JP5898238B2 - Arc welding method and plasma torch - Google Patents

Description

  The present invention relates to an arc welding method and a plasma torch. Specifically, the present invention relates to an arc welding method and a plasma torch used for plasma arc welding.

Conventionally, plasma arc welding is known. A plasma torch is used for plasma arc welding. Examples of plasma torches include those described in Patent Documents 1 and 2.
The plasma torch described in Patent Document 1 includes a center electrode for generating an arc and a nozzle that surrounds the center electrode and ejects a working gas for plasma formation, and at least the tip of the center electrode and the nozzle The jet outlet is formed in an elongated shape in a direction substantially perpendicular to the longitudinal axis direction of the center electrode.
In addition, the plasma torch described in Patent Document 2 uses a main nozzle provided at the tip of the welding torch to flow a first gas (shield gas) that protects the molten pool from the atmosphere, and at the outside of the welding torch. A second gas (plasma gas) having a composition different from that of the first gas is injected toward the arc portion formed at the tip of the welding torch using one or a plurality of external nozzles provided in .

JP 2008-284580 A JP 2005-177822 A

  Here, when plasma arc welding is performed on a galvanized steel sheet, fumes are generated due to evaporation of galvanizing at a high temperature. At this time, convection of the fume occurs between the shield gas and the plasma gas, the fume adheres to the tip surface of the nozzle, and the fume and the metal on the tip surface of the nozzle combine to form an alloyed layer. Since the alloying layer has a low melting point, the nozzle is easily consumed, and the weld quality may not be stabilized due to the nozzle damage. In addition, the durability of the nozzle also decreases due to the formation of the alloying layer.

  The present invention is for solving the above problems, and its purpose is to prevent convection fumes generated by evaporation of galvanizing at a high temperature inside the shield gas from adhering to the tip surface of the nozzle, The purpose is to stabilize the welding quality and suppress the deterioration of the durability of the nozzle.

( 1 ) A plasma torch (for example, plasma torch 1 described later) used for plasma arc welding, which is provided around a rod-shaped electrode (for example, electrode 10 described later) and the electrode, and a plasma gas (for example, A cylindrical first nozzle (for example, a later-described first nozzle 11) that ejects a plasma gas PG (to be described later) and a shield gas (for example, to be described later) provided around the first nozzle and surrounding the plasma gas. A cylindrical second nozzle (for example, a second nozzle 12 described later) for ejecting the shield gas SG) in an annular shape, and a non-circular shape toward the tip surface of the first nozzle inside the shield gas ejected in an annular shape. active gas (e.g., inert gas FG below) and the third nozzle for ejecting a (e.g., the third nozzle 13 to be described later), wherein the third nozzle, wherein the inert gas It is ejected so as to be a gas flow parallel to the tip surface of the nozzle, and is arranged evenly spaced in the circumferential direction inside the shield gas ejected in an annular shape from the circumferential direction of the second nozzle. A characteristic plasma torch.

According to the invention of ( 1 ), the inert gas is jetted toward the tip surface of the first nozzle inside the shield gas jetted in an annular shape from the third nozzle toward the workpiece, and the inert gas layer is formed. It is formed.
This prevents fume that is generated by the galvanization of the zinc gas from evaporating at a high temperature inside the shield gas from adhering to the tip surface of the first nozzle by the inert gas layer. Therefore, it can suppress that a fume adheres to the front end surface of a 1st nozzle, a fume and the metal of the front end surface of a 1st nozzle combine, and an alloying layer is formed.
Further, since the inert gas is ejected toward the tip surface of the first nozzle inside the shield gas ejected in an annular shape from the third nozzle toward the workpiece, the inert gas interferes with the shield gas. There is no.
Therefore, the first nozzle is hardly consumed and the welding quality can be stabilized, and the formation of the alloyed layer can be suppressed to suppress the decrease in the durability of the nozzle.
In addition, the inert gas ejected from the third nozzle becomes a gas flow parallel to the tip surface of the first nozzle, and an inert gas layer is formed. The gas flow parallel to the tip surface of the first nozzle of the inert gas is a stable flow along the surface to be protected without being reflected by the tip surface of the first nozzle on the front surface of the tip surface of the first nozzle. Thus, a stable inert gas layer can be formed. Thereby, it can prevent that the fumes which generate | occur | produce by galvanization evaporating at high temperature inside shield gas, and adhere to the front end surface of a 1st nozzle by the layer of an inert gas can be prevented.
Furthermore, in order to form an inert gas layer so as to cover the tip surface of the first nozzle evenly for each of the third nozzles that are equally spaced in the circumferential direction, The inert gas ejected can form a stable inert gas layer covering the entire front end surface of the first nozzle. Thereby, it can prevent that the fumes which generate | occur | produce by galvanization evaporating at high temperature inside shield gas, and adhere to the front end surface of a 1st nozzle by the layer of an inert gas can be prevented.

( 2 ) The plasma torch according to ( 1 ), wherein the same gas as the shield gas is used as the inert gas ejected from the third nozzle.

According to the invention of ( 2 ), since the same gas as the shielding gas is used as the inert gas, it is not necessary to prepare many kinds of gases, and the cost can be reduced.

  According to the present invention, it is possible to prevent the convection fumes generated by evaporation of zinc plating at a high temperature inside the shielding gas from adhering to the tip surface of the nozzle, and to stabilize the welding quality and the durability of the nozzle. Reduction can be suppressed.

It is a schematic diagram which shows schematic structure of the plasma torch concerning the 1st Embodiment of this invention, (a) is a side sectional view, (b) is a bottom view. It is the schematic which shows the state which the fume generate | occur | produced in the plasma torch of the prior art. It is the schematic which shows the formation state of the layer of the inert gas which concerns on the said embodiment. It is a schematic diagram which shows schematic structure of the plasma torch relevant to this invention.

  Embodiments of the present invention will be described below with reference to the drawings.

(First embodiment)
FIG. 1 is a schematic diagram showing a schematic configuration of a plasma torch 1 according to the first embodiment of the present invention, in which (a) is a side sectional view and (b) is a bottom view.
The plasma torch 1 is provided around the electrode 10, a cylindrical first nozzle 11 that is provided around the electrode 10 and ejects the plasma gas PG, and is provided around the first nozzle 11 to eject the shield gas SG. The cylindrical 2nd nozzle 12 and the 3rd nozzle 13 which injects the inert gas FG toward the front end surface 11c of the 1st nozzle 11 inside the shield gas SG injected circularly are provided.

  The first nozzle 11 is a cylindrical member and accommodates the rod-shaped electrode 10, and has a center hole 11 a having a diameter reduced in accordance with the tip of the electrode 10. A spout 11b is formed at the tip of the center hole 11a. Plasma gas PG is ejected from the ejection port 11b. A front end surface 11c of the first nozzle 11 having a flat annular surface is formed around the ejection port 11b that ejects the plasma gas PG.

  The second nozzle 12 is a cylindrical member, surrounds the first nozzle 11, and accommodates the first nozzle 11 in the center hole 12a thereof. The second nozzle 12 is provided so as to recede from the tip portion 11 d having the tip surface 11 c of the first nozzle 11, and the tip portion 11 d of the first nozzle 11 protrudes from the second nozzle 12. The tip portion 11d of the first nozzle 11 projects with a reduced diameter toward the tip inside the jet nozzle 12b. An annular jet 12 b is formed between the outer periphery before reaching the tip 11 d of the first nozzle 11 and the inner periphery of the second nozzle 12. The shield gas SG supplied through the gap between the outer periphery of the first nozzle 11 and the inner periphery of the second nozzle 12 is ejected from the annular ejection port 12b.

Unlike the first nozzle 11 and the second nozzle 12, the third nozzle 13 has a small diameter, and in the circumferential direction from the outer side to the inner side of the shield gas SG ejected in an annular shape from the circumferential direction of the second nozzle 12. Four are equally spaced apart. That is, each of the third nozzles 13 extends away from the outer peripheral side of the second nozzle 12 by 90 ° in the circumferential direction, and as shown in FIG. And bent in the inner diameter direction. From the third nozzle 13 bent in the inner diameter direction, the inert gas FG is ejected so as to form a gas flow parallel to the tip surface 11 c of the first nozzle 11.
Note that the same gas as the shield gas SG is preferably used as the inert gas FG ejected from the third nozzle 13.

  Next, plasma arc welding using the plasma torch 1 will be described with reference to FIGS. In plasma arc welding, a tailored blank material is formed by butt welding a first workpiece, which is a thin plate material, and a second workpiece, which is a plate material, which is thicker than the first workpiece. As the first and second workpieces, galvanized steel sheets or the like are used.

First, the plasma gas PG (arc) generated by receiving the discharge of the energized electrode 10 is ejected from the ejection port 11b of the first nozzle 11, and this plasma gas PG is supplied to the first and second workpieces.
At the same time, the shield gas SG is ejected in an annular shape from the ejection port 12b of the second nozzle 12 toward the first and second workpieces so as to surround the periphery of the plasma gas PG. The shield gas SG flows along the outer peripheral surface of the plasma gas PG while spreading in a direction away from the plasma gas PG, and is sprayed so as to be dispersed in the outer diameter direction with respect to the surface of the molten pool.
This prevents the plasma gas PG from contacting the atmosphere outside the shield gas SG.

At this time, when plasma arc welding is performed on the first and second workpieces using the galvanized steel sheet, fume HG is generated due to evaporation of the zinc plating at a high temperature.
FIG. 2 is a schematic diagram showing a state in which fume HG is generated in the plasma torch 100 of the prior art. As shown in FIG. 2, convection of the fume HG occurs between the shield gas SG and the plasma gas PG, so that the fume HG adheres to the tip surface 111 c of the first nozzle 111 and the fume HG and the first nozzle 111 In some cases, the alloyed layer is formed by combining with the metal of the front end surface 111c.
If the alloyed layer is formed, the first nozzle 111 is easily consumed because the alloyed layer has a low melting point, and the weld quality may not be stabilized due to damage of the first nozzle 111. Moreover, durability of the 1st nozzle 111 may also fall by alloying layer formation.

Therefore, in the present embodiment, an inert gas FG using the same gas as the shield gas SG is ejected from the third nozzle 13. The third nozzle 13 ejects the inert gas FG so as to form a gas flow parallel to the tip surface 11 c of the first nozzle 11, and the four third nozzles 13 are on the circumference of the second nozzle 12. Inert gas FG is ejected from four spaced apart directions. Accordingly, the gas flow of the inert gas FG parallel to the tip surface 11c of the first nozzle 11 is protected on the front surface of the tip surface 11c of the first nozzle 11 without being reflected by the tip surface of the first nozzle 11. A stable flow along the power surface is formed, and a stable inert gas FG layer is formed. Further, the inert gas FG ejected from each third nozzle 13 can equally cover and cover the front end surface 11 c of the first nozzle 11, and the four third nozzles 13 have the front end surface of the first nozzle 11. A stable inert gas FG layer covering the entire surface of 11c is formed.
FIG. 3 is a schematic view showing a state of forming the layer of the inert gas FG according to the present embodiment. As shown in FIG. 3, the fume HG generated and convected inside the shield gas SG is prevented from adhering to the tip surface 11c of the first nozzle 11 by the layer of the inert gas FG.
Therefore, it can suppress that the fume HG adheres to the front end surface 11c of the 1st nozzle 11, the fume HG and the metal of the front end surface 11c of the 1st nozzle 11 combine, and an alloying layer is formed. Therefore, the first nozzle 11 is not easily consumed, the welding quality can be stabilized, and the formation of the alloyed layer is suppressed, so that a decrease in durability of the first nozzle 11 can be suppressed.
The inert gas FG, which forms a stable inert gas FG layer covering the entire front end surface 11c of the first nozzle 11, becomes a swirl flow between the shield gas SG and the plasma gas PG.

According to the above embodiment, there exist the following effects.
(1) According to the present embodiment, the inert gas FG is applied to the tip surface 11c of the first nozzle 11 inside the shield gas SG that is ejected in an annular shape from the third nozzle 13 toward the first and second workpieces. A layer of inert gas FG is sprayed in parallel to form the front surface of the tip surface 11 c of the first nozzle 11.
This prevents fume HG generated by the evaporation of zinc plating at a high temperature inside shield gas SG from adhering to tip surface 11c of first nozzle 11 due to the layer of inert gas FG. . Therefore, it can suppress that the fume HG adheres to the front end surface 11c of the 1st nozzle 11, and the fume HG and the metal of the front end surface 11c of the 1st nozzle 11 combine, and an alloying layer is formed.
Further, the inert gas FG is blown in parallel with the tip surface 11c of the first nozzle 11 inside the shield gas SG that is ejected in an annular shape from the third nozzle 13 toward the first and second workpieces. The active gas FG does not interfere with the shield gas SG.
Therefore, the first nozzle 11 is not easily consumed, the welding quality can be stabilized, and the formation of the alloyed layer is suppressed, so that a decrease in durability of the first nozzle 11 can be suppressed.

  (2) According to this embodiment, since the same gas as the shield gas SG is used as the inert gas FG, it is not necessary to prepare many kinds of gases, and the cost can be reduced.

  (3) According to the present embodiment, the inert gas FG ejected from the third nozzle 13 becomes a gas flow parallel to the tip surface 11c of the first nozzle 11, and forms a layer of the inert gas FG. The gas flow of the inert gas FG parallel to the front end surface 11c of the first nozzle 11 is on the front surface of the front end surface 11c of the first nozzle 11 so that the gas flow is not reflected by the front end surface of the first nozzle 11 and should be protected. Therefore, a stable inert gas FG layer can be formed. Thereby, it can prevent that the fumes HG which generate | occur | produces when zinc plating evaporates at high temperature inside shield gas SG, and adheres to the front end surface 11c of the 1st nozzle 11 with the layer of the inert gas FG.

  (4) According to the present embodiment, the tip surface 11c of the first nozzle 11 is evenly shared and covered for each of the three third nozzles 13 that are equally spaced in the circumferential direction. In order to form the gas layer, the inert gas FG ejected from the four arranged third nozzles 13 can form a stable inert gas FG layer covering the entire front end surface 11 c of the first nozzle 11. Thereby, it can prevent that the fumes HG which generate | occur | produces when zinc plating evaporates at high temperature inside shield gas SG, and adheres to the front end surface 11c of the 1st nozzle 11 with the layer of the inert gas FG.

( Plasma torch related to the present invention )
FIG. 4 is a schematic diagram showing a schematic configuration of a plasma torch 1a related to the present invention.
The plasma torch 1a includes a rod-shaped electrode 10, a cylindrical first nozzle 11 that is provided around the electrode 10 and ejects the plasma gas PG, and is provided around the first nozzle 11 so as to surround the plasma gas PG. A second nozzle having a first jet port 12c for jetting the shield gas SG in an annular shape in the axial direction and a second jet port 12d for jetting the shield gas SG in the inner diameter direction toward the tip surface 11c of the first nozzle 11. And comprising.

  The first nozzle 11 is a cylindrical member and accommodates the rod-shaped electrode 10, and has a center hole 11 a having a diameter reduced in accordance with the tip of the electrode 10. A spout 11b is formed at the tip of the center hole 11a. Plasma gas PG is ejected from the ejection port 11b. A front end surface 11c of the first nozzle 11 is formed around the ejection port 11b that ejects the plasma gas PG.

The second nozzle 12 is a cylindrical member, surrounds the first nozzle 11, and accommodates the first nozzle 11 in the center hole 12a thereof. The second nozzle 12 is provided so as to recede from the tip portion 11 d having the tip surface 11 c of the first nozzle 11, and the tip portion 11 d of the first nozzle 11 protrudes from the second nozzle 12. The shield gas SG is supplied through a gap between the outer periphery before reaching the tip 11d of the first nozzle 11 and the inner periphery of the second nozzle.
The second nozzle 12 includes a plurality of first jet nozzles 12c that are opened in the axial direction at positions retracted from the tip portion 11d having the tip surface 11c of the first nozzle 11, and the first nozzle 11 through the first jet nozzle 12c. And a second jet port 12d that surrounds the tip portion 11d with a cover portion 12e and opens at the position of the tip surface 11c of the first nozzle 11 in the inner diameter direction. The shield gas SG is divided into a plurality of first outlets 12c that are opened in the axial direction and a second outlet 12d that is opened all around in the inner diameter direction, and is annularly formed in the axial direction from the first outlet 12c. It is ejected and ejected in the inner diameter direction from the second ejection port 12d.

  Next, plasma arc welding using the plasma torch 1a will be described with reference to FIGS. In plasma arc welding, a tailored blank material is formed by butt welding a first workpiece, which is a thin plate material, and a second workpiece, which is a plate material, which is thicker than the first workpiece. As the first and second workpieces, galvanized steel sheets or the like are used.

First, the plasma gas PG generated by receiving the discharge of the energized electrode 10 is ejected from the ejection port 11b of the first nozzle 11, and this plasma gas PG is supplied to the first and second workpieces.
At the same time, the shield gas SG is ejected in an annular shape from the first ejection port 12c of the second nozzle 12 toward the first and second workpieces so as to surround the periphery of the plasma gas PG. The shield gas SG ejected from the first ejection port 12c flows along the outer peripheral surface of the plasma gas PG while spreading in a direction away from the plasma gas PG, and is dispersed in the outer diameter direction with respect to the surface of the molten pool. Be sprayed.
This prevents the plasma gas PG from coming into contact with the atmosphere outside the shield gas SG ejected from the ejection port 11b.

At this time, when plasma arc welding is performed on the first and second workpieces using the galvanized steel sheet, fume HG is generated as in the first embodiment due to evaporation of the galvanizing at a high temperature.
FIG. 2 is a schematic diagram showing a state in which fume HG is generated in the plasma torch 100 of the prior art. As shown in FIG. 2, convection of the fume HG occurs between the shield gas SG and the plasma gas PG, so that the fume HG adheres to the tip surface 111 c of the first nozzle 111 and the fume HG and the first nozzle 111 In some cases, the alloyed layer is formed by combining with the metal of the end face 11c.
If the alloyed layer is formed, the first nozzle 111 is easily consumed because the alloyed layer has a low melting point, and the weld quality may not be stabilized due to damage of the first nozzle 111. Moreover, durability of the 1st nozzle 111 may also fall by alloying layer formation.

Therefore, in the present embodiment, the shield gas SG is ejected in the inner diameter direction from the second ejection port 12d that is opened in the whole circumference inward of the second nozzle 12. The second ejection port 1d ejects the shield gas SG so as to be a gas flow parallel to the tip surface 11c of the first nozzle 11, and the second ejection port 12d is entirely on the circumference of the second nozzle 12. Therefore, a stable shield gas SG layer that covers the entire front end surface 11c of the first nozzle 11 is formed.
FIG. 4 also shows the formation state of the shield gas SG layer. As shown in FIG. 4, the fume HG generated and convected inside the shield gas SG ejected from the first ejection port 12c toward the first and second workpieces is ejected from the second ejection port 12d in the inner diameter direction. The shield gas SG layer is prevented from adhering to the tip surface 11 c of the first nozzle 11.
Therefore, it can suppress that the fume HG adheres to the front end surface 11c of the 1st nozzle 11, and the fume HG and the metal of the front end surface 11c of the 1st nozzle 11 combine, and an alloying layer is formed. Therefore, the first nozzle 11 is not easily consumed, the welding quality can be stabilized, and the formation of the alloyed layer is suppressed, so that a decrease in durability of the first nozzle 11 can be suppressed.
The shield gas SG, which is ejected from the second ejection port 12d and forms a stable shield gas SG layer covering the entire front end surface 11c of the first nozzle 11, is transferred from the first ejection port 12c to the first and second workpieces. It becomes a swirl flow between the shield gas SG and the plasma gas PG ejected toward the direction.

The above plasma torch 1a has the following effects.
(5) According to the plasma torch 1a , the shield gas SG is ejected from the second jet port 12d in the inner diameter direction in parallel to the tip surface 11c of the first nozzle 11, and the layer of the shield gas SG is applied to the tip of the first nozzle 11. It is formed on the front surface of the surface 11c.
As a result, galvanization occurs due to evaporation of the zinc plating at a high temperature inside the shield gas SG that is ejected in an annular shape toward the first and second workpieces so as to surround the plasma gas PG from the first ejection port 12c. The fume HG is prevented from adhering to the tip surface 11c of the first nozzle 11 by the layer of the shield gas SG ejected from the second ejection port 12d. Therefore, it can suppress that the fume HG adheres to the front end surface 11c of the 1st nozzle 11, and the fume HG and the metal of the front end surface 11c of the 1st nozzle 11 combine, and an alloying layer is formed.
Moreover, the 2nd jet nozzle 12d is located inside the 1st jet nozzle 12c, and shield gas SG ejected from each of the 1st jet nozzle 12c and the 2nd jet nozzle 12d does not interfere.
Therefore, the first nozzle 11 is not easily consumed, the welding quality can be stabilized, and the formation of the alloyed layer is suppressed, so that a decrease in durability of the first nozzle 11 can be suppressed.
Further, since no other parts such as the third nozzle 13 are provided as in the first embodiment, the plasma torch 1a can be downsized.
Further, since the same shielding gas is ejected from the first ejection port 12c and the second ejection port 12d, it is not necessary to prepare many kinds of gases, and the cost can be reduced.

Note that the present invention is not limited to the above-described embodiment, and modifications, improvements, and the like within the scope that can achieve the object of the present invention are included in the scope of the present invention.
For example, the number of the third nozzles 13 in the first embodiment may be at least one, and preferably four such that an inert gas FG layer can be formed on the entire front end surface 11 c of the first nozzle 11. It is good to have more.
The inert gas FG ejected from the third nozzle 13 in the first embodiment may be the same as or different from the shield gas SG.
Moreover, the form of the 1st jet nozzle 12c of the 2nd nozzle 12 in the above-mentioned plasma torch 1a may be a several opening etc., if the layer of shield gas SG can be formed in the whole surface of the front end surface 11c of the 1st nozzle 11, The shape etc. Is not limited.

DESCRIPTION OF SYMBOLS 1 ... Plasma torch 10 ... Electrode 11 ... 1st nozzle (arc electrode)
11a ... center hole 11b ... outlet 11c ... tip surface 11d ... tip 12 ... second nozzle 12a ... center hole 12b ... outlet 12c ... first outlet 12d ... second outlet 12e ... cover part 13 ... third nozzle 100 ... plasma torch 111 ... first nozzle 111c ... tip surface

Claims (2)

A plasma torch used for plasma arc welding,
A rod-shaped electrode;
A cylindrical first nozzle that is provided around the electrode and ejects plasma gas;
A cylindrical second nozzle that is provided around the first nozzle and that jets the shielding gas in an annular shape so as to surround the plasma gas;
A third nozzle for injecting an inert gas toward the tip surface of the first nozzle inside the shield gas ejected in an annular shape ,
The third nozzle ejects an inert gas in a gas flow parallel to the tip surface of the first nozzle, and inside the shield gas ejected in an annular shape from the circumferential direction of the second nozzle, A plasma torch characterized by being spaced evenly in the circumferential direction . Wherein as an inert gas ejected from the third nozzle, the plasma torch according to claim 1 which comprises using the same gas as the shielding gas.

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