JP2024065575A - Welding torch - Google Patents

Abstract

[Problem] To provide a welding torch suitable for miniaturization and structural simplification. [Solution] A welding torch A1 includes an electrode 25 extending in an axial direction z, an inner nozzle 30 arranged outside an end of the electrode 25 on one axial side z1, an outer nozzle 31 arranged outside the inner nozzle 30, and a torch body 2 arranged on the other axial side z2 of the inner nozzle 30, and a first gas flow path G1 is formed between the electrode 25 and the inner nozzle 30, and a second gas flow path G2 is formed between the inner nozzle 30 and the outer nozzle 31. The torch body 2 has a first gas inlet 211 communicating with the first gas flow path G1 and a second gas inlet 212 communicating with the second gas flow path G2. The first gas inlet 211 is located on the other axial side z2 of the second gas inlet 212. The first gas inlet 211 is inclined so as to be located on the one axial side z1 as it approaches the electrode 25 in a first direction x perpendicular to the axial direction z. [Selected figure] Figure 3

Description

The present invention relates to a welding torch.

In welding (TIG welding and plasma welding) using a welding torch equipped with a non-consumable electrode, an arc is generated between the electrode (non-consumable electrode) made of tungsten and the workpiece, and the heat of the arc melts the workpiece. In TIG welding, shielding gas is flowed between the gas nozzle and the electrode. In plasma welding, in addition to the shielding gas, plasma gas is flowed inside the insert tip placed around the electrode, thereby constraining the arc (plasma arc). As a result, a highly concentrated high-temperature plasma flow is generated, and the stored energy is used to perform welding.

When welding metals with a relatively low melting point (low melting metals) such as zinc-plated steel sheets, zinc vapor and fumes are generated by the welding heat. If metals such as fumes adhere to the electrode, the arc generated during welding becomes unstable. In TIG welding, the tip of the electrode usually protrudes from the tip of the nozzle, and if the tip of the electrode is covered with metals such as fumes, there is a risk of poor ignition at the start of welding. In plasma welding, the tip of the electrode is usually retracted from the tip of the insert tip that surrounds the electrode. In addition, plasma gas is flowed inside the insert tip (around the electrode). For this reason, when welding low melting metals such as zinc-plated steel sheets, metals such as fumes are less likely to adhere to the electrode in plasma welding than in TIG welding. On the other hand, in plasma welding, metals such as fumes may adhere to the tip of the insert tip, which then alloys with the tip of the insert tip. This alloying of the tip of the insert tip may cause poor arcing or poor welding.

Patent Document 1 discloses a configuration in which multiple side plasma gas ejection holes made of small diameter holes are provided around the plasma gas ejection hole at the tip of the insert tip. By providing these multiple additional side plasma gas ejection holes, it is possible to reduce the adhesion of fumes and the like to the tip of the insert tip during welding. However, the structure described in Patent Document 1 makes the insert tip structure complex and leads to an increase in the size of the tip of the insert tip (welding torch).

JP 2009-172644 A

The present invention was conceived under these circumstances, and its main objective is to provide a welding torch that is suitable for miniaturization and simplified structure.

To solve the above problems, the present invention employs the following technical means:

The welding torch provided by the present invention comprises a non-consumable electrode extending in the axial direction, an inner nozzle disposed radially outward at one end of the non-consumable electrode in the axial direction, an outer nozzle disposed radially outward relative to the inner nozzle, and a torch body disposed on the other side of the axial direction relative to the inner nozzle, a first gas flow path is formed between the non-consumable electrode and the inner nozzle, a second gas flow path is formed between the inner nozzle and the outer nozzle, the torch body has a first gas inlet leading to the first gas flow path and a second gas inlet leading to the second gas flow path, the first gas inlet is located on the other side of the axial direction relative to the second gas inlet, and the first gas inlet is inclined so as to be located on one side of the axial direction as it approaches the non-consumable electrode in a first direction perpendicular to the axial direction.

In a preferred embodiment, the second gas inlet is inclined to one side of the axial direction as it approaches the non-consumable electrode in the first direction.

In a preferred embodiment, the torch body has a female threaded portion adjacent to the other side of the first gas inlet in the axial direction, and further includes a screw member that screws into the female threaded portion.

In a preferred embodiment, the torch body has a cooling water passage located between the first gas inlet and the second gas inlet in the axial direction and formed along the circumferential direction of the non-consumable electrode.

In a preferred embodiment, the torch body includes a first cylindrical portion extending along the axial direction, and a second cylindrical portion connected to the first cylindrical portion and extending in a direction intersecting the axial direction, and the first cylindrical portion is disposed across the first gas inlet and the second gas inlet in the axial direction, and further includes a first gas pipe leading to the first gas inlet and a second gas pipe leading to the second gas inlet, each of which passes through the inside of the second cylindrical portion.

The welding torch of the present invention allows the opening end of the first gas inlet provided in the torch body to be brought closer to the inner nozzle side (one side in the axial direction) in the axial direction. This allows the axial dimension of the torch body to be reduced, making it possible to miniaturize the welding torch.

Other features and advantages of the present invention will become more apparent from the following detailed description taken in conjunction with the accompanying drawings.

FIG. 1 is a front view showing an example of a welding torch according to the present invention. FIG. 2 is a plan view of the welding torch shown in FIG. 1 . 3 is a cross-sectional view taken along line III-III in FIG. 2. FIG. 4 is a cross-sectional view taken along line IV-IV in FIG. 4 is an enlarged cross-sectional view taken along line VV in FIG. 3. FIG. 6 is an enlarged cross-sectional view taken along line VI-VI in FIG. FIG. 7 is an enlarged cross-sectional view taken along line VII-VII in FIG. FIG. 4 is a partially enlarged view of FIG. 3 .

The preferred embodiment of the present invention will now be described in detail with reference to the drawings. In the following description, terms such as "first" and "second" are used merely as labels and are not necessarily intended to assign any order to the objects they refer to.

Figures 1 to 8 show an example of a welding torch according to the present invention. The welding torch A1 of this embodiment includes a handle 1, a torch body 2, insulating rings 23 and 24, a non-consumable electrode 25, a collet body 26, a collet 27, a collet retainer 28, a cap 29, an inner nozzle 30, an outer nozzle 31, a nozzle holder 32, a locking member 33, an electrode centering member 34, a first gas pipe 41, a second gas pipe 42, a first cooling water pipe 43, and a second cooling water pipe 44. The welding torch A1 of this embodiment is configured so that an operator can hold it by hand to perform welding work. In addition, as will be described in detail later, the welding torch A1 has two gas flow paths (a first gas flow path G1 and a second gas flow path G2) for flowing a predetermined welding gas.

In the explanation of welding torch A1, the up-down direction in Fig. 1 and Fig. 3 is an example of the "axial direction" of the present invention, and is referred to as the "axial direction z". In Fig. 3 and Fig. 8, the direction perpendicular to the axial direction z (the left-right direction in the figures) is an example of the "first direction" of the present invention, and is referred to as the "first direction x". In Fig. 1 and Fig. 3, the lower side in the figures is an example of the "one side of the axial direction" of the present invention, and is referred to as the "one axial side z1", and the upper side in the figures is an example of the "other axial side" of the present invention, and is referred to as the "other axial side z2".

The handle 1 is the part that the operator holds with his/her hand. As shown in FIG. 3, the handle 1 is a cylindrical member made of an insulating material.

The torch body 2 is cylindrical, and one end is held by the handle 1. The torch body 2 includes a main body 20, a cylindrical member 21, and a cylindrical member 22. The main body 20 appropriately houses the components of the welding torch A1 inside. The main body 20 is made of an insulating material. The main body 20 has a first cylindrical portion 20A and a second cylindrical portion 20B.

The first cylindrical portion 20A extends along the axial direction z. The second cylindrical portion 20B is connected to the first cylindrical portion 20A in a branched manner. The second cylindrical portion 20B extends in a direction intersecting the axial direction z (the upper right direction in FIG. 3). In the illustrated example, the angle between the direction in which the first cylindrical portion 20A extends (axial direction z) and the direction in which the second cylindrical portion 20B extends is about 65°. The angle between the direction in which the first cylindrical portion 20A extends (axial direction z) and the direction in which the second cylindrical portion 20B extends is not particularly limited, and may be, for example, a right angle (90°). The end of the second cylindrical portion 20B (the end on the upper right side in FIG. 3) is held by the end of the handle 1. In the illustrated example, the end of the second cylindrical portion 20B and the end of the handle 1 are fixed to each other by a screw connection.

The cylindrical member 21 is disposed radially inside the first cylindrical portion 20A. The cylindrical member 21 is a member that receives power from a power source unit (not shown) and is made of a conductive material. An example of the conductive material that constitutes the cylindrical member 21 is copper. As shown in FIG. 8, the cylindrical member 21 has a first gas inlet 211, a second gas inlet 212, a groove 213, a tapered surface 214, and a female threaded portion 215. The cylindrical member 22 is disposed radially outside the cylindrical member 21. The cylindrical member 21 and the cylindrical member 22 will be described in detail later.

The insulating rings 23 and 24 are each a cylindrical member made of an insulating material. The insulating ring 23 is disposed adjacent to the other axial side z2 of the first cylindrical portion 20A. The insulating ring 24 is disposed adjacent to one axial side z1 of the second cylindrical portion 20B.

The non-consumable electrode 25 is a rod-shaped conductor extending along the axial direction z (the direction in which the axis CL extends). The non-consumable electrode 25 is made of, for example, tungsten. The non-consumable electrode 25 is connected to a power supply (not shown) via, for example, a conduit cable (not shown), and generates an arc between the non-consumable electrode 25 and the workpieces when an arc voltage is applied between the non-consumable electrode 25 and the workpieces.

The non-consumable electrode 25 has an electrode main portion 251 and an electrode tapered portion 252. The electrode main portion 251 is a portion with a constant outer diameter, and occupies most of the non-consumable electrode 25 except for the tip. The electrode main portion 251 is a portion formed in an approximately cylindrical shape so that the outer diameter is constant in design, and may include some manufacturing errors. The outer diameter of the electrode main portion 251 is not particularly limited, and in this embodiment, it is, for example, about 1.0 to 4.0 mm. The electrode tapered portion 252 is connected to the tip side (one axial side z1) of the non-consumable electrode 25 relative to the electrode main portion 251. The electrode tapered portion 252 has a diameter that decreases toward the tip side (one axial side z1) of the non-consumable electrode 25, and is approximately conical.

The collet body 26, collet 27, and collet pressing member 28 cooperate with each other to hold the non-consumable electrode 25. The collet body 26, collet 27, and collet pressing member 28 are made of a conductive material. An example of the conductive material that constitutes the collet body 26, collet 27, and collet pressing member 28 is copper.

The collet 27 surrounds the non-consumable electrode 25. The collet body 26 is disposed radially outward of the collet 27. The collet body 26 is disposed radially inward of the cylindrical member 21. Although detailed illustrations are omitted, the collet body 26 is fixed to the cylindrical member 21, for example, by a screw connection.

The collet holding member 28 is disposed on the other axial side z2 relative to the collet 27. Although detailed illustrations are omitted, the collet holding member 28 has a screw portion that is screwed into the cylindrical member 21. As shown in FIG. 8, a female screw portion 215 is formed at the upper end (the end on the other axial side z2) of the cylindrical member 21, and the above-mentioned screw portion of the collet holding member 28 is screwed into the female screw portion 215. A cap 29 is provided on the other axial side z2 of the collet holding member 28. By turning this cap 29, the position of the collet holding member 28 in the axial direction z relative to the collet body 26 can be adjusted. The end of the collet holding member 28 on the one axial side z1 abuts against the end of the collet 27 on the other axial side z2. When the collet holding member 28 is moved to the one axial side z1, the collet 27 is pressed against the one axial side z1.

The collet 27 has multiple slits formed at its tip (one axial side z1) that extend in the axial direction z, and has multiple movable pieces 271 located between adjacent slits. As described above, when the collet pressing member 28 is moved toward one axial side z1, the collet 27 is pressed toward one axial side z1. Then, the multiple movable pieces 271 at the tip of the collet 27 are pressed against the tip of the collet body 26, reducing its diameter, and the collet 27 holds the non-consumable electrode 25 by sandwiching it. In this way, the collet body 26, collet 27, and collet pressing member 28 cooperate with each other to hold the non-consumable electrode 25.

As shown in FIG. 3, the inner nozzle 30 is disposed around the tip of the non-consumable electrode 25 (the end on one axial side z1). The inner nozzle 30 is disposed on one axial side z1 relative to the collet body 26. The inner nozzle 30 is substantially cylindrical, and disposed radially outward of the non-consumable electrode 25 (electrode main portion 251). In this embodiment, an electrode centering member 34 is interposed between the inner nozzle 30 and the non-consumable electrode 25.

The locking member 33 is fitted over both the collet body 26 and the inner nozzle 30. More specifically, the locking member 33 is fitted over the end of the collet body 26 on one axial side z1 and the end of the inner nozzle 30 on the other axial side z2. In the illustrated example, the locking member 33 has a cap nut structure.

In this embodiment, as shown in FIG. 3, the locking member 33 and the end of the collet body 26 on one axial side z1 are screwed together. For example, a male thread 261 is formed on the outer periphery of the end of the collet body 26 on one axial side z1, and the female thread 331 formed on the locking member 33 is screwed into the male thread 261 of the collet body 26. Meanwhile, the portion of the locking member 33 on one axial side z1 is fitted onto the inner nozzle 30, and the locking member 33 is locked by the large diameter portion of the outer periphery on the other axial side z2 of the inner nozzle 30. This limits the relative movement of the inner nozzle 30 and the locking member 33 in the axial direction z.

The electrode centering member 34 is roughly cylindrical and is disposed radially outside the non-consumable electrode 25 and radially inside the inner nozzle 30. A tapered recess is formed on the inner circumference of the inner nozzle 30 on the other axial side z2, and the tapered protrusion of the electrode centering member 34 fits into this tapered recess. The inner diameter dimension of the electrode centering member 34 is slightly larger than the outer diameter dimension of the non-consumable electrode 25 (electrode main portion 251). As a result, the electrode centering member 34 is concentrically fitted around the non-consumable electrode 25. In addition, the tapered protrusion of the electrode centering member 34 fits into the tapered recess of the inner nozzle 30. As a result, the inner nozzle 30 is concentrically fitted around the electrode centering member 34. Therefore, the inner nozzle 30 is disposed concentrically around the non-consumable electrode 25 via the electrode centering member 34. As shown in FIG. 7, a plurality of grooves 341 are formed on the inner circumference of the electrode centering member 34. These grooves 341 are provided at regular intervals around the circumference of the electrode core member 34. A gap is formed between the non-consumable electrode 25 and the portion where the grooves 341 are formed, and this gap constitutes the first gas flow path G1, which will be described later.

In this embodiment, the tip of the non-consumable electrode 25 coincides with the tip of the inner nozzle 30 in the axial direction z, or protrudes slightly from the tip of the inner nozzle 30 to one axial side z1. The protruding length by which the tip of the non-consumable electrode 25 protrudes from the tip of the inner nozzle 30 to one axial side z1 is, for example, in the range of 0 to 2 mm.

The nozzle holder 32 is cylindrical. The nozzle holder 32 is integrally connected to the outer periphery of the middle part of the collet body 26 in the axial direction z by means of, for example, brazing.

As shown in FIG. 3, the outer nozzle 31 is disposed radially outward of the inner nozzle 30. The outer nozzle 31 is disposed on one axial side z1 of the first cylindrical portion 20A, and an insulating ring 24 is interposed between the outer nozzle 31 and the first cylindrical portion 20A. In the illustrated example, the outer nozzle 31 is generally cylindrical, and the tip side (one axial side z1) has a smaller diameter than other portions. In this embodiment, the outer nozzle 31 is disposed concentrically with the non-consumable electrode 25 and the inner nozzle 30. The outer nozzle 31 is attached, for example, by a screw connection to the outer periphery of the nozzle holder 32.

As shown in FIG. 3, in this embodiment, the tip of the inner nozzle 30 protrudes from the tip of the outer nozzle 31 to one axial side z1. The protruding length by which the tip of the inner nozzle 30 protrudes from the tip of the outer nozzle 31 to one axial side z1 is, for example, in the range of 0 to 5 mm.

As shown in Figures 3 to 8, in this embodiment, the welding torch A1 is formed with a first gas flow path G1, a second gas flow path G2, and a cooling water flow path W.

In this embodiment, the welding gas supplied to the welding torch A1 includes two types of inert gas that differ in gas supply manner, such as gas type and flow rate. For convenience of explanation, the two types of inert gas are appropriately distinguished as a "first inert gas" and a "second inert gas."

The first gas flow path G1 is a flow path for flowing the first inert gas. In FIG. 3, the flow of the first inert gas is indicated by the two-dot chain arrows. The first gas flow paths G1 are formed between the collet 27 and the collet body 26, between the non-consumable electrode 25 (electrode main part 251) and the collet 27, between the non-consumable electrode 25 (electrode main part 251) and the collet body 26, between the non-consumable electrode 25 (electrode main part 251) and the electrode centering member 34, and between the non-consumable electrode 25 (electrode main part 251) and the inner nozzle 30.

In this embodiment, as shown in Figures 3 and 8, the torch body 2 (cylindrical member 21) is provided with a first gas inlet 211 for introducing a first inert gas. The first gas inlet 211 is connected to the first gas flow passage G1. When the first inert gas is introduced from the first gas inlet 211, the first inert gas flows in the first gas flow passage G1 from the other axial side z2 to the one axial side z1, passes between the non-consumable electrode 25 (electrode main portion 251) and the inner nozzle 30, and then is ejected from the opening at the tip of the inner nozzle 30.

The second gas flow path G2 is a flow path for flowing the second inert gas. In FIG. 3, the flow of the second inert gas is indicated by dotted arrows. The second gas flow paths G2 are formed between the collet body 26 and the cylindrical member 21, between the collet body 26 and the insulating ring 24, between the nozzle holder 32, the locking member 33 and the outer nozzle 31, and between the inner nozzle 30 and the outer nozzle 31.

In this embodiment, as shown in Figures 3 and 8, the torch body 2 (cylindrical member 21) is provided with a second gas inlet 212 for introducing a second inert gas. The second gas inlet 212 is connected to the second gas flow passage G2. When the second inert gas is introduced from the second gas inlet 212, the second inert gas flows from the other axial side z2 to the one axial side z1 in the second gas flow passage G2, passes between the inner nozzle 30 and the outer nozzle 31, and is then ejected from the opening at the tip of the outer nozzle 31.

The cooling water flow path W is a flow path for flowing cooling water. As shown in FIG. 4, the cooling water flow path W is formed along the circumferential direction of the non-consumable electrode 25. The cooling water flow path W is formed mainly between the cylindrical member 21 and the cylindrical member 22.

The first gas inlet 211, the second gas inlet 212, the groove 213, the tapered surface 214, and the female threaded portion 215 of the cylindrical member 21 will be described with reference to FIG. 8 and other figures. As shown in FIG. 8, the first gas inlet 211 is located on the other axial side z2 relative to the second gas inlet 212. The first gas inlet 211 is inclined with respect to the first direction x. The first gas inlet 211 is inclined to be located on one axial side z1 as it approaches the non-consumable electrode 25 in the first direction x.

The second gas inlet 212 is inclined with respect to the first direction x. The second gas inlet 212 is inclined so as to be located on one axial side z1 as it approaches the non-consumable electrode 25 in the first direction x. The first cylindrical portion 20A, which is located radially outside the cylindrical member 21, is positioned across the first gas inlet 211 and the second gas inlet 212 in the axial direction z.

The opening end of the second gas inlet 212 is located on the tapered surface 214. The tapered surface 214 is inclined so as to be located on the other axial side z2 as it approaches the non-consumable electrode 25. In the cross section shown in FIG. 8, the angle between the tapered surface 214 and the second gas inlet 212 is approximately a right angle.

The recessed groove 213 is a portion of the outer circumferential surface of the tubular member 21 recessed radially inward. The tubular member 22 is roughly cylindrical and is disposed radially outward of the tubular member 21. The tubular member 22 blocks the recessed groove 213 from the radially outward side. As shown in Figures 4 and 8, in this embodiment, the cooling water flow path W is formed by the space between the recessed groove 213 and the tubular member 22 that blocks it. Also, in this embodiment, as shown in Figure 8, the cooling water flow path W is located between the first gas inlet 211 and the tubular member 22 in the axial direction z.

As shown in FIG. 8, the female threaded portion 215 is adjacent to the first gas inlet 211 on the other axial side z2. As described above, the threaded portion of the collet holding member 28 is screwed into this female threaded portion 215. The collet holding member 28 having this threaded portion corresponds to an example of the "screw member" of the present invention.

3 and 8, the first gas pipe 41 and the second gas pipe 42 pass through the inside of the second cylindrical portion 20B. The first gas pipe 41 is a pipe that flows through the first gas flow path G1 and is connected to the first gas inlet 211 of the cylindrical member 21. The second gas pipe 42 is a pipe that flows through the second gas flow path G2 and is connected to the second gas inlet 212 of the cylindrical member 21. The second cylindrical portion 20B has a narrowed shape in which the portion closer to the first cylindrical portion 20A has a smaller diameter than the portion closer to the handle 1. In the illustrated example, the first gas pipe 41 and the second gas pipe 42 are appropriately bent in accordance with the narrowed shape of the second cylindrical portion 20B. The end of the first gas pipe 41 that is connected to the first gas inlet 211 extends along the first direction x.

As shown in FIG. 4, the first cooling water pipe 43 and the second cooling water pipe 44 pass through the inside of the second cylindrical portion 20B. In the illustrated example, the first cooling water pipe 43 is a pipe for sending cooling water toward the above-mentioned cooling water flow path W. The second cooling water pipe 44 is a pipe for sending the cooling water that has flowed through the cooling water flow path W to the outside. The end of the first cooling water pipe 43 on the first cylindrical portion 20A side is connected to one end of the cooling water flow path W. The end of the second cooling water pipe 44 on the first cylindrical portion 20A is connected to the other end of the cooling water flow path W. As a result, as shown in FIG. 4, the cooling water flows in the order of the first cooling water pipe 43, the cooling water flow path W, and the second cooling water pipe 44. In FIG. 4, the flow of the cooling water is represented by solid arrows.

The type of each of the first inert gas and the second inert gas supplied to the welding torch A1 is not particularly limited, and may be, for example, a gas containing at least one selected from argon (Ar) gas and helium (He) gas. The flow rates of the first inert gas and the second inert gas supplied to the welding torch A1 are individually adjusted as appropriate depending on the welding conditions, etc.

Next, the operation of this embodiment will be explained.

The welding torch A1 of this embodiment includes a non-consumable electrode 25 extending in the axial direction z, an inner nozzle 30, and an outer nozzle 31. The inner nozzle 30 is arranged concentrically on the radial outside of the non-consumable electrode 25, and a first gas flow path G1 is formed between the non-consumable electrode 25 and the inner nozzle 30. The outer nozzle 31 is arranged on the radial outside of the inner nozzle 30, and a second gas flow path G2 is formed between the inner nozzle 30 and the outer nozzle 31. With this configuration, during welding, the first inert gas flowing through the first gas flow path G1 and ejected from the tip of the inner nozzle 30 functions as a plasma gas, and the second inert gas flowing through the second gas flow path G2 and ejected from the tip of the outer nozzle 31 functions as a shielding gas. As a result, the arc generated between the workpiece and the tip of the non-consumable electrode 25 is narrowed, and welding can be performed efficiently using an arc (plasma arc) with high energy density.

The torch body 2 is disposed on the other axial side z2 relative to the inner nozzle 30. The torch body 2 (cylindrical member 21) has a first gas inlet 211 that leads to the first gas flow passage G1 and a second gas inlet 212 that leads to the second gas flow passage G2. The first gas inlet 211 is located on the other axial side z2 relative to the second gas inlet 212. The first gas inlet 211 is inclined so as to be located on one axial side z1 as it approaches the non-consumable electrode 25 in the first direction x perpendicular to the axial direction z. With this configuration, it is possible to move the opening end of the first gas inlet 211 provided in the torch body 2 (cylindrical member 21) closer to the inner nozzle 30 side (one axial side z1) in the axial direction z. This makes it possible to reduce the dimension of the torch body 2 (first cylindrical portion 20A) in the axial direction z, thereby making it possible to miniaturize the welding torch A1. The welding torch A1 of this embodiment is a hand-held type that is held by the worker while performing welding work. The miniaturization of the welding torch A1 contributes to reducing the burden on the worker and is expected to improve welding work.

In this embodiment, the second gas inlet 212 is inclined in the first direction x so as to be positioned on one axial side z1 as it approaches the non-consumable electrode 25. With this configuration, the area where the opening end of the second gas inlet 212 is located can be, for example, a tapered surface 214, thereby making it possible to reduce the size of the peripheral portion of the second gas inlet 212 in the cylindrical member 21 (torch body 2).

The cylindrical member 21 (torch body 2) has a female threaded portion 215. The female threaded portion 215 is adjacent to the first gas inlet 211 on the other axial side z2. The welding torch A1 is provided with a collet holding member 28 (screw member) that screws into the female threaded portion 215. With this configuration, the attachment position of the collet holding member 28 can be shifted to the other axial side z2 while ensuring the length of the female threaded portion 215 in the axial direction z. In addition, it is possible to prevent the second gas inlet 212 from being blocked by the collet holding member 28 that screws into the female threaded portion 215. This structure is more preferable in terms of miniaturizing the welding torch A1.

The torch body 2 has a cooling water flow passage W. The cooling water flow passage W is located between the first gas inlet 211 and the cylindrical member 22 in the axial direction z, and is formed along the circumferential direction of the non-consumable electrode 25. With this configuration, the welding torch A1 can be made compact while still providing a cooling function to the welding torch A1.

The torch body 2 includes a first cylindrical portion 20A and a second cylindrical portion 20B connected to the first cylindrical portion 20A. The first cylindrical portion 20A extends along the axial direction z, and the second cylindrical portion 20B extends in a direction intersecting the axial direction z. The first cylindrical portion 20A is disposed across the first gas inlet 211 and the second gas inlet 212 in the axial direction z. In addition, a first gas pipe 41 and a second gas pipe 42 are provided that pass through the inside of the second cylindrical portion 20B. The first gas pipe 41 is connected to the first gas inlet 211, and the second gas pipe 42 is connected to the second gas inlet 212. With this configuration, different gases (for example, the above-mentioned first inert gas and second inert gas) can be appropriately supplied to the first gas flow passage G1 and the second gas flow passage G2 via the first gas pipe 41 and the second gas pipe 42.

In this embodiment, the welding torch A1 includes an electrode centering member 34 and a locking member 33. The electrode centering member 34 is concentrically fitted around the non-consumable electrode 25. The inner nozzle 30 is also concentrically fitted around the electrode centering member 34. As a result, the inner nozzle 30 is arranged concentrically around the non-consumable electrode 25 via the electrode centering member 34. The locking member 33 is fitted across the end of the collet body 26 on one axial side z1 and the end of the inner nozzle 30 on the other axial side z2, and locks onto both the collet body 26 and the inner nozzle 30. With this configuration, some radial flexibility can be provided between the locking member 33 and the collet body 26 or the inner nozzle 30. Therefore, for example, even if the non-consumable electrode 25 is slightly bent due to manufacturing errors, the inner nozzle 30 can be arranged concentrically around the non-consumable electrode 25.

In addition, since the inner nozzle 30 is arranged concentrically on the radial outside of the non-consumable electrode 25, the gas (first inert gas) flowing through the first gas flow passage G1 between the non-consumable electrode 25 and the inner nozzle 30 becomes a substantially uniform and relatively high-speed airflow around the non-consumable electrode 25 and is ejected from the opening at the tip of the inner nozzle 30. As a result, even when welding a workpiece made of a low-melting metal such as a zinc-plated steel sheet, fumes and the like generated during welding are blown away by the high-speed airflow of the first inert gas flowing around the non-consumable electrode 25. Therefore, it is possible to prevent fumes and the like from adhering to the tip of the non-consumable electrode 25 or the tip of the inner nozzle 30.

Furthermore, the tip of the non-consumable electrode 25 coincides with the tip of the inner nozzle 30 in the axial direction z, or protrudes slightly from the tip of the inner nozzle 30 to one axial side z1. The length by which the tip of the non-consumable electrode 25 protrudes from the tip of the inner nozzle 30 to one axial side z1 is in the range of 0 to 2 mm. With such a tip position of the non-consumable electrode 25, the gap between the non-consumable electrode 25 and the inner nozzle 30 is kept approximately constant and narrow in the range from the middle of the axial direction z of the inner nozzle 30 to the vicinity of the tip. Therefore, the high-speed airflow of the first inert gas flowing around the non-consumable electrode 25 is ejected from the opening at the tip of the inner nozzle 30 with almost no decrease in flow rate. This is preferable in terms of preventing adhesion of fumes, etc. to the tip of the non-consumable electrode 25 and the tip of the inner nozzle 30. In addition, the above-mentioned action and effect are realized by ingenuity in the shape and arrangement of the inner nozzle 30, making it possible to relatively simplify the structure of the welding torch A1 and to reduce the size of the tip of the welding torch A1.

Although the embodiments of the present invention have been described above, the scope of the present invention is not limited to the above-mentioned embodiments, and all modifications within the scope of the matters described in each claim are included in the scope of the present invention.

In the above embodiment of the welding torch A1, the outer nozzle 31 is arranged concentrically with the inner nozzle 30, but the present invention is not limited to this. The outer nozzle 31 may be arranged offset radially from the inner nozzle 30. In addition, the welding torch A1 in the above embodiment is an example of a hand-operated torch that is held by a worker to perform welding work, but the present invention is not limited to this. The welding torch according to the present invention may be configured as a robot torch that is equipped on a welding robot (such as an articulated robot), for example.

A1: welding torch, 2: torch body, 20A: first cylindrical part, 20B: second cylindrical part, 211: first gas inlet, 212: second gas inlet, 215: female thread, 25: non-consumable electrode, 28: collet retainer (threaded member), 30: inner nozzle, 31: outer nozzle, 41: first gas pipe, 42: second gas pipe, G1: first gas flow path, G2: second gas flow path, W: cooling water flow path, z: axial direction, z1: one side of axial direction, z2: other side of axial direction, x: first direction

Claims (5)

a non-consumable electrode extending in an axial direction;
an inner nozzle disposed radially outwardly of the non-consumable electrode at one end in the axial direction;
an outer nozzle disposed radially outward relative to the inner nozzle;
a torch body disposed on the other side of the inner nozzle in the axial direction,
a first gas flow passage is formed between the non-consumable electrode and the inner nozzle;
A second gas flow passage is formed between the inner nozzle and the outer nozzle,
the torch body has a first gas inlet communicating with the first gas passage and a second gas inlet communicating with the second gas passage;
the first gas inlet is located on the other side of the second gas inlet in the axial direction,
A welding torch, wherein the first gas inlet is inclined in a first direction perpendicular to the axial direction so as to be positioned on one side of the axial direction as it approaches the non-consumable electrode. The welding torch of claim 1, wherein the second gas inlet is inclined to be located on one side of the axial direction as it approaches the non-consumable electrode in the first direction. the torch body has a female thread portion adjacent to the other side of the first gas inlet in the axial direction,
The welding torch of claim 1 , further comprising a threaded member that threadably engages with the female threaded portion. The welding torch according to any one of claims 1 to 3, wherein the torch body has a cooling water flow passage located between the first gas inlet and the second gas inlet in the axial direction and formed along the circumferential direction of the non-consumable electrode. The torch body includes a first cylindrical portion extending along the axial direction, and a second cylindrical portion connected to the first cylindrical portion and extending in a direction intersecting the axial direction,
the first cylindrical portion is disposed across the first gas inlet and the second gas inlet in the axial direction,
4. The welding torch according to claim 1, further comprising: a first gas pipe that passes through the second cylindrical portion and leads to the first gas inlet; and a second gas pipe that leads to the second gas inlet.

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