«Previous Article|Table of Contents|Next Article»

Journal of Marine Science and Application[ISSN:1002-2848/CN:61-1400/f]

卷:

期数:

2010年2

页码:

115-120

栏目:

出版日期:

2010-06-25

Info

Title:

Influence of Forward Speed on the Lateral Vibration of a Slender Structure in Water

Author(s):

Li Zhou* and Zhi Zong

Affilations:

Author(s):

Li Zhou* and Zhi Zong

State Key Laboratory of Structural Equipment for Industrial Equipment, Faculty of Vehicle Engineering, Dalian University of Technology, Dalian 116024, China

Keywords:

forward speed;  vibration in water;  slender structure;  fluid-structure interaction

分类号:

-

DOI:

-

Abstract:

In this paper, the effects of forward speed on the lateral vibration of a slender structure in an infinite fluid are considered. By equating the bending stress of the structure with the hydrodynamic force acting on it, the equation which governs the fluid-structure interaction of a slender structure both vibrating and moving in water is obtained. Numerical results show that the influence of forward speed on the vibration of a slender structure in water is significant. It behaves like damping, reducing both natural frequencies and responses significantly.

References:

Armand JL, Orsero P (1979). A method for evaluating the hydrodynamic added mass in ship hull vibration. Trans. SNAME, 87, 99-120.
Anderson JM, Steitlien K, Triantafylou MS (1998). Oscillating foils of high propulsive efficiency. Journal of Fluid Mechanics, 360, 41-72.
 Atkinson KE. An introduction to numerical analysis. 2nd ed. Whiley, New York, 210. Bandyopadhyay PR, Castano JM, Rice JQ, Philips RB, Nedderman WH, Macy WK (1997). Low-speed maneuvering hydrodynamics of fish and small underwater vehicles. Trans. ASME-J. Fluids Engineering, 119, 136-144.
Daidola JC (1984). Natural vibrations of beams in a fluid with applications to ships and other marine structures. Trans. SNAME, 92, 331-351.
 Lamb H (1932). Hydrodynamics. 6th ed. Dover Publications, New York, 738. Landweber L (1971). Natural frequencies of a body of revolution vibrating transversely in a fluid. J. of Ship Research, 15, 20-30. Landweber L (1967). Vibration of a flexible cylinder in a fluid. J. of Ship Research, 11, 143-150.
 Lighthill J, Blake R (1990). Biofluiddynamics of ballistiform and gymnotiform locomotion 1: biologival background, and analysis by elongated body theory. Journal of Fluid Mech, 212, 183-207. Lighthill MJ (1960). Note on the swimming of slender fish. J. Fluid Mech., 9, 305-317.
Newman JN (1978). Marine hydrodynamics. The MIT Press, Cambridge, Massachusetts, 362-373.
Vorus WS, Hylarides S (1981). Hydrodynamic added-mass matrix of vibrating ship based on a distribution of hull surface sources. Trans. SNAME, 89, 397-416.
 Zong Z, Lam KY (1999). Hydrodynamic influences on the ship hull vibrations in shallow water. Journal of Engineering Mathematics, 37, 363-374.
Zong Z, Lam KY (2000). The flexural response of a submarine pipeline to an underwater explosion bubble. Journal of Offshore Mechanics and Arctic Engineering, 122, 194-199. Zong Z, Zhang YY (2009). Advanced differential quadrature methods. CRC Press, London, 71-87.

Memo

Memo:

-

Commonly used function

Last Update: 2010-06-01