JPH09206947A - Tig welding equipment - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an electrode oscillating type (narrow groove) TIG welding equipment which is free from deformation in bearing on a work, excellent in insulation characteristic and capable of every postures. SOLUTION: This welding equipment is structured such that it is provided with a torch block 10 supporting a non-consumable electrode 11 and having a cold water inflow tube 2 and outflow tube 1 and with a shield gas block 9A, 9B having cold water inflow tubes 5A, 5B, outflow tubes 6A, 6B, and shield gas inflow tubes 7A, 7B; and that the torch block 10 and the shield gas block 9A, 9B are adjacently arranged so that all the above inflow and outflow tubes 2, 5A, 5B, 1, 6A, 6B, 7A, 7B may be arranged side by side. In this case, an exterior protecting body 8 is also provided which sheathes all these inflow and outflow tubes 2, 5A, 5B, 1, 6A, 6B, 7A, 7B bundled integrally into one unit.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a TIG welding apparatus, and more particularly to a TIG torch capable of welding in a narrow groove.

[0002]

2. Description of the Related Art A conventional TIG torch has a torch block 100 and a shield gas block 10 as shown in FIG.
1, the swing unit 102, and the wire feeding unit. The torch block 100 is connected to the swing unit 102 by a pipe joint 103 as a single unit, and the shield gas block 101 is provided.
Is also connected to the swing unit 102 by a pipe joint 104 by itself, and the torch block 100 and the shield gas block 1
01 are separately arranged (Japanese Patent Laid-Open No. 6-748).
No. 18).

This TIG torch has been proposed for downward welding, and when the work is a pipe or the like, consideration should be given to all-position welding in which the torch is welded around the outer periphery of the member to be welded. It wasn't done.

[0004]

In all-position welding, a welding head including an oscillating unit and a narrow groove torch is generally attached to a rail installed on the outer circumference of a pipe. When the welding head is attached to the rail, Since the narrow groove torch is long, the narrow groove torch often hits the pipe (work).

In the conventional torch, both the torch block and the shield block are only a torch pipe and a gas pipe. Further, since the torch block and the shield block are separately provided, they are easily deformed when hitting a work or the like. Therefore, the position of the non-consumable electrode and the position of the gas outlet portion at the tip of the shield block change. As a result, the wire does not enter the weld pool formed by the non-consumable electrode, or the shield is deteriorated, which causes welding defects.

The torch block is attached to the rocking unit by a metal pipe joint for energizing and preventing leakage of cooling water. This type of pipe joint deforms a metal abacus ball. The torch block may be damaged or water may leak when parts are replaced because the torch block is not leaked.

The object of the present invention is to provide a highly reliable TI in which the position of the non-consumable electrode and the position of the gas outlet at the tip of the shield block are stable without being deformed even when hitting a work or the like.
It is to provide a G welding device.

[0008]

In order to achieve the above object, the present invention supports a non-consumable electrode at its tip and has a torch block having a cooling water inflow pipe and a cooling water outflow pipe, and a cooling water inflow pipe and a cooling water outflow pipe. And a shield gas block having a shield gas inflow pipe, and a TIG welding apparatus in which the torch block and the shield gas block are arranged adjacent to each other so that the cooling water inflow pipe, the cooling water outflow pipe, and the shield gas inflow pipe are arranged in parallel. It is intended.

Then, the cooling water inflow pipe and the cooling water outflow pipe of the torch block, the cooling water inflow pipe and the cooling water outflow pipe of the shield gas block, and the shield gas inflow pipe are integrally connected to each other, and the exterior is made of, for example, a heat-resistant polyimide resin. It is characterized in that a protector is provided.

[0010]

BEST MODE FOR CARRYING OUT THE INVENTION As described above, the present invention integrates the cooling water inflow pipe and the cooling water outflow pipe of the torch block, the cooling water inflow pipe and the cooling water outflow pipe of the shield gas block, and the shield gas inflow pipe into one body. Since it has been
There is no deformation even when hitting a work or the like as in the past.
Therefore, the positions of the torch block and the shield gas block are kept normal, high-quality and stable welding can be performed in welding in a narrow groove, and reliability can be improved.

An embodiment of the present invention will be described below with reference to the drawings. 1 is a front view of a narrow groove TIG torch of the present invention, FIG. 2 is a vertical sectional view of the narrow groove TIG torch, FIG. 3 is a partially enlarged vertical sectional view of the narrow groove TIG torch, and FIG. It is a cross-sectional view of a groove TIG torch.

In the TIG torch, a torch block 10 is brazed to the tip of a cooling water inflow pipe 2 into which a cooling water outflow pipe 1 is inserted, and a non-consumable electrode 11 is attached to the torch block 10. For this torch block 10,
The first and second shield gas blocks 9A and 9B are arranged adjacent to each other at symmetrical positions, and the shield gas block 9
Cooling water inflow pipes 5A and 5B in which cooling water outflow pipes 6A and 6B are inserted and shield gas inflow pipes 7A and 7B are brazed to A and 9B.

As described above, the cooling water outflow pipe 1 and the cooling water inflow pipe 2 of the torch block 10, and the cooling water outflow pipes 6A and 6B and the cooling water inflow pipes 5A and 5B of the shield gas blocks 9A and 9B are both double pipe structures. The cooling water inflow pipes 1, 6A, 6B and the cooling water outflow pipes 2, 5A, 5
B and the shield gas inflow pipes 7A and 7B are arranged in parallel.

The cooling water inflow pipe 2 and the cooling water outflow pipe 1 of the torch block 10 and the shield gas blocks 9A, 9
B cooling water inflow pipes 5A, 5B and cooling water outflow pipes 6A, 6
B and the shield gas inflow pipes 7A and 7B are respectively inserted into the holes formed in the outer protective body 8 having electrical insulation and heat resistance, and the respective pipes are integrally connected and the outer casing is protected. There is. In this way, each tube is integrated,
Moreover, by adopting the above-mentioned double tube structure, the strength is improved, and the torch block 10 and the non-consumable electrode 11 are all electrically insulated.

As shown in FIGS. 2 and 4, the arrangement of the respective pipes is such that the double pipe of the cooling water outflow pipe 1 and the cooling water inflow pipe 2 of the torch block 10 is arranged at the center, and the first shield is provided on both the left and right sides thereof. A double pipe of the cooling water inflow pipe 5A and the cooling water outflow pipe 6A of the gas block 9A, and a double pipe of the cooling water inflow pipe 5B and the cooling water outflow pipe 6B of the second shield gas block 9B are arranged, and both outsides thereof. Shield gas inflow pipes 7A and 7B are arranged in the. As shown in FIG. 5, the sheath protector 8 extends over substantially the entire length of each tube.

The water from the cooling water pump is the cooling water inflow pipe 5A.
The cooling water outflow pipe 6A after cooling the shield gas block 9A, and the water sent to the cooling water inflow pipe 5B passes through the cooling water outflow pipe 6B after cooling the shield gas block 9B to the outside. Get out.

Further, the cooling water discharged from the cooling water outflow pipe 6B enters the cooling water inflow pipe 2 after passing through a torch drive section (not shown), cools the torch block 10 and is discharged from the cooling water outflow pipe 1. . This cools the entire torch and prevents the temperature of the torch from rising due to radiant heat from preheating and welding. Inflow and outflow of the cooling water may be reversed.

FIG. 3 shows details of the tip portion of the torch. The torch block 10 is cooled by making four holes 1a in the vicinity of the tip of the cooling water outflow pipe 1 for the cooling water sent from the cooling water inflow pipe 2 and circulating the holes 1a.

The non-consumable electrode 11 is fixed to the torch block 10 at an angle of about 15 degrees, and by rotating the torch block 10, welding is performed at an advancing angle with respect to the welding advancing direction to improve the penetration of the groove corner. To prevent fusion defects.

To cool the shield gas block 9A, the tip of the shield gas inflow pipe 7A is closed by brazing, four holes 13 are formed near the tip, and the shield gas is dispersed and discharged. Further, a gas flow path is formed at the tip of the shield gas block 9A, and a gas guide member 12A inclined toward the non-consumable electrode 11 side is attached in the gas flow path so that the flow of the shield gas G is not consumed. By guiding near the electrode 11, the shield properties of the welded portion and the non-consumable electrode 11 are improved.

FIG. 4 shows a cross section of the narrow groove TIG torch. The exterior protector 8 is made of a heat-resistant and electrically insulating molding such as wholly aromatic polyimide resin or ceramic, and has a thickness t of 12 mm or less, preferably 8 mm or less,
Inside the exterior protective body 8, the cooling water inflow pipe 2 of the torch block 10 and the cooling water inflow pipes 5A, 5 of the shield gas block 9 are provided.
B and holes for the shield gas inflow pipes 7A and 7B are formed at predetermined intervals, and the pipes are inserted therein, and the hole diameter is +1 mm or less with respect to the pipe diameter.

In particular, the cooling water inflow pipe 2 of the torch block 10
The hole diameter is 0.5 mm or less with respect to the tube diameter.
This is because during welding, the torch block 10 constantly oscillates by repeating a half-reciprocation.
This is to prevent rotation blur of the.

If the mechanical properties of the wholly aromatic polyimide resin used as the exterior protector 8 are shown, the tensile strength is 11
80 [Kg / cm ² ], tensile elongation: 5.0 [%], bending strength: 1640 [Kg / cm ² ], bending elastic modulus: 42
500 [Kg / cm ² ], compressive stress: 270 [Kg / c
m ² ], compression elastic modulus: 26500 [Kg / cm ² ], Rockwell hardness: 114 [M scale], compression creep: 0.83 [%].

FIG. 5 is a side view of the narrow groove TIG torch and the swing unit portion. The torch body is attached to the rocking unit body via the holder 27, and the cooling water inflow pipe 2 is clamped and fixed by the power feeding block 31. When the non-consumable electrode 11 swings, the motor 17 drives the toothed pulley 2
2 and 23 and the timing belt 24, and the adjustment of the swing angle θ is controlled by the encoder 18. In the figure, 16 is a power cable, 19 and 20 are bearings,
Reference numeral 21 is a cam, and 25 is a timing belt.

FIG. 6 shows a cross section of the swing unit portion. The power cable 16 is attached to the upper end of the power supply shaft A29, and the power supply shaft A29 is fastened and fixed to the power supply shaft B30 and further to the power supply block 31, and the cooling water inflow pipe 2 is energized.

The non-consumable electrode 11 is rotated by a motor 17 via a timing belt 24 to rotate a toothed pulley 22 attached to a power feed shaft B30.
It swings so as to be supported by 9, 20. 28 is a water cooling hose.

[0027]

According to the invention of claim 1, the cooling water inflow pipe and the cooling water outflow pipe of the torch block, the cooling water inflow pipe and the cooling water outflow pipe of the shield gas block, and the shield gas inflow pipe are integrated in the outer protective body. Since it has been
There is no deformation even when hitting a work or the like as in the past.
Therefore, the positions of the torch block and the shield gas block are kept normal, high-quality and stable welding can be performed in welding in a narrow groove, and reliability can be improved.

When the cooling water inflow pipe and the cooling water outflow pipe of the torch block and the cooling water inflow pipe and the cooling water outflow pipe of the shield gas block both have a double pipe structure as described in claim 2, together with the exterior protector. The strength of the welding torch can be improved.

According to a third aspect of the present invention, the first shield gas block and the second shield gas block are provided on both sides of the torch block.
By arranging the shielding gas block of No. 1 and integrating them with the exterior protector, the strength of the welding torch can be further improved and a high gas shielding effect can be obtained.

As described in claim 4, the tip end of the shield gas inflow pipe is closed to form a hole in the outer circumference of the pipe in the vicinity of the tip end, and a gas flow path is formed in the opening of the shield gas block. If the gas flow path is equipped with a gas guide member that allows the shield gas to flow to the non-consumable electrode side, the shield gas flow path is always in the direction of the molten pool, and the welded part in the narrow groove can be easily and reliably shielded. can do.

According to a fifth aspect of the present invention, the exterior protector is a molded body having holes into which the cooling water inflow pipe of the torch block, the shield gas inflow pipe of the shield gas block and the cooling water inflow pipe are respectively inserted. Since each tube is housed inside the exterior protective body, even if the tip of a long torch is swung in a narrow groove, the tip does not shake as in the conventional case and the non-consumable electrode is shaken accurately. It is possible to perform high quality and stable narrow groove welding.

As described in claim 6, when the narrow groove TIG torch is attached to the swing unit by tightening and fixing it with the holder and the power feeding block, and the seal component is incorporated in the passage of the cooling water, when the torch block or the like is replaced. In addition, there is no risk of poor energization or water leakage, the torch performance is stable, and good narrow groove welding is possible.

[Brief description of drawings]

FIG. 1 is a front view of a narrow groove TIG torch according to an embodiment of the present invention.

FIG. 2 is a vertical sectional view of the narrow groove TIG torch.

FIG. 3 is an enlarged vertical sectional view showing the structure of the tip portion of the narrow groove TIG torch.

FIG. 4 is a transverse cross-sectional view showing the structure inside the outer protective body of the narrow groove TIG torch.

FIG. 5 is a view showing a swing structure of the narrow groove TIG torch.

FIG. 6 is an enlarged vertical cross-sectional view showing a cooling water passage and a structure in the swing unit of the narrow groove TIG torch.

FIG. 7 is a cross-sectional view showing a structure of a conventional swing-type narrow groove TIG torch and a swing unit.

[Explanation of symbols]

 1, 6A, 6B Cooling water outflow pipe 1a Hole 2, 5A, 5B Cooling water inflow pipe 7A, 7B Shield gas inflow pipe 8 Exterior protective body 9A, 9B Shield gas block 10 Torch block 11 Non-consumable electrode 12 Gas guide member 16 Water cooling power Cable 17 Motor 27 Holder 29 Feeding shaft A 30 Feeding shaft B 31 Feeding block G Shield gas

Claims (6)

[Claims] 1. A torch block having a non-consumable electrode supported at its tip and having a cooling water inflow pipe and a cooling water outflow pipe, and a shield gas block having a cooling water inflow pipe, a cooling water outflow pipe, and a shield gas inflow pipe, In a TIG welding apparatus in which the torch block and the shield gas block are arranged adjacent to each other so that the cooling water inflow pipes, the cooling water outflow pipes, and the shield gas inflow pipes are juxtaposed, a cooling water inflow pipe and a cooling water outflow pipe of the torch block are provided. A TIG welding apparatus, characterized in that an outer protective body is provided for integrally connecting the cooling water inflow pipe, the cooling water outflow pipe, and the shield gas inflow pipe of the shield gas block. 2. The cooling water inflow pipe and the cooling water outflow pipe of the torch block, and the cooling water inflow pipe and the cooling water outflow pipe of the shield gas block according to claim 1, each having a double pipe structure. Characteristic TIG welding equipment. 3. The TIG welding apparatus according to claim 1, wherein a first shield gas block and a second shield gas block are arranged on both sides of the torch block with the torch block in between. 4. The shield gas inflow pipe according to claim 1, wherein a front end portion is closed and a hole is formed in an outer circumference of the pipe in the vicinity of the front end portion, and a gas flow path is formed in an opening portion of the shield gas block. A TIG welding apparatus characterized in that a gas guide member for flowing a shield gas to the non-consumable electrode side is provided in the gas flow path. 5. The exterior protector according to claim 1,
TI is characterized by being a molded body having holes into which the cooling water inflow pipe of the torch block and the shield gas inflow pipe and the cooling water inflow pipe of the shield gas block are inserted.
G welding equipment. 6. The TIG torch according to claim 1, further comprising a swing unit composed of a power feed shaft and a main body, which is supported by a motor, an encoder, and a bearing and is rotated by the motor. The exterior protector is attached and fixed to the swing unit main body via a holder, and the cooling water inflow pipe of the torch block is inserted into the power feed shaft incorporating the seal component of the swing unit, and the end portion of the power feed shaft on the non-consumable electrode side is inserted. The cooling water outlet pipe is longer than the cooling water inflow pipe and the upper part protrudes from the cooling water inflow pipe.
A TIG welding apparatus characterized in that the water-cooled power cable is attached to a power supply shaft incorporating a seal part of an oscillating unit, and the power supply shaft has a shaft end opposite to a non-consumable electrode.