Software Speeds Electromechanical Component Design

Dec 14, 2005 11:36 AM

Ansoft has released Maxwell v11, 3D electromagnetic analysis software used to accurately predict the performance of low-frequency electromechanical (EM) components. This release introduces Ansoft desktop technology into Maxwell and adds unparalleled capabilities for 3D analytical and FEM-based machine design.

This Ansoft-pioneered graphical user interface and desktop environment, presently available with HFSS, Q3D Extractor and Ansoft Designer, increases engineering productivity through new geometry creation/import; integrated parameterization and optimization; model resolution; healing techniques; and electrically aware meshing.

In addition, with this release, Ansoft introduces a new 3D analytical/FEM design flow for today's high-performing rotating electric machines by integrating Maxwell v11 and RMxprt within the same design environment. The new design capability allows engineers to make initial sizing decisions and design choices, and automatically creates 3D finite-element models of the machine required to accurately analyze end effects, saturation and lamination effects.

The new desktop environment features a graphical project tree and parametric design entry of all aspects of the design, from geometry and material properties, to analysis control and post-processing. Coupled to Optimetrics, Maxwell delivers automated optimization and parametric sweeps that are integrated within the same project tree.

Maxwell v11 now supports Windows XP Professional x64 and Red Hat Enterprise Linux. This new 64-bit processing expands memory accessibility, thus delivering additional capacity and speed to the simulation process. A new Distributed Analysis option applies parallel computation to the investigation of parametric design variations, saving overall analysis time while maximizing the use of existing computer hardware.

Maxwell v11 includes new analysis features that aid in the analysis of electric machines and other electromagnetic devices. Examples include transient core-loss modeling (including eddy, hysteresis and supplemental losses), dynamic demagnetization and nonlinear anisotropic materials. Lamination models with selectable stacking factor and direction also are provided, as well as a graphical winding editor that includes commutator and winding elements.

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