JP2023073711A - Nozzle cover, welding nozzle, and welding nozzle with cover - Google Patents

Abstract

To provide a nozzle cover which can inhibit scattering of spatter occurring during arc-welding, and to provide a welding nozzle and a welding nozzle with a cover.SOLUTION: In a nozzle cover 2, a cylindrical outer cover 10 is located at an outer periphery of a cylindrical inner cover 11 attached to an outer periphery of a welding nozzle 1 and an air supply port 13 is located at the outer cover 10. An air passage 12 communicating with the air supply port 13 is located between the inner cover 11 and the outer cover 10, and a lower end of the air passage 12 serves as an air outlet 14. A diffusion part 15 which spreads out to the outer side is located at the tip side of the inner cover 11. The diffusion part 15 protrudes toward a tip farther than a tip of the outer cover 10 and the air outlet 14. Air which is supplied from the air supply port 13, passes through the air passage 12, and is jetted from the air outlet 14 is diffused to the outer side by the diffusion part 15. In a welding nozzle with a cover, the outer periphery of the welding nozzle includes the nozzle cover.SELECTED DRAWING: Figure 1

Description

The present invention comprises a cover (hereinafter referred to as "nozzle cover") that can be put on the outer periphery of a nozzle for gas shielded arc welding (hereinafter referred to as "welding nozzle"), a welding nozzle, and a nozzle cover around the outer periphery of the welding nozzle. It relates to a welding nozzle with an attached cover.

Arc welding is widely used in various industrial fields. Arc welding can be broadly classified into two types: a consumable electrode type (electrode type) in which the welding rod (or wire) melts, and a non-consumable electrode type (non-meltable electrode type) in which the welding rod (or wire) does not melt. Arc welding includes manual welding in which the operator replaces the filler material (welding rod) and automatic welding in which the welding rod is automatically supplied. In either method, arc welding encloses the welding point with a shielding gas to protect it from the atmosphere. The nozzle cover, welding nozzle, and welding nozzle with cover of the present invention can be applied to any of the above methods of arc welding.

During arc welding, spatter is generated and scattered around the work site. If the scattered spatter adheres to nearby screws, metal parts, etc., the screws and metal parts may become unusable. In order to solve this problem, spatter adhesion prevention devices have been developed. There are patent documents 1 and 2 as a main example.

JP 2007-83282 A JP-A-6-122089

An object of the present invention is to provide a nozzle cover, a welding nozzle, and a welding nozzle with a cover that can suppress scattering of spatter generated during arc welding.

[Nozzle cover]
The nozzle cover of the present invention is a nozzle cover that can be attached to and detached from the welding nozzle, is attached to the outer periphery of the welding nozzle, is a cover that can send compressed air (air) from the outside and eject the air, and has a cylindrical inner part. There is a cylindrical outer cover on the outer periphery of the cover, there is an air flow path between the inner cover and the outer cover, the outer cover has an air supply port communicating with the air flow path, and the lower end of the air flow path At the tip of the inner cover, there is a diffusing part that flares outward, and the diffusing part protrudes further than the tip of the outer cover and the air outlet.

[Welding nozzle]
The welding nozzle of the present invention has one or more of a ring-shaped collar and/or a groove on the outer circumference of the tip side of the welding nozzle. If there are two or more flanges or grooves, they should be spaced apart in the axial direction on the tip side of the welding nozzle. When both the flange and the concave groove are provided, it is desirable to provide the concave groove closer to the tip of the nozzle than the flange.

[Welding nozzle with cover]
A welding nozzle with a cover according to the present invention has the nozzle cover detachably attached to the outer circumference of the welding nozzle. In this case, the tip side of the welding nozzle is attached so as to protrude ahead of the diffusion portion of the nozzle cover.

[Nozzle cover]
Since the nozzle cover of the present invention is provided with the diffusion portion that widens outward at the tip of the inner cover, the air ejected from the air outlet of the nozzle cover is diffused outward by the diffusion portion of the nozzle cover. As a result, scattering of spatter generated by arc welding can be suppressed, and spatter is less likely to adhere to screws, metal parts, and the like near the welding location.

[Welding nozzle]
Since the welding nozzle of the present invention has both or one of the flange and the concave groove, the air ejected from the air outlet of the nozzle cover is less likely to flow into the outlet side of the gas passage of the welding nozzle. As a result, the ejection of the shielding gas from the outlet of the gas passage is less likely to be adversely affected.

[Welding nozzle with cover]
In the covered welding nozzle of the present invention, since the nozzle cover is attached to the welding nozzle, the effects of both the nozzle cover and the welding nozzle can be obtained.

1 is a cross-sectional view of a covered welding nozzle of the present invention; FIG. FIG. 2 is a cross-sectional view of a nozzle with a collar, which is a welding nozzle with a cover according to the present invention. 1 is a cross-sectional view of a grooved welding nozzle with cover according to the present invention; FIG. 1 is a cross-sectional view of a covered welding nozzle of the present invention with a collar and groove; FIG.

(Embodiment 1)
FIG. 1 shows Embodiment 1 of a welding nozzle with a cover according to the present invention, in which a nozzle cover 2 is attached to the outer circumference of the welding nozzle 1 .

[Welding nozzle]
The welding nozzle 1 shown in FIG. 1 is a general-purpose product, and has a connecting hole 4 in the upper part of the tapered outer cylinder 3, a welding tip 5 inside the outer cylinder 3, and the inner peripheral surface of the outer cylinder 3 and the welding tip 5. There is a gas passage 6 through which the shielding gas flows between it and the outer peripheral surface, and the lower end of the gas passage 6 is a gas outlet 7 . The inner peripheral surface of the connecting hole 4 is threaded with a screw 4a for attaching and detaching a torch body (not shown). A welding wire 8 can be passed through the center of the welding tip 5 .

[Nozzle cover]
The nozzle cover 2 shown in FIG. 1 is press-fitted to the inside of the outer cover 10 so that the inner cover 11 does not come off. The air channel 12 communicates with an air supply port 13 on the outside of the outer cover 10, and has an air outlet 14 at its lower end. The air is jetted (air blow) from the air outlet 14 through the .

The inner cover 11 has a cylindrical shape with an inner diameter that can be attached to the outer periphery of the welding nozzle 1, and is press-fitted inside the outer cover 10 so as not to come off. On the tip side of the inner cover 11, there is a spreading portion 15 that spreads outward. The diffusing portion 15 protrudes farther than the front end portion 16 of the outer cover 10 and the air outlet 14, and protrudes to the outside of the air outlet 14 to widen at the bottom. It is designed to be diffused outward. The divergence angle α of the diffusing portion 15 can be designed to be an angle at which the colliding air is easily diffused outward. It is desirable that the diffusing portion 15 be provided along the entire circumference or substantially the entire circumference of the inner cover 11 on the distal end side.

A fixing portion 17 is provided on the upper portion of the outer cover 10 . In FIG. 1, the fixing portion 17 is a screw. When the screw is tightened, the tip thereof is pressed against the inner cover 11 to press the inner cover 11 against the outer cylinder 3 of the welding nozzle 1 so that the nozzle cover 2 does not come off from the welding nozzle 1.例文帳に追加When the screw of the fixing portion 17 is loosened, the tip of the screw separates from the inner cover 11, releasing the pressure of the inner cover 11 against the outer cylinder 3 of the welding nozzle 1, and the nozzle cover 2 can be removed from the welding nozzle 1. become able to. As long as the fixing part 17 can fix the nozzle cover 2 to the welding nozzle 1, other structures such as a band capable of expanding/reducing the inner diameter, or other devices may be used.

[Welding nozzle with cover]
FIG. 1 shows a welding nozzle with a cover, in which the outer periphery of a general-purpose welding nozzle 1 is covered with a nozzle cover 2 having the structure described above. In FIG. 1 , the nozzle cover 2 covers the upper periphery of the welding nozzle 1 and the tip side of the welding nozzle 1 protrudes beyond the diffusion portion 15 of the nozzle cover 2 . By protruding in this manner, the nozzle cover 2 is prevented from coming into contact with the welding member even if the welding torch is tilted a little and the welding operation is performed.

[Operation of welding nozzle with cover in Fig. 1]
When arc welding is performed using the covered welding nozzle of _FIG . At this time, high-pressure air is supplied from the air supply port 13 of the nozzle cover 2 to the air flow path 12, and the air is ejected (air blown) from the air outlet 14. As shown in FIG. The jetted air is diffused outward by the diffusion portion 15 of the nozzle cover 2, does not affect the shielding gas jetted from the gas outlet 7, and suppresses scattering of spatter generated by arc welding. As a result, the spatter is less likely to scatter over a long distance, and the amount of spatter falling on screws, metal parts, and the like near the welded portion is reduced, thereby preventing the screws and metal parts from becoming defective. In addition, since the scattered spatter is cooled by the air ejected from the air outlet 14 of the nozzle cover 2, even if the spatter falls on screws or metal parts, it will not easily adhere to them, and even if it adheres, it will easily peel off. Become.

(Embodiment 2)
FIG. 2 shows Embodiment 2 of the welding nozzle with a cover of the present invention, in which a nozzle cover 2 is attached to the upper periphery of the welding nozzle 1 as in the case of FIG.

The welding nozzle 1 of FIG. 2 has the same basic configuration as the welding nozzle 1 of FIG.

The welding nozzle 1 of FIG. 2 is provided with three flanges 20 spaced apart from each other on the tip side in the axial direction. The flange 20 is for preventing the air jetted from the air outlet 14 of the nozzle cover 2 from going around to the gas outlet 7 side of the welding nozzle 1 . The sizes (protrusion dimensions), intervals, etc. of the three flanges 20 shown in FIG. 2 are designed to prevent the wraparound. The sizes are not all the same, and the upper ones may be made larger than the lower ones, or vice versa. The collar 20 can be attached by welding a ring to the tip of the welding nozzle 1, but it can also be attached by fitting a general-purpose C ring into a groove provided on the tip side of the welding nozzle 1. The number of collars 20 can be one or any number of two or more. If there are two or more, they are attached at intervals in the axial direction of the welding nozzle 1.

[Operation of welding nozzle with cover in FIG. 2]
Arc welding using the welding nozzle with a cover of FIG. 2 is performed in the same manner as in the case of FIG. At this time, since the air ejected from the air outlet 14 is diffused outward by the diffusion portion 15 of the nozzle cover 2, the same effect as in the case of FIG. 1 is obtained. Furthermore, since the flange 20 suppresses the air that wraps around to the tip side of the welding nozzle 1, the amount of air that wraps around to the gas outlet 7 is reduced, and the shielding gas ejected from the gas outlet 7 is less likely to be affected. , there is no problem with arc welding.

(Embodiment 3)
FIG. 3 shows Embodiment 3 of the welding nozzle with a cover of the present invention, in which a nozzle cover 2 is attached to the upper periphery of the welding nozzle 1 .

The welding nozzle 1 of FIG. 3 has the same basic configuration as that of FIG.

The welding nozzle 1 of FIG. 3 is provided with three grooves 30 spaced apart from each other on the tip side in the axial direction. The concave groove 30 is for preventing the air jetted from the air outlet 14 of the nozzle cover 2 from going around to the gas outlet 7 side of the welding nozzle 1 . Each of the three concave grooves 30 in FIG. 3 is ring-shaped (annular), and the depth, width, interval, etc., are designed so as to prevent the wraparound. The depth and width are not all the same, and the upper layer may be deeper and wider than the lower layer, or vice versa. The groove 30 may be spiral. The number of grooves 30 may be one or an arbitrary number of two or more.

[Operation of welding nozzle with cover in FIG. 3]
Arc welding using the welding nozzle with a cover in FIG. 3 is performed in the same manner as in FIGS. At this time, since the air ejected from the air outlet 14 is diffused outward by the diffusion portion 15 of the nozzle cover 2, the same effect as in the case of FIG. 1 is obtained. Furthermore, since the groove 30 prevents the air jetted toward the tip of the welding nozzle 1 from flowing toward the gas outlet 7 of the welding nozzle 1, the shielding gas jetted from the gas outlet 7 is not affected. It becomes hard and does not interfere with arc welding.

(Embodiment 4)
FIG. 4 shows Embodiment 4 of the welding nozzle with a cover of the present invention, in which a nozzle cover 2 is attached to the upper periphery of the welding nozzle 1 .

The welding nozzle 1 of FIG. 4 has the same basic configuration as that of FIG.

The welding nozzle 1 of FIG. 4 has two concave grooves 30 and one mounting groove 21 spaced apart from each other on the tip end side in the axial direction, and a flange 20 is mounted in the mounting groove 21 . The concave groove 30 and the flange 20 are for preventing the air jetted from the air outlet 14 of the nozzle cover 2 from going around to the gas outlet 7 side of the welding nozzle 1 . The two concave grooves 30 in FIG. 4 are ring-shaped (annular) like the concave groove 30 in FIG. The collar 20 of FIG. 4 is similar to the collar 20 of FIG. The number of grooves 30 and the number of flanges 20 can be arbitrary. If the mounting groove 21 is shallower and narrower than the lower two grooves 30 like the uppermost groove 30 in FIG. 3, the C-ring can be easily mounted.

[Operation of Covered Welding Nozzle in FIG. 4]
Arc welding using the welding nozzle with a cover in FIG. 4 is performed in the same manner as in FIGS. Also in this case, the air ejected from the air outlet 14 is diffused outward by the diffusion portion 15 of the nozzle cover 2, so that the same effect as in the case of FIG. 1 is obtained. Furthermore, since the air ejected to the tip side of the welding nozzle 1 is suppressed from flowing toward the gas outlet 7 side of the welding nozzle 1 by both the flange 20 and the groove 30, the air ejected from the gas outlet 7 is shielded. It becomes less affected by gas and does not interfere with arc welding.

The above Embodiments 1 to 4 are examples of the present invention. The present invention can be modified in design to the extent that the problems of the present invention can be solved.

1 welding nozzle 2 nozzle cover 3 outer cylinder 4 connecting hole 4a screw 5 welding tip 6 gas passage 7 gas outlet 8 welding wire 10 outer cover 11 inner cover 12 air flow path 13 air supply port 14 air outlet 15 diffusion part 16 (outer cover ) tip portion 17 fixing portion 20 collar 21 mounting groove 30 concave groove

Claims (5)

A nozzle cover that can be attached to and detached from a welding nozzle for gas-shielded arc welding,
The nozzle cover has a cylindrical outer cover on the outer periphery of a cylindrical inner cover attached to the outer periphery of the welding nozzle,
The outer cover has an air supply port,
An air flow path communicating with the air supply port is provided between the inner cover and the outer cover,
The lower end of the air flow path serves as an air outlet,
At the tip of the inner cover, there is a diffusing part that expands to the outside, and the diffusing part protrudes beyond the tip of the outer cover and the air outlet,
The air supplied from the air supply port, passed through the air flow path, and ejected from the air outlet is diffused outward by the diffusion portion,
A nozzle cover characterized by: The nozzle cover according to claim 1,
The diffusive part is a flared bottom that protrudes to the outside of the air outlet,
A nozzle cover characterized by: In the nozzle cover according to claim 1 or claim 2,
The diffusing portion is formed around the entire circumference or substantially the entire circumference of the inner cover on the tip side,
A nozzle cover characterized by: A welding nozzle for gas-shielded arc welding,
One or more of a ring-shaped flange protruding outside the outer peripheral surface and/or a concave groove are provided on the outer peripheral surface of the tip side of the welding nozzle,
The two or more collars or grooves are spaced apart in the axial direction of the welding nozzle,
A welding nozzle characterized by: A welding nozzle for gas-shielded arc welding,
A nozzle cover is detachably attached to the outer periphery of the welding nozzle,
The welding nozzle is the welding nozzle of claim 4,
The nozzle cover is the nozzle cover according to any one of claims 1 to 3,
The tip of the welding nozzle or the flange or groove of the welding nozzle protrudes forward from the diffusion portion of the nozzle cover,
A welding nozzle with a cover, characterized in that:

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