[1] R. F. Fung, K. W. Chen, “Constant speed control of the quick return mechanism driven by a DC motor,” JSME International Journal 1997; 40(3).
[2] B. El-Kribi, A. Houidi, Z. Affi, L. Romdhane, “Application of multi-objective genetic algorithms to the mechatronic design of a four bar system with continuous and discrete variables,” Mechanism and Machine Theory 2013; 61, 68–83.
[3] J. Tao, J. P. Sadler, “Constant speed control of a motor driven mechanism system,” Mechanism and Machine Theory 1995; 30(5), 737-748.
[4] J. L. Ha, R. F. Fung, K. Y. Chen, S. C. Hsien, “Dynamic modeling and identification of a slider-crank mechanism,” Journal of Sound and Vibration 2006; 289, 1019-1044.
[5] R. J. Wai, F. J. Lin, “A fuzzy neural network controller with adaptive learning rates for nonlinear slider-crank mechanism,” Neuocomputing 1998; 20, 295-320.
[6] F. J. Lin, R. J. Wai, “Adaptive and fuzzy neural network sliding-mode controllers for motor-quick-return servomechanism,” Mechatronics 2003; 13, 477-506.
[7] P. R. Ouyang, Q. Li, W. J. Zhang, L. S. Guo, “Design, modeling and control of a hybrid machine system,” Mechatronics 2004; 14, 1197-1217.
[8] Ö. Gündoğdu, K. Erentürk, “Fuzzy control of a dc motor driven four-bar mechanism,” Mechatronics 2005; 15, 423-438.
[9] Z. Affi, B. El-Kribi, L. Romdhane, “Advanced mechatronic design using a multi-objective genetic algorithm optimization of a motor-driven four-bar system,” Mechatronics 2007; 17, 489-500.
[10] H. S. Yan, G. J. Yan, “Integrated control and mechanism design for the variable input-speed servo four-bar linkages,” Mechatronics 2009; 19, 274-287.
[11] A. K. Tanyıldızı, O. Çakar, “Velocity control of a slider crank mechanism using moving sliding mode control,” 15. Ulusal Makine Teorisi Sempozyumu 2011; 449-457.
[12] O. Çakar, A. K. Tanyıldızı, “Application of moving sliding mode control for a DC motor driven four-bar mechanism,” Advances in Mechanical Engineering 2018; 103, 1-13.
Year 2023,
Volume: 13 Issue: 1, 61 - 67, 30.06.2023
[1] R. F. Fung, K. W. Chen, “Constant speed control of the quick return mechanism driven by a DC motor,” JSME International Journal 1997; 40(3).
[2] B. El-Kribi, A. Houidi, Z. Affi, L. Romdhane, “Application of multi-objective genetic algorithms to the mechatronic design of a four bar system with continuous and discrete variables,” Mechanism and Machine Theory 2013; 61, 68–83.
[3] J. Tao, J. P. Sadler, “Constant speed control of a motor driven mechanism system,” Mechanism and Machine Theory 1995; 30(5), 737-748.
[4] J. L. Ha, R. F. Fung, K. Y. Chen, S. C. Hsien, “Dynamic modeling and identification of a slider-crank mechanism,” Journal of Sound and Vibration 2006; 289, 1019-1044.
[5] R. J. Wai, F. J. Lin, “A fuzzy neural network controller with adaptive learning rates for nonlinear slider-crank mechanism,” Neuocomputing 1998; 20, 295-320.
[6] F. J. Lin, R. J. Wai, “Adaptive and fuzzy neural network sliding-mode controllers for motor-quick-return servomechanism,” Mechatronics 2003; 13, 477-506.
[7] P. R. Ouyang, Q. Li, W. J. Zhang, L. S. Guo, “Design, modeling and control of a hybrid machine system,” Mechatronics 2004; 14, 1197-1217.
[8] Ö. Gündoğdu, K. Erentürk, “Fuzzy control of a dc motor driven four-bar mechanism,” Mechatronics 2005; 15, 423-438.
[9] Z. Affi, B. El-Kribi, L. Romdhane, “Advanced mechatronic design using a multi-objective genetic algorithm optimization of a motor-driven four-bar system,” Mechatronics 2007; 17, 489-500.
[10] H. S. Yan, G. J. Yan, “Integrated control and mechanism design for the variable input-speed servo four-bar linkages,” Mechatronics 2009; 19, 274-287.
[11] A. K. Tanyıldızı, O. Çakar, “Velocity control of a slider crank mechanism using moving sliding mode control,” 15. Ulusal Makine Teorisi Sempozyumu 2011; 449-457.
[12] O. Çakar, A. K. Tanyıldızı, “Application of moving sliding mode control for a DC motor driven four-bar mechanism,” Advances in Mechanical Engineering 2018; 103, 1-13.
Yiğid, O., & Şen, M. (2023). Optimum Design and Control of a Quick-Return Mechanism Used in a Jewelry Welding Powder Production Machine. European Journal of Technique (EJT), 13(1), 61-67. https://doi.org/10.36222/ejt.1181023
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