KR20070002466A - Laser vision sensor system tracking welding line - Google Patents

Abstract

A laser vision system which reduces a distance between a welding torch and a laser diode to track a welding line in near real-time when performing TIG welding using a welding wire feeder, and can avoid interference of a welding wire accordingly is provided. A laser vision system for tracking a welding line comprises: two light generators distanced from a torch(110) in a welding direction and installed at both sides of a welding line; cameras(100) installed such that the cameras are spaced from the light generators in the welding direction. The cameras are parallel to the torch, and the laser vision system for tracking a welding line further comprises optical mirrors(102) slantly installed in lower parts of the cameras. The laser vision system for tracking a welding line further comprises protection glasses(104) installed below the optical mirrors. The laser vision system for tracking a welding line further comprises an other laser vision system oppositely to the laser vision system based on the torch.

Description

Laser Vision Sensor System tracking welding line

1 is a perspective view of a conventional laser vision system for tracing weld lines.

2 is a perspective view showing an embodiment of a laser vision system for welding seam tracking according to the present invention.

3 is a side view showing the embodiment shown in FIG.

4 is a photograph using the laser vision system shown in FIG.

<Explanation of symbols for the main parts of the drawings>

100: camera 102: optical mirror

104: protective glass 110: welding torch

120: laser diode 122: laser stripe

130: welding wire 140: pipe

The present invention relates to a laser vision system for welding seam tracking, and more particularly to a laser vision system for seam tracking that can be avoided from interference of the welding wire during the TIG (TIG) welding of the liquefied natural gas pipe.

Due to the advancement of industrial technology and the improvement of the working environment, many phenomena have been avoided.

For this reason, a variety of automation equipments are emerging to allow robots to work on behalf of humans in harsh environments.

In particular, in the shipbuilding industry, welding is dangerous in a position to be fused, and the environment is also poor, and more realization of automation is required.

Therefore, in order to automate the hull assembly process of the ship, the function of automatically tracking the weld line must be provided, and by this function, the welding torch can be accurately positioned on the weld line to obtain good welding quality.

In general, weld line tracking sensors are mounted at the front end of the welding torch and are divided into contact and non-contact types. Among them, the laser vision sensor is widely used as a non-contact welding seam tracking sensor.

The laser vision sensor is generally composed of a laser diode that emits a laser and a camera that detects the weld line by receiving the emitted laser reflected from the welded object and returning.

1 shows a weld seam tracking sensor for a pipe of a conventional liquefied natural gas carrier.

As shown in FIG. 1, in the conventional laser vision sensor, a welding wire 50 is injected from the front surface of the welding torch 20, and the welding torch 20 is forwardly aligned with the welding wire 50. A laser diode 30 is mounted which emits laser light spaced by a predetermined distance.

 A charge coupled device (CCD) camera 10 having a predetermined tilt is mounted in front of the laser diode 30.

The laser diode 30 is scanned by the laser diode 30 in the direction of the welding line 60, is reflected by the welding line 60, and then photographed by the camera 10.

Liquefied natural gas pipes are made of stainless steel, so most of them use TIG welding. TIG welding is a tungsten inert gas welding, in which an arc is generated between a tungsten electrode having a highest melting point and a base metal, and the welding is protected by argon gas to prevent oxidation and nitriding during welding.

In particular, the welding machine to be used in this development is a TIG welding machine using a welding wire injector, and the welding machine has a structural feature of injecting a welding wire 50 from the outside.

However, in the TIG welding using the welding wire injector, since the separation between the welding torch and the laser vision system is large due to the interference of the welding wire, it is impossible to trace the weld line in real time and there is a concern of welding failure.

The present invention has been made to overcome the disadvantages of the prior art as described above, to reduce the separation between the welding torch and the laser diode for near-real-time weld line tracking in the TIG welding using a welding wire injector, thereby The technical challenge is to provide a laser vision system that avoids interference.

In order to achieve the above technical problem, a laser vision system for welding seam tracking according to the present invention, two light generators spaced apart from the torch in the welding direction and positioned on both sides of the welding line; It provides a laser vision system for welding seam tracking comprising a camera which is spaced apart from the light generator in the welding direction.

Preferably, the camera may further include an optical mirror positioned in parallel with the torch, inclined at the bottom of the camera.

This is the preferred form for increasing the separation angle. The separation angle refers to the angle between the laser and the camera. The larger the separation angle, the more obvious the shape of the groove, and the better the image processing of the camera.

 In order to increase the separation angle without the optical mirror, it is necessary to increase the installation angle of the camera, which increases the size of the laser vision system, and uses an upright camera and an optical mirror to avoid this.

Preferably, the lower surface of the optical mirror may further include a protective glass.

Thus, the lens of the camera and the optical mirror can be protected from dust, welding gas, etc. generated during welding.

Preferably, another laser vision system may be located opposite the laser vision system with respect to the torch.

This is related to the welding path of the liquefied natural gas pipe. The welding machine welds the semicircle from the lowest end to the highest end of the pipe, and then moves back to the lowest end to draw the semicircle on the opposite side and welds to the highest end. Has This is to exclude this, because when welding from the top to the bottom, the flow of the material is likely to cause poor welding.

For this reason, another laser vision system is mounted on the opposite side of the torch, so that it can be welded in a dual path clockwise or counterclockwise.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 is a perspective view showing an embodiment of a laser vision system for welding seam tracking according to the present invention.

As shown in FIG. 2, two light generators 120 are positioned at both sides of the welding line 142 and spaced apart from the torch 110 in the welding direction.

In this case, a laser diode is used as the light generator 120.

The light output from the laser diode has its own divergence and thus is difficult to use directly. For this reason, collimated beams are made by using aspherical lenses and various lenses, and line beams are generated by using them.

The two laser diodes 120 scan the laser light 122 into the pipe 140 to be welded.

In this case, the two laser lights 122 have a portion overlapping with respect to the welding wire 130 injected along the welding line 142. This makes it possible to avoid the interference caused by the welding wire in a single light source.

The camera 100 is spaced apart from the two laser diodes 120 in the welding direction and positioned in parallel with the torch 110. The optical mirror 102 is inclinedly mounted on the lower portion of the camera 100. In another embodiment, the camera may be mounted obliquely.

Separation angle refers to the angle between the laser and the camera 100, the larger the separation angle is the shape of the groove (Groove) is clear and the image processing of the camera 100 is better.

However, in order to increase the separation angle without the optical mirror 102, it is possible to increase the installation angle of the camera 100. However, this increases the size of the laser vision system, it is effective to use the optical mirror 102 for the vertical installation of the camera 100 and to change the incident angle.

At this time, the inclination of the optical mirror 102 increases the separation angle (for example, 60 degrees).

This is because the shape of the groove can be clearly seen due to the large separation angle, and image processing is improved.

The protective glass 104 is mounted on the front surface of the optical mirror 102. This serves to prevent the optical mirror 102 or the lens of the camera 100 from being damaged during welding, and uses a normal transparent glass through which the laser light can pass. You may use it.

3 is a side view showing the embodiment shown in FIG.

As shown in FIG. 3, the laser vision system based on the torch 110 has a form that includes another laser vision system symmetrically opposite.

In order to weld the circular liquefied natural gas pipe 140, the welding path of the welder does not consist of only one rotation in one direction.

It is recommended to weld from bottom to top to improve the quality of the weld. This is because, in the case of welding while moving from the top to the bottom, the melted material at high temperature flows downward, and there is a high possibility of defects in the beads.

For this reason, the welding moves from the bottom up, but the circular pipe 140 as described above does not end the welding by only one revolution.

That is, in the circular pipe 140, it is divided into the lowest end and the highest end, and the welding is performed by moving the semicircle from the lowest end to the highest end in the clockwise direction first, and then moving back in the counterclockwise direction to return to the lowest end point.

Then, we weld with the semicircle moving from the lowest end to the highest end in the counterclockwise direction, and then moving back clockwise to return to the lowest end. As another embodiment, welding may be performed in the reverse order to the above.

In order to have the welding path as described above, two laser vision systems are mounted in both directions of the torch 110 so that the welding line can be sensed even when moving in any direction in both directions.

In addition, the laser vision system performs welding seam tracking using only 1Pass groove shape after welding 1Pass manually, and multi-pass is based on the characteristics of pipe welding. .

4 is a photograph using the laser vision system shown in FIG.

As shown in FIG. 4, the liquefied natural gas pipe 140, which is a welded object, and a welding line 142 positioned vertically at the center portion thereof, and a laser light 122 are scanned in a horizontal direction perpendicular to the weld line 142.

At this time, the non-sensing part generated by the interference by the welding wire did not appear.

In addition, by adding an optical mirror to increase the separation angle (for example 60 degrees), the image of the groove appears clearly.

According to the present invention, in constructing a laser vision system that enables near-real-time welding seam tracking in a TIG welding using a welding wire injector, two light generators are used to avoid interference due to welding wires, and thus welding line tracking is performed. Can be measured closer to real time.

Claims (4)

Two light generators spaced apart from the torch in the welding direction and positioned on both sides of the welding line; And a camera positioned spaced apart from the light generator in the welding direction. The method of claim 1, And the camera further comprises an optical mirror positioned parallel to the torch and inclined at the bottom of the camera. The method of claim 2, The laser vision system for welding seam tracking further comprises a protective glass at the lower end of the optical mirror. The method of claim 1, And another laser vision system is positioned opposite the laser vision system with respect to the torch.

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