The Investigation of Monitoring Systems for SMAW Processes

Nabeel K. Abid Al-Sahib; Osamah F. Abdulateef; Ahmed Samir Hamza

Authors

Nabeel K. Abid Al-Sahib Department of Mechatronics Engineering/ AL-Khwarizmi College of Engineering/ University of Baghdad
Osamah F. Abdulateef Department of Manufacturing Operation Engineering / AL-Khwarizmi College of Engineering/ University of Baghdad
Ahmed Samir Hamza Department of Mechatronics Engineering/ AL-Khwarizmi College of Engineering/ University of Baghdad

Abstract

The monitoring weld quality is increasingly important because great financial savings are possible because of it, and this especially happens in manufacturing where defective welds lead to losses in production and necessitate time consuming and expensive repair. This research deals with the monitoring and controllability of the fusion arc welding process using Artificial Neural Network (ANN) model. The effect of weld parameters on the weld quality was studied by implementing the experimental results obtained from welding a non-Galvanized steel plate ASTM BN 1323 of 6 mm thickness in different weld parameters (current, voltage, and travel speed) monitored by electronic systems that are followed by destructive (Tensile and Bending) and non-destructive (Hardness on HAZ) tests to investigate the quality control on the weld specimens. The experimental results obtained are then processed through the ANN model to control the welding process and predict the level of quality for different welding conditions. It has been deduced that the welding conditions (current, voltage, and travel speed) have a dominant factors that affect the weld quality and strength. Also we found that for certain welding condition, there was an optimum weld travel speed to obtain an optimum weld quality. The system supports quality control procedures and welding productivity without doing more periodic destructive mechanical test to dozens of samples.

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References

[1] Rong - Ho (Ron) Lin & Gary W. Fischer, "An On-Line Arc Welding Quality Monitor and Process Control System", 1994, Proceedings of the Second International Conference on Machine Learning and Cybernetics, 0-7803-2646-6 1994 IEEE.
[2] C. S. WU, T. Polet & D. Rehfeldt, "A Fuzzy Logic System for Process Monitoring and Quality Evaluation in GMAW", 2001,Sponsored by the American Welding Society and the Welding Research Council. WELDING JOURNAL 33-s to 38-s.
[3] Hallowell Avenue Arcadia, "Weld Monitoring Primer for MicroResistance Welding – Update", 2005, MicroJoining Solutions – microTips™ 5563, CA 91007.
[4] Rittichai Phounium & Bovornchok Poopat, "On-line Quality Monitoring of Welding Defect Susceptibility in SMAW", 2001, by King Mongkut's University of technology Thonburi, Bankok.
[5] CHUN-HUA ZHANG, LI DI, ZENG AN, "Welding Quality Monitoring and Management System Based on Data Mining Technology", 2003, Proceedings of the Second International Conference on Machine Learning and Cybernetics 0-7803-7865-2/03/ 17.00 2003 IEEE, pp 13-17.
[6] A. G. Glover, J. T. McGrath, M. J. Tinkler & G. C. Weatherly, "The Influence of Cooling Rate and Composition on Weld Metal Microstructure in C-Mn & HSLA Steels", 1977, Welding Journal, pp. 267s - 273s.
[7] G. M. Evans, "Effect of Manganese on Microstructure and Properties of All Weld Metal Deposits", 1980, Welding Journal, pp. 67s - 75s.
[8] M. ZHOU, H. ZHANG, & S. J. HU., "Relationships between Quality and Attributes of Spot Welds", 2003, Sponsored by the American Welding Society and the Welding Research Council, Welding Journal, 72-s to 77-s.
[9] Sadek C.A. Alfaro, Diogo de S. Mendonca and Marcelo S. Matos, "Emission spectrometry evaluation in arc welding monitoring system"2006, Published by Elsevier Science Ltd. Journal of Materials Processing Technology, Vol. 179, (2006) pp. 219 – 224.
[10] Aimen Mohammed Ahmed Bachaa, "Wear Monitoring in Turning Processes using Vibration and Strain Measurements", 2005, Msc thesis - Mechanical Engineering – Baghdad University.