Electromagnetic Actuators are used to convert electrical energy to linear mechanical motion. Simulation helps to analyze the performance in terms of mechanical force requirements, number of turns, materials, and integration of control circuitry.
Computation of Electric stress distribution in the insulating medium greatly helps in analyzing partial discharge and identifying proper insulating material.
E-magnetic sensors are majorly used to identify the rotor position and current sensing in electric machines. Hall and reluctance sensors are the best examples.
Bus Bar plays a vital role in power transmission and distribution systems and acts as a common link for multiple input and output terminals. Simulation of busbars provides Power handling capability, power losses, electrostatic effects, and thermal rise.
Planar inductors and transformers design plays a critical role in electronic control design. Simulation enables the user to identify the effects due to fringing flux, circulating currents, winding configurations, eddy and proximity, and non-linear materials at the early stage of the design.
Enables users to simulate the performance of radial/axial flux and linear motors for a wide range of operations. Reduced order modeling of motors helps in improving the simulation time at the system level.
Electromagnetic simulation of the transformer provides power losses(Hysteresis, eddy, copper, and stray load losses), insulation system design, short circuit forces, and effects of faulty scenarios.