Dynamic load characteristics and wake vortex structure of spiral finned cylinders in cross-flow

doi:10.1016/j.cjche.2025.02.009

Abstract

Abstract: In this study, four types of spiral fins with varying parameters were mounted on an upstream cylinder, and the effects of spiral fins on the vibration response of heat exchange tubes and the vortex structure in cross flow were studied through experiments and numerical simulations. The results indicate a strong dependency of the cylinder's vibration response on the fin parameters. The results indicate that the vibration response and wake structure of the cylinder are significantly influenced by the parameters of the fins. The introduction of a finned cylinder affects both its own vibration amplitude and frequency, as well as the downstream cylinder. The amplitudes of finned cylinders I and III are reduced by 57.8% and 59.9%, respectively, compared to the bare cylinder. This reduction helps to restrain vibration and diminishes the amplitudes of the downstream cylinder. Although finned cylinder II slightly decreases its own vibration, it increases the amplitude of the downstream cylinder by 13.7%. The mean drag coefficient and the root mean square of the lift coefficient of the finned cylinder are higher than those of the bare cylinder when the finned cylinder is positioned upstream. Smaller pitch and larger equivalent diameter will lead to increased drag, resulting in enhanced vortex shedding in the wake, which amplifies the vibrations of the cylinder in that wake. The downstream of finned cylinder II has the widest wake and higher vortex strength, and the dynamic load and vibration of the downstream cylinder are increased. The vortex intensity decays faster in the wake of finned cylinder III, and the vibration of the downstream cylinder is weaker.

Key words: Computational fluid dynamics (CFD), Finned cylinder, Large-eddy simulation (LES), Numerical simulation, Turbulence

摘要： In this study, four types of spiral fins with varying parameters were mounted on an upstream cylinder, and the effects of spiral fins on the vibration response of heat exchange tubes and the vortex structure in cross flow were studied through experiments and numerical simulations. The results indicate a strong dependency of the cylinder's vibration response on the fin parameters. The results indicate that the vibration response and wake structure of the cylinder are significantly influenced by the parameters of the fins. The introduction of a finned cylinder affects both its own vibration amplitude and frequency, as well as the downstream cylinder. The amplitudes of finned cylinders I and III are reduced by 57.8% and 59.9%, respectively, compared to the bare cylinder. This reduction helps to restrain vibration and diminishes the amplitudes of the downstream cylinder. Although finned cylinder II slightly decreases its own vibration, it increases the amplitude of the downstream cylinder by 13.7%. The mean drag coefficient and the root mean square of the lift coefficient of the finned cylinder are higher than those of the bare cylinder when the finned cylinder is positioned upstream. Smaller pitch and larger equivalent diameter will lead to increased drag, resulting in enhanced vortex shedding in the wake, which amplifies the vibrations of the cylinder in that wake. The downstream of finned cylinder II has the widest wake and higher vortex strength, and the dynamic load and vibration of the downstream cylinder are increased. The vortex intensity decays faster in the wake of finned cylinder III, and the vibration of the downstream cylinder is weaker.

关键词: Computational fluid dynamics (CFD), Finned cylinder, Large-eddy simulation (LES), Numerical simulation, Turbulence

Hewei Yang, Bowen Tang, Ye Tian, Wei Tan. Dynamic load characteristics and wake vortex structure of spiral finned cylinders in cross-flow[J]. Chinese Journal of Chemical Engineering, 2025, 82(6): 105-115.

Hewei Yang, Bowen Tang, Ye Tian, Wei Tan. Dynamic load characteristics and wake vortex structure of spiral finned cylinders in cross-flow[J]. 中国化学工程学报, 2025, 82(6): 105-115.

References

[1] D.R. Reid, J. Taborek, Selection criteria for plain and segmented finned tubes for heat recovery systems, J. Eng. Gas Turbines Power 116 (2) (1994) 406-410.
[2] F.L. Eisinger, R.E. Sullivan, Further evidence for acoustic resonance in full size steam generator and tubular heat exchanger tube banks, J. Press. Vessel. Technol. 132 (4) (2010) 044501.
[3] S.L. Finnegan, C. Meskell, S. Ziada, Experimental investigation of the acoustic power around two tandem cylinders, J. Press. Vessel. Technol. 132 (4) (2010) 041306.
[4] N. Arafa, A. Mohany, Flow-excited acoustic resonance of isolated cylinders in cross-flow, J. Press. Vessel. Technol. 138 (1) (2016) 011302.
[5] P. Abraham, M.H. Sharqawy, M.E. Shawkat, Thermal and hydraulic characteristics of multiple row spiral finned tube heat exchangers, Int. J. Refrig. 130 (2021) 56-66.
[6] W.L. Wu, J.E. Luo, D.W. Li, X.W. Feng, L. Tang, Z.S. Fang, Z.M. Zheng, Experimental investigation of heat transfer performance of a finned-tube heat exchanger under frosting conditions, Sustain. Cities Soc. 80 (2022) 103752.
[7] M. Yuan, W.P. Zhang, G.M. Liu, X.Y. Zhang, M.Z. Yousif, J.H. Song, H. Lim, Performance study of spiral finned tubes on heat transfer and wake flow structure, Int. J. Heat Mass Transf. 196 (2022) 123278.
[8] P. Kiatpachai, T. Kaewkamrop, M. Mesgarpour, H.S. Ahn, A.S. Dalkilic, O. Mahian, S. Wongwises, Air-side performance of embedded and welded spiral fin and tube heat exchangers, Case Stud. Therm. Eng. 30 (2022) 101721.
[9] H. Zhou, T.X. Liu, F.Z. Cheng, D. Liu, Y.F. Zhu, W.W. Ma, Heat transfer and pressure drop performance evaluation of twisted and bent fins when steam flows through the tubes, Int. J. Heat Mass Transf. 184 (2022) 122333.
[10] M.P. Paidoussis, Real-life experiences with flow-induced vibration, J. Fluids Struct. 22 (6-7) (2006) 741-755.
[11] S. Ziada, Flow-excited acoustic resonance in industry, J. Press. Vessel. Technol. 132 (1) (2010) 015001.
[12] J. McClure, S. Yarusevych, Vortex shedding and structural loading characteristics of finned cylinders, J. Fluids Struct. 65 (2016) 138-154.
[13] N. Arafa, A. Mohany, Wake structures and acoustic resonance excitation of a single finned cylinder in cross-flow, J. Fluids Struct. 86 (2019) 70-93.
[14] M.R. Islam, A. Mohany, On the three-dimensional flow development around circular finned cylinders, Phys. Fluids 32 (11) (2020) 115116.
[15] M.R. Islam, A. Mohany, Vortex shedding characteristics in the wake of circular finned cylinders, Phys. Fluids 32 (4) (2020) 045113.
[16] H. Hamakawa, Y. Kouno, E. Nishida, Effect of fins on vortex shedding noise generated from a circular cylinder in cross flow, ASME 2010 7th International Symposium on Fluid-Structure Interactions, Flow-Sound Interactions, and Flow-Induced Vibration and Noise: Volume 3, Parts A and B, Montreal, Quebec, Canada, 2010. https://doi.org/10.1115/FEDSM-ICNMM2010-30290.
[17] M. Eid, S. Ziada, Vortex shedding and acoustic resonance of single and tandem finned cylinders, J. Fluids Struct. 27 (7) (2011) 1035-1048.
[18] M. Alziadeh, A. Mohany, Passive noise control technique for suppressing acoustic resonance excitation of spirally finned cylinders in cross-flow, Exp. Therm. Fluid Sci. 102 (2019) 38-51.
[19] P. Pongsoi, S. Pikulkajorn, C.C. Wang, S. Wongwises, Effect of number of tube rows on the air-side performance of crimped spiral fin-and-tube heat exchanger with a multipass parallel and counter cross-flow configuration, Int. J. Heat Mass Transf. 55 (4) (2012) 1403-1411.
[20] P. Pongsoi, S. Pikulkajorn, S. Wongwises, Heat transfer and flow characteristics of spiral fin-and-tube heat exchangers: A review, Int. J. Heat Mass Transf. 79 (2014) 417-431.
[21] V. Azadeh-Ranjbar, N. Elvin, Y. Andreopoulos, Vortex-induced vibration of finite-length circular cylinders with spanwise free-ends: Broadening the lock-in envelope, Phys. Fluids 30 (10) (2018) 105104.
[22] M. Alziadeh, A. Mohany, Vortex shedding characteristics and aerodynamic forces of a finned cylinder in cross-flow, Phys. Fluids 34 (9) (2022) 095110.
[23] M. Alziadeh, A. Mohany, Flow structure and aerodynamic forces of finned cylinders during flow-induced acoustic resonance, J. Fluids Struct. 119 (2023) 103887.
[24] D. Sumner, Two circular cylinders in cross-flow: A review, J. Fluids Struct. 26 (6) (2010) 849-899.
[25] Y.H. Yan, C.N. Ji, N. Srinil, On wake modulation and interaction features of a pair of dual-step circular cylinders in side-by-side arrangements, Phys. Fluids 33 (9) (2021) 093604.
[26] M. Alziadeh, A. Mohany, Vorticity shedding and acoustic resonance excitation of two tandem spirally finned cylinders in cross-flow, J. Press. Vessel. Technol. 143 (2) (2021) 021405.
[27] M. Alziadeh, A. Mohany, Vortex dynamics of tandem bare and spiral finned cylinders in cross-flow and their susceptibility to acoustic resonance excitation, Phys. Fluids 34 (4) (2022) 045105.
[28] S.M. Dash, M.S. Triantafyllou, P.V.Y. Alvarado, A numerical study on the enhanced drag reduction and wake regime control of a square cylinder using dual splitter plates, Comput. Fluids 199 (2020) 104421.
[29] P. Sikdar, S.M. Dash, K.P. Sinhamahapatra, A numerical study on the drag reduction and wake regime control of the tandem circular cylinders using splitter plates, J. Comput. Sci. 66 (2023) 101927.
[30] A. Bhunia, P. Sikdar, S.M. Dash, An investigation on the steady and unsteady wake flow regimes and aerodynamic characteristics of the trapezoidal cylinders using immersed boundary-lattice Boltzmann method, J. Fluids Eng. 146 (4) (2024) 041501.
[31] P. Sikdar, S.M. Dash, K.P. Sinhamahapatra, A. Sharma, Splitter plate-based flow control study for two square cylinders in tandem arrangement, Ocean. Eng. 281 (2023) 115022.
[32] W.A. Mair, P.D.F. Jones, R.K.W. Palmer, Vortex shedding from finned tubes, J. Sound Vib. 39 (3) (1975) 293-296.
[33] M.J. Pettigrew, C.E. Taylor, Vibration analysis of shell-and-tube heat exchangers: An overview: Part 2: Vibration response, fretting-wear, guidelines, J. Fluids Struct. 18 (5) (2003) 485-500.
[34] M.J. Pettigrew, C.E. Taylor, Vibration analysis of shell-and-tube heat exchangers: An overview: Part 1: Flow, damping, fluidelastic instability, J. Fluids Struct. 18 (5) (2003) 469-483.
[35] M. Alziadeh, A. Mohany, Near-wake characteristics and acoustic resonance excitation of crimped spirally finned cylinders in cross-flow, J. Press. Vessel. Technol. 140 (5) (2018) 051301.
[36] J. Smagorinsky, General circulation experiments with the primitive equations, Mon. Wea. Rev. 91 (3) (1963) 99-164.
[37] D. Pastrana, J.C. Cajas, O. Lehmkuhl, I. Rodriguez, G. Houzeaux, Large-eddy simulations of the vortex-induced vibration of a low mass ratio two-degree-of-freedom circular cylinder at subcritical Reynolds numbers, Comput. Fluids 173 (2018) 118-132.
[38] M.J. Gong, D.Y. Yu, J. Bao, The effect of transverse inclination angle on hydrodynamic characteristics of two tandem circular cylinders in an X arrangement, Ocean. Eng. 281 (2023) 114971.
[39] M.J. Gong, B. Dally, Numerical study on flow-induced vibration of an oscillating cylinder with an unattached downstream square plate at a low Reynolds number, Ocean. Eng. 288 (2023) 116072.
[40] A. Sohankar, Large eddy simulation of flow past rectangular-section cylinders: Side ratio effects, J. Wind. Eng. Ind. Aerodyn. 96 (5) (2008) 640-655.
[41] Q.M. Zheng, M.M. Alam, Intrinsic features of flow past three square prisms in side-by-side arrangement, J. Fluid Mech. 826 (2017) 996-1033.
[42] A. Sohankar, A numerical investigation of the flow over a pair of identical square cylinders in a tandem arrangement, Int. J. Numer. Meth. Fluids 70 (10) (2012) 1244-1257.
[43] J.M. Shang, Q. Zhou, M.M. Alam, H.L. Liao, S.Y. Cao, Numerical studies of the flow structure and aerodynamic forces on two tandem square cylinders with different chamfered-corner ratios, Phys. Fluids 31 (7) (2019) 075102.
[44] P. Parnaudeau, J. Carlier, D. Heitz, E. Lamballais, Experimental and numerical studies of the flow over a circular cylinder at Reynolds number 3900, Phys. Fluids 20 (8) (2008) 085101.
[45] K. Lam, Y.F. Lin, L. Zou, Y. Liu, Investigation of turbulent flow past a yawed wavy cylinder, J. Fluids Struct. 26 (7-8) (2010) 1078-1097.
[46] W. Kim, J. Lee, H. Choi, Flow around a helically twisted elliptic cylinder, Phys. Fluids 28 (5) (2016) 053602.
[47] Q. Zhou, M.M. Alam, S.Y. Cao, H.L. Liao, M.S. Li, Numerical study of wake and aerodynamic forces on two tandem circular cylinders at Re = 103, Phys. Fluids 31 (4) (2019) 045103.