Load motion on an ice cover in the presence of a liquid layer with velocity shear

Capa

Citar

Texto integral

Acesso aberto Acesso aberto
Acesso é fechado Acesso está concedido
Acesso é fechado Somente assinantes

Resumo

The behavior of an ice cover on the surface of an ideal incompressible fluid of finite depth under the action of a pressure domain that moves rectilinearly at a constant velocity in the presence of a current with velocity shift in the upper layer is studied. It is assumed that the ice deflection is steady in the coordinate system moving with the load. The Fourier transform method is used within the framework of the linear wave theory. The critical velocities, the deflection of ice cover, and the wave forces are studied depending on the current velocity gradient, the shear layer thickness, the direction of motion, and the compression ratio.

Sobre autores

L. Tkacheva

Институт гидродинамики им. М.А. Лаврентьева СО РАН

Autor responsável pela correspondência
Email: tkacheva@hydro.nsc.ru
Rússia, Новосибирск

Bibliografia

  1. Ткачева Л.А. Движение нагрузки по ледяному покрову при наличии течения со сдвигом скорости // Изв. РАН. МЖГ. 2023. № 2. С. 113–122.
  2. Thompson P.D. The propagation of small surface disturbances through rotational flow // Ann. NY Acad. Sci. 1949. V. 51. P. 463–474.
  3. Abdullah A.J. Wave motion at the surface of a current which has an exponential distribution of vorticity // Ann. NY Acad. Sci. 1949. V. 51. P. 425–441.
  4. Fenton J.D. Some results for surface gravity waves on shear flows // J. Inst. Maths. Applics. 1953. V. 1. P. 1–20.
  5. Peregrine D.H. Interaction of water waves and currents // Adv. Appl. Mech. 1976. V. 16. P. 9–117.
  6. Kirby J.T., Chen T.M. Surface waves on vertically sheared flows: Approximate dispersion relation // J. Geophys. Res. 1989. V. 94. P. 1013–1027. doi: 10.1029/jc094ic01p01013.
  7. Skop R.A. Approximate dispersion relation for wave-current interactions // J. Waterw., Port, Coastal, Ocean Eng. 1987. V. 113. P. 187–195.
  8. Swan С., James R. A simple analytical model for surface water waves on a depth-varying current // Appl. Ocean Res. 2001. V. 22. P. 331–347.
  9. Stewart R.H., Joy J.W. HF radio measurements of surface currents // Deep Sea Res. 1974. V. 21. P. 1039–1949.
  10. Shrira V.I. Surface waves on shear currents: Solution of the boundary-value problem // J. Fluid Mech. 1993. V. 252. P. 565–584.
  11. Thompson P.D. The propagation of small surface disturbances through rotational flow // Ann. NY Acad. Sci. 1949. V. 51. P. 463–474.
  12. Герценштейн С.Я., Ромашева Н.Б., Чернявский М.В. О возникновении и развитии ветрового волнения // Изв. РАН. МЖГ. 1988. № 3. С. 163–169.
  13. Longuet-Higgins M.S. Instabilities of a horizontal shear flow with a free surface // J. Fluid Mech. 1998. V. 364. P. 147–162.
  14. Smeltzer B.K., Ellingsen S.A. Surface waves on arbitrary vertically-sheared currents // Phys. Fluids. 2017. V. 29. P. 047102.
  15. Zhang X. Short surface waves on surface shear // J. Fluid Mech. 2005. V. 541. P. 345–370.
  16. Стурова И.В. Действие пульсирующего источника в жидкости при наличии сдвигового слоя // Изв. РАН. МЖГ. 2023. № 4. С. 14–26.
  17. Brown M.K. A quadratically convergent Newton-like method upon Gaussian elimination // SIAM Numer. Anal. 1969. V. 6. № 4. P. 560–569.
  18. Лайтхилл Дж. Волны в жидкостях. М.: Мир, 1981.

Declaração de direitos autorais © Russian Academy of Sciences, 2024

Este site utiliza cookies

Ao continuar usando nosso site, você concorda com o procedimento de cookies que mantêm o site funcionando normalmente.

Informação sobre cookies