Coil Geometry
The Coil Geometry subnode of the Coil is available if the Conductor model of the parent feature is Homogenized multi-turn and the Coil type is Linear or Circular. This feature was previously called Reference Edge. This subnode is used to specify the direction of the tiny wires constituting the multi-turn coil.
In Linear coils, the wires are all parallel and straight lines. Select an edge or a group of co-linear edges. The direction of the wires and the coil length is taken to be the direction and the length of the edges. To avoid unphysical currents, a Linear coil should be terminated on external boundaries.
In Circular coils, the wires are wound in circles around the same axis. 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. The coil length used is computed as the coil volume divided by the coil cross-sectional area, unless the Use robust geometry analysis method box is checked. When the robust method is used, the coil length is simply the length of the selected edges.
Select the Use robust geometry analysis method check box to use an alternative algorithm for the computation of the coil axis and direction. This method works even in models without geometry (for example, with an imported mesh), but requires that the selected edges form a complete circle.
Coil Geometry
The direction of the coil is shown in the Graphics window with a red arrow. Select the Reverse direction check box to reverse the direction of the coil.
The length of the coil is computed from the length of the selected edges. To manually specify the length, select the Override length of the edges check box, and enter the Total length of the edges Ledges (SI unit: m).
If the model represents only a part of a geometry obtained from symmetry cuts (for example, a quarter of a circle), use the settings under Symmetry specification to specify appropriate correction factors. Enter the Coil length multiplication factor FL and Coil area multiplication factor FA (dimensionless integer numbers). The actual length of the coil, used to compute the coil voltage and resistance, is then computed as the product FL·Ledges. The cross-section area of the coil is computed as FA·Adomain.
See Using Coils in 3D Models in the modeling section to learn more about this node.