Browse > Article
http://dx.doi.org/10.1016/j.ijnaoe.2017.11.002

Three-dimensional dynamics of vortex-induced vibration of a pipe with internal flow in the subcritical and supercritical regimes  

Duan, Jinlong (Collaborative Innovation Center for Advanced Ship and Deep-Sea Exploration, Shanghai Jiao Tong University)
Chen, Ke (Collaborative Innovation Center for Advanced Ship and Deep-Sea Exploration, Shanghai Jiao Tong University)
You, Yunxiang (Collaborative Innovation Center for Advanced Ship and Deep-Sea Exploration, Shanghai Jiao Tong University)
Wang, Renfeng (Collaborative Innovation Center for Advanced Ship and Deep-Sea Exploration, Shanghai Jiao Tong University)
Li, Jinlong (Collaborative Innovation Center for Advanced Ship and Deep-Sea Exploration, Shanghai Jiao Tong University)
Publication Information
International Journal of Naval Architecture and Ocean Engineering / v.10, no.6, 2018 , pp. 692-710 More about this Journal
Abstract
The Three-dimensional (3-D) dynamical behaviors of a fluid-conveying pipe subjected to vortex-induced vibration are investigated with different internal flow velocity ${\nu}$. The values of the internal flow velocity are considered in both subcritical and supercritical regimes. During the study, the 3-D nonlinear equations are discretized by the Galerkin method and solved by a fourth-order Runge-Kutta method. The results indicate that for a constant internal flow velocity ${\nu}$ in the subcritical regime, the peak Cross-flow (CF) amplitude increases firstly and then decrease accompanied by amplitude jumps with the increase of the external reduced velocity. While two response bands are observed in the In-line (IL) direction. For the dynamics in the lock-in condition, 3-D periodic, quasi-periodic and chaotic vibrations are observed. A variety of CF and IL responses can be detected for different modes with the increase of ${\nu}$. For the cases studied in the supercritical regime, the dynamics shows a great diversity with that in the subcritical regime. Various dynamical responses, which include 3-D periodic, quasi-periodic as well as chaotic motions, are found while both CF and IL responses are coupled while ${\nu}$ is beyond the critical value. Besides, the responses corresponding to different couples of ${\mu}_1$ and ${\mu}_2$ are obviously distinct from each other.
Keywords
Vortex-Induced Vibration (VIV); Three Dimension (3-D); Internal flow; Wake oscillator; Bifurcation diagram;
Citations & Related Records
연도 인용수 순위
  • Reference
1 Bai, X., Huang, W., Vaz, M.A., Yang, C., Duan, M., 2015. Riser-soil interaction model effects on the dynamic behavior of a steel catenary riser. Mar. Struct. 41, 53-76.   DOI
2 Bai, X., Vaz, M.A., Morooka, C.K., Xie, Y., 2017. Dynamic tests in a steel catenary riser reduced scale model. Ships Offshore Struct. 1-13.
3 Blevins, R.D., 1990. Flow-induced Vibration.
4 Blevins, R.D., Coughran, C.S., 2009. Experimental investigation of vortex-induced vibration in one and two dimensions with variable mass, damping, and reynolds number. J. Fluid Eng. 131, 101202.   DOI
5 Bourdier, S., Chaplin, J.R., 2012. Vortex-induced vibrations of a rigid cylinder on elastic supports with end-stops, part 1: experimental results. J. Fluid Struct. 29, 62-78.   DOI
6 Brika, D., Laneville, A., 1993. Vortex-induced vibrations of a long flexible circular cylinder. J. Fluid Mech. 250, 481-481.   DOI
7 Chen, S.S., 1987. Flow-induced Vibration of Circular Cylindrical Structures, vol. 414. Hemisphere publishing corporation, Washington, DC.
8 Chen, W., Li, M., Zheng, Z., Tan, T., 2012. Dynamic characteristics and viv of deepwater riser with axially varying structural properties. Ocean Eng. 42, 7-12.   DOI
9 Dai, H., Wang, L., 2012. Vortex-induced vibration of pipes conveying fluid using the method of multiple scales. Theoretical and Applied Mechanics Letters 2 022006.   DOI
10 Dai, H.,Wang, L., Qian, Q., Ni, Q., 2013. Vortex-induced vibrations of pipes conveying fluid in the subcritical and supercritical regimes. J. Fluid Struct. 39, 322-334.   DOI
11 Dai, H.,Wang, L., Qian, Q., Ni, Q., 2014. Vortex-induced vibrations of pipes conveying pulsating fluid. Ocean Eng. 77, 12-22.   DOI
12 Facchinetti, M.L., De Langre, E., Biolley, F., 2004. Coupling of structure and wake oscillators in vortex-induced vibrations. J. Fluid Struct. 19, 123-140.   DOI
13 Feng, C., 1968. The Measurement of Vortex Induced Effects in Flow Past Stationary and Oscillating Circular and D-section Cylinders. Ph.D. thesis. University of British Columbia.
14 Furnes, G.K., S_rensen, K., et al., 2007. Flow induced vibrations modeled by coupled non-linear oscillators. In: The Seventeenth International Offshore and Polar Engineering Conference. International Society of Offshore and Polar Engineers.
15 Iwan, W., 1981. The vortex-induced oscillation of non-uniform structural systems. J. Sound Vib. 79, 291-301.   DOI
16 Gabbai, R., Benaroya, H., 2005. An overview of modeling and experiments of vortex-induced vibration of circular cylinders. J. Sound Vib. 282, 575-616.   DOI
17 Ge, F., Long, X., Wang, L., Hong, Y., 2009. Flow-induced vibrations of long circular cylinders modeled by coupled nonlinear oscillators. Science in China Series G: Phy. Mech. Astronomy 52, 1086-1093.   DOI
18 Huera-Huarte, F., Bearman, P., 2009.Wake structures and vortex-induced vibrations of a long flexible cylinder part 1: dynamic response. J. Fluid Struct. 25, 969-990.   DOI
19 Khalak, A., Williamson, C., 1996. Dynamics of a hydroelastic cylinder with very low mass and damping. J. Fluid Struct. 10, 455-472.   DOI
20 Kheiri, M., Paidoussis, M., 2015. Dynamics and stability of a flexible pinned-free cylinder in axial flow. J. Fluid Struct. 55, 204-217.   DOI
21 Kheiri, M., Paidoussis, M., Del Pozo, G.C., Amabili, M., 2014. Dynamics of a pipe conveying fluid flexibly restrained at the ends. J. Fluid Struct. 49, 360-385.   DOI
22 Lou, M.,Wu, W.g., Chen, P., 2017. Experimental study on vortex induced vibration of risers with fairing considering wake interference. Int. J. Naval Arch.Ocean Eng. 9, 127-134.   DOI
23 Meng, D., Guo, H.Y., Xu, S.P., 2011. Non-linear dynamic model of a fluid-conveying pipe undergoing overall motions. Appl. Math. Model. 35, 781-796.   DOI
24 Pantazopoulos, M.S., 1994. Vortex-induced Vibration Parameters: Critical Review. Technical Report. American Society of Mechanical Engineers, New York, NY (United States).
25 Modarres-Sadeghi, Y., Paidoussis, M.P., 2013. Chaotic oscillations of long pipes conveying fluid in the presence of a large end-mass. Comput. Struct. 122, 192-201.   DOI
26 Nayfeh, A.H., Emam, S.A., 2008. Exact solution and stability of postbuckling configurations of beams. Nonlinear Dynam. 54, 395-408.   DOI
27 Paidoussis, M.P., 1998. Fluid-structure Interactions: Slender Structures and Axial Flow, vol. 1. Academic press.
28 Sarpkaya, T., 1978. Fluid forces on oscillating cylinders. NASA STI/Recon Technical Report A 78, 46523.
29 Sarpkaya, T., 2004. A critical review of the intrinsic nature of vortex-induced vibrations. J. Fluid Struct. 19, 389-447.   DOI
30 Srinil, N., Zanganeh, H., 2012. Modelling of coupled cross-flow/in-line vortexinduced vibrations using double duffing and van der pol oscillators. Ocean Eng. 53, 83-97.   DOI
31 Stangl, M., Gerstmayr, J., Irschik, H., 2008. An alternative approach for the analysis of nonlinear vibrations of pipes conveying fluid. J. Sound Vib. 310, 493-511.   DOI
32 Sumer, B.M., Fredsoe, J., 1997. Hydrodynamics Around Cylindrical Structures, vol. 12. World Scientific.
33 Trim, A., Braaten, H., Lie, H., Tognarelli, M., 2005. Experimental investigation of vortex-induced vibration of long marine risers. J. Fluid Struct. 21, 335-361.   DOI
34 Vandiver, J.K., et al., 1983. Drag coefficients of long flexible cylinders. In: Offshore Technology Conference. Offshore Technology Conference.
35 Wang, L., Dai, H., Qian, Q., 2012. Dynamics of simply supported uid-conveying pipes with geometric imperfections. J. Fluid Struct. 29, 97-106.   DOI
36 Violette, R., De Langre, E., Szydlowski, J., 2007. Computation of vortex-induced vibrations of long structures using a wake oscillator model: comparison with dns and experiments. Comput. Struct. 85, 1134-1141.   DOI
37 Wanderley, J.B., Souza, G.H., Sphaier, S.H., Levi, C., 2008. Vortex-induced vibration of an elastically mounted circular cylinder using an upwind tvd two-dimensional numerical scheme. Ocean Eng. 35, 1533-1544.   DOI
38 Wang, L., 2009. A further study on the non-linear dynamics of simply supported pipes conveying pulsating fluid. Int. J. Non Lin. Mech. 44, 115-121.   DOI
39 Wang, X., So, R., Chan, K., 2003. A non-linear fluid force model for vortex-induced vibration of an elastic cylinder. J. Sound Vib. 260, 287-305.   DOI
40 Williamson, C., Govardhan, R., 2008. A brief review of recent results in vortex-induced vibrations. J. Wind Eng. Ind. Aerod. 96, 713-735.   DOI
41 Wu, X., Ge, F., Hong, Y., 2012. A review of recent studies on vortex-induced vibrations of long slender cylinders. J. Fluid Struct. 28, 292-308.   DOI
42 Yamamoto, C., Meneghini, J., Saltara, F., Fregonesi, R., Ferrari, J., 2004. Numerical simulations of vortex-induced vibration on flexible cylinders. J. Fluid Struct. 19, 467-489.   DOI