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, Etape 1 : Définition de tous les fluides circulant dans ce composant (l'air humide, l'ammoniac et l'eau)

, Etape 2 : Définition de toutes les variables impliquées

. Modelica, . Siunits, and . Power-q_flow, , vol.1

. Modelica, . Siunits, and . Massflowrate-m_flow_air, , vol.2

. Modelica, . Siunits, and . T_entree_air, , vol.3

. Modelica and . Siunits, Temperature T_sortie_air "variable, vol.4

, Real Hum_entree_air " variable, vol.5

, Real Hum_sortie_air " variable, vol.6

. Modelica, . Siunits, and . Massflowrate-masse_glace, , vol.7

. Modelica, . Siunits, and . M_flow_ammoniac, , vol.8

. Modelica, . Siunits, and . P_ammoniac, , vol.9

. Modelica, . Siunits, and . Specificenthalpy, , vol.10

. Modelica, . Siunits, and . Specificenthalpy, , vol.11

, Real x_sortie_ammoniac " variable, vol.12

. Ammoniacmedium, SaturationProperties satur_ammoniac

, Modelica.SIunits.SpecificEnthalpy h_l_ammoniac

, Modelica.SIunits.SpecificEnthalpy h_v_ammoniac

. Eaumedium,

. Modelica and . Siunits,

, Modelica.SIunits.SpecificEnthalpy Hfg_eau

, parameter Real P_atm =1e5 "pression atmospherique

, parameter Real Cp_air, 1004.

, parameter Real Cp_vapeur, 1900.

, Etape 3 : Définition de l'ensemble des paramètres binaires permettant le contrôle des équations : parameter Real eq1= 1, equation_cote_air

, parameter Real eq2= 0 "equation_cote_ammoniac

, parameter Real eq3= 0, equation_masse_glace

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