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d2q9 pf velocity Outflow autosym

Description

The 'd2q9_pf_cm' model is a multiphase 2D (planar) lattice Boltzmann model for the simulation of incompressible, immiscible fluids (at both high and low density ratios).

The base implementation uses an incompressible, velocity based LBM for capturing the hydrodynamics of the flow and solves the conservative phase field equation for the interfacial dynamics. To enhance stability, a Multiple-Relaxation-Time and Cascaded collision operator are used.

The MRT model has 2 options at compile time:

  • GF: Guo Forcing;

    This is using a higher order Forcing scheme from the work of Guo et al. (2002) for the hydrodynamics

  • RT: Ren Temporal

    This is using the Temporal term included in the phase field equilibrium distribution function by Ren et al. (2016)

Publications: " Improved locality of the phase-field lattice Boltzmann model for immiscible fluids at high density ratios " Authors: A. Fakhari, T. Mitchell, C. Leonardi, D. Bolster (2017) DOI: 10.1103/PhysRevE.96.053301

Boundary Conditions options at compile time: * Outflow:

  This is used for outflow boundaries, it is made as an
  option as it requires additional fields for calculations
  so results in a slower code.
  • autosym:

    Allows symmetry node type flags introduced in v6.2

Updates: 16/08/2018: Cascaded (CLBM) collision scheme is introduced for both hydrodynamics and phase-field.

Details

Model description files files for this model: Dynamics.c Dynamics.R

Zonal Settings

Name Comment
PhaseField_init Initial/Inflow PhaseField distribution
VelocityX inlet/outlet/init velocity
VelocityY inlet/outlet/init velocity
Pressure inlet/outlet/init density
GravitationX applied (rho)*GravitationX
GravitationY applied (rho)*GravitationY
PressureLossInObj Weight of [pressure loss] in objective
OutletFluxInObj Weight of [pressure loss] in objective
InletFluxInObj Weight of [pressure loss] in objective
TotalDensityInObj Weight of [Mass conservation check] in objective
RTIBubbleInObj Weight of [Bubble Tracker] in objective
RTISpikeInObj Weight of [Spike Tracker] in objective
NMovingWallForceInObj Weight of [force exerted on the N Moving Wall] in objective
NMovingWallPowerInObj Weight of [implented: Vx* incoming momentum (precollision)] in objective
FDragInObj Weight of [Force exerted on body in X-direction] in objective
FLiftInObj Weight of [Force exerted on body in Y-direction] in objective
FTotalInObj Weight of [Force exerted on body in X+Y -direction] in objective

Global Settings

Name Derived Comment
Period Number of cells per cos wave
Perturbation Size of wave perturbation, Perturbation Period
MidPoint height of RTI centerline
Radius Radius of diffuse interface circle
CenterX Circle center x-coord
CenterY Circle Center y-coord
BubbleType Drop/bubble
Density_h High density fluid
Density_l Low density fluid
PhaseField_h PhaseField in high density fluid
PhaseField_l PhaseField in low density fluid
W Anti-diffusivity coeff (phase interfacial thickness)
omega_phi 1.0/(3*M+0.5) one over relaxation time (phase field)
M Mobility
sigma surface tension
ContactAngle Contact angle in degrees - in reference to the high density fluid
radAngle ContactAngle*3.1415926535897/180 Conversion to rads for calcs
tau_l (3*Viscosity_l) relaxation time (low density fluid)
tau_h (3*Viscosity_h) relaxation time (high density fluid)
Viscosity_l kinematic viscosity
Viscosity_h kinematic viscosity
omega_bulk 1.0/(3*bulk_visc+0.5) inverse of bulk relaxation time
bulk_visc bulk viscosity
BuoyancyX applied (rho-rho_h)*BuoyancyX
BuoyancyY applied (rho-rho_h)*BuoyancyY
fixedIterator fixed iterator for velocity calculation
Threshold Parameters threshold

Exported Quantities (VTK, etc)

Name Unit Comment
Rho kg/m3 Rho
PhaseField 1 PhaseField
U m/s U
NormalizedPressure Pa NormalizedPressure
Pressure Pa Pressure
Normal 1 Normal

Exported Global Integrals (CSV, etc)

Name Unit Comment
RTIBubble 1 Bubble Tracker
RTISpike 1 Spike Tracker
PressureLoss 1mPa pressure loss
OutletFlux 1m2/s pressure loss
InletFlux 1m2/s pressure loss
TotalDensity 1kg/m3 Mass conservation check
NMovingWallForce 1 force exerted on the N Moving Wall
NMovingWallPower 1 implented: Vx* incoming momentum (precollision)
FDrag N Force exerted on body in X-direction
FLift N Force exerted on body in Y-direction
FTotal N Force exerted on body in X+Y -direction
Objective 1 Objective function

Node Types

Group Types
ADDITIONALS SpikeTrack, BubbleTrack, Smoothing
BODY Body
BOUNDARY MovingWall_N, MovingWall_S, NVelocity, WVelocity, Convective_E, Convective_N, Neumann_E, Solid, Wall
COLLISION BGK, MRT
SETTINGZONE DefaultZone
SYMX SymmetryX_plus, SymmetryX_minus
SYMY SymmetryY_plus, SymmetryY_minus

Solved fields

Name Access pattern Comment
g[0] stencil g[0]
g[1] stencil g[1]
g[2] stencil g[2]
g[3] stencil g[3]
g[4] stencil g[4]
g[5] stencil g[5]
g[6] stencil g[6]
g[7] stencil g[7]
g[8] stencil g[8]
h[0] stencil h[0]
h[1] stencil h[1]
h[2] stencil h[2]
h[3] stencil h[3]
h[4] stencil h[4]
h[5] stencil h[5]
h[6] stencil h[6]
h[7] stencil h[7]
h[8] stencil h[8]
gold0 stencil gold0
gold1 stencil gold0
gold2 stencil gold0
gold3 stencil gold0
gold4 stencil gold0
gold5 stencil gold0
gold6 stencil gold0
gold7 stencil gold0
gold8 stencil gold0
hold0 stencil hold0
hold1 stencil hold0
hold2 stencil hold0
hold3 stencil hold0
hold4 stencil hold0
hold5 stencil hold0
hold6 stencil hold0
hold7 stencil hold0
hold8 stencil hold0
nw_x stencil phase field normal at the wall in x direction, pointing into fluid
nw_y stencil nw_y
U stencil U
V stencil V
PhaseF stencil PhaseF

Densities - default accessors

Name Field Pulling field from Comment
g[0] g[0] stencil g[0]
g[1] g[1] stencil g[1]
g[2] g[2] stencil g[2]
g[3] g[3] stencil g[3]
g[4] g[4] stencil g[4]
g[5] g[5] stencil g[5]
g[6] g[6] stencil g[6]
g[7] g[7] stencil g[7]
g[8] g[8] stencil g[8]
h[0] h[0] stencil h[0]
h[1] h[1] stencil h[1]
h[2] h[2] stencil h[2]
h[3] h[3] stencil h[3]
h[4] h[4] stencil h[4]
h[5] h[5] stencil h[5]
h[6] h[6] stencil h[6]
h[7] h[7] stencil h[7]
h[8] h[8] stencil h[8]
gold0 gold0 stencil gold0
gold1 gold1 stencil gold0
gold2 gold2 stencil gold0
gold3 gold3 stencil gold0
gold4 gold4 stencil gold0
gold5 gold5 stencil gold0
gold6 gold6 stencil gold0
gold7 gold7 stencil gold0
gold8 gold8 stencil gold0
hold0 hold0 stencil hold0
hold1 hold1 stencil hold0
hold2 hold2 stencil hold0
hold3 hold3 stencil hold0
hold4 hold4 stencil hold0
hold5 hold5 stencil hold0
hold6 hold6 stencil hold0
hold7 hold7 stencil hold0
hold8 hold8 stencil hold0
nw_x nw_x stencil phase field normal at the wall in x direction, pointing into fluid
nw_y nw_y stencil nw_y
U U stencil U
V V stencil V

Action stages

Name Main procedure Preloaded densities Pushed fields
PhaseInit Init_phase none PhaseF
WallInit Init_wallNorm none nw_x, nw_y
BaseInit Init_distributions none g[0], g[1], g[2], g[3], g[4], g[5], g[6], g[7], g[8], h[0], h[1], h[2], h[3], h[4], h[5], h[6], h[7], h[8], gold0, gold1, gold2, gold3, gold4, gold5, gold6, gold7, gold8, hold0, hold1, hold2, hold3, hold4, hold5, hold6, hold7, hold8, U, V
BaseIter calcHydroIter g[0], g[1], g[2], g[3], g[4], g[5], g[6], g[7], g[8], h[0], h[1], h[2], h[3], h[4], h[5], h[6], h[7], h[8], gold0, gold1, gold2, gold3, gold4, gold5, gold6, gold7, gold8, hold0, hold1, hold2, hold3, hold4, hold5, hold6, hold7, hold8, nw_x, nw_y, U, V g[0], g[1], g[2], g[3], g[4], g[5], g[6], g[7], g[8], h[0], h[1], h[2], h[3], h[4], h[5], h[6], h[7], h[8], gold0, gold1, gold2, gold3, gold4, gold5, gold6, gold7, gold8, hold0, hold1, hold2, hold3, hold4, hold5, hold6, hold7, hold8, nw_x, nw_y, U, V
PhaseIter calcPhaseFIter g[0], g[1], g[2], g[3], g[4], g[5], g[6], g[7], g[8], h[0], h[1], h[2], h[3], h[4], h[5], h[6], h[7], h[8], gold0, gold1, gold2, gold3, gold4, gold5, gold6, gold7, gold8, hold0, hold1, hold2, hold3, hold4, hold5, hold6, hold7, hold8, nw_x, nw_y, U, V PhaseF
WallIter calcWallPhaseIter nw_x, nw_y PhaseF

Actions

Name Stages
Iteration BaseIter, PhaseIter, WallIter
Init PhaseInit, WallInit, WallIter, BaseInit