Governing equations on differential form: Difference between revisions

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==== Conservation of Mass ====
==== Conservation of Mass ====


Apply Gauss's divergence theorem on the surface integral in Eqn. \ref{eq:governing:cont:int} gives
The continuity equation on integral form reads
 
{{NumEqn|<math>
\frac{d}{dt}\iiint_{\Omega} \rho dV+\iint_{\partial \Omega}\rho \mathbf{v}\cdot \mathbf{n} dS=0
</math>|nonumber=1}}
 
Apply Gauss's divergence theorem on the surface integral gives


{{NumEqn|<math>
{{NumEqn|<math>
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==== Conservation of Momentum ====
==== Conservation of Momentum ====
The momentum equation on integral form reads
{{NumEqn|<math>
\frac{d}{dt}\iiint_{\Omega} \rho \mathbf{v} dV+\iint_{\partial \Omega} \left[(\rho\mathbf{v}\cdot\mathbf{n})\mathbf{v}+p\mathbf{n}\right]dS=\iiint_{\Omega}\rho \mathbf{f}dV
</math>|nonumber=1}}


As for the continuity equation, the surface integral terms are rewritten as volume integrals using Gauss's divergence theorem.
As for the continuity equation, the surface integral terms are rewritten as volume integrals using Gauss's divergence theorem.
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==== Conservation of Energy ====
==== Conservation of Energy ====


Gauss's divergence theorem applied to the surface integral term in the energy equation (Eqn. \ref{eq:governing:energy:int}) gives
The energy equation on integral form reads
 
{{NumEqn|<math>
\frac{d}{dt}\iiint_{\Omega}\rho e_o dV+\iint_{\partial \Omega}\rho h_o(\mathbf{v}\cdot\mathbf{n})dS=</math><br><br><math>\iiint_{\Omega}\rho\mathbf{f}\cdot\mathbf{v}dV+\iiint_{\Omega} \dot{q}\rho dV
</math>|nonumber=1}}
 
Gauss's divergence theorem applied to the surface integral term in the energy equation gives


{{NumEqn|<math>
{{NumEqn|<math>
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{{NumEqn|<math>
{{NumEqn|<math>
\frac{D\rho}{Dt}+\rho(\nabla\cdot\mathbf{v})=0
\frac{D\rho}{Dt}+\rho(\nabla\cdot\mathbf{v})=0
</math>}}
</math>|label=eq-pde-noncons-cont}}


Eqn. \ref{eq:governing:cont:non} says that the mass of a fluid element with a fixed set of fluid particles is constant as the element moves in space.
{{EquationNote|label=eq-pde-noncons-cont|nopar=1}} says that the mass of a fluid element with a fixed set of fluid particles is constant as the element moves in space.


==== Conservation of Momentum ====
==== Conservation of Momentum ====
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