TRUST 1.9.8
HPC thermohydraulic platform
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Flux_interfacial_Zeitoun.cpp
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15
16#include <Flux_interfacial_Zeitoun.h>
17#include <Pb_Multiphase.h>
18
19Implemente_instanciable(Flux_interfacial_Zeitoun, "Flux_interfacial_Zeitoun", Flux_interfacial_base);
20
21Sortie& Flux_interfacial_Zeitoun::printOn(Sortie& os) const
22{
23 return os;
24}
25
26Entree& Flux_interfacial_Zeitoun::readOn(Entree& is)
27{
28 Param param(que_suis_je());
29 param.ajouter("dv_min", &dv_min_);
30 param.lire_avec_accolades_depuis(is);
31 return is;
32}
33
34void Flux_interfacial_Zeitoun::completer()
35{
36 Pb_Multiphase *pbm = sub_type(Pb_Multiphase, pb_.valeur()) ? &ref_cast(Pb_Multiphase, pb_.valeur()) : nullptr;
37
38 if (!pbm || pbm->nb_phases() == 1) Process::exit(que_suis_je() + " : not needed for single-phase flow!");
39 for (int n = 0; n < pbm->nb_phases(); n++) //recherche de n_l, n_g : phase {liquide,gaz}_continu en priorite
40 if (pbm->nom_phase(n).debute_par("liquide") && (n_l < 0 || pbm->nom_phase(n).finit_par("continu"))) n_l = n;
41
42 if (n_l < 0) Process::exit(que_suis_je() + " : liquid phase not found!");
43
44 if (!pbm->has_champ("diametre_bulles")) Process::exit("Flux_interfacial_Ranz_Mashall : bubble diameter needed !");
45
46 if (a_res_ < 1.e-12)
47 {
48 a_res_ = ref_cast(QDM_Multiphase, pb_->equation(0)).alpha_res();
49 a_res_ = std::max(1.e-4, a_res_*10.);
50 }
51
52 a_res_ = -1.;
53}
54
55
56void Flux_interfacial_Zeitoun::coeffs(const input_t& in, output_t& out) const
57{
58 out.hi = 0.;
59 out.da_hi= 0.;
60 out.dp_hi = 0.;
61 out.dT_hi= 0.;
62
63 int k, N = out.hi.dimension(0);
64 for (k = 0; k < N; k++)
65 if (k != n_l)
66 {
67 int ind_trav = (k>n_l) ? (n_l*(N-1)-(n_l-1)*(n_l)/2) + (k-n_l-1) : (k*(N-1)-(k-1)*(k)/2) + (n_l-k-1);
68 if ( in.T[k] > in.T[n_l]) // Cas condensation
69 {
70 double Re_b = in.rho[n_l] * in.nv[N * n_l + k] * in.d_bulles[k] / in.mu[n_l];
71
72 double Ja = std::max(in.T[k] - in.T[n_l], 2.) * in.rho[n_l] * in.Cp[n_l] / (in.rho[k] * in.Lvap[ind_trav] );
73 double dP_Ja = std::max(in.T[k] - in.T[n_l], 2.) * in.rho[n_l] * in.Cp[n_l] / in.rho[k] * -in.dP_Lvap[ind_trav]/(in.Lvap[ind_trav]*in.Lvap[ind_trav]) ;
74 double dTk_Ja = (in.T[k] - in.T[n_l] > 2.) ? in.rho[n_l] * in.Cp[n_l] / (in.rho[k] * in.Lvap[ind_trav] ) : 0. ;
75 double dTl_Ja = (in.T[k] - in.T[n_l] > 2.) ? - in.rho[n_l] * in.Cp[n_l] / (in.rho[k] * in.Lvap[ind_trav] ) : 0. ;
76
77 double Nu = 2.04* std::pow(Re_b, .61)* std::pow(std::max(in.alpha[k], a_min_coeff), 0.328)* std::pow(Ja, -0.308);
78 double da_Nu = 2.04* std::pow(Re_b, .61)*( (in.alpha[k] > a_min_coeff) ? 0.328*std::pow(in.alpha[k], 0.328-1.) : 0. )* std::pow(Ja, -1.308);
79 double dP_Nu = 2.04* std::pow(Re_b, .61)* std::pow(std::max(in.alpha[k], a_min_coeff), 0.328)* -.308*dP_Ja *std::pow(Ja, -1.308);
80 double dTk_Nu = 2.04* std::pow(Re_b, .61)* std::pow(std::max(in.alpha[k], a_min_coeff), 0.328)* -.308*dTk_Ja *std::pow(Ja, -1.308);
81 double dTl_Nu = 2.04* std::pow(Re_b, .61)* std::pow(std::max(in.alpha[k], a_min_coeff), 0.328)* -.308*dTl_Ja *std::pow(Ja, -1.308);
82
83 out.hi(n_l, k) = Nu * in.lambda[n_l] * 6. / (in.d_bulles[k]*in.d_bulles[k]) * std::max(in.alpha[k], a_min); // std::max() pour que le flux interfacial sont non nul
84 out.da_hi(n_l, k, k) = (in.alpha[k] > a_min ?
85 Nu * in.lambda[n_l] * 6. / (in.d_bulles[k]*in.d_bulles[k]) :
86 0.)
87 + da_Nu* in.lambda[n_l] * 6. / (in.d_bulles[k]*in.d_bulles[k]) * std::max(in.alpha[k], a_min);
88 out.dp_hi(n_l, k) = dP_Nu * in.lambda[n_l] * 6. / (in.d_bulles[k]*in.d_bulles[k]) * std::max(in.alpha[k], a_min);
89 out.dT_hi(n_l, k,n_l)= dTl_Nu * in.lambda[n_l] * 6. / (in.d_bulles[k]*in.d_bulles[k]) * std::max(in.alpha[k], a_min);
90 out.dT_hi(n_l, k, k) = dTk_Nu * in.lambda[n_l] * 6. / (in.d_bulles[k]*in.d_bulles[k]) * std::max(in.alpha[k], a_min);
91 out.hi(k, n_l) = 1e8;
92 if (in.alpha[k] < a_res_)
93 {
94 double hi_loc = out.hi(n_l, k);
95 out.hi(n_l, k) = 1.e8*(1-in.alpha[k]/a_res_) + out.hi(n_l, k) * in.alpha[k]/a_res_;
96 out.da_hi(n_l, k, k) = -1.e8/a_res_ + out.da_hi(n_l, k, k) * in.alpha[k]/a_res_ + hi_loc/a_res_;
97 out.dp_hi(n_l, k) = out.dp_hi(n_l, k) * in.alpha[k]/a_res_ ;
98 }
99 }
100 else // Cas flashing
101 {
102 out.hi(n_l, k) = 1.e8;
103 out.da_hi(n_l, k, k) = 0.;
104 out.dp_hi(n_l, k) = 0.;
105 out.dT_hi(n_l, k,n_l)= 0.;
106 out.dT_hi(n_l, k, k) = 0.;
107 out.hi(k, n_l) = 1e8;
108 }
109 }
110}
Entree
Class defining operators and methods for all reading operation in an input flow (file,...
Definition Entree.h:42
Flux_interfacial_Zeitoun
Flux interfacial a coefficient constant par phase.
Definition Flux_interfacial_Zeitoun.h:28
Flux_interfacial_Zeitoun::a_min
double a_min
Definition Flux_interfacial_Zeitoun.h:37
Flux_interfacial_Zeitoun::coeffs
void coeffs(const input_t &in, output_t &out) const override
Definition Flux_interfacial_Zeitoun.cpp:56
Flux_interfacial_Zeitoun::completer
void completer() override
Definition Flux_interfacial_Zeitoun.cpp:34
Flux_interfacial_Zeitoun::a_res_
double a_res_
Definition Flux_interfacial_Zeitoun.h:38
Flux_interfacial_Zeitoun::a_min_coeff
double a_min_coeff
Definition Flux_interfacial_Zeitoun.h:36
Flux_interfacial_Zeitoun::n_l
int n_l
Definition Flux_interfacial_Zeitoun.h:35
Flux_interfacial_base
classe Flux_interfacial_base correlations de flux de chaleur interfacial de la forme
Definition Flux_interfacial_base.h:43
Flux_interfacial_base::dv_min_
double dv_min_
Definition Flux_interfacial_base.h:83
Nom::debute_par
virtual int debute_par(const char *const n) const
Definition Nom.cpp:319
Objet_U::que_suis_je
const Nom & que_suis_je() const
renvoie la chaine identifiant la classe.
Definition Objet_U.cpp:104
Objet_U::readOn
virtual Entree & readOn(Entree &)
Lecture d'un Objet_U sur un flot d'entree Methode a surcharger.
Definition Objet_U.cpp:293
Objet_U::printOn
virtual Sortie & printOn(Sortie &) const
Ecriture de l'objet sur un flot de sortie Methode a surcharger.
Definition Objet_U.cpp:282
Pb_Multiphase
classe Pb_Multiphase Cette classe represente un probleme de thermohydraulique multiphase de type "3*N...
Definition Pb_Multiphase.h:46
Pb_Multiphase::nom_phase
const Nom & nom_phase(int i) const
Definition Pb_Multiphase.h:60
Pb_Multiphase::nb_phases
int nb_phases() const
Definition Pb_Multiphase.h:59
Probleme_base::has_champ
bool has_champ(const Motcle &nom, OBS_PTR(Champ_base) &ref_champ) const override
Definition Probleme_base.cpp:785
Process::exit
static void exit(int exit_code=-1)
Routine de sortie de TRUST dans une region Kokkos.
Definition Process.cpp:455
QDM_Multiphase
classe QDM_Multiphase Cette classe porte les termes de l'equation de la dynamique
Definition QDM_Multiphase.h:41
Sortie
Classe de base des flux de sortie.
Definition Sortie.h:52
TRUSTTab::dimension
_SIZE_ dimension(int d) const
Definition TRUSTTab.tpp:133
Flux_interfacial_base::input_t
Definition Flux_interfacial_base.h:48
Flux_interfacial_base::input_t::mu
const double * mu
Definition Flux_interfacial_base.h:56
Flux_interfacial_base::input_t::T
const double * T
Definition Flux_interfacial_base.h:51
Flux_interfacial_base::input_t::nv
const double * nv
Definition Flux_interfacial_base.h:54
Flux_interfacial_base::input_t::d_bulles
const double * d_bulles
Definition Flux_interfacial_base.h:64
Flux_interfacial_base::input_t::rho
const double * rho
Definition Flux_interfacial_base.h:57
Flux_interfacial_base::input_t::lambda
const double * lambda
Definition Flux_interfacial_base.h:55
Flux_interfacial_base::input_t::Cp
const double * Cp
Definition Flux_interfacial_base.h:58
Flux_interfacial_base::input_t::alpha
const double * alpha
Definition Flux_interfacial_base.h:50
Flux_interfacial_base::input_t::dP_Lvap
const double * dP_Lvap
Definition Flux_interfacial_base.h:60
Flux_interfacial_base::input_t::Lvap
const double * Lvap
Definition Flux_interfacial_base.h:59
Flux_interfacial_base::output_t
Definition Flux_interfacial_base.h:75
Flux_interfacial_base::output_t::hi
DoubleTab hi
Definition Flux_interfacial_base.h:76
Flux_interfacial_base::output_t::dT_hi
DoubleTab dT_hi
Definition Flux_interfacial_base.h:77
Flux_interfacial_base::output_t::da_hi
DoubleTab da_hi
Definition Flux_interfacial_base.h:78
Flux_interfacial_base::output_t::dp_hi
DoubleTab dp_hi
Definition Flux_interfacial_base.h:79