Single-phase, multi-component Darcy flow with mineralization. More...
A single-phase, multi-component model considering mineralization processes.
This model implements one-phase n-component flow of a compressible fluid composed of the n components \(\kappa \) in combination with mineral precipitation and dissolution of the solid phases. The standard multi-phase Darcy approach is used as the equation for the conservation of momentum. For details on Darcy's law see dumux/flux/darcyslaw.hh.
By inserting Darcy's law into the equations for the conservation of the components, one gets one transport equation for each component,
\[ \frac{\partial ( \phi \varrho_f X^\kappa )} {\partial t} - \nabla \cdot \left\{ \varrho_f X^\kappa \frac{k_{r}}{\mu} \mathbf{K} (\nabla p - \varrho_{f} \mathbf{g}) \right\} - \nabla \cdot \left\{{\bf D_{pm}^\kappa} \varrho_{f} \nabla X^\kappa \right\} - q_\kappa = 0 \qquad \kappa \in \{w, a,\cdots \}, \]
where:
The solid or mineral phases are assumed to consist of a single component. Their mass balance consists of only a storage and a source term,
\[ \frac{\partial ( \varrho_\lambda \phi_\lambda )} {\partial t} = q_\lambda, \]
where:
The primary variables are the pressure \(p\) and the mole fractions of the dissolved components \(x^k\). The primary variable of the solid phases is the volume fraction \(\phi_\lambda = \frac{V_\lambda}{V_{total}}\),
where:
The source an sink terms link the mass balances of the n-transported component to the solid phases. The porosity \(\phi\) is updated according to the reduction of the initial (or solid-phase-free porous medium) porosity \(\phi_0\) by the accumulated volume fractions of the solid phases, \( \phi = \phi_0 - \sum (\phi_\lambda),\)
where:
Files | |
file | porousmediumflow/1pncmin/model.hh |
A single-phase, multi-component model considering mineralization processes. | |