Coil

The node can be used to model coils, cables and other conductors subject to a lumped excitation, such as an externally applied current or voltage. The Coil feature transforms this lumped excitation into local quantities (electric field and electric current density), and computes lumped parameters of interest such as impedance, and inductance.

The feature supports two different :

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, which models a conductive body such as a wire, busbar, or other metallic conductor in which the current flows freely due to the material’s conductivity. This model can be used when the current flow has a well-defined beginning and end (for example, connections to an external source) or is closed in a loop.

	The Domain Selection has to be complete in the sense that selecting only part of a contiguous conductor will lead to unphysical results.

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, which models a bundle of tiny wires tightly wound together but separated by an electrical insulator. In this scenario, the current flows only in the direction of the wires and is negligible in other directions.

The feature is available both for domain and for boundary selections. In the latter case, it represents a flat coil or a conductor with a thickness negligible compared with the other dimensions. Different subnodes can be added to the node in different cases.

The global Harmonic Perturbation subnode is available from the context menu (right-click the parent node and select it from the menu) or from the toolbar, menu. The subnode can be used to apply a harmonic perturbation to the coil excitation.

In 2D and 2D axisymmetric components, the feature supports the functionality, that can be activated by selecting the corresponding check box.

	The Coil group option assumes that the selected domains represent cross sections of the same conductor going in and out of the modeling plane. These are expected to have the same areas. The same total current will be imposed in each domain, even if the domain areas are not equal but the computed concatenated flux, coil voltage and inductance will be incorrect. For cases with varying cross section areas, it is recommended to use separate coil features that are coupled using The Electrical Circuit Interface.

Refer to the Coil Features section in the modeling guide for more information about this node.

	In 2D and 2D axisymmetric components, the wires are assumed to be in the out-of-plane direction.

	See Coil Features in this guide to learn more about using this feature.

The setting decides how materials behave and how material properties are interpreted when the mesh is deformed. Select for materials whose properties change as functions of material strain, material orientation and other variables evaluated in a material reference configuration (material frame). Select for materials whose properties are defined only as functions of the current local state at each point in the spatial frame, and for which no unique material reference configuration can be defined. Select to pick up the corresponding setting from the domain material on each domain. Since features model conductors or bundles of wires, the correct choice is usually .

Enter a . This name is appended to the global variables (current, voltage) defined by this coil, and it can be used to identify the coil in a study step.

Select the for the coil. The choices correspond to rather different physical model, although the set up is similar. The model (the default) is appropriate for solid, massive current-carrying conductors. The model represent a bundle of tiny wires that are not geometrically resolved but taken into account in their average effect. The choice of affects the controls that are visible in the GUI and the available subnodes for the Coil feature.

This section is available when selecting as the in 3D components and is used to specify the coil geometry (the direction of the wires).

Select a — (the default), , , or . The different alternatives are described in the following sections. Also see Using Coils in 3D Models for more information.

When is selected as the , the coil behaves as if is , including the presence of the Geometry Analysis subnode.

In a coil, all the wires are parallel and straight lines. Use the Coil Geometry subnode to select an edge or a single group of connected edges that maps out the local coil direction. The direction of the wires and the coil length is taken to be the direction and the length of the edge(s), as marked by the red arrow. Avoid selecting multiple parallel edge groups as that will result in an incorrect coil length.

In a coil, the wires are wound in circles around the same axis. Use the Coil Geometry subnode to select a group of edges forming a circle or a part of a circle around the coil’s axis. From the selected edges, the coil axis is computed and the direction of the wires is taken to be the azimuthal direction around the axis, as marked by the red arrows. The coil length used is computed as the coil volume divided by the coil cross sectional area, unless the box is checked. When the robust method is used, the coil length is simply the length of the selected edges.

This option is available at the domain level only. In a coil, the current flow is computed automatically in a study step. Use the Geometry Analysis subnode to set up the problem.

	Automatic Coil Geometry Analysis

For manually specify the direction of the wires as a vector field and the length of the coil. Use the User Defined Coil Geometry subnode to specify the coil geometry.

The check box is only available for 2D and 2D axisymmetric components. Select this check box to enable the mode for this feature. With this settings, the domains or domain groups in this feature’s selection are considered series-connected. Selecting this check box activates the Domain Group subnode. See Coil Groups for more information.

Select a — (the default), , , , or (2D and 2D axisymmetric components only).

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forces a total current flowing in the coil wire. Enter a Icoil (SI unit: A). The default is 1 A. See the box below for study limitations on this setting.

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(only available for 2D and 2D axisymmetric components) forces the coil input power (cycle-average in frequency studies) to the specified value. Choosing this option makes the problem nonlinear. For enter a Pcoil (SI unit: W). The default value is 1 W.

This section is available only when is selected as the . In this case, the coil represents a solid, massive conductor and the conductivity of the material is required to compute the current density flowing in it.

This section is identical to the one in the Ampère’s Law node.

This section is available only when is the selected as the . In this case, the coil represents a bundle of tiny wires separated by an insulator. Additional settings can be specified.

Enter the N. The default is 10. This is the number of tiny wires constituting the coil. The coil resistance is affected by this number and so is the current density in the coil as it together with the setting defines the number of Ampère-turns in the coil.

Enter a σcoil (SI unit: S/m). The default value is approximately the conductivity for copper, 6·107 S/m. This parameter represents the conductivity of the metal wires forming the coil. This is not the bulk conductivity of the material, which is instead set to zero according to the lumped model of a bundle of wires.

Enter the cross-section area of the individual wire in the bundle. It is used, for example, to compute the lumped resistance of the coil. The area can be specified in different ways, according to the option selected in the list — (the default), , , or .

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For , enter the AWG size. Sizes between 0000 and 40 are available. Sizes such as 0000 can be also written as 4/0. The default size is 0.

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For , enter the diameter of the individual wire dcoil (SI unit: m). The cross-section area of the round wire will be computed from it. The default value of dcoil is 1 mm.

At the domain level, the Coil node replaces the Ampère’s Law node in the definition of the material model for the domain. The window for the domain node contains the sections and , identical to the ones in the Ampère’s Law node.

When is selected as the , the material properties to be specified are the ones of the material constituting the domain. when is selected, specify the homogenized material properties of the domain, that is, the homogenized properties of the conducting wires and the surrounding insulator.

To display this section, click the button (

) and select in the dialog box. This section is available only in 3D components when using as the and it contains advanced settings relative to the accuracy and stabilization of the solution.

The check box enables a current filtering functionality that improves the accuracy of the computed electric field and the induced coil voltage, at the cost of a slightly increased number of degrees of freedom. This functionality is only applicable for time dependent and frequency domain studies, and is active by default.

For the purpose of stabilizing the solution, the coil feature can apply a small electric conductivity to the coil domain. Use the combo box to specify the value of the conductivity. Choose (the default) to use a conductivity automatically computed by the coil. In frequency domain studies, the conductivity is chosen so that the skin depth in the coil is much larger than the coil length (see the sections Coil Geometry and User Defined Coil Geometry below). It is deduced from the formula

by setting the coil length, equal to the skin depth δ. In other study types the conductivity is set to 0.6 S/m.

If is chosen, no conductivity is used in the coil domain. Choose to specify the σΩ (SI unit: S/m). The default value is 1 S/m. The purpose of this electrical conductivity is only to stabilize the solution. According to the Homogenized multi-turn model, the domain should not be conductive and all the currents should flow in the direction of the wires only.