ISSN 0869-6632 (Print)
ISSN 2542-1905 (Online)


For citation:

Landa P. S. Stall flutter as one of mechanisms of transmission line self-oscillations. Izvestiya VUZ. Applied Nonlinear Dynamics, 2009, vol. 17, iss. 2, pp. 3-15. DOI: 10.18500/0869-6632-2009-17-2-3-15

This is an open access article distributed under the terms of Creative Commons Attribution 4.0 International License (CC-BY 4.0).
Full text PDF(Ru):
(downloads: 218)
Language: 
Russian
Article type: 
Article
UDC: 
537

Stall flutter as one of mechanisms of transmission line self-oscillations

Autors: 
Landa Polina Solomonovna, Lomonosov Moscow State University
Abstract: 

Self-oscillations of wires caused by the vortex separation from the wire surface (so called stall flutter) are considered.

Reference: 
  1. Landa PS. Nonlinear oscillations and waves. Moscow: Fizmatlit; 1997. 496 p. (In Russian).
  2. Landa PS. Self-oscillation of wire, heating by electric current, with the strain-resistive effect taking into account. Izvestiya VUZ. Applied Nonlinear Dynamics. 2008;16(1):19–32. DOI: 10.18500/0869-6632-2008-16-1-19-32.
  3. Rocard Y. Dynamique Generale des Vibrations. Paris, Masson et Cie; 1943. 522 p.
  4. Panovko YaG, Gubanova AI. Stability and vibrations of elastic systems. Moscow: Nauka; 1979. 384 p. (In Russian).
  5. Karman Th. von Uber den Mechanismus des Widerstandes, den ein bewegter in einer Flussigkeit erfahrt. Gottingen Nachrichten; 1911. 178 p.
  6. Bisplinghoff RL, Ashley H, Halfman RL. Aeroelasticity. Moscow: Foreign Languages Publishing House; 1958. 799 p. (In Russian).
  7. Kazakevich MI. Aerodynamics of bridges. Moscow: Transport; 1987. 240 p. (In Russian).
  8. Forschung HG. Aeroelasticity basics. Moscow: Mashinostroeniye; 1984. 599 p. (In Russian).
  9. Goldenblatt AI. Modern problems of oscillation and stability of engineering structures. Moscow: Gosstroyizdat; 1947. 136 p. (In Russian).
  10. Rokar I. Instability in mechanics. Moscow: Foreign Languages Publishing House; 1959. 287 p. (In Russian).
  11. Grossman EP. Flutter. Moscow: Central Aerohydrodynamic Institute; 1937, 248 p. (In Russian).
  12. Halfman RL, Johnson HC, Haley SM. Evaluation of high-angle-of-attack aerodynamic-derivative data and stall-flutter prediction techniques. Washington: NACA Technical Notes 2533; 1951. 154 p.
  13. Landau LD, Lifshits EM. Hydrodynamics. Moscow: Nauka; 1986. 736 p. (In Russian).
  14. Bolotin BV. Dynamic stability of elastic systems. Moscow: Gostehizdat; 1956. 600 p. (In Russian).
  15. Fung YC. An introduction to the theory of aeroelasticity. Moscow: Fizmatgiz; 1959. 523 p. (In Russian).
  16. Devnin SI. Hydroelasticity of structures at tear-off streamlining. Leningrad: Sudostroenie; 1975. 192 p. (In Russian).
  17. Strouhal V. Uber eine besondere Art der Tonerregung. Ann. Phys. 1878;5(10):216–251. DOI: 10.1002/andp.18782411005.
  18. Andronov AA, Witt AA. To the mathematical theory of self-oscillating systems with two degrees of freedom. JTF. 1934;4(1):122–136.
  19. Strelkov SP, Skibarko AP. Qualitative investigation of processes in the generator according to a complex scheme. To the Van der Paul tightening theory. JTF. 1934;4(1):158.
  20. Theodorchyk KF. Self-oscillating systems.Moscow: Гостехиздат, 1952. 104 p. (In Russian).
  21. Landa PS Self-oscillations in systems with a finite number of degrees of freedom. Moscow: Nauka; 1980. 359 p. (In Russian).
  22. Richardson EG. Eolian Tones. Proc. Phys. Soc. Lond. 1923;36:53.
  23. Pavlikhina MA, Smirnov PL. Vortex trace at flow of oscillating cylinders. Izv. AS USSR, OTN. 1958;8:124–127.
  24. Bishop RED, Hassan AY. The lift and drag forces on a circular cylinder oscillating in a flowing fluid. Proc. Royal Soc. (London). 1964;277(1368):51–75. DOI: 10.1098/rspa.1964.0005.
  25. Blumina LH, Fedyaevsky KK. Investigation of influence of forced oscillations of cylinder in air flow on mechanism of vortex failure. Izv. AS USSR, MZG. 1969;1:118–119.
  26. Fedyaevsky KK, Blumina LK. Hydrodynamics of tear-off flowing bodies. Moscow: Mashinostroenie; 1977. 117 p. (In Russian).
  27. Schnittger JR. The aerodynamic mechanism of vibrating compressor blades. Sc. D. Thesis M.I.T., J. Aeronaut. Sci.; 1953.
  28. Sisto F. Stall flutter in cascades. J. of the Aeronaut. Sci. 1953;20(9):598–604.
  29. Bishop RED, Hassan AY. The lift and drag forces on a circular cylinder in a flowing fluid. Proc. Royal Soc. (London). 1964;277(1368):32–50. DOI: 10.1098/rspa.1964.0004.
  30. Karman Th. Uber den Mechanismus des Flussigkeitsund Luftwiderstands. Phys. Z. 1912;13:49–59.
  31. Roshko A. Experiments on the the fow past a circular Cylinder at very high Reynolds number. J. Fluid Mech. 1961;10:345–356. DOI: 10.1017/S0022112061000950.
  32. Neymark YuI, Landa PS. Stochastic and chaotic fluctuations. Moscow: Nauka; 1987. 424 p. (In Russian).
  33. Landa PS. Self-oscillations in distributed systems. Moscow: Nauka; 1983. 320 p.(In Russian).
  34. Bogolyubov NN. The theory of perturbations in nonlinear mechanics. In sb. Institute builds. mechanics of AN of the Ukrainian SSR. 1950;14(2):9–34.
  35. Mitropolskiy YuA. Averaging method in nonlinear mechanics. Kiev: Naukova Dumka; 1971. 440 p. (In Russian).
Received: 
22.01.2009
Accepted: 
22.01.2009
Published: 
30.06.2009
Short text (in English):
(downloads: 116)