1. MMC
  2. All Volumes and Issues
  3. Volume 3, Number 2, 2016
  4. Longitudinal vibrations of viscoelastic longitudinally nonuniform rod under power load distributed along its length

Longitudinal vibrations of viscoelastic longitudinally nonuniform rod under power load distributed along its length

MMC.
2016;
Volume 3, Number 2
: pp. 135-145
https://doi.org/10.23939/mmc2016.02.135
Received: December 01, 2016

Math. Model. Comput. Vol. 3, No. 2, pp. 135-145 (2016)

Authors:
  1. B. Gera
  2. M. Sitarz
  3. Ya. Bolzhelarskyi
1
Dnipropetrovsk National University of Railway Transport named after Academician V. Lazaryan
2
The University of Dambrowa Górnicza
3
Dnipropetrovsk National University of Railway Transport named after Academician V. Lazaryan

In this article, the dynamic behavior of a moving elongated object is simulated using the relations for a viscoelastic rod, which moves at a constant speed under the action of traction force and distributed along its length external forces of resistance. We investigate the change of displacements and internal forces after the sudden application in the rod section of the local force directed longitudinally. The correlations of the initial boundary value problem that describes the dynamic behavior of the rod are written down, and its solution is obtained in the form of a series expansion in terms of eigenfunctions. For a viscoelastic rod consisting of three connected uniform rods, the analysis of wave processes induced by the application to the rod of a sudden concentrated force that resists the motion is carried out. This affects the motion of the rod as a whole, and induces the wave processes, the propagation and reflection of waves on the inner surfaces of joints. The comparison is performed for the behavior of an elastic, piecewise nonuniform rod and a viscoelastic rod with different mechanical characteristics, where the waves during their propagation are damped and smoothed.

viscoelastic rod
propagation and reflection of longitudinal wave
resistance to motion
  1. Abramson H. N., Plass H. J., Ripperger E. A. Stress Wave Propagation in Rods and Beams. Adv. in Appl. Mech. 5, 111–194 (1958).
  2. Timoshenko S. P., Goodier J. N. Theory of elasticity. McGraw-Hill, N.Y. (1970).
  3. Ke Yang. A unified solution for longitudinal wave propagation in an elastic rod. J. Sound and Vibr. 314 (1,2), 307–329, (2008).
  4. Fu Y. B., Scott N. H. Propagation of simple waves and shock waves in a rod of slowly varying cross-sectional area. Int. J. Engn. Sci. 32 (1), 35–44 (1994).
  5. Chunbiao Gan, Yimin Wei, Shixi Yang. Longitudinal wave propagation in a rod with variable cross-section. J. Sound and Vibr. 333, 434–445 (2014).
  6. Guo S., Zhang Z., Yang S. Longitudinal waves in one-dimensional non-uniform waveguides. Theor. Appl. Mech. Lett. 2, 021007 (2011).
  7. Li Q. S. Exact solutions for free longitudinal vibrations of non-uniform rods. J. Sound and Vibr. 234, 1–19 (2000).
  8. Kumar B. M., Sujith R. I. Exact solutions for the longitudinal vibration of non-uniform rods. J. Sound and Vibr. 207, 721–729 (1997).
  9. Li Q. S. Exact solutions for free longitudinal vibration of stepped non-uniform rods. Appl. Acoustics. 60, 13–28 (2000).
  10. Gera В. Determining of the optimal transient conditions of longitudinal loading for moving one-dimensional elastic system. Physical Modeling and Information Technology. 13, 21–30 (2011), (in Ukrainian).
  11. Schuler K. W., Nunziato J. W., Walsh E. K. Recent results in nonlinear viscoelastic wave propagation. Int. J. Solids and Struct. 9, 10, 1237–1281 (1973).
  12. Campos L. M. B. C., Santos A. J. P. On the propagation and damping of longitudinal oscillations in tapered visco-elastic bars. J. Sound and Vibr. 126 (1), 109–125 (1988).
  13. Lazaryan V. A., Blokhin E. P., Belik L. V. Longitudinal vibrations of nonlinear systems in the one-dimensional perturbations propagating along their length. J Appl. Mech. 9 (6), 89–94 (1973) (in Russian).
  14. Lazaryan V. A., Manashkin L. A., Ryzhov A. V. The longitudinal vibrations of elastic rods at propagating perturbations. J. Appl. Mech. 10 (5), 132–137 (1975) (in Russian).
  15. Blokhin E. P., Manashkin L. A. Train dynamics (nonstationar longitudinal vibrations). Moscow, Transport (1982), (in Russian).
  16. Grebenyuk P. T., Dolganov A. N., Skvortsova A. I. Traction calculations. Moscow, Transport (1987), (in Russian).
  17. Sitarz M., Nowak A., Manka A. Modelling of the dynamics of the railway vehicle by use of the networks graphs. Visnik of the East Ukrainian National University, Transport. 1 (6), 57–61 (2002).
  18. Sitarz M., Nowak A., Verbicki W. Analysis of the Brake-Wheelset Raiway Dynamics during the Motion. Mechanika. 2 (46), 52 (2004).