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2D Transient Diffusion
Created using ANSYS 2019R2
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Under construction |
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This tutorial has videos. If you are in a computer lab, make sure to have head phones. |
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In this tutorial, you will learn to:
- Create a mesh for a three dimensional internal flow,Model a transient 2D axisymmetric diffusion problem
- Visualize the flow results and compare to expected results
Problem Specification
Consider the following 3D model of a carotid artery bifurcation.
This model is created from a luminal casting of a carotid artery bifurcation and generously shared in Grabcad community
https://grabcad.com/library/carotid-bifurcation
Blood flows through the bifurcating artery from the inlet (to the left in the graph above) and exits from the two outlets (to the right). The diameter of the artery at the inlet is around 6.3mm. The diameter of Outlet 1 is around 4.5mm and the diameter of Outlet 2 is around 3.0mm. The density of blood is 1060 kg/m^3 [1]. Blood is a non-Newtonian fluid, meaning the coefficient of viscosity of blood is not a constant, but is a function of velocity gradients. This only has approximately a 10% effect on the results, and so for simplicity we will model the fluid with a constant viscosity here. We will also ignore the pulsatile and cyclic nature of blood flow, as the problem would become transient. If you are interested in modelling these effects, please see the 3D Bifurcating Artery (unsteady) tutorial. The pressure at the outlet is defined to be constant (100 mmHg). More details on boundary conditions will be provided in the next page Pre-Analysis and Set-up.
See HW statement.
Summary of steps (ANSYS 2019R2): in progress
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