Join us online for COMSOL Day Benelux to engage in product demonstrations, speak with others in the field of simulation, and participate in an interactive Tech Café.
View our schedule below and please note sessions may be subject to change.
Please join us 10 minutes before the presentation starts to settle in and make sure that your audio and visual capabilities are working.
To start, we will briefly discuss the format of the day and go over the logistics for using GoToMeeting.
Learn the fundamental workflow of COMSOL Multiphysics®. This introductory demonstration will show you all of the key modeling steps, including geometry creation, setting up physics, meshing, solving, and postprocessing.
Build a solid foundation for your modeling work. This demonstration will illustrate best practices for the entire workflow in COMSOL Multiphysics® through geometry creation, setting up your physics, meshing, solving, and postprocessing the results.
Get a brief overview of using the Heat Transfer Module within the COMSOL® software environment. We will discuss conjugate heat transfer with the combination of heat transfer in solids and heat transfer in fluids, including thermal radiation effects. These phenomena could also be coupled with structural mechanics, chemical reactions, and particle tracing.
Learn about the tools for generating a geometry model with COMSOL Multiphysics®. We will cover how to efficiently build geometry that can be parameterized and look into how to carry out tasks such as creating a sketch with dimensions and constraints, generating 2D cross sections of 3D objects, and more.
Get an overview of the Structural Mechanics Module, an add-on to COMSOL Multiphysics® for analyzing the mechanical behavior of solid structures.
Join COMSOL engineers and your colleagues to discuss how to use COMSOL Multiphysics®. Ask questions about modeling techniques and the appropriate features and settings in the COMSOL® software to model such phenomena, as well as how best to model your specific applications.
Get an overview of using the CFD Module for laminar, turbulent, non-Newtonian, multiphase, and porous media flows as well as flow in mixers. These phenomena could also be coupled with structural mechanics, chemical reactions, and particle tracing.
Learn the fundamental numerical techniques and underlying algorithms related to linear and nonlinear multiphysics simulations. We will cover the difference between iterative and direct solvers as well as the different study types, including stationary, transient, and frequency-domain analysis.
Learn about the capabilities of the AC/DC Module for modeling Maxwell's equations in the low-frequency regime. Use cases include resistive and capacitive devices, inductors and coils, as well as motors and magnets.
Learn to use gradient-based and derivative-free optimization techniques to define and solve problems in shape, parameter, and topology optimization. The techniques shown are applicable for almost all types of models.