JP2010070851A - Hot-dip galvanized member superior in coatability by thermal spraying - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a hot-dip galvanized member superior in coatability by thermal spraying, and to provide a method for connecting steel members with each other by using the same. <P>SOLUTION: The member having a hot-dip galvanized film on a base steel material, wherein the hot-dip galvanized coating film contains 0.16 mass% or less of components of [Pb+Cd+Sn+Bi] in total. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a hot dip galvanized steel member excellent in adhesion of a thermal spray coating and the like and a joining structure of a steel member using the same.

In steel structures such as bridges and buildings, thermal spray coating is performed using a thermal spray material made of a Zn-Al-based or Al-Mg-based alloy for the purpose of long-term rust prevention of steel materials.
In the technical fields such as steel girders, thermal spray coating has been studied for the purpose of long-term rust prevention. Although the main body of the steel girders is formed with a thermal spray coating, the conventional hot-dip galvanized bolts are used at the joints of the girders. The long-term rust prevention of the part was insufficient.
The biggest reason is that, when a high-strength bolt is previously sprayed with an Al—Mg alloy or the like, relaxation due to the sprayed film occurs after tightening, and a reduction in the tightening axial force becomes a problem.
On the other hand, if thermal spray coating is performed after tightening with a conventional hot-dip galvanized high-strength bolt, the thermal spray coating peels off due to poor adhesion to the plating surface, and good thermal spray coating cannot be performed.

Japanese Patent Application Laid-Open No. 2006-37217 discloses a method of applying sand blasting to a ground portion of a hot-dip galvanized iron product, and then applying zinc thickly by thermal spraying.
However, there is still a problem in adhesion, and it cannot be applied to the above-mentioned joint portion.

JP 2006-37217 A

  An object of this invention is to provide the hot dip galvanized member excellent in thermal spray coating property, and the joining method of the steel member using the same.

In order to investigate why the thermal spray coating peels off when the conventional hot dip galvanized surface is coated with a thermal spray, the chemical components of the conventional hot dip galvanized coating were analyzed and investigated.
As a result, Pb: 1.0%, Cd: 0.12%, Sn: 0.054% and a relatively large amount of low melting point components are contained in mass%, and a surface analysis photograph thereof is shown in FIG.
Pb, Cd, and Sn do not form a compound with Zn, but are locally scattered in a high concentration state. Therefore, these low melting point components are gasified by heat during spraying, and the sprayed film is peeled off. It was estimated.

The present invention has been made from the above viewpoint, and a hot dip galvanized member excellent in thermal spray coating according to the present invention is a member obtained by subjecting a steel material to hot dip galvanization, [Pb + Cd + Sn + Bi] The total component amount is 0.16% by mass or less.
Of the low melting point components contained in the hot dip galvanized film, the Pb component is 0.008 mass% or less, the Cd component is 0.002 mass% or less, the Sn component is 0.002 mass% or less, and the Bi component is 0. It is preferably controlled to 15% by mass or less.
The low melting point component is a component that is gasified by a temperature rise when spraying using an Al—Mg alloy or Zn—Al alloy spray material, and is generally measured by differential scanning calorimetry (DSC measurement). A component that exhibits endothermic characteristics at 380 ° C. or lower.

The hot dip galvanizing with a low amount of the low melting point component has excellent adhesion even when sprayed thereon, and the surface coating structure of steel products with excellent rust prevention power according to the present invention has a Pb component. 0.008 mass% or less, Cd component is 0.002 mass% or less, Sn component is 0.002 mass% or less, Bi component is 0.15 mass% or less, and Al component is 0.001 to 0.1 mass%. , Galvanizing was applied to steel materials using a plating bath in which the Cu component was 0.005 to 0.4 mass% and the balance was Zn and inevitable impurities, and a thermal spray coating was formed thereon by thermal spraying. Features.
Thereby, after joining another steel member with the joining member which performed the said hot dip galvanization, the sprayed coating can also be formed by spraying the joining member.
It is preferable to lightly wipe the surface of the hot dip galvanizing with a solvent such as thinner before spraying, and it is desirable to perform a light blast treatment.
Furthermore, the primary rust prevention treatment by chemical conversion coating after blast treatment (short-term rust prevention treatment by chemical conversion coating) can maintain adhesion even if exposed outdoors before spraying, so spraying within a specified number of days after joining on site. It can be done and is excellent on site construction.

In the present invention, a low melting point component that exhibits endothermic characteristics at 380 ° C. or lower during hot dip galvanization is suppressed to a predetermined concentration or lower, so that gasification phenomenon is less likely to occur when spraying on it. A thermal spray coating structure is obtained.
Thereby, long-term rust prevention of a steel product and its junction part is attained.
Furthermore, if the primary rust prevention process (short-term rust prevention) by a chemical conversion film is performed after the said hot dip galvanization, generation | occurrence | production of the white rust by outdoor exposure to a plating surface can be suppressed.

The component table | surface of the hot dip galvanization used for evaluation is shown. Indicates the size of the test piece. The thermal spraying condition and evaluation method of a test piece are shown. An evaluation result is shown. The DSC measurement result is shown. The thermal spraying conditions evaluated are shown. The thermal spraying conditions and the evaluation results of the adhesion of the sprayed film are shown. The treatment conditions after plating and the evaluation conditions for the adhesion are shown. The adhesion evaluation result of the thermal spray film by the presence or absence of primary rust prevention treatment is shown. The result of investigating the influence of the outdoor exposure period is shown. The chemical composition in a plating film and the adhesion evaluation result of a thermal spray film are shown. The cross-sectional surface analysis result of the conventional hot dip galvanization is shown.

The contents of the present invention will be specifically described below based on examples.
A hot dip galvanizing bath having a composition as shown in FIG. 1 is used to hot dip galvanize an iron plate having a size as shown in FIG. 2 at a bath temperature of 450 ° C., and then, as shown in FIG. The thinner was wiped, and the left side was lightly air-blasted with Alundum # 60 (Sansho Abrasive Co., Ltd.).
The test piece is coated with a thermal spray film (pw thermal spraying) using an Al-5% Mg, φ1.6 thermal spray material, and the appearance evaluation and adhesion force measurement of the thermal spray film (Techno Tester R-2000D) Used).
The conditions are shown in a table in FIG. 3, and the measurement results are shown in FIG.
In FIG. 4, the measurement positions a, b, c, and d are the portions shown in FIG. 2, where a and b are in charge of the lightly blasted portion and c and d are in the thinner wiped portion.
TPNo. No. of plating bath. The film thickness of the sprayed film was determined by subtracting the film thickness of the plating film from the measured total film thickness.
In Comparative Example 1 (plated film shown in paragraph 0006) by conventional hot dip galvanization, the sprayed film peeled off, and the spraying itself could not be performed.
As a result, the product of the present invention had much less scorching during thermal spraying and repelling of the thermal spray coating as compared with the comparative example even with degreasing treatment only by thinner wiping.
However, NO. It became clear that 1 and 2 were not sufficient for degreasing alone, and it was preferable to lightly blast.
NO. Since a certain degree of adhesion is recognized even if only 3 and 4 are degreased, it is presumed that there is also an influence of the Cu component, which suppresses high-temperature oxidation, and NO. From FIG. 5, it was estimated that the Cu component was excessive at 0.5%.

Next, the results of differential scanning calorimetry (DSC measurement) of the hot dip galvanized film are shown in FIG.
FIG. 5A shows the NO. 4 and FIG. 5B corresponds to a comparative example.
As a result, in the present invention, no endothermic phenomenon due to the low melting point component was observed.

Next, the plating bath No. 1 shown in FIG. 4 was used to investigate the difference in adhesion depending on the thermal spraying condition using a test piece that had been subjected to hot dip galvanizing treatment with a film thickness of 45 to 55 μm.
The conditions are shown in the table of FIG.
In order to evaluate the adhesion of the sprayed coating by gas flame spraying, arc spraying, and plasma spraying after light blasting after hot dip galvanizing, a predetermined number of days after blasting is applied and then sprayed on site. It is assumed that
Therefore, for the purpose of promoting outdoor exposure, purified water was sprayed on a blasted plated plate with a spray spray, and the sample was left outdoors for 24 hours and was sprayed immediately after blasting.
The results are shown in the table of FIG.
It was revealed that the adhesion of purified water sprayed and allowed to stand outdoors for 24 hours may decrease.

Next, the treatment conditions before thermal spraying were investigated so that adhesion could be secured even after thermal spraying after outdoor exposure.
The processing conditions and the evaluation results of adhesion are shown in the table of FIG.
In the table, “plated plate specification” indicates the preparation conditions of the test piece before thermal spraying.
Plating bath no. 3 is No. 3 shown in the table of FIG. No. 3 plating bath was used, and this bath was added together with the addition of 0.15% by mass of the Bi component and evaluated.
Similarly, plating bath no. 4 is the plating bath No. in the table of FIG. 4 was used, and a comparative evaluation was made with this bath to which 0.2 mass% of the Bi component was added.
In the table, “with and without water cooling” was a comparative investigation of those that were water cooled after hot dip galvanizing and those that caused burns on the plating surface by air cooling.
In the table, “sandblasting + white rust prevention treatment” indicates that the surface of the plating was subjected to sandblasting by air injection and then immersed in a tannic acid aqueous solution having a concentration of about 0.1 to 1% to perform organic conversion coating treatment.
Therefore, in the table, “as it is” means that neither the sand blasting treatment nor the white rust prevention treatment is performed, and “sand blasting” means only the sand blasting treatment.
All of these test pieces were sprayed with purified water, and allowed to stand outdoors for 24 hours, followed by gas flame spraying using a sprayed material of Al-5% Mg alloy.
Considering the adhesion evaluation results shown in FIG. 8, water spraying without rust-proofing after hot dip galvanization, and adhesion is reduced if left outdoors for 24 hours. It became clear that the primary rust prevention treatment was good.
In addition, when sandblasting + white rust prevention treatment (primary rust prevention treatment), it was also clarified that the influence of the burn on the plating surface is reduced.
In addition, when Bi component is added, the influence on adhesion is small at Bi: 0.15%, but the adhesion of the sprayed coating is slightly lowered at Bi: 0.2%.

Next, the influence of the white rust prevention treatment (primary rust prevention treatment) on the adhesion of the sprayed film was investigated.
The conditions and evaluation results are shown in the table of FIG.
In the table, the presence or absence of a plating bath and a water cooling step in “plating specifications” is the same as in the table of FIG. 8. In the table, “E” in “white rust prevention treatment” is 0.1 to 1.0. % Tannic acid aqueous solution, and “C” indicates a chromate-treated chromate aqueous solution.
In the table of FIG. 9, each test piece is lightly air-blasted (average surface roughness Ra: 5 to 30 μm) using White Alundum # 24 (Sansho Abrasive Co., Ltd.) as the blasting material, and then Gas flame spraying of Al-5% Mg sprayed material was performed on the tannic acid treatment or chromate treatment and left outdoors for 24 hours after spraying with purified water.
As a result, it is clear that if the galvanizing treatment is lightly blasted after hot dip galvanization and the primary rust prevention treatment is performed with a chemical conversion coating, the adhesion of the sprayed film is excellent even after 24 hours exposure. Even if Bi: 0.15% is added to the plating bath, there is no problem in adhesion if the Pb component in the bath is 0.008% or less, the Cd component is 0.002% or less, and the Sn component is 0.002% or less. Became clear.

Now that the conditions for ensuring the adhesion of the thermal spray coating have been clarified, the effect of the outdoor exposure period was confirmed.
The conditions and evaluation results are shown in the table of FIG.
In the table, the outdoor exposure period indicates the number of days left outdoors after sprinkling of purified water, and other conditions are the same as those shown in the table of FIG.
As a result, no decrease in adhesion was observed even when left outdoors for 14 days after watering.
In addition, if the adhesive force is 3 MPa or more, there is no problem in practical use.

Since the treatment conditions after hot dip galvanization became clear by the previous tests and evaluation studies, the influence of the low melting point component in the hot dip galvanized film was re-investigated.
The chemical components in the plating film subjected to the investigation are shown in the table of FIG.
Each sample was left outdoors for 24 hours after hot-dip galvanizing, water cooling, sandblasting, primary rust prevention treatment (organic chemical conversion coating) with an aqueous tannic acid solution, and watering of purified water.
As a result, as shown in (b), the adhesion force measurement result corresponding to the sample number of (a) is controlled not only when the low melting point component is kept low and the Bi component is controlled to be 0.15% or less. When the component was suppressed to a level of 0.001%, the adhesion of the sprayed film did not decrease even when 0.15% of any other Pb, Cd, or Sn was added, so Pb, Cd, Sn It was confirmed that the adhesiveness of the sprayed film could be secured if the plating film had a total of Bi components suppressed to about 0.16% by mass or less.

Claims (5)

  A hot dip galvanized member excellent in thermal spraying coating, characterized in that the total amount of [Pb + Cd + Sn + Bi] in the hot dip galvanized coating is 0.16% by mass or less, which is a member obtained by subjecting a steel material to hot dip galvanizing .   A member obtained by subjecting a steel material to hot dip galvanization, and among the low melting point components contained in the hot dip galvanized film, the Pb component is 0.008% by mass or less, the Cd component is 0.002% by mass or less, and the Sn component Is a hot dip galvanized member excellent in thermal spray coating, characterized in that is controlled to 0.002 mass% or less and Bi component is controlled to 0.15 mass% or less.   The Pb component is 0.008% by mass or less, the Cd component is 0.002% by mass or less, the Sn component is 0.002% by mass or less, the Bi component is 0.15% by mass or less, and the Al component is 0.001 to 0.00%. 1% by mass, Cu component is 0.005 to 0.4% by mass, the remainder is hot dip galvanized on a steel material using a plating bath with Zn and inevitable impurities, and a thermal spray coating is formed thereon by thermal spraying A surface coating structure for steel products with excellent rust-proofing characteristics.   The Pb component is 0.008% by mass or less, the Cd component is 0.002% by mass or less, the Sn component is 0.002% by mass or less, the Bi component is 0.15% by mass or less, and the Al component is 0.001 to 0.00%. 1% by mass, Cu component is 0.005 to 0.4% by mass, and the balance is a galvanized hot-dip galvanized steel member using a plating bath with Zn and inevitable impurities. After that, a method for joining steel members, wherein a sprayed coating is formed on the joining member by thermal spraying.   5. The method for joining steel members according to claim 4, wherein the joining member subjected to hot dip galvanization is further subjected to blast treatment and then subjected to primary rust prevention treatment.