Simcenter Flux
Accelerate motor, sensor, and actuator design
SimcenterTM FluxTM is a Siemens product
SimcenterTM FluxTM is a Siemens product
Simcenter Flux is a high precision simulation software that captures the full complexity of electromechanical systems, enabling you to optimize performance, efficiency, size, cost, and weight. With Flux, you can simulate magnetostatic, steady state, and transient behaviors, together with electrical and thermal phenomena, all within a single robust environment.
For more than 35 years, Flux has been trusted by leading companies worldwide as the benchmark solution for electromagnetic simulation. Its continuously evolving technology makes it a versatile, efficient, and intuitive tool that helps engineers design high performance products faster and with fewer prototypes.
By integrating with the Simcenter platform, Simcenter Flux provides a complete view of subsystem interactions and streamlines the entire product development workflow.
Leverage scripting, macros, and multi parametric tools within the open Simcenter Flux environment. Fine tune models and solvers and automate simulation workflows with high efficiency.
Simcenter Flux has a long track record of matching real world measurements and reproducing complex electromagnetic phenomena with exceptional accuracy, delivering reliable results engineers can trust.
Design machines that are efficient, quiet, and robust through seamless integration with the Simcenter platform.
Accelerate pre processing and focus on 2D, skew, and 3D innovative designs using a dedicated toolset: sketcher/modeler, defeaturing options, e motor environment, and intelligent auto adaptive meshing.
Access built in models for magnetic, electric, and thermal effects; static, AC steady state, and transient analysis; complex circuit editing; and rigid body motion for realistic simulations.
Benefit from advanced capabilities such as non meshed coils, nonlinear anisotropic materials, hysteresis modeling, and accurate representation of skin and proximity effects in windings.
Explore new design configurations using multi parametric tools supported by efficient linear and nonlinear solvers, further enhanced by optimization methods and HPC acceleration.
Use a comprehensive post processor to analyze, report, and export results across multi parametric scenarios: potentials, flux density, temperatures, electromagnetic fields, mechanical quantities, and more.
Connect all physics domains within a unified optimization loop. Share models, mesh, and design variables to quickly understand complex interactions.
Send your technical questions to our experts!
Connect you with an EnginSoft expert who can provide a reliable answer to your technical question or recommend a
proven solution.
CASE STUDY
The scope of this study was to determine and validate a more efficient simulation procedure for the design phase of Al-Si alloy components for the aeronautical industry.
aerospace magma metal process simulation
CASE STUDY
The adoption of SBES has significantly increased in the last two decades, driven by advancements in computing technology and the rise of Industry 4.0, which promotes nine key enabling technologies, including engineering simulation and big data analytics. SBES is crucial for the integration and automation of production systems, improving flexibility, speed, and quality.
automotive construction energy cfd metal-process-simulation
CASE STUDY
The adoption of SBES has significantly increased in the last two decades, driven by advancements in computing technology and the rise of Industry 4.0, which promotes nine key enabling technologies, including engineering simulation and big data analytics. SBES is crucial for the integration and automation of production systems, improving flexibility, speed, and quality.
automotive construction energy cfd metal-process-simulation
CASE STUDY
In this article, we show that the main turbine characteristics, such as efficiency and exit flow angle, can be sufficiently improved using parametric optimization.
modefrontier energy optimization
CASE STUDY
The object of this study was simulating and optimizing the cold forging process for a silent block bush steel sleeve. A silent block bush is traditionally used in the linkage system of a car suspension, in railway carriages and in agricultural machinery.
metal-process-simulation forge forging automotive