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189 lines
7.6 KiB
TeX
189 lines
7.6 KiB
TeX
\chapter[Models]{Physical and numerical models}
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\section{Physical and mathematical description}
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Characteristic of compositional multiphase models is that the phases
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are not only matter of a single chemical substance. Instead, their
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composition in general includes several species, and for the mass transfer,
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the component behavior is quite different from the phase behavior. In the following, we
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give some basic definitions and assumptions that are required for the
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formulation of the model concept below. As an example, we take a
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three-phase three-component system water-NAPL-gas
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\cite{A3:class:2002a}. The modification for other multicomponent
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systems is straightforward and can be found, e.\ g., in
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\cite{A3:bielinski:2006,A3:acosta:2006}.
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\subsection{Basic Definitions and Assumptions for the Compositional
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Model Concept}
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\textbf{Components:}
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The term {\it component} stands for constituents of the phases which
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can be associated with a unique chemical species, or, more generally, with
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a group of species exploiting similar physical behavior. In this work, we
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assume a water-gas-NAPL system composed of the phases water (subscript
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$\text{w}$), gas ($\text{g}$), and NAPL ($\text{n}$). These phases are
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composed of the components water (superscript $\text{w}$), air
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($\text{a}$), and the organic contaminant ($\text{c}$) (see Fig.\
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\ref{A3:fig:mundwtrans}).
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%
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\begin{figure}[hbt]
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\centering
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\includegraphics[width=0.7\linewidth]{EPS/masstransfer}
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\caption{Mass and energy transfer between the phases}
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\label{A3:fig:mundwtrans}
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\end{figure}
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\textbf{Equilibrium:}
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For the nonisothermal multiphase processes in porous media under
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consideration, we state that the assumption of local thermal
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equilibrium is valid since flow velocities are small. We neglect
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chemical reactions and biological decomposition and assume chemical
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equilibrium. Mechanical equilibrium is not valid in a porous medium,
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since discontinuities in pressure can occur across a fluid-fluid
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interface due to capillary effects.
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\textbf{Notation:} The index $\alpha \in \{\text{w}, \text{n}, \text{g}\}$ refers
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to the phase, while the index $\kappa \in \{\text{w}, \text{a}, \text{c}\}$ refers
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to the component. \\
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\begin{tabular}{llll}
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$p_\alpha$ & phase pressure & $\phi$ & porosity \\
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$T$ & temperature & $K$ & absolute permeability tensor \\
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$S_\alpha$ & phase saturation & $\tau$ & tortuosity \\
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$x_\alpha^\kappa$ & mole fraction of component $\kappa$ in phase $\alpha$ & $\boldsymbol{g}$ & gravitational acceleration \\
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$X_\alpha^\kappa$ & mass fraction of component $\kappa$ in phase $\alpha$ & $q^\kappa_\alpha$ & volume source term of $\kappa$ in $\alpha$ \\
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$\varrho_{\text{mol},\alpha}$ & molar density of phase $\alpha$ & $u_\alpha$ & specific internal energy \\
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$\varrho_{\alpha}$ & mass density of phase $\alpha$ & $h_\alpha$ & specific enthalpy \\
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$k_{\text{r}\alpha}$ & relative permeability & $c_\text{s}$ & specific heat enthalpy \\
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$\mu_\alpha$ & phase viscosity & $\lambda_\text{pm}$ & heat conductivity \\
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$D_\alpha^\kappa$ & diffusivity of component $\kappa$ in phase $\alpha$ & $q^h$ & heat source term \\
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$v_\alpha$ & Darcy velocity & $v_{a,\alpha}$ & advective velocity
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\end{tabular}
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\subsection{Balance Equations}
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For the balance equations for multicomponent systems, it is in many
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cases convenient to use a molar formulation of the continuity
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equation. Considering the mass conservation for each component allows
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us to drop source/sink terms for describing the mass transfer between
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phases. Then, the
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molar mass balance can be written as:
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%
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\begin{eqnarray}
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\label{A3:eqmass1}
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&& \phi \frac{\partial (\sum_\alpha \varrho_{\text{mol}, \alpha}
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x_\alpha^\kappa S_\alpha )}{\partial t} \nonumber
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- \sum\limits_\alpha \Div \left( \frac{k_{\text{r}
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\alpha}}{\mu_\alpha} \varrho_{\text{mol}, \alpha}
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x_\alpha^\kappa K (\grad p_\alpha -
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\varrho_{\alpha} \boldsymbol{g}) \right) \nonumber \\
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%
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\nonumber \\
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%
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&& - \sum\limits_\alpha \Div \left( \tau \phi S_\alpha D_\alpha^\kappa \varrho_{\text{mol},
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\alpha} \grad x_\alpha^\kappa \right) \nonumber
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- q^\kappa = 0, \qquad \kappa \in \{\text{w,a,c}\}.
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\end{eqnarray}
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The component mass balance can also be written in terms of mass fractions
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by replacing molar densities by mass densities and mole by mass fractions.
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To obtain a single conserved quantity in the temporal derivative, the total
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concentration, representing the mass of one component per unit volume, is defined as
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\begin{displaymath}
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C^\kappa = \sum_\alpha \phi S_\alpha \varrho_{\text{mass},\alpha} X_\alpha^\kappa \; .
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\end{displaymath}
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Using this definition, the component mass balance is written as:
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\begin{eqnarray}
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\label{A3:eqmass2}
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&& \frac{\partial C^\kappa}{\partial t} =
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\sum\limits_\alpha \Div \left( \frac{k_{\text{r}
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\alpha}}{\mu_\alpha} \varrho_{\text{mass}, \alpha}
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X_\alpha^\kappa K (\grad p_\alpha +
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\varrho_{\text{mass}, \alpha} \boldsymbol{g}) \right) \nonumber \\
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%
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\nonumber \\
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%
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&& + \sum\limits_\alpha \Div \left( \tau \phi S_\alpha D_\alpha^\kappa \varrho_{\text{mass},
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\alpha} \grad X_\alpha^\kappa \right) \nonumber
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+ q^\kappa = 0, \qquad \kappa \in \{\text{w,a,c}\}.
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\end{eqnarray}
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In the case of non-isothermal systems, we further have to balance the
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thermal energy. We assume fully reversible processes, such that entropy
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is not needed as a model parameter. Furthermore, we neglect
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dissipative effects and the heat transport due to molecular
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diffusion. The heat balance can then be
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formulated as:
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%
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\begin{eqnarray}
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\label{A3:eqenergmak1}
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&& \phi \frac{\partial \left( \sum_\alpha \varrho_{\alpha}
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u_\alpha S_\alpha \right)}{\partial t} + \left( 1 -
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\phi \right) \frac{\partial \varrho_{\text{s}} c_{\text{s}}
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T}{\partial t} \nonumber
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- \Div \left( \lambda_{\text{pm}} \grad T \right)
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\nonumber \\
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%
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\nonumber \\
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%
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&& - \sum\limits_\alpha \Div \left( \frac{k_{\text{r}
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\alpha}}{\mu_\alpha} \varrho_{\alpha} h_\alpha
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K \left( \grad p_\alpha - \varrho_{\alpha}
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\boldsymbol{g} \right) \right) \nonumber
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- q^h \; = \; 0.
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\end{eqnarray}
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In order to close the system, supplementary constraints for capillary pressure, saturations and mole
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fractions are needed, \cite{A3:helmig:1997}.
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According to the Gibbsian phase rule, the number of degrees of freedom
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in a non-isothermal compositional multiphase system is equal to the
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number of components plus one. This means we need as many independent
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unknowns in the system description. The
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available primary variables are, e.\ g., saturations, mole/mass
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fractions, temperature, pressures, etc.
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\section{Available models}
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The following description of the available models is automatically extracted
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from the Doxygen documentation. \textbf{TODO}: Unify notation.
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\subsection{Fully coupled models}
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\subsubsection{The single-phase model: OnePBoxModel}
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\input{ModelDescriptions/1pboxmodel}
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\subsubsection{The single-phase, two-component model: OnePTwoCBoxModel}
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\input{ModelDescriptions/1p2cboxmodel}
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\subsubsection{The two-phase model using Richards' assumption: RichardsBoxModel}
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\input{ModelDescriptions/richardsboxmodel}
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\subsubsection{The two-phase model: TwoPBoxModel}
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\input{ModelDescriptions/2pboxmodel}
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\subsubsection{The non-isothermal two-phase model: TwoPNIBoxModel}
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\input{ModelDescriptions/2pniboxmodel}
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\subsubsection{The two-phase, two-component model: TwoPTwoCBoxModel}
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\input{ModelDescriptions/2p2cboxmodel}
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\subsubsection{The non-isothermal two-phase, two-component model: TwoPTwoCNIBoxModel}
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\input{ModelDescriptions/2p2cniboxmodel}
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\subsection{Decoupled models}
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\subsubsection{FractionalFlow Model}
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\input{ModelDescriptions/2pdecoupledmodel}
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\input{models_decoupled2p2c}
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%%% Local Variables:
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%%% mode: latex
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%%% TeX-master: "dumux-handbook"
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%%% End:
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