KR102166830B1 - Cross section recovery method using polymer mortar with excellent separation resistance in water by improving water tightness and material separation by including hard calcium carbonate and natural high performance thickener Xanthan gum and polymer mortar composition - Google Patents

Abstract

The present invention relates to a cross section repair method using polymer mortar having excellent underwater separation resistance by improving watertightness and material separability by including hard calcium carbonate and natural high-performance thickener xanthan gum. According to the present invention, the cross section repair method comprises: a chipping processing step; a high-pressure water washing step; a concrete adhesive applying step; a cross section repair polymer mortar laying step; and a curing and finishing step. According to the present invention, the construction efficiency can be prevented from deteriorating.

Description

Cross section recovery method using polymer mortar with excellent separation resistance in water by improving water tightness and material separability, including hard calcium carbonate and xanthan gum, a natural high-performance thickener. by improving water tightness and material separation by including hard calcium carbonate and natural high performance thickener Xanthan gum and polymer mortar composition}

The present invention relates to a cross-section repair method using a polymer mortar having excellent water-tightness and material separability, including hard calcium carbonate and xanthan gum, a natural high-performance thickener, and having excellent separation resistance in water, and a polymer mortar composition thereof By including hard calcium carbonate and xanthan gum, a natural high-performance thickener, it can be applied to various structures to be repaired, and due to the high viscosity of the polymo mortar, the mortar adheres to the mixer. Including hard calcium carbonate and xanthan gum, a natural high-performance thickener, which improves separation resistance and improves excellent finishability and workability, and improves water-tightness and material separation, a cross-section restoration method using polymer mortar with excellent separation resistance in water and its It relates to a polymer mortar composition.

If there are severe cracks in pillars, outer walls, fences, and parapets placed in the water of the structure, there is no suitable method to repair. Even if the mortar is injected and repaired, the connection part is not long enough to be lifted again, and rainwater flows in, reducing the durability of the building.

In addition, a sealing material is injected to repair small cracks, and mortar is injected into severe areas for plastering, but it is not good in terms of aesthetics because the old concrete and the junction are exposed.

Conventionally, various methods for repairing the above cracks have been disclosed, and one of them, a tape for repairing cracks, is made of butyl rubber on a punched long fiber nonwoven fabric as in Korean Utility Model Application No. 20-2007-0012062. It is attached directly to the wall without using a primer.

However, in the method of repairing cracks by taping, it will not be long if you attach it directly to the old wall with paint and foreign substances without applying a primer, and if you attach a nonwoven fabric directly on butyl rubber, which is weak to ultraviolet rays, it will not properly block UV rays and shorten the lifespan. There is a problem.

Another method of repairing cracks is to fill concrete in the formwork installed while wrapping the structure to form a reinforced concrete layer.However, since the formwork must be formed of heavy steel to prevent damage by its own weight of the filled concrete. However, there is a problem that the cost is excessive, and there is a problem that it takes a lot of equipment and time to move a heavy formwork or support it for pouring concrete.

In addition, there is a problem in that the water from the repair site cannot be completely removed due to field conditions, and thus, quality inhomogeneity occurs due to loss of cement paste or mortar when placing reinforcement mortar or concrete.

The above-described invention refers to the background technology in the technical field to which the present invention belongs, and does not mean the prior art.

Korean Patent Registration No. 10-0982241

The present invention was conceived to solve the above-described conventional problems, and an object of the present invention is to include hard calcium carbonate and a natural high-performance thickener xanthan gum in a polymer mortar, so that it can be applied to various structures to be repaired. Due to the high viscosity of the mortar, it prevents the mortar from adhering to the mixer and deteriorates construction efficiency, such as a decrease in transport performance, improves separation resistance, improves excellent finishability and workability, and uses hard calcium carbonate and xanthan gum, a natural high-performance thickener. It is an object of the present invention to provide a cross-section repair method using a polymer mortar having excellent water-tightness and material separation properties, including water-tightness and material separation, and a polymer mortar composition thereof.

In order to achieve the above object, the present invention

A cross-section repair and reinforcement method adapted to repair a cross section of a structure having moisture, comprising: a chipping processing step of forming a repair groove by trimming a crack formed in the structure; High-pressure water washing step to remove foreign substances by spraying high-pressure water into the repair groove of the structure; An old and new adhesive applying step of drying the repair groove portion of the structure and then applying the old and new adhesive to the inner surface to form a new and old adhesive layer; Placing a polymer mortar for cross-section restoration in which a polymer mortar is poured and filled in the repair groove; And a curing finishing step of curing and curing the polymer mortar, including hard calcium carbonate and xanthan gum, a natural high-performance thickener, to improve water-tightness and material separability, thereby using a polymer mortar having excellent resistance to separation in water. to provide.

In one embodiment of the present invention, after the high-pressure water washing step, a rust inhibitor coating step of applying a rust inhibitor to the reinforcing bar exposed to the outside from the inner surface of the repair groove is further added.

In addition, in one embodiment of the present invention, after the step of applying the old and new adhesive, a reinforcing material inserting step of inserting a reinforcing material into the repair groove is further added, and the reinforcing material is made of reinforcing bar or wire mesh.

In addition, in one embodiment of the present invention, after the polymer mortar placing step, a coating agent application step of forming a coating layer by applying a coating agent to the surface of the poured polymer mortar is further added.

In addition, in one embodiment of the present invention, the structure is further provided with a flow-preventing drying means to block the inflow of water in the process of curing and curing after pouring and filling polymer mortar in the repair groove, the The flow-preventing drying means includes an airtight elastic blocking frame that is in close contact with the outer surface of the structure while surrounding the repair groove, and one end is fixed to both sides of the airtight elastic frame, and an elastic connection for fixing the airtight elastic blocking frame to the structure. A band, a seating groove formed on a contact surface of the airtight elastic blocking frame disposed in contact with the structure, and a heating wire that is fitted into a seating groove formed in the airtight elastic blocking frame to transmit heat to the structure, and the It is installed on the lower blocking shaft of the airtight elastic blocking frame, characterized in that consisting of a blower pen supplying wind to the outer surface of the structure in which the repair groove is formed.

In order to achieve the above object, the present invention

As a mortar composition designed to repair the cross section of a structure having moisture, the polymer mortar is made by mixing cement, hard calcium carbonate, fiber, thickener, defoaming agent, additives, and polymer, and the fiber is polyacrylonitrile fiber or nylon It provides a polymer mortar composition having excellent resistance to separation in water by improving water-tightness and material separability, including hard calcium carbonate, characterized in that fibers are used, and Xanthan gum, a natural high-performance thickener.

Including the present invention, hard calcium carbonate and xanthan gum, a natural high-performance thickener, to improve water tightness and material separability. It can be applied to a structure to be repaired, and due to the high viscosity of the polymo mortar, it prevents the mortar from adhering to the mixer, reducing construction efficiency, such as a decrease in transport performance, and improves separation resistance, and provides excellent finisher utility and work. There is an effect of improving sex.

1 is a flow chart showing a cross-section recovery method using a polymer mortar having excellent water-tightness and material separability, including hard calcium carbonate and xanthan gum, a natural high-performance thickener according to the present invention.
2 is a cross-sectional view showing a crack formed in the structure according to the present invention.
3 is a view showing a chipping processing step according to the present invention.
4 is a view showing the old and new adhesive application step according to the present invention.
5 is a view showing a polymer concrete pouring step according to the present invention.
6 is a flow chart showing another embodiment of a cross-section repair method using a polymer mortar having excellent water-tightness and material separation by improving watertightness and material separability, including hard calcium carbonate and xanthan gum, a natural high-performance thickener according to the present invention.
7 is a front view showing a state in which the flow-preventing drying means according to the present invention is installed.
Figure 8 is a cross-sectional view showing a state in which the flow prevention drying means according to the present invention is installed.
Figure 9 is a construction state diagram showing a state in which the flow prevention drying means according to the present invention is installed.

Hereinafter, with reference to the accompanying drawings, including hard calcium carbonate and xanthan gum, a natural high-performance thickener according to the present invention, a cross-section repair method using a polymer mortar having excellent water-tightness and material separability by improving water-tightness and material separability, and a preferred polymer mortar composition An embodiment will be described with reference to the accompanying drawings. In this process, the thickness of the lines or the size of components shown in the drawings may be exaggerated for clarity and convenience of description. In addition, terms to be described later are terms defined in consideration of functions in the present invention and may vary according to the intention or custom of users or operators. Therefore, definitions of these terms should be made based on the contents throughout the present specification.

In addition, the following examples are not intended to limit the scope of the present invention, but are presented merely as examples, and there may be various embodiments implemented through the present technical idea.

1 is a flow chart showing a cross-section recovery method using a polymer mortar having excellent water-tightness and material separability, including hard calcium carbonate and xanthan gum, a natural high-performance thickener according to the present invention. 2 is a cross-sectional view showing a crack formed in the structure according to the present invention. 3 is a view showing a chipping processing step according to the present invention. 4 is a view showing the old and new adhesive application step according to the present invention. 5 is a view showing a polymer concrete pouring step according to the present invention. 6 is a flow chart showing another embodiment of a cross-section repair method using a polymer mortar having excellent water-tightness and material separation by improving watertightness and material separability, including hard calcium carbonate and xanthan gum, a natural high-performance thickener according to the present invention. 7 is a front view showing a state in which the flow-preventing drying means according to the present invention is installed. Figure 8 is a cross-sectional view showing a state in which the flow prevention drying means according to the present invention is installed. Figure 9 is a construction state diagram showing a state in which the flow prevention drying means according to the present invention is installed.

As shown in the figure, a cross-section recovery method 10 using a polymer mortar having excellent resistance to separation in water by improving water tightness and material separability, including hard calcium carbonate and xanthan gum, a natural high-performance thickener according to the present invention (hereinafter, section recovery for convenience of description) The construction method) is a cross-section repair and reinforcement method designed to repair the cross section of the structure 100 having moisture.Therefore, such a cross-section repair and reinforcement method includes a chipping processing step (S1), a high-pressure water washing step (S2), and an old and new adhesive. It comprises a coating step (S3) and a polymer mortar (400) placement step and a curing finishing step (S5).

The chipping processing step (S1) is a step of forming a repair groove 200 by trimming a crack formed in the structure 100.

The repair groove 200 is formed as a repair groove 200 of a certain shape so that the polymer mortar 400 can be filled in the cracked portion using a grinder or a crusher.

The repair groove 200 is formed in a square or circular groove structure.

The structure 100 may be a circular or square pillar installed underwater or in a facility in contact with water, and may be a structure of a certain shape.

Among the structures 100, a formwork is installed in the structure 100 installed underwater, and water inside the formwork is pumped so that the cracked portion of the structure 100 is exposed to the outside (in the atmosphere) from underwater.

In the high-pressure water washing step (S2), water or high-pressure water is sprayed into the repair groove 200 of the structure 100 to remove foreign substances.

The foreign material is crushed debris or dust formed in the process of forming the repair groove 200, and is washed by spraying high-pressure water through a nozzle connected to a pump.

At this time, after the high-pressure water washing step (S2), it is possible to further add a rust inhibitor coating step (S2-1) of applying a rust inhibitor to the reinforcing bar exposed from the inner surface of the repair groove 200 to the outside.

By applying the rust inhibitor to the reinforcing bar, it is possible to prevent the strength of the structure 100 from deteriorating due to corrosion or cracking of the reinforcing bar.

The old and new adhesive application step (S3) is a step of drying the repair groove 200 of the structure 100 and then applying the old and new adhesive to the inner surface to form the old and new adhesive layer 300.

The old and new adhesive is applied to attach the mortar to the object, which is the structure 100, and any epoxy or lane is used and any one that can bond mortar and concrete may be used.

At this time, after the old and new adhesive applying step (S3), a step of inserting a reinforcing material 500 into the repair groove 200 is further added, and the reinforcing material 500 is made of a reinforcing bar or wire mesh.

After the reinforcing material 500 is inserted into the repair groove 200, the polymer mortar 400 is filled in the repair groove 200 to be hardened, thereby improving strength and support.

At this time, the reinforcing material 500 is preferably welded to and fixed to the reinforcing bar inserted in the structure 100 exposed to the outside while forming the repair groove 200, and then the polymer mortar 400 is filled in the auxiliary groove. Do.

The polymer mortar placing step (S4) is a step of pouring and filling the polymer mortar 400 in the repair groove 200.

The polymer mortar is made by mixing cement, hard calcium carbonate, fiber, thickener, defoaming agent, additives, and polymer, and the fiber is polyacrylonitrile fiber or nylon fiber.

After the polymer mortar placing step (S4), a coating agent applying step (S4-1) of forming a coating layer 600 by applying a coating agent to the surface of the poured polymer mortar 400 is further added, and the coating layer 600 Accordingly, it is possible to prevent water from being absorbed after the polymer mortar 400 is cured during the curing process.

Epoxy or coating is used as the coating agent, and cured after being applied to the surface of the polymer mortar 400 filled in the repair groove 200 and the main surface structure 100 of the repair groove 200. The coating agent may be used as long as it is applied to the structure 100 in addition to the epoxy and the coating material to form a layer to maintain watertightness.

Here, it is preferable that anchor bolts are installed on the inner side of the repair groove 200 so that the polymer mort filled in the repair groove 200 improves bonding strength, strength, and support after drying.

The curing finishing step (S5) is a step of curing and curing the polymer mortar 400.

In the curing finishing step (S5), the polymer mortar 400 filled with the polymer mortar 400 is filled to prevent water from entering during the drying process while the polymer mortar 400 filled in the repair groove 200 is cured. It is preferable to supply the wind through the blower pen 750 to the part.

The structure 100 is further provided with a flow-preventing drying means 700 to block the inflow of water in the process of curing and curing after pouring and filling the polymer mortar 400 in the repair groove 200.

The flow-preventing drying means 700 includes a square or circular airtight elastic blocking frame 710 formed of a synthetic resin material having elasticity that is in close contact with the outer surface of the structure 100 while surrounding the repair groove 200, One end is fused or adhesively fixed to both sides of the airtight elastic blocking frame 710, the elastic connection band 720 fixing the airtight elastic blocking frame 710 to the structure 100, and the structure 100 The frame structure seating groove 730 formed on the contact surface of the airtight elastic blocking frame 710, which is disposed in contact, and the seating groove 730 formed in the airtight elastic blocking frame 710, are adhered and fixed. , The structure is fixed by screwing to the heat wire 740 for transmitting heat to the structure 100 and the lower blocking shaft 711 of the airtight elastic blocking frame 710, and the repair groove 200 is formed ( Consisting of a blower pen 750 supplying wind to the outer surface of 100), the elastic connection in the state in which the airtight elastic blocking frame 710 is in close contact with the outer surface of the structure 100 while surrounding the repair groove 200 After wrapping the structure 100 of the column structure with bands 720, the ends of the elastic connection bands 720 are tied and fixed, thereby preventing the elasticity of the elastic connection band 720 and the airtight elastic blocking frame 710. As a result, the airtight elastic blocking frame 710 is fixed to the structure 100 and closely adhered to prevent water from moving to the repair groove 200 filled with the polymer mortar 400.

The elastic connection band 720 does not wrap the structure 100 when the repair groove 200 is formed on the wall surface of the plane, in addition to tying and fixing the ends after wrapping the structure 100, the elastic connection band 720 It is also possible to fix by screwing or attaching to the outer surface of the structure 100.

In addition, the heating wire 740 blocks water from being moved to the repair groove 200 again, and the polymer filled in the repair groove 200 by transferring heat while drying the structure 100 with water. It is possible to reduce the drying time of the mortar 400.

In addition, it blocks water from being moved to the repair groove 200 again by the wind supplied from the blower pen 750, and dries the water in the structure 100, and the polymer filled in the repair groove 200 It is possible to reduce the drying time of the mortar 400.

Here, the upper blocking shaft of the airtight elastic blocking frame 710 is fixed by attaching the lower end of the support shaft to the center on the upper side, and the bottom surface of the guide panel in the shape of “” is attached to the upper end of the support shaft, It is preferable to prevent water from flowing into the repair groove 200 by guiding the water flowing downward along the structure 100 to both sides.

The outer surface of the airtight elastic blocking frame 710 is maintained at a certain interval and fixed by screwing a transfer pen, thereby supplying wind to the outside of the airtight elastic blocking frame 710 by the driving of the transfer pen. It is preferable to dry the water of) and prevent flowing water from moving to the airtight elastic barrier frame 710.

In addition, by inserting an absorption frame made of natural fiber or non-woven fabric inside the airtight elastic blocking frame 710 and then bonding and fixing it to the inner surface of the airtight elastic blocking frame 710, the airtight elastic blocking frame 710 It is preferable to absorb water penetrating between the and the structure 100 to block water from moving to the repair groove 200.

One embodiment of the present invention described above is merely exemplary, and those of ordinary skill in the technical field to which the present invention belongs will appreciate that various modifications and other equivalent embodiments are possible. . Therefore, it will be appreciated that the present invention is not limited to the form mentioned in the detailed description above. Therefore, the true technical protection scope of the present invention should be determined by the technical spirit of the appended claims. In addition, the present invention is to be understood as including the spirit of the present invention as defined by the appended claims and all modifications, equivalents and substitutes within the scope thereof.

100: structure 200: repair groove
300: old and new adhesive layer 400: polymer mortar
500: reinforcing material 600: coating layer
700: flow-preventing drying means 710: airtight elastic blocking frame
711: lower blocking shaft 720: elastic connection band
730: mounting groove 740: heated wire
750: blower pen S1: chipping processing step
S2: high pressure water washing step S2-1: rust inhibitor application step
S3: New and old adhesive application step S3-1: Reinforcing material insertion step
S4: Polymer concrete pouring step S4-1: Coating agent application step
S5: Curing finishing stage

Claims (6)

As a section repair and reinforcement method designed to repair the section of a structure with moisture,
A chipping step of trimming the cracks formed in the structure to form a repair groove;
High-pressure water washing step to remove foreign substances by spraying high-pressure water into the repair groove of the structure;
An old and new adhesive applying step of drying the repair groove portion of the structure and then applying the old and new adhesive to the inner surface to form a new and old adhesive layer;
Placing a polymer mortar for cross-section restoration in which a polymer mortar is poured and filled in the repair groove; And
It characterized in that consisting of; curing and finishing step of curing and curing the polymer mortar,
The structure is further provided with a flow-preventing drying means to block the inflow of water in the process of curing and curing after pouring and filling polymer mortar in the repair groove,
The flow-preventing drying means includes an airtight elastic blocking frame that is in close contact with the outer surface of the structure while surrounding the repair groove, and one end is fixed to both sides of the airtight elastic blocking frame to fix the airtight elastic blocking frame to the structure. An elastic connection band, a seating groove formed on a contact surface of the airtight elastic blocking frame disposed in contact with the structure, and a heating wire that is fitted into a seating groove formed in the airtight elastic blocking frame to transmit heat to the structure. , It is installed on the lower blocking shaft of the airtight elastic blocking frame, characterized in that consisting of a blower pen for supplying wind to the outer surface of the structure in which the repair groove is formed. Sectional restoration method using polymer mortar with excellent water-tightness and material separability, including hard calcium carbonate and Xanthan gum, a natural high-performance thickener.
The method of claim 1,
After the high-pressure water washing step, a rust inhibitor application step of applying a rust inhibitor to the reinforcing bar exposed to the outside from the inner surface of the repair groove is further added, including hard calcium carbonate and xanthan gum, a natural high-performance thickener. Sectional restoration method using a polymer mortar with excellent resistance to separating in water.
The method of claim 1,
After the step of applying the old and new adhesive, a reinforcing material insertion step of inserting a reinforcing material into the repair groove is further added,
The reinforcing material includes hard calcium carbonate and xanthan gum, a natural high-performance thickener, characterized in that it is made of reinforcing bar or wire mesh, and improves water-tightness and material separability, so that a cross-sectional repair method using a polymer mortar having excellent resistance to separation in water.
The method of claim 1,
After the polymer mortar pouring step, a coating agent application step of forming a coating layer by applying a coating agent to the surface of the poured polymer mortar is further added. Sectional restoration method using polymer mortar with improved resistance to separation in water.
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