Latest Opera electromagnetics simulator accelerates design projects and adds 3D mechanical stress analysis

December 07, 2011 //By Jean-Pierre Joosting
The latest version of the Opera electromagnetics simulator for design engineers, from the Vector Fields Software business unit of Cobham Technical Services, adds three-dimensional mechanical stress analysis, extending the tool's multiphysics capability to provide a single-step solution to complex design problems. By capturing mechanical deformation in conjunction with electromagnetic and thermal modelling, the integrated software can greatly reduce design complexity and timescales.

Opera version 15 provides a complete design-simulate-analyze-optimize tool chain for electromagnetic applications. Known for its accuracy of simulation and speed of execution — allowing demanding simulations to be solved on standard office-grade PCs — the software is available in a number of variants that include finite element analysis (FEA) for static and time-varying electromagnetic fields, and application-specific solvers for rotating electrical machines, superconducting magnets, charged particle beam devices, and magnetization/demagnetization processes.

Advanced material models, such as lossy dielectric insulation and magnetic hysteresis, put Opera at the cutting edge of simulation capability. Opera’s electromagnetic models may also be coupled with third-party system simulation tools available within Simulink.

The new three dimensional stress analysis module solves for deformations within the elastic limit of the materials, and may be coupled with the electromagnetic solvers to provide a single-step solution to virtual prototyping. In addition to stress and strain produced by the application of mechanical loads and by electromagnetically induced forces, Opera's thermal analysis module may be used to co-simulate thermal expansion. The effects of gravity or rotationally induced forces can also be incorporated in design simulations.

The latest version 15 of the software extends the fundamental performance advantage of Opera for many common design engineering applications. For instance, mechanical deformation is a vital consideration in the design of large and superconducting magnets, and electrical equipment and coils in transformers, motors, generators and actuators. The ability of a superconducting magnet's coils to withstand the mechanical forces generated during a quench, or the mechanical integrity of the stator end windings of a generator subject to a short-circuit condition, are critical design requirements.

Many other enhancements are incorporated in the latest release of Opera, to simplify and speed the design process. One of these supports the rapid creation of models of coils, by providing a dynamic pictorial representation of the model under construction, to guide the user as design data is entered. This extends Opera's existing

Design category: