The objective of this tutorial is to understand the steps and methodology for creating unstructured grids. A simple 2-D plate (no thickness) is created and an unstructured grid is generated for it.

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.

The objective of this tutorial is to understand the steps and methodology for creating unstructured grids for 3D geometric models. We’ll create a simple cylinder with a transverse hole and generate a grid for it. This will illustrate the general method for 3D models.

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.

The geometry of a simple two stroke engine is created and a 2D structured face is created. This face is then extruded to generate 3D structured block.

Hybrid grids imply the use if structured and unstructured grids to take advantage of the geometry, ease of gridding and even the flow/physics involved. This tutorial demonstrates the generation of hybrid grids in a 3D geometry.