JP6546112B2 - Gas shielded arc welding method and welded structural parts - Google Patents

Description

  The present invention relates to a gas shielded arc welding method and welded structural parts, particularly, a gas shielded arc welding method capable of improving the corrosion resistance of a joint portion at low cost and having high welding productivity, and a welded structure excellent in the corrosion resistance of the joint portion It relates to parts.

The gas shielded arc welding method used for welding construction of steel uses a gas such as CO ₂ , Ar, He, O ₂ , H ₂ etc. as a shielding gas for the melting portion, protects the molten metal from the atmosphere, and produces the arc material. It is a technique of melting and joining a filler material (welding rod or welding wire) or a base material. This welding method is widely used in the fields of manufacture of automobiles, buildings, bridges, electrical devices and the like. Among gas shield arc welding, fillet welding is often used for sheet metal welded structural parts such as underbody parts of automobiles.

However, even in the case of performing gas shielded arc welding, it is known that slag (an oxide such as Si or Mn) inevitably occurs around the weld bead in the weld. Since this chemical conversion film is not formed on the surface of this slag, there is a problem that the corrosion resistance of the joint portion is lowered, and the adhesion with the coating film is lowered.
In particular, when the above-described welded structural parts are used in a salt-damaged area in North America or Europe, rusting occurs in about one year, resulting in deterioration of the functions of the welded structural parts, and thus a technology for improving the corrosion resistance of the joint portion Development was desired.

Various techniques have been developed to solve such problems.
One of the techniques for improving the corrosion resistance of the joint portion is to improve the corrosion resistance of the base material. For example, a method of increasing a plate thickness to increase a rust allowance, a method of using a steel material having high corrosion resistance such as zinc-based plated steel as a base material, a method of applying a rust preventive wax to the base material, and the like are mentioned.

Furthermore, as another technique for improving the corrosion resistance of the joint portion, Patent Document 1 discloses a method of welding a zinc-based alloy plated steel sheet using a stainless-based welding wire. According to this method, the corrosion resistance of both the base metal and the weld metal can be improved, and as a result, the corrosion resistance of the joint portion can be improved.
Further, Patent Document 2 discloses a method of adjusting the contents of Si and Ti of a base material and the amount of oxidizing gas of a shield gas. According to this method, since the formation of slag at the weld bead end can be suppressed, the corrosion resistance of the joint portion can be improved.

JP, 2006-35293, A JP, 2012-213801, A

However, as for the technique for improving the corrosion resistance of the base material and the techniques disclosed in Patent Literatures 1 and 2, since the special base material, the weld metal, the shield gas, etc. are used for all, the bare steel members are welded to each other The cost increase could not be avoided compared to the case. Therefore, further improvement is desired in the point of manufacturing cost reduction.
Also, as in the technique disclosed in Patent Document 1, when welding galvanized steel sheets, although high corrosion resistance can be obtained, blow holes (spherical cavities generated in the weld bead) easily occur, and welding is performed. Further improvement was needed in terms of productivity.

  In view of such circumstances, the present invention provides a gas shielded arc welding method which is low cost and has high welding productivity and can improve the corrosion resistance of the joint portion, and a welded structure having excellent corrosion resistance of the joint portion obtained by the method. The purpose is to provide parts.

  The inventors of the present invention have conducted intensive studies on a gas shield arc welding method to solve the above problems, and as a result, using bare steel plates and zinc-based plated steel plates as base materials to be welded, these are superposed and fillet welded. By optimizing the inclination angle of the torch (advancing angle) with respect to the welding direction and the inclination angle of the torch (torch angle) with respect to the welding surface of the zinc-based plated steel sheet As a result of being able to concentrate the slag, it has been found that slag is generated at the end of the weld bead and the progress of the corrosion can be suppressed even when the corrosion occurs from the slag. Furthermore, in the present invention, since a bare steel plate is used as one of the steel plates to be welded, cost can be reduced and generation of blow holes can be suppressed as compared to the case where zinc-based plated steel plates are welded to each other. As a result, it was also found that it is possible to improve welding productivity.

The present invention has been made based on the above findings, and the summary thereof is as follows.
(1) A gas shielded arc welding method of fillet welding a bare steel plate and a zinc-based plated steel plate while supplying shielding gas, wherein the inclination of the torch with respect to the direction orthogonal to the welding direction at the time of the fillet welding By setting the angle (advancing angle) to 5 to 30 ° and the inclination angle (torch angle) of the torch to the welding surface of the zinc-based plated steel plate to 30 to 80 °, the slag generated on the welding bead portion is A gas shielded arc welding method characterized by concentrating on a zinc-based plated steel plate side.

(2) The gas shielded arc welding method according to (1), wherein the welding speed of the fillet welding is 400 to 1200 mm / min.

(3) The gas shielded arc welding method according to (1) or (2), wherein each of the bare steel plate and the zinc-based plated steel plate has a thickness of 1 to 4 mm.

(4) The shield gas is a mixed gas comprising an inert gas and an oxidizing gas, and the oxidizing gas comprises 5 to 20% by volume of CO ₂ and / or 1 to 5% by volume of O _2. The gas shielded arc welding method according to any one of the above (1) to (3), wherein the gas is supplied by an arc welding torch.

(5) A welded structural component obtained by the gas shielded arc welding method according to any one of (1) to (4) above, wherein the slag coverage of the weld bead portion on the bare steel plate side is 1%. A welded structural component, characterized in that the slag coverage of the weld bead on the side of the galvanized steel sheet is 15% or less.

  According to the present invention, it is possible to provide a gas shielded arc welding method which is low in cost and has high welding productivity and can improve the corrosion resistance of a joint portion. Furthermore, the welded structural component excellent in the corrosion resistance of the joint part obtained by the method can be provided.

It is the perspective view which showed typically one Embodiment by the gas shield arc welding method of this invention. FIG. 1 is a side view showing one embodiment of the gas shielded arc welding method of the present invention shown in FIG. 1 (a) viewed from a position opposite to the welding side of the bare steel plate, (b) along the welding direction It is the side view which showed the state seen from the other direction. (A) is a high-speed camera photograph showing a state where slag is generated and moved at the weld bead end during gas shielded arc welding, and (b) is formed at the weld bead end after gas shielded arc welding It is the photograph which expanded and showed the processed slag. It is the photograph after rust removal which showed the corrosion condition of the welding structural part welded by the gas shield arc welding method of this invention. It is the external appearance photograph after the corrosion test which showed the state after the rust resulting from slag generate | occur | produced about the arc-welded part of a bare steel plate and a galvannealed steel plate (GA steel plate), respectively.

The gas shielded arc welding method of the present invention will be specifically described with reference to the drawings as needed.
FIG. 1 is a view schematically showing an embodiment of the gas shielded arc welding method of the present invention.

(Gas shielded arc welding method)
The gas shield arc welding method of the present invention is a gas shield arc welding method of fillet welding a bare steel plate 2 and a zinc-based plated steel plate 1 while supplying a shielding gas as shown in FIG.

Here, in the gas shield arc welding, as shown in FIG. 1, the welding portion is shielded from air by a shielding gas, and the welding wire is melted (consumed by the arc plasma generated between the welding wire tip and the steel plate) ) Is a welding method that performs arc welding while In arc welding, when the molten metal is exposed to oxygen, nitrogen, water vapor, etc. in the atmosphere, the welding quality is deteriorated due to oxidation, nitridation, etc., and therefore, those used to shield these molten metals from the atmosphere Arc welding, which is shielding gas and uses shielding gas, is called gas shielded arc welding.
The fillet welding is a welding mode performed by a fillet joint (welded joint having a triangular cross section which welds two substantially orthogonal surfaces) as shown in FIG. Lap joints (welded joints in which a part of the base material is overlapped), T joints (welded joints where the end face of one plate is placed on the surface of the other plate so that the T shape is almost perpendicular), cruciform joints Welded joints), and welded joints such as corner joints (welded joints at the corners, which keep the two base materials substantially L-shaped at right angles).

  It does not specifically limit about the kind of bare steel plate used for the gas shielded arc welding method of this invention. For example, it is possible to use a pickled-descaled hot-rolled steel plate or strip, or a cold-rolled steel plate or strip obtained by cold rolling them. The conditions for the pretreatment step and the annealing step are not particularly limited, and any method can be adopted.

  Further, the zinc-based plated steel sheet used for the gas shielded arc welding method of the present invention is not particularly limited. For example, hot-dip galvanized steel sheet (GI) or alloyed hot-dip galvanized steel sheet (GA) obtained by alloying it, furthermore, hot-dip Zn-5 mass% Al alloy plated steel sheet (GF), hot-dip Zn-55 mass% Al alloy plating A steel plate (GL), an electrogalvanized steel plate (EG), an electrozinc-Ni alloy plated steel plate (Zn-11 mass% Ni), etc. are mentioned.

  And this invention makes the inclination angle (advancing angle (alpha)) of the torch 3 with respect to the direction Q orthogonal to the welding direction P at the time of the said fillet welding 5-30 degrees at the time of the said fillet welding, as shown in FIG. The weld bead portion 5 is concentrated on the end of the bare steel plate 2 by setting the inclination angle (torch angle β) of the torch 3 to the upper surface 1a of 1 to 30 to 80 °.

Here, FIG. 3A is an enlarged view of a welding portion at the time of gas shield arc welding. It can be seen from FIG. 3A that, at the time of gas shield arc welding, slag is produced at the end of the molten pool and moves in the direction opposite to the welding direction as the molten metal moves. Moreover, FIG.3 (b) shows that the moved slag is formed in the edge part of a weld bead after welding.
In addition, about formation of the slag in the edge part of the welding bead mentioned above (FIG.3 (b)), it is an unavoidable thing. As described above, since the slag does not form a chemical conversion film on the surface, it causes a problem that the corrosion resistance of the joint portion is reduced, and a problem that the adhesion with the coating film is reduced.

  Therefore, in the gas shield arc welding method of the present invention, adjustment of the advancing angle α and the torch angle β is carried out, and the bare steel plate and the zinc-based plated steel plate are fillet welded, and the welding slag is made of a zinc-based plated steel plate Concentratedly formed on the weld bead on 1 side. By collecting the slag formed in the weld bead portion 5 on the side of the zinc-based plated steel plate 1 having high corrosion resistance as much as possible, even if the slag is generated, high corrosion resistance can be achieved by the sacrificial corrosion protection effect of the zinc-based plated steel plate 1. Can be secured. Moreover, since the bare steel plate 2 without plating is used as one of the base materials, cost reduction can be achieved as compared with the case where zinc-based plated steel plates are used between each other, and many arc welding of zinc-based plated steel plates are performed. It can control also about a blowhole seen, and is excellent also in welding productivity.

  Here, FIG. 4 welds GA steel plate and a bare steel plate by fillet welding according to the gas shielded arc welding method of the present invention, and the obtained welded structural component is an environment where corrosion cycle (salt water spray → drying → wet is one cycle) State after leaving for a fixed period (350 cycles). Referring to FIG. 4, since the slag on the weld bead is formed concentrated on the GA steel plate side, it can be seen that a large amount of corrosion is also generated on the GA steel plate side. However, with regard to the corrosion seen on the GA steel plate side, although the rust is spread on the surface, it has not progressed to the inside of the steel plate due to the sacrificial corrosion protection by zinc.

  Moreover, FIG. 5 shows a state after rusting is generated from the slag portion, respectively, in the lap fillet welding of the bare steel plate and the galvanized hot-dip galvanized steel plate (GA steel plate). While bare steel sheet spreads and spreads on the surface and inside of the steel sheet starting from slag, GA steel sheet is only dotted with rust, and it is found that the growth to the inside of the steel sheet is small and corrosion resistance is excellent . Therefore, by collecting the slag on the zinc-based plated steel sheet side, even when the corrosion starts from the slag, it is possible to suppress the progress of the corrosion.

The advancing angle α is the angle of the torch 3 inclined with respect to the direction Q orthogonal to the welding direction P, as shown in FIG. 2 (a). Since the flow of the arc 4 generated from the tip of the torch 3 and the shielding gas can be controlled by setting the advancing angle α to 5 to 30 °, the flow of the surface of the molten metal (molten pool) at the welding portion can be controlled. It becomes possible to concentrate the upper floating slag on the zinc-based plated steel plate 1 side. When the advancing angle α exceeds 30 °, it is difficult to perform welding with high accuracy because the torch 3 is excessively inclined. On the other hand, when the advancing angle α is less than 5 °, The flow of molten metal can not be sufficiently controlled.
Further, the advancing angle α is set to 10 to 30 ° in that the flow of the molten metal can be controlled more accurately and the weld bead can be more surely concentrated on the galvanized steel sheet. Preferably, it is 10 to 20 °.

The torch angle β is an angle of the inclined torch 3 with respect to the upper surface (welding surface) 1 a of the galvanized steel sheet 1 as shown in FIG. 2 (b). By setting the torch angle β to 30 to 80 °, the flow of the surface of the molten metal at the welding portion can be controlled by the discharge of the arc 4 and the shield gas generated from the tip of the torch 3. It becomes possible to concentrate the formed slag part on the said zinc-based plated steel plate 1 side. If the torch angle β is less than 30 °, the inclination of the torch 3 is insufficient, so the flow of the molten metal can not be sufficiently controlled. On the other hand, if the torch angle β exceeds 80 ° Since the torch 3 is too inclined, it is difficult to perform welding with high accuracy.
Furthermore, the torch angle β can be set to 40 to 70 ° in that the flow of the molten metal can be controlled more accurately and the slag can be more reliably concentrated on the galvanized steel sheet. Preferably, it is more preferably 40 to 60 °.

  Further, the flow of the molten metal can be controlled by further adjusting the component posture of the welded structural part at the time of the fillet welding, and by performing the adjustment, the weld bead on the zinc-based plated steel plate can be more reliably The department can be concentrated. Here, the component posture refers to the inclination angle of the bare steel plate and the zinc-based plated steel plate.

The welding direction P is, as shown in FIG. 2A, a direction in which the torch 3 is advanced at the time of welding, and in the gas shielded arc welding method of the present invention, the tip of the torch 3 in the welding direction P. Adopt a forward method to advance toward the
Moreover, it is preferable that the said welding speed (speed which advances the said torch 3 to the welding direction P) is 400-1200 mm / min. This is because the flow of the molten metal can be controlled more accurately, and the weld bead can be more reliably concentrated on the zinc-based plated steel plate 1 side. If the welding speed is less than 400 mm / min, the welding speed may be too slow to perform efficient welding. On the other hand, if the welding speed exceeds 1200 mm / min, Since the welding speed is too fast, the flow of the molten metal may not be sufficiently controlled.

  Here, the plate thickness of the bare steel plate and the zinc-based plated steel plate used in the gas shield arc welding method of the present invention is not particularly limited, but is preferably 1 to 4 mm. When the plate thickness of the bare steel plate and the zinc-based plated steel plate is less than 1 mm, the rust margin decreases, so the life of the welded structural part when the corrosion progresses becomes short, while the bare steel plate and the zinc-based plating When the thickness of the steel plate exceeds 4 mm, although the life of the welded structural part becomes long, the cost of manufacturing will be increased.

  The torch 3 used for the gas shield arc welding has a wire-like welding metal and the shielding gas, and if necessary, the welding wire supply roll, the power supply contact, and the shielding gas nozzle Etc.

  In addition, the type of the welding wire is not particularly limited, and a known welding wire can be appropriately used. For example, it is preferable that the welding wire contains C, Si, Mn, and Ti from the viewpoint of obtaining better weldability.

Further, the shield gas is not particularly limited, and a known shield gas can be appropriately used. For example, from the viewpoint that the generation of the slag can be effectively suppressed, the shield gas is a mixed gas consisting of an inert gas and an oxidizing gas, and the oxidizing gas is 100% by volume of the shielding gas. Is preferably composed of 5 to 20% by volume of CO ₂ and / or 1 to 5% by volume of O ₂ so that the flow of the pre-molten metal can be controlled more accurately, and more reliably on the galvanized steel sheet. From the viewpoint of being able to concentrate the weld bead, it is preferable to supply the shield gas using a nozzle whose front end diameter is narrowed.

(Welded structural parts)
Next, the welded structural component of the present invention will be described.
The welded structural component targeted by the present invention is obtained by the gas shielded arc welding method described above.
The welded structural component of the present invention is characterized in that the slag coverage of the weld bead on the bare steel sheet is 1% or less, and the slag coverage of the weld bead on the zinc-based plated steel sheet is 15% or less I assume.

  Here, the slag coverage is the ratio of the slag area existing (coated) on the weld bead to the area of the entire weld bead, and the weld bead is divided into two along the weld line (on the galvanized steel sheet side) It can be calculated by dividing into a weld bead and a weld bead on the bare steel plate side, and multiplying the ratio of the slag area in each portion to the bead area by 100.

  In the welded structural component of the present invention, since the end portion of the weld bead portion is collected on the high corrosion resistant zinc-based plated steel plate side, generated slag is concentrated on the zinc-based plated steel plate side (the zinc-based plating) The slag coverage of the weld bead on the steel plate is increased). As a result, even when corrosion occurs from a portion of the slag, high corrosion resistance can be ensured by the sacrificial corrosion protection effect of the zinc-based plated steel sheet. In addition, since a bare steel plate without plating is used for one of the base materials, blow holes are suppressed as compared with a welded structural component formed by arc welding zinc-based plated steel plates.

  As described above, FIG. 4 shows a state after fillet welding of a GA steel plate and a bare steel plate by the gas shielded arc welding method of the present invention and leaving the obtained welded structural component in a corrosive environment for a certain period of time. Referring to FIG. 4, since the slag on the weld bead is formed concentrated on the GA steel plate side also in the joint portion, a large amount of corrosion is also generated on the GA steel plate side and the rust is spread on the surface, It can be seen that the inside of the steel plate has not progressed due to the sacrificial corrosion protection.

Furthermore, the welded structural component of the present invention can further be provided with a chemical conversion coating and / or a coating on its surface. By providing these films, better corrosion resistance can be realized.
In addition, about a kind of chemical conversion film and a coating film, limitation in particular is not carried out and a well-known thing can be used suitably.

  In addition, about the other structure of the welding structural component of this invention, it is the same as that of what was described in the gas shield arc welding method mentioned above.

Next, an embodiment of the present invention will be described.
(Samples 1 to 23)
As shown in Table 1, gas shield arc welding was performed under different conditions (base material condition, torch advancing angle, torch torch angle, welding speed, shield gas composition, slag coverage). The evaluation to be described later was performed on samples of welded joints which were fillet welded according to each condition.

(Evaluation of corrosion resistance)
For each sample, a corrosion test (a test in which an environment in which salt spray → drying → wet is one cycle) was repeated 200 cycles was performed.
The corrosion resistance was evaluated as x when the maximum corrosion depth in the weld after the corrosion test reached 25% or more of the thickness of the bare steel plate and as ○ when it was less than 25%.

From the results of Table 1, the slag on the weld bead is formed concentrated on the GA steel plate side and the formation of slag on the bare steel plate side is suppressed for Samples 1 to 15 of the example, and after the corrosion test The corrosion resistance all showed good results.
On the other hand, in the sample 16 of the comparative example, the corrosion resistance is deteriorated since the fillet welded joint of the bare steel plate and the bare steel plate is formed. Samples 17 to 21 of the comparative example are fillet welded joints of a plated steel plate and a bare steel plate, but since the advancing angle or the torch angle is set outside the optimum condition, the slag on the weld bead is concentrated on the GA steel plate side Not formed, but more than 1% formed on the bare steel plate side, and the corrosion resistance deteriorated. In the sample 22 of the comparative example, the amount of CO ₂ in the shield gas contains more than 20%, the amount of generation of slag on the weld bead increases, and the slag on the weld bead is concentrated on the GA steel plate side The corrosion resistance deteriorated because it could not be formed and was formed more than 1% on the bare steel plate side. In the sample 23 of the comparative example, since the welding speed is 1200 mm / min or more, the shielding property of the weld bead by the shield gas is deteriorated to increase the amount of generated slag on the weld bead, and the slag on the weld bead However, the corrosion resistance deteriorated because the steel plate was not formed concentrated on the GA steel plate side and was formed more than 1% on the bare steel plate side.

  According to the present invention, it is possible to provide a gas shielded arc welding method which is low in cost and has high welding productivity and can improve the corrosion resistance of a joint portion. Furthermore, according to the present invention, it is possible to provide a welded structural component which is excellent in corrosion resistance of the joint portion.

1 galvanized steel sheet 2 bare steel plate 3 torch 4 arc 5 weld bead portion P welding direction α forward angle β torch angle

Claims (5)

A gas shielded arc welding method of fillet welding a bare steel plate and a zinc-based plated steel plate while supplying a shielding gas,
The inclination angle (advancing angle) of the torch with respect to the direction orthogonal to the welding direction at the time of the fillet welding is 5 to 30 °, and the inclination angle (torch angle) of the torch to the welding surface of the galvanized steel sheet is 30 to 30 A gas shield arc welding method, characterized in that slag generated on a weld bead portion is concentrated on the side of the galvanized steel sheet by setting the angle to 80 °.   The gas shielded arc welding method according to claim 1, wherein a welding speed of the fillet welding is 400 to 1200 mm / min.   The gas shielded arc welding method according to claim 1 or 2, wherein each of the bare steel plate and the zinc-based plated steel plate has a thickness of 1 to 4 mm. The shielding gas is a mixed gas consisting of an inert gas and an oxidizing gas, the oxidizing gas consists of 5 to 20% by volume of CO ₂ and / or 1 to 5% by volume of O ₂ , and the shielding gas is an arc 4. A gas shielded arc welding method according to any one of the preceding claims, characterized in that it is supplied by a welding torch. A welded structural component obtained by the gas shielded arc welding method according to any one of claims 1 to 4,
The welded structural component, wherein a slag coverage of the weld bead on the bare steel sheet side is 1% or less, and a slag coverage of the weld bead on the zinc-based plated steel sheet side is 15% or less.