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Optimization of the semi-active vibration absorbers

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Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
In this paper, an efficient numerical approach is proposed to maximize the minimal damping of modes in a prescribed frequency range for general viscous tuned-mass systems. Methods of decomposition and numerical synthesis are considered on the basis of the adaptive schemes. The influence of dynamic vibration absorbers and basic design elastic and damping properties is under discussion. A technique is developed to give the optimal DVA’s for the elimination of excessive vibration in sinusoidal and impact forced system. One task of this work is to analyze parameters identification of the dynamic vibration absorber and the basic structure. The questions of robustness at optimization of DVA are considered. Different types of control management for semi-active DVA’s are applied. Examples of DVA’s practical implementation are presented.
Rocznik
Strony
327--336
Opis fizyczny
Bibliogr. 18 poz., rys., wykr.
Twórcy
  • Lviv National Agrarian University – LNAU, Faculty of Mechanical and Power Engineering
  • Warsaw University of Life Sciences – SGGW, Institute of Civil Engineering, Department of Mechanics and Building Structures, Nowoursynowska 159, 02-776 Warsaw, Poland
  • Lviv Polytechnic National University – LPNU, Institute of Engineering Mechanics and Transport
autor
  • Lviv Polytechnic National University – LPNU, Institute of Engineering Mechanics and Transport
  • Lviv Polytechnic National University – LPNU, Institute of Engineering Mechanics and Transport
  • Lviv National Agrarian University – LNAU, Faculty of Mechanical and Power Engineering
  • Lviv National Agrarian University – LNAU, Faculty of Mechanical and Power Engineering
Bibliografia
  • Allen, F. & Karjalainen, R. (1999). Using genetic algorithms to find technical trading rules. Journal of Financial Economics, 51(2), 245-271.
  • Casciati, F., Magonette G. & Marazzi F. (2006). Technology of semiactive devices and applications in vibration mitigation. New York: Wiley.
  • Diveyev, B., Horbay, O., Kernytskyy, I., Pelekh, R. & Velhan, I. (2017). Dynamic properties and damping predictions for laminated micro-beams by different boundary conditions. In 13th International Conference on Perspective Technologies and Methods in MEMS Design: Lviv 20-23 April 2017 (pp. 30-34). New York: IEEE.
  • Fowlkes, W.Y. & Creveling, C.M. (1995). Engineering methods for robust product design: using Taguchi methods in technology and product development. Reading, MA: Addison-Wesley Publishing Company.
  • Hu, H. & Jin, D. (1997). A semi-active vibration control strategy based on piecewise linear vibration absorbers. Journal of Vibration Engineering, 10(2), 125-130.
  • Kernytskyy, I., Diveyev, B., Horbaj, O., Hlobchak, M., Kopytko, M. & Zachek, O. (2017). Optimization of the impact multi-mass vibration absorbers. Scientific Review Engineering and Environmental Sciences, 26(3), 394-400.
  • Koo, J.H. & Ahmadian, M. (2004). In search of suitable control methods for semi-active tuned vibration absorbers. Journal of Vibration and Control, 10(2), 163-174.
  • Moutinho, C. (2015). Testing a simple control law to reduce broadband frequency harmonic vibrations using semi-active tuned mass dampers. Smart Materials and Structures, 24(5), 055007. https://doi.org/10.1088/0964-1726/24/5/055007
  • Nagarajaiah, S. (2009). Adaptive passive, semiactive, smart tuned mass dampers: identification and control using empirical mode decomposition, Hilbert transform, and short-term Fourier transform. Structural Control and Health Monitoring: The Official Journal of the International Association for Structural Control and Monitoring and of the European Association for the Control of Structures, 16(7-8), 800-841.
  • Pelekh, Y., Konyk, I., Hlobchak, M., Cherchyk, G., Opalko, V. & Diveyev, B. (2017). Optimization of the particle vibration absorbers as SDOF system. In 13th International Conference on Perspective Technologies and Methods in MEMS Design: Lviv 20-23 April 2017 (pp. 30-34). New York: IEEE.
  • Pinkaew, S.T. & Fujino, Y. (2001). Effectiveness of semi-active tuned mass dampers under harmonic excitation. Engineering Structures, 23(7), 850-856.
  • Qian, X. & Hu, H. (2001). A semi-active vibration absorber with an adjustable clearance and its realization. Journal of Vibration Engineering, 14(4), 378-381.
  • Seiler, G., Fischer, O. & Huber, P. (2002). Semi-active MR dampers in TMD’s for vibration control of footbridges: II. Numerical analysis and practical realization. Paris: Footbridge Conference.
  • Setareh, M., Ritchey, J.K., Murray, T.M., Koo, J.H. & Ahmadian, M. (2007). Semiactive tuned mass damper for floor vibration control. Journal of Structural Engineering, 133(2), 242-250.
  • Shen, Y. & Ahmadian, M. (2013). Nonlinear dynamical analysis on four semi-active dynamic vibration absorbers with time delay. Shock and Vibration, 20(4), 649-663.
  • Spencer Jr, B.F. & Nagarajaiah, S. (2003). State of the art of structural control. Journal of Structural Engineering, 129(7), 845-856.
  • Weber, F. & Distl, H. (2013). Real-time controlled tuned mass dampers for Wolgograd Bridge. Beton-und Stahlbetonbau, 108(6), 362-372.
  • Zang, C., Friswell, M.I. & Mottershead J.E. (2005). A review of robust optimal design and its application in dynamics. Computers and Structures, 83(4-5), 315-326.
Uwagi
Opracowanie rekordu ze środków MEiN, umowa nr SONP/SP/546092/2022 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2022-2023)
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-294616f7-b2d0-4487-85c6-2e616736f3ae
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