Principle of Consevation
For mass, momentum and energy conservation
Balancing equation
Rate of change of ϕ
= flow transport in
- flow transport out
+ molecular transport in
- molecular transport out
-+sources/sinks in CV
-+effects on CV-surfaces (2D,3D)
Example: Heat flow
Flow transport: convection
Molecular transport: conduction
Mass Conservation
Mass = Density * Volume
Mass flow rate = Density * Volume flow rate
= Density * Velocity * Area
Mass conservation equation ; Continuity equation
Momentum Conservation
Momentum = mass x velocity
Momentum is a vector because velocity is a vector.
One momentum equation per coordinate direction (x, y, z)
Conservation equation:
Temporal change of momentum = mass * acceleration
Newton: mass * acceleration * force
Momentum balance = force balance
CV Balancing
Momentum conservation equation: Balancing
Momentum conservation equation
2D-conservation equations for x-, y- momentum:
3D -conservation equations for x-, y-, z-momentum:
• Set of partial, coupled, nonlinear differential equations with variable coefficients.
Law of Stokes
Stokes: Momentum flows contrary to the velocity gradient, from “fast” to “slow”
Terms on the right side of the normal stresses are zero for incompressible fluids
Stresses (e.g. molecular momentum fluxes) are symmetric tensor of second order (3 x 3-Matrix)
Conservation equations in tensor-notation
Energy conservation
Turbulence modeling
Turbulence Characteristics
Turbulence Effects
Negative
Increased friction & resistance
Increased losses
Increased energy (heat) transfer
Noise
Vibrations
Positive
Increased mass (species concentration) transfer
Mixing
Navier-Stokes Equations
Turbulence Eddy Spectrum
Mean Values has many industrial applications
interest in mean (averaged) quantities:
Friction coefficients
Lift coefficients
Heat transfer rates
Alternatives:
Averaging of the results of a Direct(3D, time-dependent) Numerical Simulation
Averaging of the equations
averaged quantities as result
Modeling Strategies
DNS
LES
(U)RANS
DNS = Direct Numerical Simulation
solves Navier-Stokes equations without averaging or approximation (only discretization)
3D , time dependent
all motions contained in the flow are resolved by using a very fine grid
limited by processing speed and memory of the machine
most exact and „simplest“ approach
possible only at low Reynolds numbers
Resolves all scales and is used for none of the models.
LES = Large Eddy Simulation
treats only large eddies exactly (more energetic,mainly responsible for turbulent transport), uses models for small scales
prefered method for flows in which the Reynolds number is too high or the geometry is too complex for DNS
Resolves all scales and works for small models.
RANS
RANS (=Reynolds Averaged Navier Stokes) Model
Turbulence description
Eddy Viscosity Hypothesis
Conservation equations
RANS model: e.g. k-ε turbulence model
Turbulence Model Usage
Near-Wall Resolution
Last changed4 months ago