Advection Schemes

ADV 1

(Monotone streamline upwind)

This is the default scheme for nearly all analyses (except rotating regions). It is the “work horse,” and is recommended as a starting point for most analysis types.

• Numerically stable
• Recommended for meshes aligned with flow direction
• Numerically diffusive for meshes not aligned with flow
• Works well for geometries with numerous internal obstructions
• Works well for extruded meshes

ADV 2

(Petrov-Galerkin)

• Moderate numerical stability (less than ADV 1)
• Less numerical diffusion for random meshes. Models with random meshes have large domains, and often feature unrestricted external flow. Examples include:
  • AEC and Displacement Ventilation
  • Large External Flow Domains
  • Data Centers
• Recommended for pressure driven flows
• Recommended for compressible flows
• Default for scalar and energy transport equations
• Default for rotating region analyses

ADV 3

(Flux based scheme)

• Numerically unstable for most flows
• Can only be used for INCOMPRESSIBLE flows
• Cannot be used for moving solids analyses
• Specially tuned for drag or external flow problems
• Mesh Enhancement must be invoked.

ADV 4

(Min-Mod scheme--Petrov-Galerkin variant)

• Moderate numerical stability (less than ADV 1)
• Specially tuned for flows in long narrow ducts

ADV 5

(Modified Petrov-Galerkin)

ADV 5 is a more stable variation of ADV 2, the Petrov-Galerkin advection scheme. It is suitable for all application types recommended with ADV 2, but typically produces more globally conservative results. ADV 5 has demonstrated improvements over ADV 2 in the following areas:

• Accuracy of recirculating and secondary flows
• Pressure drop prediction
• Natural convection stability
• Compressible flow accuracy and stability
• Rotating (turbomachinery) and Motion accuracy and stability
• Energy balance stability