KR20220090748A - Anti corrosion tape for repairing steel structures and manufaturing method thereof - Google Patents

Abstract

The present invention relates to a rust preventive tape for repairing a steel structure and a method for manufacturing the same, comprising an adhesive sheet providing adhesive strength, zinc (Zn) and a zinc magnesium alloy (Zn ₂ Mg, Zn ₁₁ Mg ₂ ), and an upper portion of the adhesive sheet It provides a rust-preventive tape for repairing a steel structure, comprising: a sacrificial anticorrosive layer coated on the sacrificial anticorrosive layer, and an external protective sheet attached to the upper portion of the sacrificial anticorrosive layer and protecting the sacrificial anticorrosive layer from external environmental factors.
According to the present invention as described above, the repair work can be completed only by cutting it into a certain size and attaching it to the corrosion-generating area, so repair work is sufficiently possible even in a narrow space, and therefore repair without replacing part or all of the structure As the work progresses, there is an effect that can greatly reduce the maintenance cost.

Description

Anti-corrosion tape for repairing steel structures and manufaturing method thereof

The present invention relates to a rust-preventive tape for repairing a steel structure and a method for manufacturing the same, and more particularly, by using a sacrificial anticorrosive layer, the corrosion resistance can be greatly improved, and the repair work of the corrosion-generating area can be easily performed even in a narrow space. It relates to a rust-preventive tape for repairing steel structures and a manufacturing method thereof.

In general, steel structures exposed to the external environment are oxidized by reaction with the atmosphere. In particular, in the case of coastal areas, oxidation is promoted due to salt in the air, and corrosion of steel structures and industrial plants proceeds rapidly.

In addition, with the advancement of technology and industrial growth, large steel structures and large industrial plants are increasing, and maintenance costs are continuously increasing.

On the other hand, in some areas, steel structures and industrial plants are used with anticorrosive treatment to minimize corrosion. .

Here, if we briefly look at the repair work in the corrosion-generating area, after removing all corrosion products from the corrosion-inducing area, electroplating, metal coating, painting, etc. are performed.

However, in order to perform the conventional anticorrosive treatment, special equipment is required, and since it takes a considerable amount of time to work, there is a problem in that the cost of the maintenance work is greatly increased.

Furthermore, there was a problem in that repair work was very difficult due to the problem that the access of workers and anticorrosive materials required for repair work was restricted depending on the shape and installation environment of the steel structure and industrial plant.

If the corrosion condition is left unattended due to this problem, the corrosion proceeds in the depth direction and can cause major accidents such as partial damage or collapse of the structure. There was a problem with this taking.

The present invention has been devised to solve the above problems, and an object of the present invention is to provide a rust preventive tape for repairing a steel structure that can easily perform repair work in a corrosion-generating area even in a narrow space and a method for manufacturing the same. have.

According to one aspect of the present invention for achieving the above object, it includes an adhesive sheet for providing adhesive strength, zinc (Zn) and a zinc magnesium alloy (Zn ₂ Mg, Zn ₁₁ Mg ₂ ), and on the adhesive sheet upper part It provides a rust-preventive tape for repairing a steel structure, comprising: a coated sacrificial anticorrosion layer;

In addition, the sacrificial anticorrosion layer preferably further includes a magnesium silicon alloy (Mg ₂ Si).

In addition, the adhesive sheet may be made of a material having conductivity so that the sacrificial anticorrosive layer is in electrical contact with the iron structure to be repaired, or at least one hole may be formed by perforating one side of the adhesive sheet.

On the other hand, preparing an adhesive sheet or an external protective sheet providing adhesive strength, preparing a mixture of zinc (Zn) and a zinc magnesium alloy (Zn ₂ Mg, Zn ₁₁ Mg ₂ ), and PVD the mixture Forming a sacrificial anticorrosive layer by coating either the upper surface of the adhesive sheet or the lower surface of the external protective sheet by an anticorrosive or wet coating method, and the outer protective layer or the adhesive sheet on the upper or lower portions of the sacrificial anticorrosive layer, respectively It provides a method of manufacturing a rust-preventive tape for steel structure repair, characterized in that it comprises the step of attaching.

And, in the step of preparing the mixture, a magnesium silicon alloy (Mg ₂ Si) is further included to prepare the mixture, wherein the mixture is 50 to 96% by weight of zinc (Zn) and 2 to 30% by weight of magnesium ( Mg) and 2 to 20% by weight of silicon (Si) is preferable.

According to the present invention as described above, the repair work can be completed only by cutting it into a certain size and attaching it to the corrosion-generating area, so repair work is sufficiently possible even in a narrow space, thereby repairing without replacing part or all of the structure. As the work progresses, there is an effect that can greatly reduce the maintenance cost.

1 is a perspective view of a rust preventive tape for repairing a steel structure according to an embodiment of the present invention;
2 is a cross-sectional view of an anti-rust tape for repairing a steel structure according to an embodiment of the present invention;
3 is a flowchart of a manufacturing method of a rust-preventing tape for repairing a steel structure according to an embodiment of the present invention.

Hereinafter, a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a perspective view of a rust preventive tape for repairing a steel structure according to an embodiment of the present invention, and FIG. 2 is a cross-sectional view of the antirust tape for repairing a steel structure according to an embodiment of the present invention.

As shown in FIGS. 1 to 2 , the rust-preventive tape 1 for repairing a steel structure according to an embodiment of the present invention includes an adhesive sheet 10 , a sacrificial anticorrosive layer 20 and an external protective sheet 30 . is composed

The adhesive sheet 10 provides adhesive force to attach the sacrificial anticorrosive layer 20 to the corrosion area, which will be described later. When attached to a steel material, it is preferable to use a butyl rubber adhesive to maintain the adhesive force for a long time. .

And, the adhesive sheet 10 is made of a material having conductivity or a material having voids so that the sacrificial corrosion protection layer 20 can be electrically contacted with the iron structure to be repaired, or by perforating one side to form at least one hole This may be used, which is to provide an electron movement path so that electrons generated while the sacrificial anticorrosion layer 20 to be described below is oxidized are in electrical contact with the base material to suppress oxidation of the base material.

The sacrificial anticorrosive layer 20 according to this embodiment is formed by coating a mixture of zinc (Zn) and a zinc magnesium alloy (Zn ₂ Mg, Zn ₁₁ Mg ₂ ) on the top surface of the adhesive sheet 10, at this time, the base material. In order to have the effect of the galvanic sacrificial method, the electrochemical potential value compared to iron must be designed to be at least 50mV lower.

Here, the sacrificial anticorrosive layer 20 may be formed by preparing the mixture in powder form and wet coating the mixed powder on the adhesive sheet, or depositing the mixed powder on the adhesive sheet by PVD method of a bulk alloy target.

In addition, as the zinc magnesium alloy, a Zn ₂ Mg alloy may be used, and a Zn ₁₁ Mg ₂ alloy may be used in order to obtain a better sacrificial anticorrosive effect.

Accordingly, the present applicant conducted the following experiment to find out whether the magnesium (Mg) content affects the corrosion result.

In this experiment, specimens with different magnesium content in zinc (Zn) were prepared and prepared through high-frequency vacuum melting, and after immersing these specimens in 5% saline for 30 days, the weight loss results were examined. It was found that the corrosion resistance of zinc magnesium having a magnesium content of 3 wt% to 16 wt% was excellent.

alloy manufacturing Zn content (wt.%) Mg content (wt.%) alloy phase Zn 99.99 Zn ZnMg1.5 98.49 1.51 Zn, Mg ₂ Zn11 ZnMg3 97.05 2.98 Zn, MgZn ₂ ZnMg6 94.03 5.97 Zn, MgZn ₂ ZnMg9 90.99 9.01 Zn, MgZn ₂ ZnMg12 88.04 11.96 Zn, MgZn ₂ ZnMg16 83.99 16.01 MgZn ₂ ZnMg32 67.98 32.02 MgZn

Zinc-magnesium alloy specimen manufactured through high-frequency vacuum melting

Corrosion test result of zinc magnesium alloy material for 30 days by immersion in 5% brine

On the other hand, the aforementioned sacrificial method (犧牲防蝕) means to protect the object by transferring electrons to the object to be protected in a process where the sacrificial method is first oxidized and consumed instead of the object to be protected.

Furthermore, the sacrificial anticorrosion layer 20 may be incorporated into a portion of the adhesive sheet 10 to further improve the white anticorrosion effect. At this time, when adding 20% or more of the mixed powder to the adhesive sheet 10 , the adhesive strength is lowered, so it is preferable to add less than 20% of the mixed powder when applied to the adhesive sheet 10 .

Looking at the reaction state of the sacrificial anticorrosive layer 20, the initial elution occurs preferentially on the zinc-magnesium alloy (Equation 1) to form cations of Mg and Zn, and the electrons present on the surface are Zn acting as a relative cathode. It is consumed through a cathodic reduction reaction (Equation 2) through bonding with O ₂ in the phase, and enables stable formation of initial corrosion products due to a local pH increase due to OH ⁻ formation.

MgZn ₂ → Mg ₂ + + 2Zn ²⁺ + 6 ^e- (Equation 1)

O ₂ + 4 ^e- + 2H ₂ O → 4OH- (Formula 2)

That is, Mg forms Mg(OH)2 to change ZnO into Simonkolleite, which is known as a dense corrosion product, and also forms MgO corrosion product, contributing to enhancing the thermodynamic stability of corrosion products generated in the sacrificial corrosion protection system In this way, the corrosion resistance is improved.

Meanwhile, in the process of preparing the mixture, magnesium silicon (Mg ₂ Si) may be further included. This magnesium silicon alloy (Mg2Si) forms SiO ₂ in the corrosion behavior to suppress the local corrosion reaction. However, if it is excessively added, it is quickly consumed in the sacrificial method, resulting in a problem of shortening the protective life.

Accordingly, the mixture according to this embodiment may be composed of 50 to 96 wt% of zinc (Zn), 2 to 20 wt% of magnesium (Mg), and 2 to 30 wt% of silicon (Si), and magnesium (Mg) In the case of the above, it can be mixed with other components in the form of an alloy.

The external protective sheet 30 is attached to the upper portion of the sacrificial anticorrosive layer 20 to protect the sacrificial anticorrosive layer 20 from external environmental factors, and is made of a material that has strong UV resistance and can block moisture and oxygen. it is preferable

Accordingly, the outer protective sheet 30 may be made of polyethylene or polypropylene material, and the sacrificial anticorrosive layer 20 can be sufficiently protected from external environmental factors and is not too thick for ease of use. It may be formed to a thickness of 0.1 to 3 mm to provide a.

3 is a flowchart of a manufacturing method of a rust-preventing tape 1 for repairing a steel structure according to an embodiment of the present invention.

The manufacturing method of the anti-rust tape 1 for repairing a steel structure according to an embodiment of the present invention will be described as follows.

In the following description, a mixture of zinc (Zn), zinc-magnesium alloy (Zn ₂ Mg, Zn ₁₁ Mg ₂ ) and magnesium silicon alloy (Mg ₂ Si) components will be described as the basis, and the method of forming the sacrificial anticorrosive layer 20 is The wet coating method will be described.

Prior to manufacturing the anti-corrosive tape 1 according to this embodiment, an adhesive sheet 10 providing adhesive strength and a PP film to be used for the external protective sheet 30 are prepared. (S10)

In this case, the adhesive sheet 10 may be formed of a material having conductivity or a material having voids, or at least one hole may be formed by perforating one side in the preparation process.

Next, a mixed powder is prepared by mixing the zinc (Zn) powder prepared in advance, zinc magnesium alloy (Zn ₂ Mg, Zn ₁₁ Mg ₂ ) powder and magnesium silicon alloy powder (Mg ₂ Si). (S20)

Here, as a result, the mixed powder may consist of 50 to 96 wt% of zinc (Zn), 2 to 20 wt% of magnesium (Mg), and 2 to 30 wt% of silicon (Si), and in this case, 0.1 μm to A powder having a size of 100 μm is used. The reason is that, in the case of zinc-magnesium alloy, cohesive energy is high, so that when using a powder of 0.1 μm or less, it is difficult to physically disperse.

The sacrificial anticorrosive layer 20 is formed by applying the mixed powder thus mixed on the adhesive sheet 10 by a wet coating method. (S30)

Thereafter, the anticorrosive tape 1 is manufactured by attaching a PP film, that is, an external protective layer, on the sacrificial anticorrosive layer 20 (S40).

Furthermore, the present applicant prepares a zinc powder specimen, a zinc + zinc magnesium alloy powder specimen and a zinc + zinc magnesium alloy + magnesium silicon powder specimen in order to test the corrosion protection efficiency of the sacrificial corrosion protection layer prepared as above, and applies the same to these specimens. The results were examined by applying the corrosion potential of iron as a condition, and the results of the potentiostatic corrosion test for this experiment are as follows.

Potential corrosion test result applying corrosion potential of iron

As can be seen from the above results, the density of corrosion products of the specimen containing zinc + magnesium alloy powder was significantly lower than that of the zinc specimen.

In addition, it was confirmed that the current density was lower in the result of performing a potential corrosion test by immersing a zinc-zinc-magnesium alloy + magnesium-silicon powder specimen in which a magnesium-silicon alloy (Mg ₂ Si) was added to a zinc-magnesium alloy in 5% saline. became It is analyzed that this is because the magnesium magnesium silicon alloy (Mg ₂ Si) forms SiO ₂ in the corrosion behavior and contributes to suppressing the corrosion reaction.

As such, the present embodiment has a feature that not only can significantly increase the corrosion reaction suppression efficiency of the object through the sacrificial anticorrosive layer, but also maximize the usability by applying it to the anti-rust tape, thereby greatly reducing the maintenance cost.

Although the present invention has been described with reference to the above-mentioned preferred embodiments, various modifications and variations are possible without departing from the spirit and scope of the invention. Accordingly, it is intended that the appended claims cover such modifications and variations as fall within the scope of the present invention.

10: adhesive sheet 20: sacrificial anticorrosive layer
30: outer protection sheet

Claims (5)

an adhesive sheet providing adhesive strength;
A sacrificial anticorrosive layer comprising zinc (Zn) and a zinc magnesium alloy (Zn ₂ Mg, Zn ₁₁ Mg ₂ ) and coated on the adhesive sheet;
Anti-rust tape for repairing a steel structure, characterized in that it is attached to the upper portion of the sacrificial anticorrosive layer and comprises an external protective sheet for protecting the sacrificial anticorrosive layer from external environmental factors.
According to claim 1,
The sacrificial anticorrosive layer is an antirust tape for repairing a steel structure, characterized in that it further comprises a magnesium silicon alloy (Mg ₂ Si).
3. The method of claim 2,
The adhesive sheet is made of a material having conductivity so that the sacrificial anticorrosion layer can be in electrical contact with the iron structure to be repaired, or one side is perforated to form at least one hole. .
Preparing an adhesive sheet or an external protective sheet to provide adhesive strength;
Preparing a mixture of zinc (Zn) and zinc magnesium alloy (Zn ₂ Mg, Zn ₁₁ Mg ₂ );
forming a sacrificial anticorrosive layer by coating the mixture on either the upper surface of the adhesive sheet or the lower surface of the external protective sheet by a PVD method or a wet coating method; and
A method of manufacturing a rust-preventive tape for repairing a steel structure, characterized in that it comprises the step of attaching the external protective layer or the adhesive sheet to the upper or lower portions of the sacrificial anticorrosive layer, respectively.
4. The method of claim 3,
In the step of preparing the mixture, it further comprises a magnesium silicon alloy (Mg ₂ Si) to prepare the mixture,
The mixture is 50 to 96% by weight of zinc (Zn), 2 to 30% by weight of magnesium (Mg), and 2 to 20% by weight of silicon (Si), characterized in that the manufacturing method of the anti-rust tape for repair.

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