Every time you deliver a product to a customer, you are promising them that it will work as advertised and make their life easier in some way. Using ANSYS engineering simulation software to design your products ensures that you can keep that promise, with every product and every order for every customer.
ANSYS users come from various industrial sectors. ANSYS is particularly widespread in the following industries: industrial equipment, energy, automotive, aerospace and defense, railway and ship building, consumer goods and healthcare technology. Even in higher education and research institutes ANSYS is used intensively.
ANSYS electromagnetic field simulation helps you design innovative electrical and electronic products faster and more cost-effectively.
In today’s world of high performance electronics and advanced electrification systems, the effects of electromagnetic fields on circuits and systems cannot be ignored. ANSYS software can uniquely simulate electromagnetic performance across component, circuit and system design, and can evaluate temperature, vibration and other critical mechanical effects. This unmatched electromagnetic-centric design flow helps you achieve first-pass system design success for advanced communication systems, high-speed electronic devices, electromechanical components and power electronics systems.
Simulation that involves multiple physical models or multiple simultaneous physical phenomena. Like the electromagnetic coupled with Structural and Magneto-structural, FSI-Fluid Structure interactions, Induction heating, Piezo electric...Etc. is being addressed to our customers.
Structural Analysis is the determination of the effects of loads on physical structures and their components. Structures subject to this type of analysis include all that must withstand loads, such as buildings, bridges, vehicles, machinery, furniture, attire, soil strata, prostheses and biological tissue. In Finite Element Analysis.
Fluid Flow Analysis to solve and analyze problems that involve fluid flows. Computers are used to perform the calculations required to simulate the interaction of liquids and gases with surfaces defined by boundary conditions. The fundamental basis of almost all CFD problems is the Navier–Stokes equations, which define any single-phase fluid flow.
These equations can be simplified by removing terms describing viscosity to yield the Euler equations.Further simplification, by removing terms describing vorticity yields the full potential equations. Finally, for small perturbations in subsonic and supersonic flows (not transonic or hypersonic) these equations can be linear zed to yield the linear zed potential equations.
Innovation in semiconductor design and manufacturing is enabling smaller device architectures with higher performance and more energy-efficient devices for powering the smart product revolution.
The physics associated with shrinking geometries, especially in the emerging 3D-IC, FinFET and stacked-die architectures bring out design challenges related to power and reliability, affecting design closure. ANSYS simulation and modeling tools offer you the sign-off accuracy and performance needed to ensure the power noise integrity and reliability of even the most complex ICs, taking into account electro migration, thermal effects and electrostatic discharge phenomena.
A Multibody system or Mechanisms are used to model the dynamic behavior of interconnected rigid or flexible bodies, each of which may undergo large translational and rotational displacements for the purpose of achieving desired work.
The new concepts to accomplish a work by means of mechanism design can be achieved through Kinematics & the dynamic loads generated due to the moving parts in the mechanisms can be obtained from MBD simulation.