Nonlinear finite element analyses confront users with many choices. An understanding of the fundamental concepts of
nonlinear finite element analysis is necessary if you do not want to use the finite element program as a black box.
The purpose of this manual is to describe the numerical methods included in Radioss.
Kinematic constraints are boundary conditions that are placed on nodal velocities. They are mutually exclusive for each degree
of freedom (DOF), and there can only be one constraint per DOF.
The stability of solution concerns the evolution of a process subjected to small perturbations. A process is considered
to be stable if small perturbations of initial data result in small changes in the solution. The theory of stability
can be applied to a variety of computational problems.
A large variety of materials is used in the structural components and must be modeled in stress analysis problems.
For any kind of these materials a range of constitutive laws is available to describe by a mathematical approach the
behavior of the material.
This material law can be used to model low density closed cell polyurethane foams, impactors, impact limiters. It can
only be used with solid elements.
Explicit scheme is generally used for time integration in Radioss, in which velocities and displacements are obtained by direct integration of nodal accelerations.
The performance criterion in the computation was always an essential point in the architectural conception of Radioss. At first, the program has been largely optimized for the vectored super-calculators like CRAY. Then, a first parallel
version SMP made possible the exploration of shared memory on processors.
A large variety of materials is used in the structural components and must be modeled in stress analysis problems.
For any kind of these materials a range of constitutive laws is available to describe by a mathematical approach the
behavior of the material.
This law valid for solid elements can be used for viscoelastic materials like polymers,
elastomers, glass and fluids.
Elastic bulk behavior is assumed. Air pressure may be taken into account for closed cell
foams: (1)
with: (2)
and: (3)
Where,
Volumetric strain
Porosity
Initial air pressure
Initial volumetric strain
Bulk modulus
For deviatoric behavior, the generalized Maxwell model is used. The shear relaxation moduli
in Viscous Materials, 式 19 is then defined
as:(4)
(5)
Where,
Short time shear modulus
Long time shear modulus
Decay constant, defined as the inverse of relaxation time :(6)
; with
The coefficients , and are defined for the generalized Maxwell model, as shown in
図 1.
From 式 4, the value of governs the transition from the initial modulus to the final modulus . For =0, you obtain and when , then . For a linear response, put .