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cs_wall_functions.c File Reference
#include "cs_config.h"
#include "cs_defs.h"
#include <assert.h>
#include <errno.h>
#include <stdio.h>
#include <stdarg.h>
#include <string.h>
#include <math.h>
#include <stdlib.h>
#include <float.h>
#include <mpi.h>
#include <bft_error.h>
#include <bft_mem.h>
#include <bft_printf.h>
#include "cs_log.h"
#include "cs_mesh.h"
#include "cs_turbulence_model.h"
#include "cs_wall_functions.h"
Include dependency graph for cs_wall_functions.c:

Functions

void CS_PROCF (wallfunctions, WALLFUNCTIONS) const
 
void CS_PROCF (hturbp, HTURBP) const
 
cs_wall_functions_tcs_get_glob_wall_functions (void)
 
void cs_wall_functions_velocity (cs_wall_f_type_t iwallf, cs_lnum_t ifac, cs_real_t l_visc, cs_real_t t_visc, cs_real_t vel, cs_real_t y, cs_real_t roughness, cs_real_t rnnb, cs_real_t kinetic_en, int *iuntur, cs_lnum_t *nsubla, cs_lnum_t *nlogla, cs_real_t *ustar, cs_real_t *uk, cs_real_t *yplus, cs_real_t *ypup, cs_real_t *cofimp, cs_real_t *dplus)
 Compute the friction velocity and $y^+$ / $u^+$. More...
 
void cs_wall_functions_scalar (cs_wall_f_s_type_t iwalfs, cs_real_t prl, cs_real_t prt, cs_real_t yplus, cs_real_t dplus, cs_real_t *htur, cs_real_t *yplim)
 Compute the correction of the exchange coefficient between the fluid and the wall for a turbulent flow. More...
 

Detailed Description

Wall functions descriptor and computation.

Function Documentation

◆ cs_get_glob_wall_functions()

cs_wall_functions_t* cs_get_glob_wall_functions ( void  )

◆ CS_PROCF() [1/2]

void CS_PROCF ( hturbp  ,
HTURBP   
) const

◆ CS_PROCF() [2/2]

void CS_PROCF ( wallfunctions  ,
WALLFUNCTIONS   
) const

◆ cs_wall_functions_scalar()

void cs_wall_functions_scalar ( cs_wall_f_s_type_t  iwalfs,
cs_real_t  prl,
cs_real_t  prt,
cs_real_t  yplus,
cs_real_t  dplus,
cs_real_t htur,
cs_real_t yplim 
)

Compute the correction of the exchange coefficient between the fluid and the wall for a turbulent flow.

This is function of the dimensionless distance to the wall $ y^+ = \dfrac{\centip \centf u_\star}{\nu}$.

Then the return coefficient reads:

\[ h_{tur} = Pr \dfrac{y^+}{T^+} \]

Parameters
[in]iwalfstype of wall functions for scalar
[in]prllaminar Prandtl number
[in]prtturbulent Prandtl number
[in]yplusdimensionless distance to the wall
[in]dplusdimensionless distance for scalable wall functions
[out]hturcorrected exchange coefficient
[out]yplimvalue of the limit for $ y^+ $

◆ cs_wall_functions_velocity()

void cs_wall_functions_velocity ( cs_wall_f_type_t  iwallf,
cs_lnum_t  ifac,
cs_real_t  l_visc,
cs_real_t  t_visc,
cs_real_t  vel,
cs_real_t  y,
cs_real_t  roughness,
cs_real_t  rnnb,
cs_real_t  kinetic_en,
int *  iuntur,
cs_lnum_t nsubla,
cs_lnum_t nlogla,
cs_real_t ustar,
cs_real_t uk,
cs_real_t yplus,
cs_real_t ypup,
cs_real_t cofimp,
cs_real_t dplus 
)

Compute the friction velocity and $y^+$ / $u^+$.

Parameters
[in]iwallfwall function type
[in]ifacface number
[in]l_visckinematic viscosity
[in]t_viscturbulent kinematic viscosity
[in]velwall projected cell center velocity
[in]ywall distance
[in]roughnessroughness
[in]rnnb$\vec{n}.(\tens{R}\vec{n})$
[in]kinetic_enturbulente kinetic energy
[in]iunturindicator: 0 in the viscous sublayer
[in]nsublacounter of cell in the viscous sublayer
[in]nloglacounter of cell in the log-layer
[out]ustarfriction velocity
[out]ukfriction velocity
[out]yplusdimensionless distance to the wall
[out]ypupyplus projected vel ratio
[out]cofimp$\frac{|U_F|}{|U_I^p|}$ to ensure a good turbulence production
[out]dplusdimensionless shift to the wall for scalable wall functions