- #Comsol multiphysics 4.2 tutorial how to
- #Comsol multiphysics 4.2 tutorial series
- #Comsol multiphysics 4.2 tutorial windows
This primer allows you to get acquainted with the user-friendly desktop environment of the COMSOL Multiphysics® software, and with numerical modeling in general.
Licensed under CC BY-SA 3.0, via Wikimedia Commons. You’ll also get a detailed overview on what to expect in the other seven parts of the series.Ī submarine cable similar to the one modeled throughout this series.
#Comsol multiphysics 4.2 tutorial series
Part 1 of the tutorial series is where you meet the model - a three-core lead-sheathed XLPE HVAC (cross-linked polyethylene, high-voltage alternating current) submarine cable with a twisted magnetic armor. The beginning is a very good place to start, as most would say. Part 1: Introducing the Basics and Fundamentals of Cable Modeling The 3D twist models (Part 7 and 8) are discussed in another blog post: Using 3D Models to Investigate Inductive Effects in a Submarine Cable. Note that the models discussed in this blog post are 2D only (Part 1 to 6 of the series). It has since been updated to reflect the updated tutorial series. Keep reading for a sneak peek of what you’ll learn when you roll up your sleeves and start the series.Įditor’s note: This blog post was originally published on December 29, 2017. The numerical model is based on standard cable designs and validated by reported figures.
#Comsol multiphysics 4.2 tutorial how to
The Cable Tutorial Series shows how to model an industrial-scale cable in the COMSOL Multiphysics® software and add-on AC/DC Module, and also serves as an introduction to modeling electromagnetic phenomena in general.
Its library of physics models is really huge and it can be useful for different analysis and applications.
#Comsol multiphysics 4.2 tutorial windows
It has a user-friendly multiple windows interface incorporating geometry generation, physics model, meshing, solver, and post-processing.ĬOMSOL Multiphysics ® has the capability to solve coupled multiphysics problems, such as electro-thermal and thermo-mechanical phenomena. In the engineering field, including automotive and electronics. In this way, it is possible to focus on the structure, material properties, physics, and boundary conditions under analysis.ĬOMSOL Multiphysics ® is a commercial finite element analysis software for modeling and simulating a wide spectrum of FEM-based physical problems, especially coupled phenomena, The FEM procedure is hidden in the commercial software, which provides only the results of the analysis. The rapid development of commercial FEM softwares enables users to perform finite element analysis by hiding the finite element formulation of the problem of interest.
Powerful hardware provides analysis for complicated structure and/or physical phenomena as well as faster calculations. Strong comprehension of both the theory and mathematics behind of the FEM.įurthermore, the extension of the finite element analysis to 2D and 3D modeling makes the FEM procedure even more complicated.ĭue to the prevalence of advanced computer hardware and software, performing a finite element analysis is accessible even for users without much knowledge of the FEM . The procedure to perform a finite element analysis presented in Section 4.2 is not straight forward, because it requires a Numerical Implementation with Finite Element Method Previous: 4.2.6 Solution of the Linear Equations SystemĤ.3 Simulation Implementation in COMSOL Multiphysics
Next: 4.3.1 Finite Element Method Procedure in COMSOL Multiphysics Up: 4.
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