Real-Time Image Processing for Monitoring of Free Weld Pool Surface-Reference-Cited by-同舟云学术

Real-Time Image Processing for Monitoring of Free Weld Pool Surface

Published:1997-05-01 Issue:2 Volume:119 Page:161-169
ISSN:1087-1357
Container-title:Journal of Manufacturing Science and Engineering
language:en
Short-container-title:

Author:

Kovacevic R.¹,Zhang Y. M.¹

Affiliation:

1. Welding Research and Development Laboratory, Center for Robotics and Manufacturing Systems and, Department of Mechanical Engineering, University of Kentucky, Lexington, KY

Abstract

The arc weld pool is always deformed by plasma jet. In a previous study, a novel sensing mechanism was proposed to sense the free weld pool surface. The specular reflection of pulsed laser stripes from the mirror-like pool surface was captured by a CCD camera. The distorted laser stripes clearly depicted the 3D shape of the free pool surface. To monitor and control the welding process, the on-line acquisition of the reflection pattern is required. In this work, the captured image is analyzed to identify the torch and electrode. The weld pool edges are then detected. Because of the interference of the torch and electrode, the acquired pool boundary may be incomplete. To acquire the complete pool boundary, models have been fitted using the edge points. Finally, the stripes reflected from the weld pool are detected. Currently, the reflection pattern and pool boundary are being related to the weld penetration and used to control the weld penetration.

Publisher

ASME International

Subject

Industrial and Manufacturing Engineering,Computer Science Applications,Mechanical Engineering,Control and Systems Engineering

Link

http://asmedigitalcollection.asme.org/manufacturingscience/article-pdf/119/2/161/5931516/161_1.pdf

Reference19 articles.

1. Rokhlin S. I. , and GuuA. C., 1993, “A Study of Arc Force, Pool Depression, and Weld Penetration during Gas Tungsten Arc Welding,” Welding Journal, Vol. 72, No. 8, pp. 381s–390s381s–390s.

2. Lin, M. L., and Eagar, T. W., 1983, “Influence of Surface Depression and Convection on Arc Weld Pool Geometry,” Transport Phenomena in Material Processing, ASME PED 10, Edited by M. M. Chen, J. Mazumder, and C. L. Tucker III, November 13–18, pp. 63–69.

3. Lin M. L. , and EagarT. W., 1985, “Influence of Arc Pressure on Weld Pool Geometry.” Welding Journal, Vol. 64, No. 6, pp. 163s–169s163s–169s.

4. Renwick R. J. , and RichardsonR. W., 1983, “Experimental Investigation of GTA Weld Pool Oscillations,” Welding Journal, Vol. 62, No. 2, pp. 29s–35s29s–35s.

5. Zacksenhouse M. , and HardtD. E., 1983, “Weld Pool Impedance Identification for Size Measurement and Control,” ASME Journal of Dynamic Systems, Measurement and Control, Vol. 105, No. 3, pp. 179–184.

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