Versions Compared

Old Version 34

changes.mady.by.user Former user

Saved on

compared with

New Version 35

changes.mady.by.user Former user

Saved on

Key

  • This line was added.
  • This line was removed.
  • Formatting was changed.
Comment: Fixed Image and removed copy of page

Table of Contents

Table of Contents
maxLevel4

Streamlines around an F1 carImage Removed

Streamlines of an F1 car obtained using computational fluid dynamics [1]

What is Computational Fluid Dynamics (CFD)?

Computational fluid dynamics is an engineering analysis method used to understand how fluids flow in or around an object [1]. CFD analysis uses theoretical fluid dynamics models obtained from the Navier-Stokes equation to simulate how a specific fluid will flow around an object [1]. Other CFD software use the Lattice Boltzmann Method to solve CFD simulations [2]. By doing CFD analysis on a part you can drastically reduce the amount of prototypes and lower the development cost of the final product [1]. CFD has many applications as it can be used for anything that involves a fluid in motion. CFD can be used to simulate incompressible flow, compressible flow, laminar flow, turbulent flow, mass transport, and thermal transport [2]. The most common applications of CFD are HVAC, aerodynamics, heat transfer, turbomachinery, high-performance computing (HPC), electronics cooling, cleanrooms, and pipes and valves [2].

compressible flow cfd softwareImage Removed

SimScale Compressible Flow Analysis [2]

Computational Fluid Dynamics Software

The 6 most popular CFD software from highest to lowest popularity are ANSYS, OpenFOAM, PowerFLOW, SimScale, COMSOL Multiphysics, and Autodesk CFD [3]. The most accessible CFD software for University of Waterloo students is flow simulation in SOLIDWORKS. For projects that require a high degree of accuracy, it would be best to use a dedicated CFD software such as ANSYS or OpenFOAM.

SOLIDWORKS

In SOLIDWORKS you can perform flow simulations on parts and assemblies. There are 2 modules that can be added to the base SOLIDWORKS Flow Simulation package that add more types of flow simulations [4]. The base SOLIDWORKS Flow Simulation package has head conduction in solids, radiation, time-dependent, gravity, rotation, and free surface simulation features. The HVAC Module adds heating, cooling, and ventilation tools for simulating HVAC systems and radiation [4]. The Electronics Cooling Module adds thermal management tools for simulating printed circuit boards (PCBs) and enclosures [4]. The Student Edition of SOLIDWORKS appears to come with the base SOLIDWORKS Flow Simulation package. 

Starting a Flow Simulation in SOLIDWORKS

Navigate to the SOLIDWORKS Add-Ins tab and click SOLIDWORKS Flow Simulation. Once it appears select the Flow Simulation tab.

Wizard

After selecting the wizard command, follow its instructions by naming the study, selecting a configuration, selecting a unit system, entering unit precision, selecting internal or external analysis, selecting simulation features, select fluid(s), selecting wall conditions and roughness, selecting initial simulation parameters, and then selecting finish to close the wizard. Internal analysis is for simulating inside enclosed parts and assemblies and external analysis are for other parts and assemblies. If you select certain gases you can choose to add humidity to the simulation and if you add specific liquids you can add cavitation to the simulation.

Computational Domain

The computational domain is the region where the simulation will occur. This area is illustrated by a transparent box around the part or assembly. The simulation will calculate the flow in this region only, so it should be close to the size of the region you want to simulate because an excessively large region will require more time to calculate. Once the computational domain is properly sized, hide it by right clicking it in the projects tree and selecting hide.

Boundary Conditions

qweaikfksdv

Rotating Region

olvhbols

Goals

Goals are the parameters that you can measure during the simulation that can be plotted after running the simulation.

Results

Once the simulation is defined run the simulation. After the results have been calculated, they will load into the flow simulation. It can take several minutes to calculate the flow simulation. 

Flow Trajectories

part trans and lines and playable with R click

Goal Plots

The goals selected eailier can be plotted and then exported in an Excel spreadsheet.

Gravity Flow Simulation of an Exhaust HeaderRotating Region Flow Simulation of a Centrifugal Supercharger

then regions you want, added goals of whats recorded, run, expand and view results, flow trajectories are flow points (lines)

Widget Connector
urlhttps://www.youtube.com/watch?v=KqMI6fa-guU

Widget Connector
urlhttps://www.youtube.com/watch?v=Vr9A2oVy570

Widget Connector
urlhttps://www.youtube.com/watch?v=rtfHh5Mabso

https://confluence.cornell.edu/display/SIMULATION/Home

https://www.ansys.com/academic/free-student-products

References

Contributors:

Contributors Summary
columnslastupdate
orderupdate

Table of Contents

Table of Contents
maxLevel4


Streamlines around an F1 carImage RemovedStreamlines around an F1 carImage Added

Streamlines of an F1 car obtained using computational fluid dynamics [1]



What is Computational Fluid Dynamics (CFD)?

Computational fluid dynamics is an engineering analysis method used to understand how fluids flow in or around an object [1]. CFD analysis uses theoretical fluid dynamics models obtained from the Navier-Stokes equation to simulate how a specific fluid will flow around an object [1]. Other CFD software use the Lattice Boltzmann Method to solve CFD simulations [2]. By doing CFD analysis on a part you can drastically reduce the amount of prototypes and lower the development cost of the final product [1]. CFD has many applications as it can be used for anything that involves a fluid in motion. CFD can be used to simulate incompressible flow, compressible flow, laminar flow, turbulent flow, mass transport, and thermal transport [2]. The most common applications of CFD are HVAC, aerodynamics, heat transfer, turbomachinery, high-performance computing (HPC), electronics cooling, cleanrooms, and pipes and valves [2].


compressible flow cfd software

SimScale Compressible Flow Analysis [2]



Computational Fluid Dynamics Software

The 6 most popular CFD software from highest to lowest popularity are ANSYS, OpenFOAM, PowerFLOW, SimScale, COMSOL Multiphysics, and Autodesk CFD [3]. The most accessible CFD software for University of Waterloo students is flow simulation in SOLIDWORKS. For projects that require a high degree of accuracy, it would be best to use a dedicated CFD software such as ANSYS or OpenFOAM.


SOLIDWORKS

In SOLIDWORKS you can perform flow simulations on parts and assemblies. There are 2 modules that can be added to the base SOLIDWORKS Flow Simulation package that add more types of flow simulations [4]. The base SOLIDWORKS Flow Simulation package has head conduction in solids, radiation, time-dependent, gravity, rotation, and free surface simulation features. The HVAC Module adds heating, cooling, and ventilation tools for simulating HVAC systems and radiation [4]. The Electronics Cooling Module adds thermal management tools for simulating printed circuit boards (PCBs) and enclosures [4]. The Student Edition of SOLIDWORKS appears to come with the base SOLIDWORKS Flow Simulation package. 


Starting a Flow Simulation in SOLIDWORKS

Navigate to the SOLIDWORKS Add-Ins tab and click SOLIDWORKS Flow Simulation. Once it appears select the Flow Simulation tab.


Wizard

After selecting the wizard command, follow its instructions by naming the study, selecting a configuration, selecting a unit system, entering unit precision, selecting internal or external analysis, selecting simulation features, select fluid(s), selecting wall conditions and roughness, selecting initial simulation parameters, and then selecting finish to close the wizard. Internal analysis is for simulating inside enclosed parts and assemblies and external analysis are for other parts and assemblies. If you select certain gases you can choose to add humidity to the simulation and if you add specific liquids you can add cavitation to the simulation.


Computational Domain

The computational domain is the region where the simulation will occur. This area is illustrated by a transparent box around the part or assembly. The simulation will calculate the flow in this region only, so it should be close to the size of the region you want to simulate because an excessively large region will require more time to calculate. Once the computational domain is properly sized, hide it by right clicking it in the projects tree and selecting hide.


Boundary Conditions

qweaikfksdv


Rotating Region

olvhbols


Goals

Goals are the parameters that you can measure during the simulation that can be plotted after running the simulation.


Results

Once the simulation is defined run the simulation. After the results have been calculated, they will load into the flow simulation. It can take several minutes to calculate the flow simulation. 


Flow Trajectories

part trans and lines and playable with R click


Goal Plots

The goals selected eailier can be plotted and then exported in an Excel spreadsheet.





Gravity Flow Simulation of an Exhaust HeaderRotating Region Flow Simulation of a Centrifugal Supercharger



then regions you want, added goals of whats recorded, run, expand and view results, flow trajectories are flow points (lines)

Widget Connector
urlhttps://www.youtube.com/watch?v=KqMI6fa-guU

Widget Connector
urlhttps://www.youtube.com/watch?v=Vr9A2oVy570

Widget Connector
urlhttps://www.youtube.com/watch?v=rtfHh5Mabso

https://confluence.cornell.edu/display/SIMULATION/Home

https://www.ansys.com/academic/free-student-products



References



Contributors:

Contributors Summary
columnslastupdate
orderupdate