KR100573817B1 - A method for inhibition and prevention of corrosion of steel material by coating of spray-type pico water-soluble silica steel corrosion inhibitor PWSI and film protector composed of inorganic binder - Google Patents

Abstract

The present invention relates to a method for preventing and inhibiting corrosion of steel materials. More specifically, the Pico the soluble silica (SiO ₂ ^-) and then applying a corrosion inhibitor comprises a steel material to prevent steel material erosion formed by coating a solution consisting of a room temperature curing type nano-phase Si, Ti, Zr, etc., and suppressing method It is about.

According to the method for preventing and suppressing steel corrosion of the present invention, it not only prevents corrosion of the steel material but also gives a corrosion inhibiting effect of reacting with the rust film of the rusted steel to produce a protective film so that the corrosion does not proceed any further. Can be. In addition, it is easy to use because it can be applied by a simple coating method, it can be applied to the corrosion protection for the part that does not reach the flowable moisture, such as the box girder (steel box) or steel structure.

Anticorrosion, Corrosion Suppression, Si

Description

Coating method of inhibition-prevention and prevention of corrosion of steel material by coating of spray-type pico water-soluble silica steel corrosion inhibitor (PWSI) and film protector composed of inorganic binder}

FIG. 1 is a photograph after applying water to a specimen and a control specimen to which Pico water-soluble silica steel corrosion inhibitor (PWSI) is applied for 6 months.

Figure 2 is a photograph after applying the saline for 6 months to the PWSI applied specimens and control specimens.

Figure 3 is a photograph after applying the brine for 6 months to the rusty specimen of the PWSI applied rusty specimen and the control.

4 is a photograph comparing the progress of corrosion after leaving PWSI applied to only a portion of the rusty specimen.

Figure 5 is a photograph after leaving for more than one year without or without applying the PWSI to the zinc-plated zinc bolt.

Figure 6 is a photograph after being left for at least one year with or without applying the PWSI to the tin-plated clip.

The present invention relates to a method for preventing and inhibiting corrosion of steel materials. More specifically, the Pico the water-soluble silicate-ionic (SiO ₂ -) a corrosion inhibitor (Pico Water-soluble Silica steel corrosion Inhibitor; PWSI) with an aqueous solution of such a phase and then applied to the steel material, room temperature curing nano Si, Ti, Zr The present invention relates to a method for preventing and inhibiting corrosion of steel materials by applying an inorganic binder. The method is particularly useful for preventing and inhibiting corrosion of steel materials used in steel bridges.

Most steel is susceptible to corrosion in the atmosphere. Corrosion of such steel structures can be classified into six types according to the mechanism. Specifically, when water flows into a gap formed between the bolt and the connecting plate, and between the connecting plate and the structural member, the air contacts the outer surface and the inside of the gap. In the water, the oxygen concentration cell is formed due to the difference in the amount of dissolved oxygen, and the corrosion of the inner steel surface of the niche where the amount of oxygen is relatively charged with the anode is corroded (Crevice Corrosion); Dissimilar metal battery corrosion that occurs at relatively low potentials when galvanic cells are formed when there is a potential difference between bolts, connecting plates, and structural members of the bolt connection part; Galvanic corrosion occurring at the coating breakage portion when a potential difference occurs between the coating integrity and the coating breakage portion (or non-painting portion); When the bolts are loosened due to corrosion, stresses are concentrated in the bolt holders, and stress corrosion occurs due to such locally generated stresses (Stress Corrosion); Fatigue corrosion occurring in the cyclic stress section when a bolt column subjected to cyclic stress occurs; In the bridges to which snow calcium chloride is applied and steel structures in salt areas, the passivation film is damaged by Cl ^- ions, resulting in chloride corrosion.

Various corrosion prevention methods have been proposed to prevent corrosion of such steels. In general, a conventional corrosion prevention method includes a method of coating steel with paint or the like to block contact with corrosion factors such as water, air and chloride; A method of material designing the bolt portion to be a relative cathode; An electric method of supplying an anticorrosive current; And a method of alkalizing the surface of the steel to passivate it, but these methods have problems such as being ineffective, time-consuming, and inefficient, depending on the application site.

In addition, the conventional anti-corrosion methods, as can be seen in the term, is mostly limited to the method of preventing the corrosion of the steel material, and did not have the effect of inhibiting further corrosion when the corrosion has already occurred and rust occurs.

The present inventors have continued research to improve the problems of the conventional corrosion protection method, as a result of applying a pico-phase water-soluble silicate-based (pico-phase silica aqueous solution) corrosion inhibitor to the steel material to form a FeSiO ₂ protective film and a non-porous Si thin film Corrosion can be prevented and even when applied to rusted steel, it is confirmed that the rust film and the corrosion inhibitor react to form such films to further suppress corrosion. The present invention has been completed, which is a method capable of preventing and suppressing the present invention.

Until now, it has not been reported in the prior art that pico-phase water-soluble silicate-based corrosion inhibitors (pico-phase silica aqueous solution) can be used for corrosion prevention / suppression of steel.

An object of the present invention is a method of preventing and inhibiting corrosion of steel materials, and after applying a pico-phase water-soluble silicate-based corrosion inhibitor (pico-phase silica aqueous solution) to the steel material, the aqueous solution of room temperature-curable nano-phase Si, Ti, Zr, etc. It is to provide a method comprising applying an inorganic binder.

In addition, an object of the present invention is a method of forming a protective film on a steel material, consisting of applying a corrosion inhibitor made of pico-like silica aqueous solution to the steel material, wherein the protective film is FeSiO ₂ film layer formed by the reaction of the aqueous solution with iron or rust film It is to provide a method composed of a non-porous Si thin film.

According to the object of the present invention, by applying a corrosion inhibitor made of pico-phase silica aqueous solution to the steel material as a method of preventing and suppressing corrosion of the steel material, an inorganic binder made of an aqueous solution of room temperature-curable nano-phase Si, Ti, Zr, etc. A method consisting of applying is provided.

Corrosive inhibitors of pico water soluble silica are currently commercially available. Depending on the corrosion state of steel, the concentration of pico-phase silica aqueous solution (PWSI-1: 1 ~ 1.5%, PWSI-2: 2-4%, PWSI-3: 5-10%) and inorganic binder can be adjusted and used. .

When the pico-phase silica aqueous solution is applied to the steel, the iron or rust film and silicon react to form a FeSiO ₂ protective film according to the reaction of the following reaction formula,

Fe + Si + H ₂ O → FeSiO ₂

The Si thin film is formed on it. When the Si thin film is dried, it becomes a non-porous film and blocks contact with oxygen on the surface of steel, and when contacted with moisture, part of it dissolves and an alkalization reaction occurs. do.

FeSiO ₂ protection and the thickness of the Si thin film can be changed depending on the rust state, the coating method can be sprayed, brushed, immersed, the coating time is not limited. Each film drying time changes with temperature and humidity, but is usually within 10 minutes.

The aqueous solution of the inorganic binder room temperature-curable nanophase Si, Ti, and Zr is prepared by the Sol-Gel method, and its preparation method is also widely known to those skilled in the art, and is also commercially available. The film formed by applying the inorganic binder is nonporous and has a low oxygen permeability.

The specific role of the inorganic binder coating layer in the present invention is to protect the coating of the corrosion inhibitor.

According to the method for preventing and suppressing steel corrosion of the present invention, it not only prevents corrosion of the steel material, but also reacts with the rust film of the already rusted steel to produce a protective film, and also has a corrosion inhibiting effect of preventing the corrosion from further progressing. In addition, the application can be made in a simple coating method, so it is easy to use, and it can be applied to areas where fluid moisture does not reach, such as a box girder or steel structures, and at this time, it gives a semi-permanent surface protection effect. .

Hereinafter, the present invention will be described in more detail with reference to the following examples. However, the following examples are only for illustrating the present invention, and the scope of the present invention is not limited thereto.

Example

Example 1. Polarization Potential

Two steel specimens (100 mm long and 1 mm thick) were prepared, and one specimen was dried by brushing a pico-phase silica aqueous solution PWSI-1 (1 to 1.5% silica), a corrosion inhibitor of the present invention. The remaining specimens were used as controls without any treatment. In a container containing water, each specimen was connected to the (-) pole of the potentiometer and the reference electrode was connected to the (+) pole of the potentiometer, soaked, and then the potential was measured.

Table 1 . Measurement result

Psalter Potential (㎷ CSE)  Control specimen -650  Corrosion inhibitor coated specimen -750 ± 10

Example 2 Anticorrosive Performance Test

After the corrosion test, prepare control specimens with and without PWSI-1 (silica 1-1.5%) for steel structures, bolts, washers, etc. used in the bridge, and bring them into contact with normal water and brine (saturated water). Corrosion status was compared and analyzed. The experimental procedure is as follows.

Example 2-1. Water spray test

Place each specimen in a container, spray water so that the surface of the specimen is wet once a day for the first week, and once a week thereafter. After continuing the same method for six months, a photograph of the result is shown in FIG. 1. As can be seen in Figure 1, the control specimen was rusted, but not rusted PWSI-1 applied specimens at all.

Example 2-2. Salt water (saturated) spray test

Except for using brine, the conditions and methods of this test were the same as the above water spray test, and the result is shown in FIG. As can be seen in Figure 2, the control specimen was much rust, but the PWSI-1 applied specimen was not rust at all.

Example 2-3. Rusty specimen immersion test

In this experiment, two rusty steel specimens (horizontal, 100 mm long and 1 mm thick) were prepared and one was applied with PWSI-1 and the other was used as a control specimen without PWSI. The brine spraying conditions and methods were performed in the same manner as in Example 2-1, and the results are shown in FIG. 3. As can be seen in Figure 3, comparing the progress of corrosion between the two specimens, while the rust progressed very much in the control specimens, the PWSI applied specimens were no longer rust.

Example 2-4. Rusty specimen neglect test

After rusting pipe (length: 15 cm, diameter: 5.0 cm, thickness: 0.4 cm) after applying PWSI to only half of the specimen, the specimen was left in the air for 6 months, and the results are shown in FIG. 4. As can be seen in Figure 4, it can be seen that the area is no longer rust in the PWSI applied.

Example 2-5. Anti-corrosion test of zinc-plated bolts and nuts

PWSI was applied to galvanized bolts and nuts to prepare the test specimens, and zinc molten plated bolts and nuts without PWSI were prepared as controls. The two types of specimens were immersed in saturated saline and exposed to the same conditions, and then left for at least 1 year to confirm the progress of corrosion. As a result, the photograph is shown in FIG. As a result of this experiment, it can be confirmed that rusty in the control, but also in the area where PWSI was applied.

Example 2-6. Corrosion test of tin plated clips

Except for using the tinned clip was carried out in the same manner as in Example 2-5, the results are shown in FIG. As a result of this experiment, it can be seen that the rusty on the control clip is visible, but not on the clip with PWSI.

According to the method for preventing and suppressing steel corrosion of the present invention, it not only prevents corrosion of the steel material but also gives a corrosion inhibiting effect of reacting with the rust film of the rusted steel to produce a protective film so that the corrosion does not proceed any further. Can be. In addition, it is easy to use because it can be applied by a simple coating method, it can be widely applied to the part that does not reach the flowable moisture, such as steel bridge box girder or the inside of the steel structure such as the ventilation pipe.

Claims (2)

A method of preventing and suppressing corrosion of a steel material, comprising applying a pico-phase silica aqueous solution to a steel material and then applying an aqueous solution of room temperature-curable nano-phase Si, Ti, or Zr. The method of claim 1 wherein the steel is rusted steel.

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