Robust mechanical systems with mechatronic devices: parameters identification and vibration control

Надіслано: Травень 19, 2015
Переглянуто: Серпень 12, 2015
Прийнято: Вересень 16, 2015
1
Kyiv National University of Construction and Architecture
2
Kyiv National University of Construction and Architecture

The disturbance estimated with the help of advanced mechatronic devices is used for realization of robust mechanical system, such as agricultural machines. In the actual application, the estimated disturbance is effective not only for the disturbance compensation but also for the parameter identification in the mechanical system. The identified external force is applicable to sensorless force feed-back control in mechanical system and is utilized for a realization of mechanical vibration control. The progress of robust control technologies makes it possible to realize high performance motion control. In the industrial drive system such as a modern agricultural machine with advanced mechatronic device system for motion control, however, the developed technology is not enough to obtain the stable and high speed motion response since the mechanical vibration arises under the high accuracy positioning control. The mechanical vibration control is also taken in the field of the motion control. In particular, a vibration control based on the external force feedback brings the sophisticated advantages to the mechatronic system. The paper introduces a vibration control strategy based on the external force feedback called “resonance ratio control” in multiple resonance system. In this case, the external force may be obtained by using the identification process.

[1] Ohnishi K. Motion Control for Advanced Mechatronics / K. Ohnishi, M. Shibata, T. Murakami // IEEE/ASME Transactions on Mechatronics. – 1996. – Vol. 1. – № 1 – pp. 56–67.
[2] Gopinath B. On the control of linear multiple input – output systems / B. Gopinath // Bell System Tech. J. – 1971. – Vol. 50. – № 3. – pp. 1063–1081.
[3] Sonthward S. Robust nonlinear stick-slip friction compensation / S. Sonthward, C. Radcliffe, C. Maccluer // ASMEJ. Dynamics Syst., Masurement, Contr. – 1991. – Vol. 113. – pp. 639–645.
[4] Murakami T. Torque sensorless control in multi-degree-of-freedom manipulator / T. Murakami, K. Ohnishi // IEEE Trans. Ind. Electron. – 1993. – Vol. 40. – № 2.
[5] Murakami T. et al., Eds., J. Robot. Soc. Jpn., Special Issue on Advanced Motion Control in Vibration System. – 1995. – Vol. 13. – №. 8.
[6] Seto K., Yoshida K., Nonami K., Eds., in Proc. ISME First Int. Conf. Motion, Vibration Contr., Yokohama, 1992.
[7] Yoshida K., Nonami K., Eds., in Proc. Snd Int. Conf. Motion, Vibration Contr., Yokohama, 1994.
[8] Buja G., Fujita H., Obnishi K., Eds., Recent Advances in Motion Control. – The Nikkan Kogyo Shimbun Std., 1990.
[9] Kyura N. The development of a controller for mechatronics equipment / N. Kyura // IEEE Trans. Ind. Electron. – 1996. – vol. 43. – No. 1. – pp. 30–37.
[10] More T. Mecha-tronics / T. Mori // Yaskawa Internal Trademark Application Memo. – 1969. – July 12. – 21.131.01.
[11] Hori Y. Theories and applications of advanced motion control / Y. Hori, N. Kyura, Y. Kawabata // Trans. IEEE Jpn. – 1990. – Vol. 110-D. – No.11 – pp. 1110–1118.
[12] Sumimoto T. Vibration analysis system for mechatronics products / T. Sumimoto, H. Hamamatsu // Yaskawa Denki. – 1989. – Vol. 53. – No. 204. – pp. 259–264.
[13] Takahashi Y. Control and Dynamic Systems / Y. Takahashi, M.J. Rabins, D.M. Auslander // Reading, MA^ Addison-Wesley, 1972.
[14] Franklin G. F. Feedback Control of Dynamic Systems / G. F. Franklin, J. D. Powell, A. Emami – Naeini // Reading, MA: Addison-Wesley, 1986.
[15] Kyura N. Mechatronics – Au industrial Perspective / N. Kyura, H. Oho // IEEE/ASME Transactions on Mechatronics. – 1996. – Vol. 1. – No. 1. – pp. 10–15.
[16] Ansulander D. M. What is Mechatronics? / D. M. Auslander // IEEE/ASME Transactions on Mechatronics. – 1996. – Vol. 1. – No. 1. – pp. 5–9.
[17] Isermann R. Modeling and Design Methodology for Mechatronic Systems / R. Isermann // IEEE/ASME Transactions on Mechatronics. – 1996. – Vol. 1. – No. 1. – pp. 16–27.
[18] Luo C. R. Sensor Technologies and Microsensor Issues for Mechatronics Systems / C. R. Luo // IEEE/ASME Transactions on Mechatronics. – 1996. – Vol. 1. – No. 1. – pp. 39–49.
[19] Miller G. L. Tutorial introduction to sensors / G. L. Miller // Advanced Sensor Development in Japan. Information Gatekeepers, Inc. – 1989. – No. 1.
[20] Luo. R.C. Multisensor Integration and fusion in intelligent systems / R.C. Luo, M.G. Kay // IEEE Trans. Syst., Man., Cybern. – 1989. – Vol. 5. – pp. 901–931.
[21] Schweitzer G. Mechatronics for the Design of human-Oriented Machines / G. Schweitzer // IEEE/ASME Transactions on Mechatronics. – 1996. – Vol. 1. – No. 2. – pp. 120–126.
[22] Hirzinger G. Mechatronics for a New Robot Generation / G. Hirzinger // IEEE/ASME Transactions on Mechatronics. – 1996. – Vol. 1. – No. 2. – pp. 149–157.
[23] Walker M.W. Resolved-acceleration control of mechanical manipulators / M.W. walker, R.P.C. Naul // IEEE Trans. Automat. Contr. – 1980. – Vol. AC-25. – pp. 468–474.
[24] Чoвнюк Ю. Уточнена динамічна модель руху візка з вантажем на гнучкому підвісі . Ю. Човнюк // MOTROL. – 2011. – V. 13B. – pp. 130–137.
[25] Ловейкін В. С. Анализ динамических нагрузок в канатах подъемных кранов методом временных сплайнов / В. С. Ловейкин, Ю. В. Човнюк, П. Лымарь // MOTROL. – 2014. – Vol.16. – No 3. – pp. 12–18.