Implicit Features and Compatibility
Not all explicit features are available for implicit analyses; actual available features are presented in this section.
Element Formulations
In Radioss implicit, the element formulations are used in two main computations.
- Stiffness Matrix which will determine the displacements:
Available element formulations for this computation are given in the table below. If any other element formulation is used, it will switch to a generic element type (marked with an asterisk [*] ) in the table below.
- Strains, Stress and Internal Nodal Forces:
Implicit and explicit analyses share the same coding and all formulations are available for this computation.
Shell 4n | Shell 3n | Solid 8n | Solid 4n, 10n | Solid 20n | Beam | Thick-shell 8n, 6n | Spring Types (4, 8, 12, 13 and 32) | Truss |
---|---|---|---|---|---|---|---|---|
QEPH*, QBAT | TC0* (Ish3n=1) | HA8* | standard | standard | standard | HSEPH,HA8* | standard | standard |
Isotropic Shell property TYPE1, Orthotropic Shell property (TYPE 9, 10, 11 and 17)
In general, there are no compatibility issues as far as element formulations are concerned (except some quadratic elements, like S16); and if necessary, any new available formulations can also be supported in implicit analysis. Ish3n =DKT_S3 is not available with implicit analysis.
Isotropic Solid property TYPE14 Orthotropic Solid property (TYPE 6)
However, the elements in the above table are strongly recommended, especially in a nonlinear analysis.
Material Compatibility
Radioss uses only the elastic part of material parameters to build the stiffness matrix (or Jacobian matrix for nonlinear analyses) for most of the material laws.
For the hyper-elastic type laws (42, 62, 69, and 82), special treatments have been done to avoid the divergence. The use of elastic matrix (called initial stress method) results out slow convergence (consisting tangent matrix development is ongoing); two Nonlinear Solution methods are recommended in this case: Modified Newton and Quasi-Newton (BFGS). For the viscous type laws used for quasi-static analysis, a long duration time is recommended for the simulation (as there is no physical sense for time in this case). In this way, there is no compatibility issue with any Radioss material, but converging issues might be experienced, especially for the high nonlinear materials.
Kinematic Conditions
Several kinematic conditions are supported.
- Boundary conditions /BCS
- Imposed displacement /IMPDISP (velocity /IMPVEL, and acceleration /IMPACC)
- Rigid bodies /RBODY
- Interface TYPE2 /INTER/TYPE2 (not available with rupture or penalty methods)
- Rigid walls /RWALL (not recommended due to performance reasons. Use contact interface, if possible.)
- Adaptive meshing link /ADMESH
- Interpolation constraint element /RBE3
- Rigid element /RBE2
Contact Interfaces
Only contact interface Types 5, 7, 10 and 11 are available and are supported in Radioss Implicit.
Contact interfaces are treated through a penalty method (with fictitious springs) and the contact stiffness will be stored in an independent stiffness matrix. Information regarding this second stiffness matrix can be printed out (if /IMPL/PRINT/NONLIN/n is defined) once contacts have been detected.
Loads
Concentrated load /CLOAD, pressure /PLOAD, and gravity load /GRAV are available. The loading definition is the same as in an explicit simulation.
Thermal Analysis
In Radioss not all thermal options are currently available for implicit analysis.
Implicit Analysis Types
- Model Check: with /IMPL/CHECK
- Static or Quasi-static linear
- Buckling mode analysis
- Static or Quasi-static nonlinear
- Dynamic nonlinear
- Modal analysis