Block Format Keyword In this group, keywords are used to set default value, global parameter, analysis type, input/output print,
damping and ALE and CFD treatment for the whole model. For default value, it is still possible to overwrite in each
specific keywords.
Block Format Keyword In this group, keywords are used to combine material and property information (/PART), assemble model (/SUBSET) or define a separate model (//SUBMODEL).
Block Format Keyword Interfaces solve the contact and impact conditions between two parts of a model. Several interface types are available
in Radioss and use different contact treatments.
Block Format Keyword This law describes a solid material using the Tsai-Wu formulation that is usually used to model composites. This material
is assumed to be 3D orthotropic-elastic before the Tsai-Wu criterion is reached.
Block Format Keyword This law describes an orthotropic solid material using the Tsai-Wu formulation that is mainly designed to model uni-directional
composites. This material is assumed to be 3D orthotropic-elastic before the Tsai-Wu criterion is reached. The material
becomes nonlinear afterwards.
Block Format Keyword This law is used to model composite shell elements, similar to LAW25. The plastic behavior is based on the Tsai-Wu
criteria (/MAT/LAW25 (COMPSH) for Tsai-Wu description) and failure is based on the Chang-Chang failure criterion is used.
Block Format Keyword This law describes a hyperelastic anisotropic fabric material. It uses an anisotropic coordinate system with anisotropy
angle, following element deformation.
Block Format Keyword Radioss supports several different kinematic constraints, which are mainly used to impose acceleration, velocity, displacement
or temperature in structure or constraint the moving of structure. They are mutually exclusive for each degree-of-freedom
(DOF). Two kinematic conditions applied to the same node may be incompatible.
Block Format Keyword In Radioss the following load cases are available. Stress/strain as initial state could be considered by modeling, as well as
pressure, gravity, and thermal load.
Block Format Keyword Adaptive Meshing is used in metal forming to divide the element to better describe the geometry. /ADMESH/GLOBAL and /ADMESH/SET are not available for SPMD computation.
Optimization Keyword This manual contains the description of the keywords for the Radioss optimization. This manual is compatible with the version 2018 of Radioss.
These materials can be used to represent composite and fabric materials.
/MAT/LAW12 (3D_COMP) Block Format Keyword This law describes a solid material using the Tsai-Wu formulation that is usually used to model composites. This material is assumed to be 3D orthotropic-elastic before the Tsai-Wu criterion is reached.
/MAT/LAW14 (COMPSO) Block Format Keyword This law describes an orthotropic solid material using the Tsai-Wu formulation that is mainly designed to model uni-directional composites. This material is assumed to be 3D orthotropic-elastic before the Tsai-Wu criterion is reached. The material becomes nonlinear afterwards.
/MAT/LAW15 (CHANG) Block Format Keyword This law is used to model composite shell elements, similar to LAW25. The plastic behavior is based on the Tsai-Wu criteria (/MAT/LAW25 (COMPSH) for Tsai-Wu description) and failure is based on the Chang-Chang failure criterion is used.
/MAT/LAW19 (FABRI) Block Format Keyword This law defines an elastic orthotropic material and is available only for shell elements. It is used to model airbag fabrics.
/MAT/LAW25 (COMPSH)
Two variations of the same material law type 25 are implemented: Tsai-Wu formulation and CRASURV formulation.
/MAT/LAW58 (FABR_A) Block Format Keyword This law describes a hyperelastic anisotropic fabric material. It uses an anisotropic coordinate system with anisotropy angle, following element deformation.
/MAT/LAW114 (SPR_SEATBELT) Block Format Keyword This spring material is designed for 1D seatbelt elements.
/MAT/LAW119 (SH_SEATBELT) Block Format Keyword This orthotropic shell material is designed for 2D seatbelt element.