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Purpose: Since the welding automations have widely been required for industries and engineering, the development of the predicted model has become more important for the increased demands for the automatic welding systems where a poor welding quality becomes apparent if the welding parameters are not controlled. The automated welding system must be modelling and controlling the changes in weld characteristics and produced the output that is in some way related to the change being detected as welding quality. To be acceptable a weld quality must be positioned accurately with respect to the joints, have good appearance with sufficient penetration and reduce low porosity and inclusion content. Design/methodology/approach: To achieve the objectives, two intelligent models involving the use of a neural network algorithm in arc welding process with the help of a numerical analysis program MATLAB have been developed. Findings: The results represented that welding quality was fully capable of quantifying and qualifying the welding faults. Research limitations/implications: Welding parameters in the arc welding process should be well established and categorized for development of the automatic welding system. Furthermore, typical characteristics of welding quality are the bead geometry, composition, microstructure and appearance. However, an intelligent algorithm that predicts the optimal bead geometry and accomplishes the desired mechanical properties of the weldment in the robotic GMA (Gas Metal Arc) welding should be required. The developed algorithm should expand a wide range of material thicknesses and be applicable in all welding position for arc welding process. Furthermore, the model must be available in the form of mathematical equations for the automatic welding system. Practical implications: The neural network models which called BP (Back Propagation) and LM (Levenberg-Marquardt) neural networks to predict optimal welding parameters on the required bead reinforcement area in lab joint in the robotic GMA welding process have been developed. Experimental results have been employed to find the optimal algorithm to predict bead reinforcement area by BP and LM neural networks in lab joint in the robotic GMA welding. The developed intelligent models can be estimated the optimal welding parameters on the desired bead reinforcement area and weld criteria, establish guidelines and criteria for the most effective joint design for the robotic arc welding process. Originality/value: In this study, intelligent models, which employed the neural network algorithms, one of AI (Artificial Intelligence) technologies have been developed to study the effects of welding parameters on bead reinforcement area and to predict the optimal bead reinforcement area for lab joint in the robotic GMA welding process. BP (Back Propagation) and LM (Levenberg-Marquardt) neural network algorithm have been used to develop the intelligent model.
Wydawca
Rocznik
Tom
Strony
32--40
Opis fizyczny
Bibliogr. 19 poz., rys., tab., wykr.
Twórcy
autor
- Department of Mechanical Engineering, Mokpo National University 1666, Yeongsan-ro, Cheonggye-myeon, Muan-gun, Jeonnam, 534-729, South Korea
autor
- Department of Mechanical Engineering, Mokpo National University 1666, Yeongsan-ro, Cheonggye-myeon, Muan-gun, Jeonnam, 534-729, South Korea
autor
- Department of Mechanical Engineering, Mokpo National University 1666, Yeongsan-ro, Cheonggye-myeon, Muan-gun, Jeonnam, 534-729, South Korea
autor
- Research Institute of Medium & Small Shipbuilding, 1703-8 Yongang-ri, Samho-eup, Yeongam, Jeonnam, 526-897, South Korea
autor
- Department of Mechanical Engineering, Mokpo National University 1666, Yeongsan-ro, Cheonggye-myeon, Muan-gun, Jeonnam, 534-729, South Korea
autor
- Department of Mechanical Engineering, Mokpo National University 1666, Yeongsan-ro, Cheonggye-myeon, Muan-gun, Jeonnam, 534-729, South Korea
Bibliografia
- [1] H.B. Smartt, Welding: Theory and Practice, Elsevier Science Publishers, 175-208, 1990.
- [2] Y.W. Park, H.S. Park, S.H. Rhee, M.J. Kang, Real time estimation of CO2 laser weld quality for automotive industry, Optics & Laser Technology 34/2 (2002) 135-142.
- [3] C.H. Tsai, K.H. Hou, H. Chuang, Fuzzy control of pulsed GTA welds by using real-time root bead image feedback, Journal of Materials Processing Technology 176/1 (2006) 158-167.
- [4] D.S. Nagesh. G.L. Datta, Prediction of weld bead geometry and prediction in shield metal-arc welding using artificial neural networks. Journal of Materials Process Technology 57 (2002) 1-10.
- [5] J.M. Vitek, S.A. David, M.W. Richey, J. Biffin, N. Blundell, C.J. Page, Weld pool shape prediction in plasma augmented laser welded steel, Science and Technology of Welding and Joining 6 (2001) 305-314.
- [6] K. Eguchi, S. Yamane, H. Sugi, T. Kubota, K. Oshima, Application of neural network to arc sensor, Science and Technology of Welding and Joining 4 (1999) 327-334.
- [7] J.Y. Jeng, T.F. Mau, S.M. Leu, Prediction of laser butt joint welding parameters using back-propagation and learning vector quantization networks, Journal of Materials Process Technology 99 (2000) 207-218.
- [8] L.T. Srikanthan, R.S. Chandel, Neural network based modeling of GMA welding process using small data sets, Proceedings of the Fifth InternationaI Conference on Control, Automation, Robotics and Vision, Singapore, 1999, 474-478.
- [9] I.S. Kim, K.S. Jun, A study on prediction of optimized penetration using the neural network and empirical models, Journal of Korean Society of Machine Tool Engineers 8/5 (1999) 70-75.
- [10] X. Li, S.W. Simpson, M. Rados, Neural networks for online prediction of quality in gas metal arc welding, Science and Technology of Welding and Joining 5 (2000) 71-79.
- [11] E.A. Metzbower, J.J. DeLoach, S.H. Lalam, H.K.D.H. Bhadeshia, Analysis of toughness of welding alloys for high strength low alloy shipbuilding steels, Science and Technology of Welding and Joining 6 (2001) 368-374.
- [12] C.S. Wu, J.Q. Gao, J.K. Hu, Real-time sensing and monitoring in robotic gas metal arc welding, Measurement Science & Technology 18/1 (2007) 303-310.
- [13] S.C. Juang, Y.S. Tarng, Process parameter selection for optimizing the weld pool geometry in the tungsten inert gas welding of stainless steel, Journal of Material Processing and Technology 122 (2002) 33-37.
- [14] L.K. Pan, C.C. Wang, S.L. Wei, H.F. Sher, Optimizing multiple quality characteristics via Taguchi method-based Grey analysis, Journal of Material Processing and Technology 182 (2007) 107-116.
- [15] I.S. Kim, J.S. Son, P.K.D.V. Yarlagadda, A study on the quality improvement of robotic GMA welding process, Robotics and Computer Integrated Manufacturing 19 (2003) 567-572.
- [16] G. Buffa, G. Campanile, L. Fratini, A. Prisco, A friction stir welding of lap joints: influence of process parameters on the metallurgical and mechanical properties, Journal of Materials Science and Engineering 519 (2009) 16-26.
- [17] E. Salari, M. Jahazi, A. Khodabandeh, H. Ghasemi Nanesa, Influence of tool geometry and rotational speed on mechanical properties and defect formation in friction stir lap welded 5456 aluminium alloy sheets, Journal of Materials and Design 58 (2014) 381-389.
- [18] K. Muzaka, M.H. Park, J.P. Lee, B.J. Jin, D.H. Kim, I.S. Kim, A study on prediction of welding quality for vertical-position welding using mahalanobis distance method, International Journal of Innonvative Research in Engineering & Management 3/3 (2016) 154-150.
- [19] E.I. Poliak, Application of linear regression analysis in accuracy assessment of rolling force calculations, Metals and Materials 4/5 (1998) 1047-1056.
Uwagi
PL
Opracowanie rekordu w ramach umowy 509/P-DUN/2018 ze środków MNiSW przeznaczonych na działalność upowszechniającą naukę (2018).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-5b72deab-d55c-4011-b054-a37565d96578