Computer Aided Engineering (CAE)
We live in the age of Big Data, Industry 4.0, High-Performance Computing (HPC) and Artificial Intelligence (AI) and every new project is more complex than the previous. This requires more divers and more accurate data to ensure a successful market placement of our products. To master the highest standards in technology industry, we rely on Computer Aided Engineering (CAE). Leveraging state-of-the-art software products, we conduct Multiphysics simulations that shed light on unknown features of your product. Our expertise covers a broad range of CAE-disciplines.
Finite Element (FEA), Finite Volume (FV) and Finite Differences (FD)
We apply a variety of numerical methods to analyse the strength, thermal response, flow behaviour and life cycles of structures and mechanical parts. This variability allows us to tailor each simulation individually and deliver customized solutions for your products.
Heat Transfer Simulations (CFD | FEA)
Plastics and metals used for industrial purposes are thermoelastic materials i.e., they undergo volume change under heating or cooling. A variety of parts are heated or cooled to operating conditions by fluids like oil or water causing thermal stresses. We determine the coupling between the solid part and thermal fluid with ultra-modern CFD and FEA tools to make sure the design does not fail under the applied stresses.
Fluidics and Microfluidics - Computational Fluid Dynamics (CFD)
The Navier-Stokes and Bernoulli’s equations lay the ground for CFD simulations. Applications are across the scales and concern a broad range of industry sectors including pharma, architecture and the space industry. We conduct customer-specific simulations with state-of-the-art CFD software.
Electromagnetic Simulation (FEA)
Maxwell’s equations can be used to predict the transient behaviour of electromagnetic fields. We calculate the magnetic field strength and force of repulsion leveraging modern software products.
Fluid-structure Interaction (FSI)
Vortex shedding around structures can induce elastic stresses. Quantifying these stresses is crucial to e.g., build aircrafts or in the planning of buildings. We predict the interaction between fluids and solids by coupling the classical CFD simulation to structural analysis.
Structural Analysis (FEA)
Structural analysis determines conformation of the design with the specifications of the standard. Leveraging modern FEA-Software we predict stresses and deformation within your product design under operating conditions.