1. Reference problem#

1.1. Geometry#

Coordinates of the points (\(m\)):

1.2. Material properties#

We only give here the properties on which the solution depends, knowing that the command file contains other material data (elasticity modules, thermal conductivity…) which ultimately play no role in the solution of the problem being treated.

Liquid water	Density ( \({\mathit{kg.m}}^{\mathrm{-}3}\) ) Heat at constant pressure (\({\mathit{J.K}}^{\mathrm{-}1}\)) coefficient of thermal expansion of liquid (\({K}^{\mathrm{-}1}\))	103 4180 0.



Vapeur	Heat capacity ( \({\mathit{J.K}}^{\mathrm{-}1}\) ) Initial enthalpy (latent heat of vaporization) Molar mass (\({\mathit{kg.mol}}^{\mathrm{-}1}\))	1900 2.5E6. 0.018



Skeleton	Heat capacity at constant stress (\({\mathit{J.K}}^{\mathrm{-}1}\))	1050
Initial state	Porosity Temperature (\(K\)) Liquid Pressure (\(\mathit{Pa}\)) Vapor Pressure (\(\mathit{Pa}\)) Initial Liquid Saturation	0.3 300 1E5 3700 0.5


Constants	Ideal gas constant	8,315
Homogenized coefficients	Homogenized density ( \({\mathit{kg.m}}^{\mathrm{-}3}\) ) Sorption isotherm	2200 With

1.3. Boundary conditions and loads#

On all sides:

Heat flow \({q}_{\mathit{ext}}\mathrm{.}n\mathrm{=}{10}^{6}\)

Zero hydraulic flow