Abstract
A finite difference model for solving Navier Stokes equations with turbulence taken into account is used to investigate viscous liquid sloshing-wave interaction with baffles in a tank. The volume-of-fluid and virtual boundary force methods are employed to simulate free surface flow interaction with structures. A liquid sloshing experimental apparatus was established to evaluate the accuracy of the proposed model, as well as to study nonlinear sloshing in a prismatic tank with the baffles. Damping effects of sloshing in a rectangular tank with bottom-mounted vertical baffles and vertical baffles touching the free surface are studied numerically and experimentally. Good agreement is obtained between the present numerical results and experimental data. The numerical results match well with the current experimental data for strong nonlinear sloshing with large free surface slopes. The reduction in sloshing-wave elevation and impact pressure induced by the bottom-mounted vertical baffle and the vertical baffle touching the free surface is estimated by varying the external excitation frequency and the location and height of the vertical baffle under horizontal excitation.
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References
Akyildiz, H., 2012. A numerical study of the effects of the vertical baffle on liquid sloshing in two-dimensional rectangular tank. Journal of Sound and Vibration, 331: 41–52.
Buzhinskii, V. A., 1998. Vortex damping of sloshing in tanks with baffles. Journal of Applied Mathematics and Mechanics, 62 (2): 217–224.
Cho, J. R., Lee, H. W., and Kim, K. W., 2002. Free vibration analysis of baffled liquid-storage tanks by the structuralacoustic finite element formulation. Journal of Sound and Vibration, 258: 847–866.
Faltinsen, O. M., and Timokha, A. N., 2009. Sloshing. Cambridge University Press, New York, 577pp.
Gandhi, P. S., Joshi, K. B., and Ananthkrishnan, N., 2008. Design and development of a novel 2DOF actuation slosh rig. Journal of Dynamic Systems, Measurement, and Control, 131 (1): 011006.
Gedikli, A., and Erguven, M. E., 1999. Seismic analysis of a liquid storage tank with a baffle. Journal of Sound and Vibration, 223: 141–155.
Ibrahim, R. A., 2005. Liquid Sloshing Dynamics: Theory and Applications. Cambridge University Press, New York, 970pp.
Kim, H. S., and Lee, Y. S., 2008. Optimization design technique for reduction of sloshing by evolutionary methods. Journal of Mechanical Science and Technology, 22 (1): 25–33.
Liu, D. M., and Lin, P. Z., 2008. A numerical study of threedimensional liquid sloshing in tanks. Journal of Computational Physics, 227: 3921–3939.
Liu, D. M., and Lin, P. Z., 2009. Three-dimensional liquid sloshing in a tank with baffles. Ocean Engineering, 36: 202–212.
Lu, L., Jiang, S. C., Zhao, M., and Tang, G. Q., 2015. Twodimensional viscous numerical simulation of liquid sloshing in rectangular tank with/without baffles and comparison with potential flow solutions. Ocean Engineering, 108: 662–677.
Qin, J. M., Chen, B., and Lu, L., 2013. Finite element based viscous numerical wave flume. Advances in Mechanical Engineering, 2013: 1–17.
Rebouillat, S., and Liksonov, D., 2010. Fluid-structure interaction in partially filled liquid containers: A comparative review of numerical approaches. Computers & Fluids, 39 (5): 739–746.
Shin, J. R., Choi, K. S., and Kang, S. Y., 2005. An analytical solution to sloshing natural periods for a prismatic liquid cargo tank with baffles. Journal of Ocean Engineering and Technology, 19: 16–21.
Tuner, M. R., Bridges, T. J., and Ardakani, H. A., 2013. Dynamic coupling in Cooker’s sloshing experiment with baffles. Physics of Fluids, 25 (11): 385–395.
Xue, M. A., and Lin, P. Z., 2011. Numerical study of ring baffle effects on reducing violent liquid sloshing. Computers & Fluids, 52: 116–129.
Xue, M. A., Lin, P. Z., Zheng, J. H., Ma, Y. X., Yuan, X. L., and Nguyen, V. T., 2013. Effects of perforated baffle on reducing sloshing in rectangular tank: Experimental and numerical study. China Ocean Engineering, 27 (5): 615–628.
Xue, M. A., Zheng, J. H., Lin, P. Z., and Yuan, X. L., 2017. Experimental study on vertical baffles of different configurations in suppressing sloshing pressure. Ocean Engineering, 136: 178–189.
Younes, M. F., Younes, Y. K., El-Madah, M., Ibrahim, I. M., and El-Dannanh, E. H., 2007. An experimental investigation of hydrodynamic damping due to vertical baffle arrangements in a rectangular tank. Proceedings of the Institution of Mechanical Engineers, Part M: Journal of Engineering for the Maritime Environment, 221 (3): 115–123.
Acknowledgement
This study is supported by the National Natural Science Foundation of China (Nos. 51679079 and 51209080), the Fundamental Research Funds for the Central Universities (No. 2014B17314), the Program for Excellent Innovative Talents of Hohai University, the Open Fund of State Key Laboratory of Hydraulic Engineering Simulation and Safety, Tianjin University (HESS-1703), the Open Fund Program of Key Laboratory of Water & Sediment Science and Water Hazard Prevention, Changsha University of Science & Technology (2015SS03), and the 111 Project (B12032).
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Xue, MA., Zheng, J., Lin, P. et al. Violent transient sloshing-wave interaction with a baffle in a three-dimensional numerical tank. J. Ocean Univ. China 16, 661–673 (2017). https://doi.org/10.1007/s11802-017-3383-8
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DOI: https://doi.org/10.1007/s11802-017-3383-8