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Equations Navier-Stokes

The governing equations for mass flow, energy flow, and contaminant flow in a room will be the continuity equation, Navier-Stokes equations (one in each coordinate direction), the energy equation, and the mass transport equation, respectively. [Pg.1177]

Viscous Forces In the momentum equation (Navier-Stokes equation), forces F acting on the system result from viscous stresses. It is necessary to relate these stresses to the velocity field and the fluid s viscosity. This relationship follows from the stress and strain-rate tensors, using Stokes postulates. [Pg.17]

In earlier sections the fluid strain rate was described in terms of the velocity field. Up to this point, however, the stress has not been related to the underlying flow field. It is the quantitative relationship between fluid strain rate and stress that permits the momentum-conservation equations (Navier-Stokes equations) to be written with the velocity field as the dependent variable. [Pg.49]

There are basically two ways of modeling a flow field the fluid is either treated as a collection of molecules or is considered to be continuous and indeflnitely divisible - continuum modeling. The former approach can be of deterministic or probabilistic modeling, while in the latter approach the velocity, density, pressure, etc. are aU deflned at every point in space and time, and the conservation of mass, momentum and energy lead to a set of nonlinear partial differential equations (Navier-Stokes). Fluid modeling classiflcation is depicted schematically in Fig. 1. [Pg.2]

Numerical models try to accurately predict the behavior of a jet breaking up. If one wants to exactly solve the full set of equations (Navier-Stokes, energy, etc.) one needs to perform direct numerical simulations (DNS), which requires tremendous computational power. The computational power available today only allows modeling of simple flow with low spatial and temporal resolution. Researchers are therefore required to make approximatimis that simplify the governing equations and thereby reduce the complexity of the system. [Pg.490]

Pulsatile flow in an elastic vessel is very complex, since the tube is able to undergo local deformations in both longitudinal and circumferential directions. The unsteady component of the pulsatile flow is assumed to be induced by propagation of small waves in a pressurized elastic tube. The mathematical approach is based on the classical model for the fluid-structure interaction problem, which describes the dynamic equilibrium between the fluid and the tube thin wall (Womersley, 1955b Atabek and Lew, 1966). The dynamic equilibrium is expressed by the hydrodynamic equations (Navier-Stokes) for the incompressible fluid flow and the equations of motion for the wall of an elastic tube, which are coupled together by the boundary conditions at the fluid-wall interface. The motion of the liquid is described in a fixed laboratory coordinate system (f , 6, f), and the dynamic... [Pg.82]

The gas flow in the SOFC is governed by the momentum conservation equation (Navier-Stokes equation) ... [Pg.738]

Problem By writing the Stokes equation (Navier-Stokes equation without the inertial term) in cylindrical coordinates, show that the velocity profile in the tube is parabolic.Designate by G the pressure gradient responsible for the transport of fluid (in the present problem, G is generated by the Laplace underpressure existing at the upstream interface), and set the velocity at the solid/liquid interface equal to zero. Under these conditions, deduce the average velocity in the tube (Poiseuille s law) and, from there, the viscous force F that opposes the progress of the fluid [equation (5.40)]. [Pg.130]

Mass balances must be used with the flow pattern (knowm a priori from theory or experimental measurements) to establish species concentrations and fluxes at any point in the fuel cell. When the flow pattern is a priori unknown, conservation-of-momentum equations (also called equations of motion) must be used with mass balance equations to establish the velocity and concentration profiles. Conservation of momentum for gases leads to the following equations (Navier-Stokes equations), in which k represents one of the three orthogonal directions in the coordinate sj stem (x, y, and z) ... [Pg.295]

It turns out that there is another branch of mathematics, closely related to tire calculus of variations, although historically the two fields grew up somewhat separately, known as optimal control theory (OCT). Although the boundary between these two fields is somewhat blurred, in practice one may view optimal control theory as the application of the calculus of variations to problems with differential equation constraints. OCT is used in chemical, electrical, and aeronautical engineering where the differential equation constraints may be chemical kinetic equations, electrical circuit equations, the Navier-Stokes equations for air flow, or Newton s equations. In our case, the differential equation constraint is the TDSE in the presence of the control, which is the electric field interacting with the dipole (pemianent or transition dipole moment) of the molecule [53, 54, 55 and 56]. From the point of view of control theory, this application presents many new features relative to conventional applications perhaps most interesting mathematically is the admission of a complex state variable and a complex control conceptually, the application of control teclmiques to steer the microscopic equations of motion is both a novel and potentially very important new direction. [Pg.268]

If these assumptions are satisfied then the ideas developed earlier about the mean free path can be used to provide qualitative but useful estimates of the transport properties of a dilute gas. While many varied and complicated processes can take place in fluid systems, such as turbulent flow, pattern fonnation, and so on, the principles on which these flows are analysed are remarkably simple. The description of both simple and complicated flows m fluids is based on five hydrodynamic equations, die Navier-Stokes equations. These equations, in trim, are based upon the mechanical laws of conservation of particles, momentum and energy in a fluid, together with a set of phenomenological equations, such as Fourier s law of themial conduction and Newton s law of fluid friction. When these phenomenological laws are used in combination with the conservation equations, one obtains the Navier-Stokes equations. Our goal here is to derive the phenomenological laws from elementary mean free path considerations, and to obtain estimates of the associated transport coefficients. Flere we will consider themial conduction and viscous flow as examples. [Pg.671]

A proposal based on Onsager s theory was made by Landau and Lifshitz [27] for the fluctuations that should be added to the Navier-Stokes hydrodynamic equations. Fluctuating stress tensor and heat flux temis were postulated in analogy with the Onsager theory. Flowever, since this is a case where the variables are of mixed time reversal character, tlie derivation was not fiilly rigorous. This situation was remedied by tlie derivation by Fox and Ulilenbeck [13, H, 18] based on general stationary Gaussian-Markov processes [12]. The precise fomi of the Landau proposal is confimied by this approach [14]. [Pg.705]

Let Ap, Au and AT denote the deviations of the mass density, p, the velocity field, u, and the temperature, T, fiom their fiill equilibrium values. The fluctuating, linearized Navier-Stokes equations are... [Pg.705]

Surface waves at an interface between two innniscible fluids involve effects due to gravity (g) and surface tension (a) forces. (In this section, o denotes surface tension and a denotes the stress tensor. The two should not be coiifiised with one another.) In a hydrodynamic approach, the interface is treated as a sharp boundary and the two bulk phases as incompressible. The Navier-Stokes equations for the two bulk phases (balance of macroscopic forces is the mgredient) along with the boundary condition at the interface (surface tension o enters here) are solved for possible hamionic oscillations of the interface of the fomi, exp [-(iu + s)t + i V-.r], where m is the frequency, is the damping coefficient, s tlie 2-d wavevector of the periodic oscillation and. ra 2-d vector parallel to the surface. For a liquid-vapour interface which we consider, away from the critical point, the vapour density is negligible compared to the liquid density and one obtains the hydrodynamic dispersion relation for surface waves + s>tf. The temi gq in the dispersion relation arises from... [Pg.725]

These are the two components of the Navier-Stokes equation including fluctuations s., which obey the fluctuation dissipation theorem, valid for incompressible, classical fluids ... [Pg.726]

Quian Y H, D Humieres D and Lallemand P 1992 Lattice BGK models for Navier-Stokes equation Euro. Phys. Lett. 17 479... [Pg.2387]

Ocily n. - 1 of the n equations (4.1) are independent, since both sides vanish on suinming over r, so a further relation between the velocity vectors V is required. It is provided by the overall momentum balance for the mixture, and a well known result of dilute gas kinetic theory shows that this takes the form of the Navier-Stokes equation... [Pg.26]

Clearly then, the continuum approach as outlined above is faulty. Furthermore, since our erroneous result depends only on the non-slip boundary condition for V together with the Navier-Stokes equation (4.3), one or... [Pg.27]

Equations (1.6) and (1.7) are used to formulate explicit relationships between the extra stress components and the velocity gradients. Using these relationships the extra stress, t, can be eliminated from the governing equations. This is the basis for the derivation of the well-known Navier-Stokes equations which represent the Newtonian flow (Aris, 1989). [Pg.4]

Brooks, A. N, and Hughes, T. J.R., 1982. Streamline-upwind/Petrov Galerldn formulations for convection dominated hows with particular emphasis on the incompressible Navier -Stokes equations. Cornput. Methods Appl Meek Eng. 32, 199-259. [Pg.68]

Crouzeix, M. and Raviart, P. A., 1973. Conforming and non-conforming finite elements for solving the stationary Navier-Stokes equations. RAIRO, Seric Rouge 3, 33 -76. [Pg.68]

Taylor, C. and Hood, P., 1973. A numerical solution of the Navier-Stokes equations using the finite element technique. Comput. Fluids 1, 73-100. [Pg.69]

Papanastasiou et al. (1992) suggested that in order to generate realistic solutions for Navier-Stokes equations the exit conditions should be kept free (i.e. no outflow conditions should be imposed). In this approach application of Green s theorem to the equations corresponding to the exit boundary nodes is avoided. This is eqvrivalent to imposing no exit conditions if elements with... [Pg.97]

Gresho, P. M., Lee, R. L. and Sani, R. L., 1980. On the time-dependent solution of the incompressible Navier-Stokes equations in two and three dimensions. In Recent Advances in Numerical Methods in fluids, Ch. 2, Pineridge Press, Swansea, pp. 27-75. [Pg.109]

As already mentioned, the present code corresponds to the solution of steady-state non-isothennal Navier-Stokes equations in two-dimensional Cartesian domains by the continuous penalty method. As an example, we consider modifications required to extend the program to the solution of creeping (Stokes) non-isothermal flow in axisymmetric domains ... [Pg.215]

Dissipative particle dynamics (DPD) is a technique for simulating the motion of mesoscale beads. The technique is superficially similar to a Brownian dynamics simulation in that it incorporates equations of motion, a dissipative (random) force, and a viscous drag between moving beads. However, the simulation uses a modified velocity Verlet algorithm to ensure that total momentum and force symmetries are conserved. This results in a simulation that obeys the Navier-Stokes equations and can thus predict flow. In order to set up these equations, there must be parameters to describe the interaction between beads, dissipative force, and drag. [Pg.274]

The simplest case of fluid modeling is the technique known as computational fluid dynamics. These calculations model the fluid as a continuum that has various properties of viscosity, Reynolds number, and so on. The flow of that fluid is then modeled by using numerical techniques, such as a finite element calculation, to determine the properties of the system as predicted by the Navier-Stokes equation. These techniques are generally the realm of the engineering community and will not be discussed further here. [Pg.302]


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Cartesian Navier-Stokes Equations

Continuity and Navier-Stokes Equations

Cylindrical Navier-Stokes Equations

Dimensionless form Navier-Stokes equations

Equation, Boltzmann, generalized Stokes-Navier

Equations of Navier-Stokes

Equations of motion Navier-Stokes

Fluid flow Navier-Stokes equations

Gradient Perturbations - Navier Stokes Equations

Hydrodynamic equations Navier-Stokes

Hydrodynamics Stokes-Navier equation

Laminar Flows. Navier-Stokes Equations

Laws Navier-Stokes equations

Models/modeling Navier-Stokes equations

Momentum Navier-Stokes equation

Momentum and Navier-Stokes Equations

Navier Stokes equation flow models derived from

Navier equations

Navier-Stokes

Navier-Stokes Equation and the Classical Permeability Theory

Navier-Stokes Equations in the Case of Two-Dimensional Flow

Navier-Stokes equation Fourier-transformed

Navier-Stokes equation conditions

Navier-Stokes equation definition

Navier-Stokes equation filtered

Navier-Stokes equation for Newtonian fluid

Navier-Stokes equation for incompressible flow

Navier-Stokes equation incompressible liquid

Navier-Stokes equation numerical solutions

Navier-Stokes equation with electric force

Navier-Stokes equation, conserved order

Navier-Stokes equations cartesian coordinates

Navier-Stokes equations constant viscosity

Navier-Stokes equations coordinates

Navier-Stokes equations corrections

Navier-Stokes equations cylindrical coordinates

Navier-Stokes equations derivation

Navier-Stokes equations general vector form

Navier-Stokes equations in Cartesian coordinates

Navier-Stokes equations in cylindrical coordinates

Navier-Stokes equations incompressible

Navier-Stokes equations solution procedures

Navier-Stokes equations spherical coordinates

Navier-Stokes equations time-averaged

Navier-Stokes equations turbulent flow

Navier-Stokes equations validity

Navier-Stokes equations, simplification

Navier-Stokes, Euler, and Bernoulli Equations

Navier-Stokes’ equation, for

Nondimensionalization Navier-Stokes equation

Reynolds-averaged Navier-Stokes equation

Reynolds-averaged Navier-Stokes equation RANS)

Reynolds-averaged Navier-Stokes equations turbulence modeling

Simplifications to the Navier-Stokes equations

Solution of the Navier-Stokes Equation

Spherical Navier-Stokes Equations

Stokes equation

The Navier-Stokes equations

Turbulence on Time-Averaged Navier-Stokes Equations

Viscosity Navier-Stokes equation

Viscosity and the generalised Navier-Stokes equations

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