Electromagnetic loads

As outlined in About Prescribed Conditions, electromagnetic loads can be applied in Piezoelectric analysis, Coupled thermal-electrical analysis, Fully coupled thermal-electrical-structural analysis, Eddy current analysis, and Magnetostatic analysis.

The types of electromagnetic loads available depend on the analysis being performed, as described in the sections below. See About loads for general information that applies to all types of loading.

The following topics are discussed:

Related Topics
About Prescribed Conditions
About loads
In Other Guides
*CECHARGE
*CECURRENT
*DECHARGE
*DECURRENT
*DSECHARGE
*DSECURRENT
Defining a concentrated current
Defining a surface current
Defining a body current
Defining a surface current density
Defining a body current density
Defining a concentrated charge
Defining a surface charge
Defining a body charge

ProductsAbaqus/StandardAbaqus/CAE

Defining time-dependent electromagnetic loads

The prescribed magnitude of a concentrated or a distributed electromagnetic load can vary with time during a step according to an amplitude definition, as described in About Prescribed Conditions. If different variations are needed for different loads, each load can refer to its own amplitude definition.

In a time-harmonic eddy current analysis all loads are assumed to be time-harmonic.

Modifying electromagnetic loads

Concentrated or distributed electromagnetic loads can be added, modified, or removed as described in About loads.

Prescribing electromagnetic loads for piezoelectric analyses

In a piezoelectric analysis a concentrated electric charge can be prescribed at nodes, a distributed electric surface charge can be defined on element faces and surfaces, and a distributed electric body charge can be defined on elements.

Specifying concentrated electric charge

To specify a concentrated electric charge, specify the node or node set and the magnitude of the charge.

Input File Usage

CECHARGE
node number or node set name, , charge magnitude

Abaqus/CAE Usage

Load module: Create Load: choose Electrical/Magnetic for the Category and Concentrated charge for the Types for Selected Step; Magnitude: charge magnitude

Specifying element-based distributed electric charge

You can specify a distributed surface charge (on element faces) or a distributed body charge (charge per unit volume). For an element-based surface charge you must identify the face of the element upon which the charge is prescribed in the charge label. The distributed charge types available depend on the element type. About the element library lists the distributed charges that are available for particular elements.

Input File Usage

DECHARGE
element number or element set name, charge label, charge magnitude

where charge label is ESn or EBF

Abaqus/CAE Usage

Use the following input to define a distributed surface charge on element faces:

Load module: Create Load: choose Electrical/Magnetic for the Category and Surface charge for the Types for Selected Step; Distribution: select an analytical field, Magnitude: charge magnitude

Use the following input to define a body charge:

Load module: Create Load: choose Electrical/Magnetic for the Category and Body charge for the Types for Selected Step

Specifying surface-based distributed electric charge

When you specify a distributed electric charge on a surface, the element-based surface (see Element-based surface definition) contains the element and face information. You must specify the surface name, the electric charge label, and the electric charge magnitude.

Input File Usage

DSECHARGE
surface name, ES, charge magnitude

Abaqus/CAE Usage

Load module: Create Load: choose Electrical/Magnetic for the Category and Surface charge for the Types for Selected Step; Distribution: Uniform, Magnitude: charge magnitude

Specifying electric charge in direct-solution steady-state dynamics analysis

In the direct-solution steady-state dynamics procedure, electric charges are given in terms of their real and imaginary components.

Input File Usage

Use the following options to define electric charges in direct-integration steady-state dynamics analysis:

CECHARGE, REAL or IMAGINARY (real or imaginary component)
DECHARGE, REAL or IMAGINARY
DSECHARGE, REAL or IMAGINARY

Abaqus/CAE Usage

Load module: Create Load: choose Electrical/Magnetic for the Category and Concentrated charge, Surface charge, or Body charge for the Types for Selected Step; Magnitude: real component + imaginary component

Loading in mode-based and subspace-based procedures

Electrical charge loads should be used only in conjunction with residual modes in the eigenvalue extraction step, due to the “massless” mode effect. Since the electrical potential degrees of freedom do not have any associated mass, these degrees of freedom are essentially eliminated (similar to Guyan reduction or mass condensation) during the eigenvalue extraction. The residual modes represent the static response corresponding to the electrical charge loads, which will adequately represent the potential degree of freedom in the eigenspace.

Prescribing electromagnetic loads for coupled thermal-electrical and fully coupled thermal-electrical-structural analyses

In a coupled thermal-electrical analysis and fully coupled thermal-electrical-structural analysis a concentrated current can be prescribed at nodes, distributed current densities can be defined on element faces and surfaces, and distributed body currents can be defined on elements.

Specifying concentrated current density

To define concentrated currents, specify the node or node set and the magnitude of the current.

Input File Usage

CECURRENT
node number or node set name, , current magnitude

Abaqus/CAE Usage

Load module: Create Load: choose Electrical/Magnetic for the Category and Concentrated current for the Types for Selected Step; Magnitude: current magnitude

Specifying element-based distributed current density

You can specify distributed surface current densities (on element faces) or distributed body current densities (current per unit volume). For element-based surface current densities you must identify the face of the element upon which the current is prescribed in the current label. The distributed current types available depend on the element type. About the element library lists the distributed current densities that are available for particular elements.

Input File Usage

DECURRENT
element number or element set name, current density label, current density magnitude

where current density label is CSn, CS1, CS2, or CBF

Abaqus/CAE Usage

Use the following input to define a distributed surface current density on element faces:

Load module: Create Load: choose Electrical/Magnetic for the Category and Surface current for the Types for Selected Step; Distribution: select an analytical field, Magnitude: current density magnitude

Use the following input to define a body current density:

Load module: Create Load: choose Electrical/Magnetic for the Category and Body current for the Types for Selected Step

Specifying surface-based distributed current densities

When you specify distributed current densities on a surface, the element-based surface (see Element-based surface definition) contains the element and face information. You must specify the surface name, the current density label, and the current density magnitude.

Input File Usage

DSECURRENT
surface name, CS, current density magnitude

Abaqus/CAE Usage

Load module: Create Load: choose Electrical/Magnetic for the Category and Surface current for the Types for Selected Step: Distribution: Uniform, Magnitude: current density magnitude

Prescribing electromagnetic loads for eddy current and/or magnetostatic analyses

In an eddy current analysis a distributed surface current density vector can be defined on surfaces and a distributed volume current density vector can be defined on elements.

Specifying element-based distributed current density vectors

When you define a distributed volume current density vector, you must specify the element or element set, the current density vector label, the magnitude of the current density vector, the vector components of the current density, and an optional orientation name that defines the local coordinate system in which the vector components are specified. By default, the vector components of the current density are defined with respect to the global directions.

The specified current density vector direction components are normalized by Abaqus and, thus, do not contribute to the magnitude of the load.

Input File Usage

DECURRENT
element number or element set name, CJ, current density vector magnitude, current density vector direction components, orientation name

Abaqus/CAE Usage

Load module: Create Load: choose Electrical/Magnetic for the Category and Body current density for the Types for Selected Step; Distribution: Uniform

Specifying surface-based distributed current density vectors

When you specify distributed current density vectors on a surface, the element-based surface (see Element-based surface definition) contains the element and face information. You must specify the surface name, the current density vector label, and the magnitude of the current density vector, the vector components of the current density, and an optional orientation name that defines the local coordinate system in which the surface current density is specified. By default, the vector components of the current density are defined with respect to the global directions.

The specified current density vector direction components are normalized by Abaqus and, thus, do not contribute to the magnitude of the load.

Input File Usage

DSECURRENT
surface name, CK, current density vector magnitude, current density vector direction components, orientation name

Abaqus/CAE Usage

Load module: Create Load: choose Electrical/Magnetic for the Category and Surface current density for the Types for Selected Step; Distribution: Uniform

Defining nonuniform current density vectors in a user subroutine

Nonuniform volume current density vectors can be defined with user subroutine UDECURRENT, and nonuniform surface current density vectors can be defined with user subroutine UDSECURRENT. If the magnitude and direction components are given, the values are passed into the user subroutine.

Input File Usage

Use the following option to define nonuniform element-based current density vectors:

DECURRENT
element number or element set name, CJNU, current density vector magnitude, current density vector direction components, orientation name

Use the following option to define nonuniform surface-based current density vectors:

DSECURRENT
surface name, CKNU, current density vector magnitude, current density vector direction components, orientation name

Abaqus/CAE Usage

Use the following option to define nonuniform volume current density:

Load module: Create Load: choose Electrical/Magnetic for the Category and Body current density for the Types for Selected Step; Distribution: User-defined

Use the following option to define nonuniform surface current density:

Load module: Create Load: choose Electrical/Magnetic for the Category and Surface current density for the Types for Selected Step; Distribution: User-defined

Specifying real and imaginary components of current density vectors in a time-harmonic eddy current analysis

In a time-harmonic eddy current analysis, current density vectors are given in terms of their real (in-phase) and imaginary (out-of-phase) components.

Input File Usage

Use the following options to define current density vectors:

DECURRENT, REAL or IMAGINARY
DSECURRENT, REAL or IMAGINARY

Abaqus/CAE Usage

Load module: Create Load: choose Electrical/Magnetic for the Category and Body current density or Surface current density for the Types for Selected Step; real components + imaginary components