Numerical and experimental investigation of damping in a dam-break problem with fluid-structure interaction

Demir, Abdullah; Dinçer, Ali Ersin; Bozkuş, Zafer; Tijsseling, Arris S.

doi:10.1631/jzus.a1800520

Cited by 17 publications

(10 citation statements)

References 25 publications

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“…FSI analysis of the two-way coupling method transfers the pressure calculated by fluid domain to the solid domain, and the nodal displacement calculated by the solid domain is returned to the fluid domain to update the flow field [ 25 ]. This coupling method needs to consider every field, i.e., fields that including the fluid flow, structural deformations, and moving mesh need to be considered during the coupling process, as shown in Figure 3 .…”

Section: Methodsmentioning

confidence: 99%

Fluid-Structure Interaction Analysis on Membrane Behavior of a Microfluidic Passive Valve

Lin

Jin

2020

Membranes

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In this paper, the effect of membrane features on flow characteristics in the microfluidic passive valve (MPV) and the membrane behavior against fluid flow are studied using the fluid-structure interaction (FSI) analysis. Firstly, the microvalve model with different numbers of microholes and pitches of microholes are designed to investigate the flow rate of the MPV. The result shows that the number of microholes on the membrane has a significant impact on the flow rate of the MPV, while the pitch of microholes has little effect on it. The constant flow rate maintained by the microvalve (the number of microholes n = 4) is 5.75 mL/min, and the threshold pressure to achieve the flow rate is 4 kPa. Secondly, the behavior of the membrane against the fluid flow is analyzed. The result shows that as the inlet pressure increases, the flow resistance of the MPV increases rapidly, and the deformation of the membrane gradually becomes stable. Finally, the effect of the membrane material on the flow rate and the deformation of the membrane are studied. The result shows that changes in the material properties of the membrane cause a decrease in the amount of deformation in all stages the all positions of the membrane. This work may provide valuable guidance for the optimization of microfluidic passive valve in microfluidic system.

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Section: Methodsmentioning

confidence: 99%

Fluid-Structure Interaction Analysis on Membrane Behavior of a Microfluidic Passive Valve

Lin

Jin

2020

Membranes

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“…u, and u are the acceleration, velocity, and displacement vectors, respectively. As can be seen in the equation, damping is included in the numerical calculations knowing that damping is not very effective for inertia-driven problems containing continuous interaction [26]. Rayleigh damping proportional to a linear combination of mass and stiffness was used:…”

Section: Umentioning

confidence: 99%

“…Various numerical models to couple fluid-structure interaction problems, such as MPS-FEM coupling [21] or immersed boundary methods combined with volume of fluid or level-set approaches [22][23][24], have been proposed in the literature [25]. In the present numerical model, smoothed particle hydrodynamics was coupled with the finite element method, and the coupling was satisfied with contact mechanics [26,27]. SPH, a Lagrangian and mesh-free method, was originally developed to simulate astrophysical problems [28,29].…”

Section: Introductionmentioning

confidence: 99%

Investigation of the Sloshing Behavior Due to Seismic Excitations Considering Two-Way Coupling of the Fluid and the Structure

Dinçer

2019

Water

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Sloshing behavior due to near-fault type and earthquake excitations of a fluid in a tank having a highly deformable elastic structure in the middle was investigated experimentally and numerically in this paper. In the numerical model, fluid was simulated with smoothed particle hydrodynamics (SPH) and structure was simulated with the finite element method (FEM). The coupling was satisfied with contact mechanics. The δ-SPH scheme was adapted to lower the numerical oscillations. The proposed fluid-structure interaction (FSI) method can simulate the violent fluid-structure interaction problem successfully. The effects of near-fault type and earthquake excitations on free-surfaces of fluid and the elastic structure are presented.

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“…Nowadays, researchers propose new methods or combined methods (Demir et al 2019;Dinçer et al 2019;Fernández-Méndez, Bonet, and Huerta 2005) already in use for better simulations. Some researchers use mesh-based methods (Cho and Lee 2004;Ghalandari et al 2019) to take the advantage of robustness.…”

Section: Introductionmentioning

confidence: 99%

Numerical and experimental investigation of damping in a dam-break problem with fluid-structure interaction

Cited by 17 publications

References 25 publications

Fluid-Structure Interaction Analysis on Membrane Behavior of a Microfluidic Passive Valve

Fluid-Structure Interaction Analysis on Membrane Behavior of a Microfluidic Passive Valve

Investigation of the Sloshing Behavior Due to Seismic Excitations Considering Two-Way Coupling of the Fluid and the Structure

Hydro-elastic analysis of standing submerged structures under seismic excitations with SPH-FEM approach

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