Calculation on non-orthogonal curvelinear structured grids, finite-volume method
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Using the finite volume method the trnsformed equations can be integrated as follows: | Using the finite volume method the trnsformed equations can be integrated as follows: | ||
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+ | <table width="70%"><tr><td> | ||
+ | :<math> | ||
+ | \left[ \left( \rho U \Delta \eta \right) \right]^{e}_{w} + \left[ \left( \rho V \Delta \xi \right) \right]^{n}_{s} = \left[ \frac{\Gamma \Delta \eta}{J} \left( \alpha \frac{\partial \phi}{\partial \xi} - \beta \frac{\partial \phi}{ \partial \eta} \right) \right]^{e}_{w} + \left[ \frac{\Gamma \Delta \xi}{J} \left( \gamma \frac{\partial \phi}{\partial \eta } - \beta \frac{\partial \phi}{\partial \xi} \right) \right]^{n}_{s} + \left( J \Delta \xi \Delta \eta \right) \overline{S}^{\phi}_{P} | ||
+ | </math> | ||
+ | </td><td width="5%">(8)</td></tr></table> |
Revision as of 10:11, 18 August 2010
2D case
For calculations in complex geometries boundary-fitted non-orthogonal curvlinear grids is usually used.
General transport equation is transformed from the physical domain into the computational domain as the following equation
| (2) |
where
| (3) |
| (4) |
| (5) |
| (6) |
| (7) |
| (8) |
Using the finite volume method the trnsformed equations can be integrated as follows:
| (8) |