The vortex-induced vibrations may have disastrous effects in engineering practice, affecting significantly the durability, reliability and safety of engineering structures. This is a reason for which a great deal of effort has been dedicated to the proposition of control strategies to deal with the vortex-induced vibration problem. However, few works have proposed the use of viscoelastic materials to suppress the vibrations induced by vortex shedding, which motivates the present study. Here, the immersed boundary method combined with the virtual physical model is used to investigate the dynamics of a viscoelastically-mounted rigid cylinder in a fluid flow under transverse oscillations induced by vortex shedding. A straightforward time-domain modeling procedure of immersed viscoelastic system by using a four-parameter fractional derivative model is proposed. After the theoretical aspects, numerical tests are performed to investigate the vortex-induced oscillations and flow characteristics of the immersed viscoelastic system at Reynolds number 10,000 for a range of reduced velocity and temperature for two values of mass ratios. The results demonstrate the interest in using viscoelastic materials to mitigate the vortex-induced vibrations.
Alam MdMZhouY (2007) Flow around two side-by-side closely spaced circular cylinders. Journal of Fluids and Structures23(5): 799–805.
2.
Al-JamalHDaltonC (2004) Vortex induced vibrations using Large Eddy Simulation at a moderate Reynolds number. Journal of Fluids and Structures9(1): 73–92.
3.
AnagnostopoulosP (2002) Flow-Induced Vibrations in Engineering Practice (Advances in Fluid Mechanics), Southampton, UK: WIT Press.
4.
BagleyRLTorvikPJ (1979) A generalized derivative model for an elastomer damper. The Shock and Vibration Bulletin49(2): 135–143.
5.
BagleyRLTorvikPJ (1983) Fractional calculus – a different approach to the analysis of viscoelastically damped structures. AIAA Journal21(5): 741–748.
6.
BatheK-J (1996) Finite Element Procedures, 1 edition. Upper Saddle River, NJ: Prentice Hall.
7.
CarmoBSMeneghiniJR (2006) Numerical investigation of the flow around two circular cylinders in tandem. Journal of Fluids and Structures22(6): 979–988.
8.
CuràFMuraAScarpaF (2011) Modal strain energy based methods for the analysis of complex patterned free layer damped plates. Journal of Vibration and Control18(9): 1291–1302.
9.
da SilvaARSilveira-NetoAde LimaAMG (2016) Flow-induced vibration of a circular cylinder in cross-flow at moderate Reynolds number. Journal of the Brazilian Society of Mechanical Sciences and Engineering38(4): 1185–1197.
10.
de LimaAMGGuaraldo-NetoBSalesTPet al.(2014) A time-domain modeling of systems containing viscoelastic materials and shape memory alloys as applied to the problem of vibration attenuation. Engineering Structures68(7): 85–95.
11.
FengLHWangJJ (2010) Circular cylinder vortex-synchronization control with a synthetic jet positioned at the rear stagnation point. Journal of Fluid Mechanics662(1): 232–259.
12.
FlemmingFWilliamsonCHK (2005) Vortex-induced vibrations of a pivoted cylinder. Journal of Fluid Mechanics522(1): 215–252.
13.
GabbaiRDBenaroyaH (2005) An overview of modeling and experiments of vortex-induced vibration of circular cylinders. Journal of Sound and Vibration282(3): 575–616.
14.
GalucioACDeüJFOhayonR (2004) Finite element formulation of viscoelastic sandwich beams using fractional derivative operators. Computational Mechanics33(4): 282–291.
15.
GovardhanRNWilliamsonCHK (2006) Defining the ‘modified Griffin plot’ in vortex-induced vibration: revealing the effect of Reynolds number using controlled damping. Journal of Fluid Mechanics561(1): 147–180.
16.
JuncuG (2007) A numerical study of momentum and forced convection heat transfer around two tandem circular cylinders at low Reynolds numbers. Part I: Momentum transfer. International Journal of Heat and Mass Transfer50(19): 3788–3798.
17.
Lima e SilvaALFSilveira-NetoADamascenoJJR (2003) Numerical simulation of two dimensional flows over a circular cylinder using the immersed boundary method. Journal of Computational Physics189(2): 351–37.
18.
MarquetOSippDJacquinL (2008) Sensitivity analysis and passive control of cylinder flow. Journal of Fluid Mechanics615(1): 221–252.
19.
MehmoodAAbdelkefiAAkhtarIet al.(2014) Linear and nonlinear active feedback controls for vortex-induced vibrations of circular cylinders. Journal of Vibration and Control20(8): 1137–1147.
20.
MittalSKumarV (2001) Flow-induced vibrations of a light circular cylinder at Reynolds number 103 to 104. Journal of Sound and Vibration245(5): 923–946.
21.
MorseTLWilliamsonCHK (2009) Prediction of vortex-induced vibration response by employing controlled motion. Journal of Fluid Mechanics634(1): 5–39.
22.
NashifADJonesDIGHendersonJP (1985) Vibration Damping, New York, NY: John Wiley & Sons.
23.
NaudascherERockwellD (1994) Flow-Induced Vibrations: An Engineering Guide, Mineola, NY: Dover Publications, Inc.
24.
PanZYCuiWCMiaoQM (2007) Numerical simulation of vortex-induced vibration of a circular circular cylinder at low mass-damping using RANS code. Journal of Fluids and Structures23(1): 23–37.
25.
PastòS (2008) Vortex-induced vibrations of a circular cylinder in laminar and turbulent flows. Journal of Fluids and Structures24(7): 977–993.
26.
PeskinCS (1977) Numerical analysis of blood flow in the heart. Journal of Computational Physics25(3): 220–252.
27.
RayPChristofidesPD (2005) Control of flow over a cylinder using rotational oscillations. Computers and Chemical Engineering29(4): 877–885.
28.
RichterDIaccarinoGShaqfehSG (2010) Simulations of three-dimensional viscoelastic flows past a circular cylinder at moderate Reynolds numbers. Journal of Fluid Mechanics651(1): 415–442.
29.
Shiels D, Leonard A and Roshko A (2001) Flow-induced vibration of a circular cylinder at limiting structural parameters. Journal of Fluids and Structures 15(1): 3–21.
30.
SumnerDRichardsMDAkosileOO (2008) Strouhal number data for two staggered circular cylinders. Journal of Wind Engineering and Industrial Aerodynamics96(6): 859–871.
31.
WangSRusakZTaylorSet al.(2013) On the active feedback control of a swirling flow in a finite-length pipe. Journal of Fluid Mechanics737(1): 280–307.
32.
WilliamsonCHKRoshkoA (1988) Vortex formation in the wake of an oscillating cylinder. Journal of Fluids and Structures2(4): 355–381.
