This tutorial is designed to simulate the “real-world” working process capabilities of CFD-GEOM. An IGES file generated from a CAD package is read into GEOM. Then, the surfaces are trimmed, an unstructured domain is created, and the combustor model is gridded.
The geometry to be created in this tutorial is a generic semiconductor reactor. It has one large inlet on the top, a small outlet port and a side port. Four blocks or domains are used in this geometry. The central portion under the large inlet is a single block with a C topology and a polar singularity. A second C topology block surrounds this block. The side port and outlet pipe are filled with the final two blocks of H topology.
The objective of this tutorial is to create structured and unstructured grids for a generic bio-sensor model with the ultimate aim of running a binding-kinetics simulation for it. The grid-generation proceeds from the geometry creation stage which is covered in this tutorial.
The objective of this tutorial is to create an unstructured grid for a generic bio-sensor model with the aim of running a binding-kinetics simulation for it. This tutorial demonstrates unstructured grid generation.
The objective of this tutorial is to create an unstructured grid for a
generic bio-sensor model with the aim of running a binding-kinetics
simulation for it. This tutorial demonstrates structured grid
generation.
This tutorial demonstrates the generation of a 3D geometry model and its discretization into a 3D structured grid. A Tesla-type valve geometry is used for this demonstration.
In this tutorial, a grid system is generated to study the flow of engine oil through a compliant orifice. Effects of thermal stress and fluid-structural coupling will be included. The geometry is 2D-axisymmetric, hybrid structured/unstructured grid system. Structured gridding is used for the flow path and unstructured grid is used to model the structure.
