Electromagnetic Analysis Procedures

The following electrostatic analysis procedure is available in Abaqus/Standard:

Piezoelectric analysis

In a piezoelectric material an electric potential gradient causes straining, while stress causes an electric potential in the material (Piezoelectric Analysis). This coupling is provided by defining the piezoelectric and dielectric coefficients of a material and can be used in natural frequency extraction, transient dynamic analysis, both linear and nonlinear static stress analysis, and steady-state dynamic analysis procedures. In all procedures, including nonlinear statics and dynamics, the piezoelectric behavior is always assumed to be linear.

The following electrical conduction analyses procedures are available in Abaqus/Standard:

Coupled thermal-electrical analysis

The electric potential and temperature fields can be solved simultaneously by performing a coupled thermal-electrical analysis (Coupled Thermal-Electrical Analysis). In these problems the energy dissipated by an electrical current flowing through a conductor is converted into thermal energy, and the electrical conductivity can, in turn, be temperature dependent. Thermal loads can be applied, but deformation of the structure is not considered. Coupled thermal-electrical problems can be linear or nonlinear.

Fully coupled thermal-electrical-structural analysis

A coupled thermal-electrical-structural analysis is used to solve simultaneously for the stress/displacement, the electric potential, and the temperature fields. A coupled analysis is used when the thermal, electrical, and mechanical solutions affect each other strongly. An example of such a process is resistance spot welding, where two or more metal parts are joined by fusion at discrete points at the material interface. The fusion is caused by heat generated due to the current flow at the contact points, which depends on the pressure applied at these points.

These problems can be transient or steady state and linear or nonlinear. Cavity radiation effects cannot be included in a fully coupled thermal-electrical-structural analysis. See Fully Coupled Thermal-Electrical-Structural Analysis for more details.

The following magnetostatic analysis procedure is available in Abaqus/Standard:

Magnetostatic analysis

A magnetostatic analysis is used to solve for the magnetic vector potential, from which the magnetic field is computed in the entire domain. For example, the magnetic field due to the flow of direct current can be modeled. The procedure supports linear as well as nonlinear magnetic material properties. See Magnetostatic Analysis for more details.

Electromagnetic analyses are used to solve for the magnetic vector potential, from which both electric and magnetic fields are computed in the entire domain. The following electromagnetic analysis procedures are available in Abaqus/Standard:

Time-harmonic eddy current analysis

This procedure assumes time-harmonic excitation and response. It supports linear electrical conductivity and linear magnetic material behavior. For example, eddy currents induced in a workpiece that is in the vicinity of a source of excitation (such as a coil carrying alternating current) can be modeled. See Time-Harmonic Analysis for more details.

Transient eddy current analysis

This procedure assumes general time variation of the excitation and response. It supports linear electrical conductivity and both linear and nonlinear magnetic material behavior. For example, eddy currents induced in a workpiece that is in the vicinity of a source of excitation (such as a coil carrying time-varying current) can be modeled. See Transient Analysis for more details.