JP4673125B2 - Covered arc welding rod - Google Patents

Description

  The present invention relates to a coated arc welding rod, and in particular, has excellent resistance to defects and maintains good corrosion resistance, while maintaining good welding workability and productivity, weather resistance, seawater resistance, sulfuric acid resistance and salt resistance. The present invention relates to a coated arc welding rod for acid steel.

  Weather resistant steel is a steel material (JIS G3114) that forms an excellent dense stable rust on the surface of the steel material, and this rust prevents the subsequent corrosion of the steel material. Weather-resistant steel is widely used as bridges, steel frames, and building exteriors. For this welding, a Cu-Cr-based or Cu-Cr-Ni-based weathered steel coated arc welding rod (JIS Z3214) is used. .

  In recent years, Cu—Ni-based steel materials have been developed as unpainted steel materials in areas where the amount of incoming sea salt particles is large, such as beach areas and areas where snow melting salt is sprayed. As a welding material for this steel material, for example, a Cu—Ni component-based coated arc welding rod adapted to the steel material component is used in Japanese Patent Application Laid-Open No. 2001-300769 (Patent Document 1).

  On the other hand, the sulfuric acid resistant steel material contains Cu alone or is made of Cu-Cr, so that it exhibits excellent corrosion resistance in an environment with insufficient sulfuric acid dew point generated in the smoke exhaust device of a heavy oil boiler plant. Arc welding rods have also been put into practical use in accordance with steel materials. In recent years, steel has been developed that exhibits excellent corrosion resistance in environments where low-temperature corrosion is caused by sulfuric acid and hydrochloric acid, such as flue and chimneys of coal-fired boilers and waste incineration facilities, that is, concentrated sulfuric acid and hydrochloric acid environments. For welding rods, for example, JP-A-2004-90044 (Patent Document 2) proposes a Cu—Sb system similar to steel.

However, in such coated arc welding rods for weather resistance, seawater resistance, sulfuric acid resistance and hydrochloric acid resistance steel, since Cu is the main component in accordance with the steel material components, solidification cracking, liquefaction cracking, etc. depending on welding conditions There is often a problem that this defect is likely to occur. In addition, there may be a microcrack that cannot be detected by the X-ray transmission test or the penetration flaw detection method, and a defect such as an opening may occur in the bending test of the welded joint. As a countermeasure, the effect can be seen by including Cu in the steel core wire, but the current situation is that the cost becomes a problem and is not practical. For this reason, the development of coated arc welding rods for weathering, seawater resistance, sulfuric acid resistance and hydrochloric acid resistance steel, which has excellent defect resistance and satisfactory performance while satisfying corrosion resistance, is strong. It was desired.
JP 2001-300769 A JP 2004-90044 A

  The present invention provides a coated arc welding rod for steel, which has excellent defect resistance, weather resistance, seawater resistance, sulfuric acid resistance and hydrochloric acid resistance, which is excellent in productivity while ensuring good corrosion resistance and welding workability. The purpose is to provide.

  As a result of various investigations in order to achieve such a goal, the present invention is a coated arc welding rod for weathering, seawater resistance, sulfuric acid resistance and hydrochloric acid resistance steel that has excellent defect resistance and can satisfy various performances. In order to obtain the above, it has been found that it is extremely effective to use a low melting point metal raw material conventionally added to the coating agent of the coated arc welding rod as a high melting temperature alloy powder.

That is, the gist of the present invention is that, in a coated arc welding rod in which a coating is coated on a core wire made of mild steel or low alloy steel, the liquidus temperature is 1150 to 1400 ° C. and the average particle size is 40 to 160 μm . Fe-Cu-based or Fe-Cu-Si-based Cu alloys containing 10 to 90% by mass of Cu are contained in the coating agent in an amount of 1.3 to 9.0% by mass. In addition to this, a Fe—Sb or Fe—Sb—Si based Sb alloy containing a liquidus temperature of 1100 to 1450 ° C. and an average particle diameter of 60 to 180 μm and containing 15 to 60 mass% of Sb is coated. It is a covered arc welding rod characterized by containing 0.3 to 2.5% by mass in the agent.

  According to the coated arc welding rod of the present invention, in the welding of weather resistance, seawater resistance, sulfuric acid resistance and hydrochloric acid resistance steel, welding workability is good and good corrosion resistance is maintained, and excellent defect resistance is achieved. The obtained weld metal can be secured, so that the welding efficiency and the quality of the welded portion can be improved.

  The present inventors have intensively studied means for improving a coated arc welding rod for weather resistance, seawater resistance, sulfuric acid resistance, and hydrochloric acid resistance steel, which has excellent resistance to defects while satisfying corrosion resistance and various performances.

  Cu, which is an indispensable component of these coated arc welding rods for steel materials, is mainly added with high-purity metal Cu powder in the coating, but since Cu has a low melting point (about 1080 ° C.), the solidification process of the weld metal Then, like S and the like, it may be concentrated and segregated at the austenite grain boundary, so that solidification cracking and liquefaction cracking are likely to occur. Therefore, the present inventors focused on the Cu addition method as a raw material of the coating agent, and if the alloy powder containing Cu has a high melting temperature, the solidification rate of Cu is increased during the solidification process of the weld metal, and the grain boundary It was thought that it was possible to prevent penetration into the steel and prevent weld cracking, and an attempt was made to apply a high melting temperature Cu alloy such as Fe—Cu—Si or Fe—Cu to the coating material.

  As a result, it has been found that a solidification start temperature when the temperature is lowered from the liquid phase, that is, a Cu alloy having a high liquidus temperature is effective for weld cracking, and the liquidus temperature is extremely important. Also, the average particle size of the Cu alloy is important along with the added amount. If the average particle size becomes excessively large, the flux fluidity deteriorates during the production of the coated arc welding rod, and the productivity deteriorates, and the average particle size is small. In this case, welding workability at the time of welding deteriorates.

  Furthermore, when Sb is used in a coated arc welding rod for sulfuric acid resistant and hydrochloric acid resistant steel, the melting point of metal Sb powder is low (630 ° C.), and segregates at the austenite grain boundaries of the weld metal to cause weld cracks. In view of the same idea as the Cu alloy, weld cracking can be prevented by using an Sb alloy having a high liquidus temperature such as Fe-Sb or Fe-Si-Sb. In addition, it has been found that the average particle diameter and the amount of addition greatly affect crack resistance and welding workability.

The present invention is described in detail below.
First, the following experiment was conducted in order to grasp the proper liquidus temperature of the Cu alloy in the coating agent. The Fe-Cu-Si-based and Fe-Cu-based 9 were previously measured for the liquidus temperature in the coating so as to contain 0.4% of the Cu content (substantially weld metal Cu content) in the total mass of the welding rod. A Cu alloy of a kind was used that was pulverized to an average particle size of 90 μm. Add the Cu alloy shown in Table 2 to the coating composition shown in Table 1, coat the steel core of JIS G3523 SWY11 with a diameter of 3.2 mm and a length of 350 mm so that the coverage is 30% by mass and dry. 9 types of welding rods were made. Further, Ni and Cr were contained in the coating so as to match the Ni and Cr contents of the steel plate symbol a shown in Table 3.

  For the test, a steel plate symbol a shown in Table 3 having a thickness of 12 mm, a width of 300 mm, and a length of 450 mm was used, and a downward joint welding with a backing groove with a V groove (gap of 6 mm) (current 140 A, heat input 12 kJ / cm). In the defect resistance investigation, a surface bending test (JIS Z3122) that can confirm even a minute defect is adopted, and the determination is repeated three times, and even if the defect is a defect of any length, three or less defects are considered good. .

  Welding workability was investigated by assembling a steel plate a having a thickness of 9 mm, a width of 100 mm, and a length of 450 mm as shown in Table 3 into a T-type, with horizontal fillet welding at a current of 140 A and vertical posture welding at 110 A. Welded, investigated the arc state, slag state, spatter generation state, bead shape, etc. The judgment was made by comprehensively evaluating the evaluation of each posture welding, and good was marked with ◯, slightly inferior with Δ, and inferior with x. The results obtained from the above tests are shown in Table 2 and FIG.

  As is clear from Table 2 and FIG. 1, the weld rod using the Cu alloy having a liquidus temperature of less than 1150 ° C. has many defects in the surface bending test, and the cross section of the opening fracture surface is analyzed by EPMA. As a result, segregation of Cu was observed. Further, when the liquidus temperature of the Cu alloy exceeded 1400 ° C., the amount of spatter was increased and the bead shape was also deteriorated, so that welding workability was deteriorated.

  From the above results, it is understood that the liquidus temperature of the Cu alloy in the coating should be 1150 to 1400 ° C. in order to obtain an excellent defect-resistant coated arc welding rod while satisfying welding workability. It was.

The reason for the action of the coating agent and the limitation of the component range in the present invention will be described below.
The liquidus temperature of the Cu alloy is the most important. By using Cu alloy powder having a reasonably high liquidus temperature such as Fe-Cu or Fe-Cu-Si, the solidification rate of Cu is increased. Can hardly penetrate into the grain boundary of the weld metal and can prevent micro defects such as liquefaction cracking, which is extremely effective in improving defect resistance. If the liquidus temperature of the Cu alloy is less than 1150 ° C., this effect cannot be exerted, and if it exceeds 1400 ° C., the arc state becomes worse, frequent spattering and deterioration of the bead shape are seen and welding workability is deteriorated. .

  The average particle size of the Cu alloy is important for ensuring good productivity and welding workability. If the average particle size is excessively large, the flowability of the flux deteriorates when the core wire is coated. Becomes defective. If the average particle size is less than 40 μm, the arc state is deteriorated and welding workability is deteriorated, and if it exceeds 160 μm, the productivity is deteriorated as described above. Further, if the Cu alloy coating content is less than 1.3% by mass, the Cu content in the weld metal decreases and corrosion resistance deteriorates. If it exceeds 9.0% by mass, the slag melting point increases. As a result, the solidification rate of the slag is increased, the bead shape is disturbed and the spatter is increased, and the welding workability is deteriorated. In addition, it is preferable that the quality of Cu alloy is 10 to 90% of Cu in an alloy such as Fe-Cu or Fe-Cu-Si.

  Furthermore, Sb added together with Cu in the coating of the coated arc welding rod used in sulfuric acid and hydrochloric acid resistant steels is also effective against solidification cracking and liquefaction cracking by applying an Sb alloy having a high liquidus temperature. It is. If the liquidus temperature is less than 1100 ° C., the effect is not observed, and if it exceeds 1450 ° C., the welding workability deteriorates as in the case of the Cu alloy. The average particle size of the Sb alloy needs to be limited in order to ensure good welding workability and productivity. If it is less than 60 μm, deterioration of the arc state and dry cracking during production occur, and if it exceeds 180 μm, spatter is scattered. This increases the workability of welding and the productivity. Further, if the content of the Sb alloy in the coating agent is less than 0.3%, satisfactory corrosion resistance cannot be obtained, and if it exceeds 2.5%, the solidification rate of the slag increases and the bead shape deteriorates. The quality of the Sb alloy is preferably that containing 15 to 60% of Sb in an alloy such as Fe—Sb or Fe—Sb—Si.

  The present invention is not limited to the type of the coated arc welding rod, but can be applied to any of non-low hydrogen systems such as illuminite, lime titania, and high iron oxide systems, and low hydrogen systems. The slag agent, arc stabilizer, deoxidizer, alloy agent, and fixing agent used for the coated arc welding rod of the present invention may be ordinary ones.

The invention is explained in more detail in the examples.
In the coating component of the coated arc welding rod shown in Table 4 (A is a low hydrogen type, B is a non-low hydrogen type), the average particle size of the Cu alloy shown in Table 2 and the content in the coating were changed. In addition, Ni and Cr were contained in the coating agent so as to match the Ni and Cr contents of the steel plate symbol a shown in Table 3.

  The coated arc welding rod is a JIS G3523 SWY11 steel core wire with a diameter of 3.2 mm and a length of 350 mm. The coated core welding wire is coated to a coating rate of 30% by mass and dried to produce a coated arc welding rod as shown in Table 5. We investigated defect resistance, welding workability, productivity and corrosion resistance.

  First, in order to investigate the defect resistance, a steel plate symbol a shown in Table 3 having a thickness of 12 mm, a width of 300 mm, and a length of 450 mm was used, and a downward joint with a backing metal with a V groove (gap 6 mm) was welded. Welding was performed at a current of 140 A and a heat input of 12 kJ / cm. For the evaluation, a surface bending test (JIS Z3122) was adopted, the determination was repeated three times, and no more than three defects were considered good regardless of the length of the defect.

  Welding workability is investigated by assembling a steel plate symbol a having a thickness of 9 mm, a width of 100 mm, and a length of 450 mm as shown in Table 3 into a T-shape, welding current conditions of 140 A for horizontal fillet welding and 110 A for vertical position welding. Welding was conducted, and the arc state, slag state, spatter generation state, bead shape, etc. were investigated. The productivity survey was conducted to investigate the fluidity of the extrusion flux of the coating machine.

  Further, in the corrosion resistance test, three pieces of the corrosion test pieces (thickness 4 mm, width 25 mm, length 50 mm) shown in FIG. The test piece was installed in a state inclined 30 ° outdoors facing south, and 5% by volume of salt water was sprayed once a week for an exposure test for 6 months. After the exposure test, the average thickness reduction amount of the weld metal part was measured, and 0.5 mm or less was considered good. These results are summarized in Table 5.

In Table 5, welding rod No. 1 to 6 are examples of the present invention, welding rod Nos. 7 to 12 are comparative examples.
The welding rod no. Nos. 1 to 6 are suitable results in productivity, welding workability, defect resistance and corrosion resistance because the liquidus temperature, average particle diameter, and content in the coating material of Cu alloy are appropriate. Met.

In the comparative example, the welding rod No. No. 7 had a large number of defects in the surface bending test because the liquidus temperature of the Cu alloy was low.
Welding rod no. In No. 8, since the liquidus temperature of the Cu alloy was high, the arc state was deteriorated, spatter was scattered frequently, the solidification rate of the slag was increased, and the bead shape was deteriorated.

Welding rod no. In No. 9, since the average particle size of the Cu alloy was small, the arc became weak and the welding workability and the welding workability deteriorated.
Welding rod no. In No. 10, the average particle size of the Cu alloy was large, so the fluidity deteriorated due to the extrusion of the coater flux, resulting in poor productivity.

Welding rod no. No. 11 had a low Cu alloy content, so the corrosion resistance was poor.
Welding rod no. No. 12 had a high Cu alloy content, so the melting temperature of the slag increased, the solidification rate of the slag increased, the bead shape was disturbed and the spatter was scattered, resulting in poor welding workability.

  In the coating component of the coated arc welding rod shown in Table 4 (A is a low hydrogen type, B is a non-low hydrogen type), the average particle size of the Sb alloy shown in Table 6 and the content in the coating were changed. In addition, 5 mass% of Cu alloys having a particle size of 90 μm of A6 in Table 2 were contained in the coating agent.

  The coated arc welding rod is a JIS G3523 SWY11 steel core wire with a diameter of 3.2 mm and a length of 350 mm. We investigated defect resistance, welding workability, productivity and corrosion resistance.

The examination of defect resistance and welding workability was carried out in the same manner as in Example 1 except that the steel plate symbol b shown in Table 3 was used.
The corrosion resistance test was performed by collecting three corrosion test pieces (thickness 4 mm, width 25 mm, length 50 mm) shown in FIG. 2 from the surface of the bead, and examining the defect resistance. Was immersed in a 10% hydrochloric acid solution at a temperature of 80 ° C. for 6 hours. The evaluation method is to measure the reduced thickness of the weld metal part due to corrosion and the reduced thickness of the base metal, and determine the ratio of the reduced thickness of the weld metal part to the reduced base metal thickness. did. These results are summarized in Table 7.

In Table 7, welding rod no. 13 to 17 are examples of the present invention, welding rod No. 18-23 are comparative examples.
The welding rod no. Nos. 13 to 18 are suitable results in productivity, welding workability, defect resistance and corrosion resistance because the liquidus temperature, average particle diameter, and content in the coating material of the Sb alloy are appropriate. Met.

In the comparative example, the welding rod No. No. 18 had a large number of defects in the surface bending test because the liquidus temperature of the Sb alloy was low.
Welding rod no. In No. 19, the liquidus temperature of the Sb alloy was high, so the arc state was deteriorated, spatter was scattered a lot, and the solidification rate of the slag was increased, so that the bead shape was deteriorated.

Welding rod no. In No. 20, since the average particle size of the Sb alloy was small, coating cracks occurred during production. In addition, the arc became weak during welding, and the welding workability also deteriorated.
Welding rod no. No. 21 was poor in productivity because the average particle size of the Sb alloy was large and the fluidity was deteriorated by extrusion of the coating machine flux. In addition, the amount of spatter generated during welding was large, and the workability was poor.

Welding rod no. No. 22 had a low Sb alloy content, so the corrosion resistance was poor.
Welding rod no. No. 23 had a high Sb alloy content, so the slag melting temperature increased, the slag solidification rate increased, the bead shape was disturbed, and the welding workability was poor.

It is a graph which shows the relationship between the liquidus temperature of Cu alloy, and the number of defects of a surface bending test. It is a figure which shows the collection position and dimension of a corrosion test piece.

Claims (2)

In a coated arc welding rod in which a coating agent is coated on a core wire made of mild steel or low alloy steel, the liquidus temperature is 1150 to 1400 ° C., the average particle size is 40 to 160 μm , and Cu is 10 to 90 mass%. A coated arc welding rod comprising 1.3 to 9.0% by mass of a Fe-Cu-based or Fe-Cu-Si-based Cu alloy in the coating agent. Further, an Fe—Sb-based or Fe—Sb—Si-based Sb alloy having a liquidus temperature of 1100 to 1450 ° C. and an average particle diameter of 60 to 180 μm and containing 15 to 60% by mass of Sb is 0 in the coating agent. The coated arc welding rod according to claim 1, wherein the content is 3 to 2.5% by mass.

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