Your search keyword '"sloshing"' showing total 3 results

1. Computational Fluid Dynamics 2020.

Author

Shadloo, Mostafa Safdari and Shadloo, Mostafa Safdari

Subjects

Mathematics & science, Research & information: general, CMC-water, Casson fluid, Casson nanoliquid, Darcy law, Darcy-Forchheimer model, Hyperloop system, Joule heating, Lie group framework, MHD, MHD flow, Marangoni convection, Prandtl-Eyring nanofluid, Reiner-Rivlin nanofluid, Sisko fluid flow, Sutterby fluid, Tiwari and Das model, activation energy, aerodynamic characteristics, aerodynamic drag, bioconvection nanofluid, circular plates, concentric hexagonal annulus, convective boundary condition, cross fluid, curved surface, damaged rotor blade, damping factor, drag coefficient, dual solution, entropy, entropy generation, entropy generation minimization, exact solution, ferrofluid, finite difference method, first slip, fluid structure-interaction, gas turbine, gold particles, heat generation, heat generation/absorption, heat source, homogeneous-heterogeneous reactions, homotopy analysis method, hybrid method, hybrid nanofluid, implicit finite difference method, inclined MHD, induced magnetic effects, lattice Boltzmann method, leading-edge modification, magnetohydrodynamics (MHD), micropolar hybrid nanofluid, mixed convection, mixed convection flow, moving wall, nanofluid, nanofluids, nanoliquid, natural convection simulation, non-axisymmetric flow, plume, porous medium, porous slider, pressure wave, radiation effect, reynolds number, scaling group analysis, second slip, series solution, shockwave, slip effect, slip effects, sloshing, smoothed profile method, solid sphere, sphere, stability analysis, stagnation-point flow, steady flow, stretched cylinder, stretching surface, stretching/shrinking sheet, successive local linearization method, swimming gyrotactic microorganisms, thermal radiation, third-grade liquid, transonic speed, unsteady flow, unsteady slip flow, unsteady stagnation point, velocity slip, vibration suppression

Abstract

Summary: This book presents a collection of works published in a recent Special Issue (SI) entitled "Computational Fluid Dynamics". These works address the development and validation of existent numerical solvers for fluid flow problems and their related applications. They present complex nonlinear, non-Newtonian fluid flow problems that are (in some cases) coupled with heat transfer, phase change, nanofluidic, and magnetohydrodynamics (MHD) phenomena. The applications are wide and range from aerodynamic drag and pressure waves to geometrical blade modification on aerodynamics characteristics of high-pressure gas turbines, hydromagnetic flow arising in porous regions, optimal design of isothermal sloshing vessels to evaluation of (hybrid) nanofluid properties, their control using MHD, and their effect on different modes of heat transfer. Recent advances in numerical, theoretical, and experimental methodologies, as well as new physics, new methodological developments, and their limitations are presented within the current book. Among others, in the presented works, special attention is paid to validating and improving the accuracy of the presented methodologies. This book brings together a collection of inter/multidisciplinary works on many engineering applications in a coherent manner.

2. Advances in Hydraulics and Hydroinformatics Volume 2.

Author

Zhou, Jianguo, Borthwick, Alistair, Peng, Yong, Zhang, Jianmin, and Zhou, Jianguo

Subjects

History of engineering & technology, 3D confined wall jet, BSTEM model, Bathy-supp, CFD, CFD-DEM coupling, DEM, FGP (flaring gate pier), Froude number, Gaussian distribution, HEC-RAS controller, LES-VOF method, Ningxia-Inner Mongolia, PIV, Sichuan province, TOPSIS method, Tarim Basin, U-shaped channel, Y-shaped confluence channel, Yellow River, abutment, aerated flow, air bubble chord length, air bubble frequency, air concentration, application depth, artificial ventilation, automation of flow modeling, backward-facing step, best depth, breaking wave, bridge piers, bridge scour, cavitation bubble, central angle of step, chute aerator, clogging, coherent vortex structure, collapse near a wall, collision in air, consistent particle method, dam-break flood, decay rate, desert-oasis areas, discharge coefficient, double cavitation bubble, drag force, drip irrigation, dry season, embankment weir, energy conversion rate, energy dissipation, evolution of precipitation, experiment, experimental model, experimental study, finite crest length weir, flood &amp, floods, flow division, flow property, flow region, flow-induced vibration, fluctuating pressure, flushing, fluvial acoustic tomography, free shear layer, free surface flow, free surface measurement, gate-opening modes, gravity wave model, high-speed photography, hydraulic characteristics, hydraulic jump, hydrocyclone, hydrodynamic modelling, hydrodynamic performance, hyporheic exchange, image processing technology, impact pressure, influencing factors, information entropy theory, jet trajectory, k-ε model, large eddy simulation, lattice Boltzmann method, linearly moved irrigation system, longitudinal velocity, mean flow, micro-jet, model simulation, moving speed, multi-horizontal-submerged jets, multiple bubble collapse, near-field vibration, non-submerged rigid vegetation, numerical analysis, numerical simulation, offset jet, open channel bend, optical motion capturing, orthogonal tests, overtopping flow, parallel cavitation, particle image velocimetry, particle shape, particle size, particle size distribution, phase difference, physical hydraulic modeling, plane gate, plunge pool, pool weir, pooled stepped spillway, potential core, pressure flow, pressure wave energy, pseudopotential lattice Boltzmann model, python scripting, radius-to-width ratio, rainfall intensity distribution, river bathymetry, river flow modeling, riverbank collapse, scour and velocity field, secondary flow, sediment, sediment transport, sediment transport simulation, sediments, sensitivity analysis, separation and reattachment, shallow lake, ski-jump flow, slope coefficient, sloshing, solitary wave, spillway bottom, spillway outlet, stepped dropshaft, stilling basin with shallow-water cushion (SBSWC), subcritical flow, submerged breakwater, submerged flow, submerged jets, surface-piercing propeller, surface−groundwater flow process, synchronized PIV, tank test, three-dimensional aerator, tidal channel junction, tidal discharge, tilt distribution cavitation, trajectory line, transforming mechanism, trapezoidal cross-section, turbulence, turbulent kinetic energy, two water jets, uniformity coefficient, velocity distribution, vortex, vortical evolution, water and sediment separation, water-saving irrigation development level, wave gauge, wavelet analysis, wetland

Abstract

Summary: This Special Issue reports on recent research trends in hydraulics, hydrodynamics, and hydroinformatics, and their novel applications in practical engineering. The Issue covers a wide range of topics, including open channel flows, sediment transport dynamics, two-phase flows, flow-induced vibration and water quality. The collected papers provide insight into new developments in physical, mathematical, and numerical modelling of important problems in hydraulics and hydroinformatics, and include demonstrations of the application of such models in water resources engineering.

3. Numerical Analysis of Externally-Induced Sloshing in Spherical Liquid Containers.

Author

Karamanos, Spyros A., Patkas, Lazaros A., and Papaprokopiou, Dimitris

Abstract

Motivated by the earthquake response of industrial pressure vessels, the present chapter investigates externally-induced sloshing in spherical liquid containers. Assuming ideal and irrotational flow, small-amplitude free-surface elevation, the problem is solved through a variational (Garlerkin) formulation that uses either a numerical finite element formulation or a semi-analytical methodology in terms of harmonic global functions that allows for high-precision computations. Considering modal analysis and an appropriate decomposition of the container-fluid motion, the sloshing frequencies and the corresponding sloshing (or convective) masses are calculated, leading to a simple and efficient method for predicting the dynamic behavior of spherical liquid containers. In both solution methodologies, the accuracy and convergence of the results are examined. The calculated sloshing frequencies and masses are in very good comparison with available semi-analytical or numerical solutions, and previously reported experimental data. It is also shown that consideration of only the first sloshing mass is adequate to represent the dynamic behavior of the spherical liquid container within a good level of accuracy. [ABSTRACT FROM AUTHOR]

Published

2011