided between the tube L (110L) and the tube R (110R), and when a plurality of additional tubes are provided throughout the tube sheet in this way, a constant It becomes easier to maintain its shape. When a liquid such as water is injected into the support tube L (110L) and the support tube R (110R) through the injection port, the tube sheet roll (10) spreads on the concrete surface and covers the floor like a mat.

Preferably, the support tube provided on the tube sheet 100 is provided in a pair at at least one of the left end and the right end. That is, a pair of tubes (110L, 100L') are provided at the left end or a pair of tubes (110R, 110R') are provided at the right end, and each can be formed in a straight line in the longitudinal direction from the rear end toward the front end. there is. As a result, as shown in Figure 9, water is supplied through the inlet of the tubes to overlap adjacent tube sheets with irregularities formed by each pair of tubes, thereby increasing the number of tube sheets on a wide concrete floor where a plurality of tube sheets must be installed. It becomes easy to align the heat, and above all, it can be covered without a gap between the tube sheet and other adjacent tube sheets in the width direction. The concrete floor covered with the tube sheet not only ensures that the sealing liquid is continuously supplied, but also the absorbed sealing liquid is not easily evaporated by sunlight.

- Injecting water into the support tube to spread the tube sheet on the concrete floor, injecting the sealing liquid into the sealing liquid tube and applying it to the concrete surface to keep it wet and absorb and cure (S 3);

In the present invention, support tube L (110L) and support tube R (110R) are provided at both ends of a tube sheet, and a sealing liquid tube (110M) through which sealing liquid can be injected is provided between them. The rear end of the sealing liquid tube 110M is provided with an injection port through which the sealing liquid is injected. And the sealing liquid injected through the injection port of the sealing liquid tube ejects the sealing liquid onto the concrete surface through the blowing hole 111 provided on the lower surface of the sealing liquid tube (110M).

The sealing liquid is injected through the sealing liquid tube of the tube sheet as above and applied to the entire concrete surface through the blowhole. The sealing liquid is a dilution of the sealant in water, usually water and sealant 3:1. Dilute by mixing in the ratio of .

The sealant fuses with the concrete components through a chemical reaction with calcium hydroxide in the concrete floor, and converts the neutralized concrete to alkaline due to the strong alkalinity of the silicate itself, thereby improving strength and durability. Any silicate sealant can be used, but more preferably it contains 100 parts by weight of silicate resin, 1 to 5 parts by weight of silica fine powder, 0.1 to 5 parts by weight of polyacrylate, 0.1 to 5 parts by weight of quaternary ammonium solution, It contains 0.1 to 5 parts by weight of polysiloxane emulsion, 0.1 to 3 parts by weight of polyether-modified siloxane copolymer, and 5 to 50 parts by weight of water. Sealing is the process of filling porous pores in the concrete layer using a sealant such as silicate. However, even if small pores are filled with a sealant, large pores are not filled with a sealant.

In the present invention, the sealing liquid is continuously injected through the blowhole of the tube sheet so that a large amount of the sealing liquid can be absorbed from the concrete surface to a predetermined depth. The key to sealing liquid is to keep the concrete floor wet for a long time. Preferably, it should be kept wet for about 24 to 48 hours. In this way, the wet state is maintained by the sealing liquid for a predetermined period of time so that the sealing liquid penetrates deeply into the porous interior of the concrete surface. As a result, the sealing liquid is absorbed into the surface of the concrete floor and the inside of the porous grooves of the concrete, thereby hardening the surface. The sealing layer is formed not only on the concrete surface, but also inside the porous grooves of the concrete surface. The absorbed sealing liquid is absorbed to a predetermined depth on the concrete surface and is dried and hardened, so that small porous pinholes inside the concrete surface are filled with the sealing liquid. The entire concrete floor covered by the tube sheet is sprayed with the sealing fluid from the ejection hole of the tube sheet's sealing fluid tube, so the applied sealing fluid is less affected by external wind and sunlight.

- Removing the sealing layer on the concrete surface by grinding the concrete surface hardened by the sealing liquid (S 4);

This is a step of removing the coated sealing layer that cannot penetrate and remains on the concrete surface by grinding. As a result, the sealing layer is removed from the concrete surface and remains only inside the porous groove. The sealing layer formed on the concrete surface is like a kind of glass film, so the next subsequent process can only proceed after removing the sealing layer on the concrete surface.

- Applying the grouting liquid to the concrete surface and then grinding it to generate dust on the concrete surface to form a grouting layer on the concrete surface and porous interior with a mixture of grouting liquid and dust (S 5);

The grouting solution is a diluted mixture of water and resin, and the grouting resin may be any one of water-soluble acrylic emulsion, styrene emulsion, acetic acid tube emulsion, acetic acid tube acrylic emulsion, EVA emulsion, water-dispersed urethane, and water-dispersed epoxy. In this way, since the grouting liquid is applied to the concrete surface and then ground, it is mixed with dust generated by grinding and penetrates into the grooves of the concrete surface to fill micropores.

- Grinding to surface grouting residues on the concrete surface (S 6);

Finally, chamfering the concrete surface involves mixing the grouting liquid and dust to remove the layer formed by mixing the grouting liquid and dust from the concrete surface. Reinforced concrete floors are usually finished with a ceramic finish, epoxy finish, or urethane finish rather than being used as is. By removing the residue consisting of grouting liquid and dust, it becomes possible to form subsequent finishing layers such as ceramic finishing materials and epoxy finishing materials.

The process below can be added as an additional step.

- A step of allowing silica sol to penetrate into the micropores of the concrete surface and coating it with ceramic (S 7);

As a next step to the above step (S6), silica gel is absorbed into the concrete surface to form a glass film with a predetermined thickness so that external water is not absorbed into the concrete surface. Meanwhile, due to the structural characteristics of ceramics, water vapor can evaporate through micropores, so evaporation of moisture inside concrete is possible.

Additionally, the ceramic that permeates the concrete surface acts as a cement paste. In other words, since it is common to reduce the amount of cement, which has a high cost ratio, at concrete pouring sites, problems often occur with the strength of concrete, but the concrete maintains high adhesion due to ceramics that play the role of cement paste. It may further include a step of chamfering and removing remaining ceramic on the concrete surface by grinding.

As described above, the present invention has been described with specific details such as specific components and limited embodiments and drawings, but this is only provided to facilitate a more general understanding of the present invention, and the present invention is not limited to the above embodiments. , those skilled in the art can make various modifications and variations from this description. Accordingly, the spirit of the present invention should not be limited to the described embodiments, and the scope of the patent claims described later as well as all things that are equivalent or equivalent to the scope of this patent claim shall fall within the scope of the spirit of the present invention. .

10: Tube seat roll
100: tube sheet
110R, 110L: support tube, 110M: sealing liquid tube,
110i: injection port, 111: blowout hole
120: adhesive part
200: Supply department
210: water supply pipe
220: Sealing liquid pipe

Claims (3)

A step of grinding to remove the mortar layer and clean the dust by grinding the concrete surface (S 1);
Installing a tube sheet roll in which the support tube and the sealing liquid tube are wound in a roll shape on one end of the concrete floor (S 2);
Spreading the tube sheet on the concrete floor by injecting water through the injection port of the support tube, and injecting the sealing fluid through the injection port of the sealing fluid tube to apply the sealing fluid to the concrete surface and absorb and harden it (S 3);
A step of chamfering the concrete surface to remove and clean the sealing layer on the surface (S 4);
A step of generating dust on the concrete floor by grinding after applying the grouting liquid and filling the porous grooves of the concrete floor with a mixture of the grouting liquid and dust (S 5); and
A concrete floor reinforcement method comprising a step (S 6) of chamfering the grouting layer of the concrete surface by grinding,

The tube sheet 100 installed in step (S 2) is wound in a roll shape,
It is made of at least two layers of sheets with an upper sheet and a lower sheet overlapping, and the upper and lower sheets are bonded at a predetermined interval in the width direction to form a plurality of tubes in the longitudinal direction, with at least one support tube at the left end. At least one support tube R (110R) is provided at L (110L) and the right end, and between the support tube L (110L) and support tube R (110R), one or more sealing liquid tubes (110M) for injecting sealing liquid. ), but the lower surface of the sealing liquid tube (110M) is provided with a blowout hole (111) along the longitudinal direction,
Characterized in that the rear ends of the support tube L (110L), the support tube R (110R) and the sealing liquid tube (110M) are provided with respective injection ports (110i) for injecting water or sealing liquid.
Concrete floor reinforcement method using tube sheet roll.
According to paragraph 1,
As the next step of the step (S 6), applying silica sol to penetrate into the micropores of the concrete surface and coating it with ceramic (S 7);
A concrete floor reinforcement method using a tube sheet roll, further comprising the step of removing the ceramic layer on the concrete surface by grinding (S 8).
According to claim 1 or 2,
The tube sheet 100 in step (S 2) is provided with a pair of support tubes (110L, 100L') at the left end or a pair of support tubes (110R, 110R') at the right end. A concrete floor reinforcement method using tube sheet rolls.

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