Home  CFD-ACE+ User Tips Spatial Differencing Schemes for Flow
|
|
Spatial Differencing Schemes for Flow |
|
Spatial differencing schemes control the spatial accuracy of the simulation. Several spatial differencing schemes are available in CFD-ACE+ to estimate the convective term in the transport
equations. The Spatial tab under SC (Solver Control) allows the user to select a spatial differencing scheme as shown in Figure 1.
Figure 1. Spatial differencing options in the Solver Control → Spatial tab.
The default scheme is the first-order Upwind Differencing scheme. If higher-order schemes are selected, you can also enter a blending factor to blend the higher-order scheme with the Upwind Differencing scheme for added stability.
Given below is list of spatial differencing schemes available for flow:
-
Upwind (1st Order)
-
Central (2nd Order)
-
2nd Order Upwind or 2nd Order (2nd Order)
-
2nd Order Limiter (2nd Order)
-
Van-Leer or 3rd Order (3rd Order) [only available for structured meshes]
-
Smart Scheme [only available for structured meshes]
Tips for selecting spatial differencing scheme for
flow:
-
For steady state problems:
-
Use second order scheme for higher accuracy.
-
If you encounter stability problem with second
order, but want a more accurate solution than
first order, use second order scheme with
non-zero blending factor, for instance 0.5, or
you can try using smart scheme where the
blending factor is not fixed but dynamically
determined according to local flow conditions.
-
Be careful when doing steady state runs on
oscillatory flows such as vortex shedding
behind an automobile. Convergence with second
order will probably be bad, but first order,
despite giving a better convergence, is less
accurate compared to taking the mean of a
partially non-converged second order.
-
A better way for oscillatory flows is transient
mode, which is necessary if one is to obtain
the Strouhal number of the oscillation. But for
a quick averaged solution in steady state mode,
you can smooth out the oscillations by
coarsening the grid in the wake region, this
way second order can give much better
convergence and may still be more accurate to
first order with finer grid in the wake region.
-
Use second order scheme (central or 2nd order
upwind) for simulations having rotating body or
rotating boundary for steady state and transient
problems.
-
For time-accurate problems like LES, DES, use
central scheme or second order upwind.
-
For shock capturing problems, use third order
scheme (van-Leer).
If you have any questions about this tip or would
like us to discuss some other topic in the future,
please let us know.
Regards,
Kartik Shah
ESI CFD Support Team
|
|
Using Cyclic Boundaries in CFD-ACE+ There are many applications that involve rotating
mechanical components that result in rotational or circumferential
symmetric flows. One can model an entire 3D rotating system, but
the computational resources to do so can be quite large.
Online User Subroutine Compilation An online version of the CFD-ACE+ user subroutine compiler is available now from the ESI-CFD customer support website! This new capability provides you with online access to the appropriate FORTRAN compiler to be used for CFD-ACE+ user subroutines.
CFD-ACE-GUI V2007 Residual Plotter
For those of you who already use CFD-ACE-GUI V2007,
you probably noticed numerous enhancements made to
the Residual / Monitor point plotter
Setting Summary Output Frequency Independently of the DTF File Save Frequency
Did you know you can output summaries, such as mass flow summary, force summary etc. at your desired time interval independently of the DTF file save frequency? This option not only saves time but also memory and disk space. Using a “Special DTF Update” command, you can activate the summary output frequency at your choice of iteration interval (for steady state cases) or time steps (for transient cases).
|
|