KR20060022132A - The repairing method for underwater pile structure surface using bandages - Google Patents

Abstract

The present invention relates to a method for repairing the surface of an underwater steel pipe structure using a bandage, the purpose of which is to repair the steel pipe structure in the water by the pressure bandage impregnated with a coating material for curing underwater, easy installation underwater, steel pipe structure It is to provide a method for repairing the surface of an underwater steel pipe structure using a bandage that can extend the life by restoring and increasing the bearing capacity.

The present invention removes the deteriorated portion of the underwater steel pipe structure, the surface treatment step of removing foreign matters on the steel pipe structure, foreign matter and deterioration part removing step of removing foreign matters of the surface-treated steel pipe structure by high pressure washing water; In addition, the bandage installation step of winding the bandage impregnated with the ceramic coating material in close contact with the steel pipe structure from which the foreign material is removed, and the ceramic coating material coating step of applying a ceramic coating material on the upper surface of the bandage installed in the steel pipe structure.

Bandage, steel pipe, underwater repair, ceramic coating material, repair method

Description

The repairing method for underwater pile structure surface using bandages             

1 is an exemplary view of surface cleaning after a deterioration part grinder according to the present invention

Figure 2 is an exemplary view showing the installation state of the bandage impregnated with a ceramic coating material according to the present invention

3 is a block diagram according to the present invention;

* Explanation of symbols for main parts of the drawings

10: steel pipe structure 20: grinder

30: scaffolding 40: upper concrete

50: Bandage

The present invention relates to a method for repairing the surface of an underwater steel pipe structure using a bandage, and to the corrosion of steel and steel pipe structures submerged by the invasion of HO ₂ and chloride using steel bandages impregnated with a coating material for curing underwater The present invention relates to a surface repair method of an underwater steel pipe structure using a bandage for repairing the surface of the structure.

Most steel submerged steel and steel pipe structures are to be installed by the method of coating the coating material on the steel and steel pipe surface on the ground, and then moving them into water to fix them. The surface coating material is applied to prevent corrosion in the water and to prevent the attachment of microorganisms and foreign substances, but the surface coating material submerged in the water is a phenomenon that falls from the steel frame and steel pipe structure due to the flow of microorganisms and seawater underwater In this case, corrosion of the steel frame and steel pipe surface is caused by the dropping of the surface coating material, and the life of the structure is significantly shortened.

As such, when corrosion occurs in the steel frame and steel pipe structure, a method of repairing the steel frame and steel pipe structure to repair it is mainly used in the form of the form and the frame on the ground to join the underwater steel pipe structure.

However, in the conventional method as described above, since a separate formwork and a frame must be installed on the surface of the steel frame and the steel pipe structure in water, a lot of work time is required, construction is difficult, and thus the worker's risk is increased. There was this.

In addition, since working in the water, a separate dedicated equipment is required, because the work must be carried out by a number of skilled workers, there were various problems such as increased labor and construction costs.

The present invention has been made in consideration of the above problems, the object of which is to repair the steel pipe structure in the water by the pressure bandage impregnated with the coating material for curing under water, easy installation underwater, restoring the bearing capacity of the steel pipe structure And to provide a surface repair method of the underwater steel pipe structure using a bandage that can be extended to extend the life.

1 is an exemplary view showing the surface cleaning after the deterioration part grinder according to the present invention, Figure 2 is an illustration showing the installation state of the bandage impregnated with a ceramic coating material according to the present invention, Figure 3 is a block diagram according to the present invention In one embodiment, the present invention removes the deteriorated portion and foreign matter of the underwater steel pipe structure, wound around the removed portion of the steel pipe structure impregnated with a bandage impregnated with a ceramic coating material, the bandage is installed again on the site It is adapted to apply a ceramic coating material.

That is, the present invention is to remove the deteriorated portion of the underwater steel pipe structure, the surface treatment step (S100) for removing foreign matters on the steel pipe structure, foreign matter to remove the foreign matter of the surface-treated steel pipe structure by high pressure washing water and Deterioration step removal step (S200), the bandage installation step of impregnating the ceramic coating material using a bandage on the steel pipe structure from which the material is removed (S300), and the ceramic coating material coating step of applying a ceramic coating material on the top surface of the bandage installed. It consists of (S400).

The surface treatment step (S100) is to remove rust contamination and fish and shellfish on the surface of the steel pipe caused by aging such as salt and iron corrosion, and completely remove the deteriorated steel pipe surface using a tool such as a grinder.

The debris and deterioration unit removing step (S200) completely removes debris by using a high-pressure cleaner of 100 to 150 kg / m 2 on the ground surface.

The bandage installation step (S300) is to impregnate the ceramic coating material mixed with a certain ratio of the epoxy resin and the curing agent and ceramic powder in the bandage and then to install it on the damaged steel pipe structure, the epoxy resin and the curing agent, ceramic powder to the use ratio After weighing the mixture, mixing the mixture evenly, and then putting a bandage on the mixture to impregnate the ceramic coating material with the bandage, and then include the steel pipe surface in which the foreign material and the deterioration part were removed from the bandage impregnated with the ceramic coating material. Wind tightly on the steel pipe. The end of the bandage wound and installed in close contact as described above is fixed by sticking the bandage and the bandage with fixing means such as pins. When the end of the bandage is fixed in this way, the curing of the ceramic coating material impregnated with the bandage progresses over time, and thereby the bandage is firmly fixed to the steel pipe. The ceramic coating material impregnated in the bandage by the bandage installation step is impregnated into the steel pipe structure.

The ceramic coating material is composed of 50 to 80 wt% of a bisphenol-type epoxy resin (Diglycidyl ether of bisphenol), 8 to 25 wt% of an amine curing agent, and 10 to 30 wt% of ceramic powder.

The properties of the epoxy resin is (Average degree of polymerization) 0.1 ~ 0.2, epoxy equivalent (Epoxide equivalent) 180 ~ 210, specific gravity 1.5 ~ 1.75.

The curing agent uses a curing agent mixed with a modified aliphatic amine and a polyamide so that the curing reaction with the epoxy resin is excellent even at low temperatures to ensure the stability and curability of the coating film, and has excellent curability and adhesive performance in water and water. When the amount of the curing agent is 8 wt% or less, the coating film is poorly cured in water, and the adhesion performance is significantly decreased. When the amount of the curing agent is 25 wt% or more, the water resistance and the compressive strength of the cured product are sharply lowered, so the curing agent is preferably 8 to 25 wt%. Do.

In addition, when the mixing ratio of the modified aliphatic amine and the polyamide curing agent is 1 or less, the curability of the coating film is lowered at low temperature, thereby reducing the stability and tensile strength of the coating film in water, and when the mixing ratio of polyamide is 1 or less, Since the adhesive force tends to decrease and the water resistance greatly decreases, the mixing ratio of the modified aliphatic amine and the polyamide curing agent is preferably 1: 1 to 1: 3 by weight.

The ceramic powder is a silicate composed of iron, magnesium, an alkali metal and aluminum, and a powder of 200 mesh or less is suitable as a mineral having a specific gravity of 2.95 to 3.5. This ceramic powder acts to generate a fine current to reduce the adhesion of various fish and shellfish to the surface of the coating material, and when the powder of 200 mesh or more is used, the separation of materials occurs and the storage stability of the mixture is reduced as well as the mixing performance. As a result, the homogeneity of the coating film is reduced, and the adhesion preventing performance of fish and shellfish is greatly degraded.

In addition, when the ceramic powder is used more than 30%, the painting work performance is greatly reduced and the impregnation performance is reduced to reduce the adhesion performance and water resistance of the coating film, when used below 10% adhesion of fish and shellfish, etc. Since the prevention performance tends to be greatly reduced, it is preferable to mix 10 to 30 wt% of the ceramic powder.

Hereinafter, the ceramic coating material of the present invention will be described in detail with reference to Examples.

Example 1

Compressive strength, tensile strength, adhesion strength and hardness were tested for the coating material composition consisting of 66.6wt% epoxy resin, 16.7wt% amine-based curing agent, and 16.7wt% ceramic powder. The results are shown in [Table 1]. .

TABLE 1

Test Items unit Result Remarks Compressive strength kgf / cm ² 1060 The tensile strength kgf / cm ² 330 Adhesion strength kgf / cm ² 215 Hardness - 112 SHORE D

Example 2

Compressive strength, tensile strength, and adhesive strength were tested for the coating material composition consisting of 76.5 wt% epoxy resin, 7 wt% amine-based curing agent, and 16.5 wt% ceramic powder, which were compared with the composition ratio of Example 1. The results are shown in [Table 2].

TABLE 2

Amine Curing Agent Content Compressive strength (kgf / cm ² ) Tensile Strength (kgf / cm ² ) Adhesion Strength (kgf / cm ² ) 16.7wt% 1060 330 215 7wt% 520 144 60

Example 3

Compressive strength, tensile strength and adhesion strength were tested for the coating material composition consisting of 52.3 wt% epoxy resin, 16.7 wt% amine-based curing agent, and 31 wt% ceramic powder, which were compared with the composition ratio of Example 1. The results are shown in [Table 3].

TABLE 3

Ceramic powder content Compressive strength (kgf / cm ² ) Tensile Strength (kgf / cm ² ) Adhesion Strength (kgf / cm ² ) 16.7wt% 1060 330 215 31wt% 850 235 110

Example 4

A coating material composition consisting of 66.6 wt% epoxy resin, 16.7 wt% amine curing agent, and 16.7 wt% ceramic powder was compared with a conventional epoxy coating material (Product A), and the results are shown in [Table 4].

TABLE 4

Test Items unit Result value Remarks Example 1 Product A Compressive strength kgf / cm ² 1060 650 The tensile strength kgf / cm ² 330 160 Adhesion strength kgf / cm ² 215 70 Hardness - 112 65 SHORE D

Example 5

A coating material composition consisting of 66.6 wt% of epoxy resin, 16.7 wt% of amine curing agent, and 16.7 wt% of ceramic powder was prepared using a conventional epoxy coating material (composition of product A-epoxy resin 80.0 wt% and curing agent 20.0 wt%) and absorbed state. After applying to the water curing was compared to compare the adhesive strength, the results are shown in [Table 5].

TABLE 5

Test Items unit Result Remarks Example 1 Product A Adhesion strength kgf / cm ² 64 28

As described above, considering that the physical property value of the anticorrosive coating is to be specified in KS F with an adhesion strength of 25.5 kgf / cm2 or more in the case of the specimen in the absorbed state, the composition of the present invention is very superior to the conventional products. It can be seen that it has an adhesive performance.

The tests of Examples 1 to 4 were conducted in accordance with various quality tests specified in KS. The adhesion strength test was KS M 3734-01, the compressive strength test was KS M 5333-98, and the tensile strength test was KS M 6518-. The test method of 01 was applied. And the adhesion strength test of Example 5 was measured by curing in water after applying the test method of KS F 4929-02.

The ceramic coating material applying step (S400) is to install a bandage impregnated with a ceramic coating material on the steel pipe structure, and then to re-apply the ceramic coating material on the upper surface of the installed bandage, if the surface of the ceramic coating material impregnated around the steel pipe rough rubber Use the back to clean up the surface.

The present invention is not limited to the above-described specific preferred embodiments, and various modifications can be made by any person having ordinary skill in the art without departing from the gist of the present invention claimed in the claims. Of course, such changes will fall within the scope of the claims record.

As described above, the present invention impregnates the ceramic coating material consisting of 50 to 80 wt% of a bisphenol-type epoxy resin (Diglycidyl ether of bisphenol), 8 to 25 wt% of an amine curing agent, and 10 to 30 wt% of ceramic powder in a bandage, and then damaged the steel pipe in water. Since it is designed to be closely attached to the structure, it is not necessary to install a separate structure, it is convenient to work underwater, and the steel pipe and steel structure located in the water prevent the deterioration of the bearing capacity of the structure due to corrosion and increase the expiration date. .

In addition, the present invention is impregnated with a ceramic coating material on the damaged area is bandaged to be wound, preventing damage to the steel pipe structure, recovering and increasing the bearing capacity to ensure safety, lower the number of repairs, etc. have.

Claims (4)

A surface treatment step of removing the deteriorated portion of the underwater steel pipe structure and removing foreign matters on the steel pipe structure; Removing foreign substances and deterioration parts to remove foreign substances of the surface-treated steel pipe structure by high pressure washing water; A bandage installation step of winding a bandage impregnated with a ceramic coating material on the steel pipe structure from which the foreign substances are removed, and installing the adhesive bandage; Surface repair method of the underwater steel pipe structure using a bandage, characterized in that consisting of a ceramic coating material coating step of applying a ceramic coating material on the upper surface of the bandage installed in the steel pipe structure. The method of claim 1; The bandage installation step is a step of forming a ceramic coating material by mixing the epoxy resin, the curing agent and the ceramic powder by mixing in a mixing vessel; Injecting a bandage into the mixing vessel to impregnate the ceramic coating with the bandage; Contacting one end of the bandage impregnated with the ceramic coating material to a steel pipe structure from which foreign matter and deterioration are removed; Winding the close bandage to include a damaged portion of a steel pipe structure; Surface repair method of the underwater steel pipe structure using a bandage, characterized in that the step of fixing the end of the bandage with a pin. The method of claim 1 or 2; The ceramic coating material is a bisphenol-type epoxy resin (Diglycidyl ether of bisphenol) 50 to 80wt%, amine-based hardener 8 to 25wt%, ceramic powder 10 to 30wt%, the surface repair method of the underwater steel pipe structure using a bandage. The method of claim 3; Wherein the epoxy resin (Average degree of polymerization) 0.1 ~ 0.2, Epoxy equivalent (Epoxide equivalent) 180 ~ 210, Specific gravity 1.5 ~ 1.75 Surface repair method of the underwater steel pipe structure using a bandage.

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