AI Chat Paper
Note: Please note that the following content is generated by AMiner AI. SciOpen does not take any responsibility related to this content.
{{lang === 'zh_CN' ? '文章概述' : 'Summary'}}
{{lang === 'en_US' ? '中' : 'Eng'}}
Chat more with AI
Powered by AMiner. Clicking this button will take you away from SciOpen.
Home Experimental and Computational Multiphase Flow Article
Article Link
Cite
EndNote(RIS) BibTeX
Collect
Submit Manuscript
Show Outline
Outline
Show full outline
Hide outline
Outline
Show full outline
Hide outline
Research Article

Numerical simulation of flow past stationary and oscillating deformable circles with fluid-structure interaction

Xu Liu1Nan Gui1Hao Wu1Xingtuan Yang1Jiyuan Tu1,2Shengyao Jiang1( )
Institute of Nuclear and New Energy Technology, Collaborative Innovation Center of Advanced Nuclear Energy Technology, Key Laboratory of Advanced Reactor Engineering and Safety, Ministry of Education, Tsinghua University, Beijing 100084, China
School of Engineering, RMIT University, Melbourne, VIC 3083, Australia
Show Author Information

Abstract

The oscillation and deformation of the tube affect its safe and efficient operation in the shell-and-tube heat exchanger of the nuclear power plant. To offer in-depth understandings, numerical simulation of the flow around the cylinder (or particle) was carried out here by using COMSOL Multiphysics as a research tool. This paper mainly discusses the influence of physical parameters (elastic modulus and Poisson’s ratio) and lateral oscillation on the flow around the circles (cylinder or particle). The physical property parameters have a greater influence on the deformation, lift coefficient, and drag coefficient of the object, and it basically does not affect the vortex shedding frequency. After analyzing the flow around the oscillating particle, four kinds of vortex separation modes (AI, AII, S, S-S modes) are defined. In addition, the lift coefficient and drag coefficient for different modes are discussed. The phenomenon of "frequency locking" occurs in the flow around the oscillating particle. Simulation results prove that the separation frequency of vortex is related to the oscillation frequency.

Keywords

particlefluid-structure interactionflow around cylinderflow induced oscillationvortex sheddingheat exchangereactor thermal hydraulics

References

 
Cadenaro, M., Codan, B., Navarra, C. O., Marchesi, G., Turco, G., di Lenarda, R., Breschi, L. 2011. Contraction stress, elastic modulus, and degree of conversion of three flowable composites. Eur J Oral Sci, 119: 241-245.
Crossref Google Scholar
 
Catalano, P., Wang, M., Iaccarino, G., Moin, P. 2003. Numerical simulation of the flow around a circular cylinder at high Reynolds numbers. Int J Heat Fluid Fl, 24: 463-469.
Crossref Google Scholar
 
Fournier, J. B., Barbetta, C. 2008. Direct calculation from the stress tensor of the lateral surface tension of fluctuating fluid membranes. Phys Rev Lett, 100: 078103.
Crossref Google Scholar
 
Gessesse, Y. B. 2014. On the fretting wear of nuclear power plant heat exchanger tubes using a fracture mechanics approach: Theory and verification. Ph.D. Thesis. Concordia University.
 
Gong, M. J., Peng, M. J., Zhu, H. S. 2018. Research of multiple refined degree simulating and modeling for high pressure feed water heat exchanger in nuclear power plant. Appl Therm Eng, 140: 190-207.
Crossref Google Scholar
 
Greenspan, D. 1991. Vortex Street Modelling.
 
Guidoboni, G., Glowinski, R., Cavallini, N., Canic, S. 2009. Stable loosely-coupled-type algorithm for fluid-structure interaction in blood flow. J Comput Phys, 228: 6916-6937.
Crossref Google Scholar
 
Hamed, A. M., Vega, J., Liu, B., Chamorro, L. P. 2017. Flow around a semicircular cylinder with passive flow control mechanisms. Exp Fluids, 58: 22.
Crossref Google Scholar
 
He, T. 2015. A partitioned implicit coupling strategy for incompressible flow past an oscillating cylinder. Int J Comput Methods, 12: 1550012.
Crossref Google Scholar
 
He, X. W., Liu, N., Wang, G. P., Zhang, F. J., Li, S., Shao, S. D., Wang, H. 2012. Staggered meshless solid-fluid coupling. ACM T Graphic, 31: 1-12.
Crossref Google Scholar
 
Jiang, H. B., Cheng, Z. Q., Zhao, Y. P. 2013. Function airfoil and its pressure distribution and lift coefficient calculation. Appl Mech Mater, 328: 351-356.
Crossref Google Scholar
 
Meneghini, J. R., Saltara, F., Siqueira, C. L. R., Ferrari, J. A. Jr. 2001. Numerical simulation of flow interference between two circular cylinders in tandem and side-by-side arrangements. J Fluid Struct, 15: 327-350.
Crossref Google Scholar
 
Meng, F. Q., He, B. J., Zhu, J., Zhao, D. X., Darko, A., Zhao, Z. Q. 2018. Sensitivity analysis of wind pressure coefficients on CAARC standard tall buildings in CFD simulations. J Build Eng, 16: 146-158.
Crossref Google Scholar
 
Mustto, A. A., Bodstein, G. C. R. 2011. Subgrid-scale modeling of turbulent flow around circular cylinder by mesh-free vortex method. Eng Appl Comput Fl Mech, 5: 259-275.
Crossref Google Scholar
 
Mustto, A. A., Bodstein, G. C. R. 2013. Improved vortex method for the simulation of the flow around circular cylinders. In: Proceedings of the AIAA Computational Fluid Dynamics Conference.
 
Park, J., Kwon, K., Choi, H. 1998. Numerical solutions of flow past a circular cylinder at Reynolds numbers up to 160. KSME Int J, 12: 1200-1205.
Crossref Google Scholar
 
Penrose, J. M. T., Staples, C. J. 2002. Implicit fluid-structure coupling for simulation of cardiovascular problems. Int J Numer Meth Fl, 40: 467-478.
Crossref Google Scholar
 
Ploumhans, P., Winckelmans, G. S., Salmon, J. K., Leonard, A., Warren, M. S. 2002. Vortex methods for direct numerical simulation of three-dimensional bluff body flows: Application to the sphere at Re = 300, 500, and 1000. J Comput Phys, 178: 427-463.
Crossref Google Scholar
 
Rajani, B. N., Kandasamy, A., Majumdar, S. 2009. Numerical simulation of laminar flow past a circular cylinder. Appl Math Model, 33: 1228-1247.
Crossref Google Scholar
 
Rajesh, V., Chamkha, A. J., Sridevi, C,Al-Mudhaf, A. F. 2017. A numerical investigation of transient MHD free convective flow of a nanofluid over a moving semi-infinite vertical cylinder. Eng Comput, 34: 1393-1412.
Crossref Google Scholar
 
Ricci, M., Patruno, L., de Miranda, S., Ubertini, F. 2017. Flow field around a 5:1 rectangular cylinder using LES: Influence of inflow turbulence conditions, spanwise domain size and their interaction. Comput Fluids, 149: 181-193.
Crossref Google Scholar
 
Rival, D. E., Kriegseis, J., Schaub, P., Widmann, A., Tropea, C. 2014. Characteristic length scales for vortex detachment on plunging profiles with varying leading-edge geometry. Exp Fluids, 55: 1660.
Crossref Google Scholar
 
Son, J. S., Hanratty, T. J. 1969. Numerical solution for the flow around a cylinder at Reynolds numbers of 40, 200 and 500. J Fluid Mech, 35: 369-386.
Crossref Google Scholar
 
Tschoegl, N. W., Knauss, W. G., Emri, I. 2002. Poisson’s ratio in linear viscoelasticity—A critical review. Mech Time-Depend Mat, 6: 3-51.
Crossref Google Scholar
 
Wang, Y., Wei, S., Yan, X. T., Yao, C., Ming, Y. 2010. Computer simulation for bone scaffolds on account of fluid-solid coupling model. In: Proceedings of the 2009 International Forum on Computer Science-Technology and Applications: 251-254.
 
Wang, Z., Luo, W., Gao, L., Li, M. 2014. Modeling the bottom-up filling of through silicon vias with different additives. In: Proceedings of the 2014 15th International Conference on Electronic Packaging Technology: 618-621.
Crossref
 
Williamson, C. H. K. 1995. Vortex dynamics in the wake of a cylinder. In: Fluid Vortices. Fluid Mechanics and Its Applications, Vol. 30. Green, S. I. Ed. Springer Dordrecht: 155-234.
Crossref
 
Yue, Q., Liu, J., Luo, M., Zhang, Q. 2018. A method of fluid-solid coupling dynamics for tube bundle vibration and collision in a cylinder fluid domain. Appl Math Mech, 39: 568-583. (in Chinese)
Google Scholar
 
Zare Ghadi, A., Goodarzian, H., Gorji-Bandpy, M., Sadegh Valipour, M. 2012. Numerical investigation of magnetic effect on forced convection around two-dimensional circular cylinder embedded in porous media. Eng Appl Comp Fluid, 6: 395-402.
Crossref Google Scholar
 
Zhang, Y., Xiao, Z., Fu, S. 2007. Analysis of vortex shedding modes of an in-line oscillating circular cylinder in a uniform flow. Chinese Journal of Theoretical & Applied Mechanics, 39: 408-416. (in Chinese)
Google Scholar
 
Zhou, X., Wang, J. J., Hu, Y. 2019. Experimental investigation on the flow around a circular cylinder with upstream splitter plate. Journal of Visual, 22: 683-695.
Crossref Google Scholar
Experimental and Computational Multiphase Flow
Volume 2 Issue 3,
September 2020
Pages 151-161
DOI: 10.1007/s42757-019-0054-6
Cite this article:
Liu X, Gui N, Wu H, et al. Numerical simulation of flow past stationary and oscillating deformable circles with fluid-structure interaction. Experimental and Computational Multiphase Flow, 2020, 2(3): 151-161. https://doi.org/10.1007/s42757-019-0054-6

610

Views

16

Crossref

14

Web of Science

16

Scopus

Altmetrics
Received: 17 July 2019
Revised: 21 October 2019
Accepted: 21 October 2019
Published: 15 November 2019
© Tsinghua University Press 2019
Return