Three‐dimensional modal analysis of sloshing under surface tension

El-Kamali, Mahdi; Schotté, Jean-Sébastien; Ohayon, Roger

doi:10.1002/fld.2457

Cited by 16 publications

(12 citation statements)

References 15 publications

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“…The ISCFM is not involved in solving the flow equations due to its infinitely small size, and its effect is to reflect the contact angle and then to incorporate its orientation in calculating the mean curvatures at apparent-contact-line nodes. After these mean curvatures are calculated, the surface tension forces at these nodes can be computed, and the liquid pressures at these nodes can be determined by Equation (5), which contribute to the essential boundary condition for solving the pressure.…”

Section: Implementation Of the Contact Angle Boundary Conditionmentioning

confidence: 99%

“…3 With the increase in computational capabilities, there also has been a large amount of research works relating to the computational study of sloshing in recent years. [4][5][6] In order to deal with the moving free surface, several methods have been presented, including volume-of-fluid methods, [6][7][8] level-set methods, 9,10 and techniques based on the finite element method using moving grids. [11][12][13] Each of these classes of methods has its relative strengths and weaknesses.…”

Section: Introductionmentioning

confidence: 99%

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Improved method for implementing contact angle condition in simulation of liquid sloshing under microgravity

Tang

Yue

Yan

2018

Numerical Methods in Fluids

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Summary The finite element simulation of liquid sloshing under microgravity is focused on in this paper. For this class of flows, an important issue is to implement the contact angle boundary condition appropriately. A novel method of adding infinitely small free‐surface mesh just adjacent to the contact line is proposed here, which coincides with the physical definition of the contact angle. This free‐surface mesh has its orientation determined according to the contact angle, and the mean curvature at the contact line can be computed using this orientation. Hence, surface tension force can be computed and incorporated as an essential boundary condition into the pressure solve. This method is convenient to be applied in three‐dimensional simulations, and the use of relatively coarse meshes near the contact line is allowed. In order to validate the proposed method, several numerical simulations of flows in two‐dimensional circular and three‐dimensional cylindrical and spherical containers are presented, including calculation of equilibrium positions of the free surfaces, unsteady flows of liquid reorientation, and large‐amplitude nonlinear liquid sloshing under lateral excitation in microgravity. Parts of the numerical results are compared with the theoretical and published experimental results.

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Section: Implementation Of the Contact Angle Boundary Conditionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Improved method for implementing contact angle condition in simulation of liquid sloshing under microgravity

Tang

Yue

Yan

2018

Numerical Methods in Fluids

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“…Potential flow theory has been used by many researchers to analyze the sloshing effects in both time and frequency domains [4,5]. The rapid progress in computer technology in recent years has enabled researchers to perform a realistic simulation of the fluid motion in a moving container, including secondary effects such as turbulence [6,7], surface tension [8,9], and compressibility [10,11]. Several design concepts have been recently proposed in the literature to reduce sloshing effects in moving liquid containers.…”

Section: Introductionmentioning

confidence: 99%

Liquid Sloshing Damping in an Accelerated Tank Using a Novel Slot-Baffle Design

Demirel

Aral

2018

Water

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A slot-baffle design used in water treatment tanks previously developed by the authors is used to suppress sloshing effects in an accelerated tank. This new application is another example of the versatility of the slot-baffle design in inducing turbulence in fluid flow systems, which has numerous uses in engineering applications. Large amplitude surface waves in a harmonically excited tank are simulated using a second-order accurate numerical model in OpenFOAM. The verification of the numerical model is performed by comparing the numerical results with existing laboratory measurements, which show a favorable agreement. Various slot configurations are studied in order to evaluate the damping performance during the external excitation of the tank. It is shown that the present design shows an effective dissipation performance in a broad range of oscillation frequencies, while 88% of the internal kinetic energy of the liquid is dissipated over thirty oscillation periods for the resonance case.

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“…Concerning the linear formulation for the compressible liquid with free surface, the sloshing is taken into account with surface tension (capillarity) effects. We refer the reader to [6,7] for the classical theory on capillarity, to [8,9,10] for developments of the behavior of liquids in microgravity environment, to [11,12] for general analyzes of sloshing problems for incompressible liquids in rigid structures, to [13,14,15,16,17,18] for sloshing problems of incompressible liquids without capillarity effects in elastic structures, to [13,19,20,21] for sloshing problems of incompressible liquids with capillarity effects in rigid structures, to [22,23,24,25,26,27,28,13,29] for the conditions of contact angle between the free surface and the structure, to [30] for sloshing problems of incompressible liquids with capillarity effects in elastic structures, to [31,32,33] for sloshing problems of compressible liquids with capillarity effects in rigid structures, to [1] for linear dissipative acoustic liquids with sloshing and capillarity effects in linear elastic structures. Concerning nonlinear sloshing and capillarity for incompressible liquids in rigid tanks submitted to rigid body motions, see [34,35,36,37,38].…”

Section: Introductionmentioning

confidence: 99%

Nonlinear model reduction for computational vibration analysis of structures with weak geometrical nonlinearity coupled with linear acoustic liquids in the presence of linear sloshing and capillarity

Ohayon

Soize

2016

Computers & Fluids

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International audienceThis paper deals with a novel formulation of a nonlinear reduced-order computational model for analyzing the non-linear vibrations of a linear viscoelastic structure with weak nonlinear geometrical effects, coupled with a linear acoustic liquid with sloshing and capillarity on the free surface. The model proposed is derived from the one used in fluid-structure interaction for linear systems, for which the analysis of the acoustic-sloshing-capillarity phenomena is efficient thanks to the use of a projection on the linear modes of the linear acoustic liquid and on the sloshing modes with capillarity. Concerning the construction of the vector basis for the structure, it is proposed to use a POD approach for the viscoelastic structure with weak nonlinear geometrical effects and taking into account the added mass induced by the liquid. The methodology for constructing the vector bases of the admissible sets and for obtaining the non-linear ROM are detailed. The computational nonlinear ROM that is presented can directly be used for analyzing the vibrations of such fluid-structure systems using commercial finite element softwares for computing the vector bases and the projections

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Three‐dimensional modal analysis of sloshing under surface tension

Cited by 16 publications

References 15 publications

Improved method for implementing contact angle condition in simulation of liquid sloshing under microgravity

Improved method for implementing contact angle condition in simulation of liquid sloshing under microgravity

Liquid Sloshing Damping in an Accelerated Tank Using a Novel Slot-Baffle Design

Nonlinear model reduction for computational vibration analysis of structures with weak geometrical nonlinearity coupled with linear acoustic liquids in the presence of linear sloshing and capillarity

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