Solidworks Flow Simulation 2012 Tutorial.pdf |top| -
Defining inlets (velocity, pressure), outlets, and wall conditions.
Browse the pre-defined engineering database. Expand the Gases or Liquids folder, select your fluid (e.g., Water or Air), and click Add .
Old tutorials assume you have a perfect model. If your imported CAD has gaps, Flow Simulation 2012 will fail the . The PDF won't fix this; you must use the "Create Lids" tool (Chapter 2 of the PDF) to close inlets/outlets manually.
Click . The solver window will appear, showing mathematical convergence graphs. Monitor your defined Goals . solidworks flow simulation 2012 tutorial.pdf
The is the most crucial part of the tutorial. It sets up the study in seven steps, ensuring that the necessary physical models are activated (e.g., gravity, time-dependency). Step-by-Step Tutorial Summary: Flow Through a Valve
If you run into issues during your analysis, check these common problem areas: Error / Symptom Likely Cause Open gaps in assembly Use the Check Geometry tool; enlarge or rebuild your lids. Averaging lines fluctuating Unsteady/turbulent flow
To truly appreciate the resource, let's walk through a classic tutorial: . This example perfectly demonstrates how the PDFs and the software worked in tandem. Old tutorials assume you have a perfect model
Mastering SolidWorks Flow Simulation 2012: Your Ultimate Guide
Click the icon. Name the project "Pipe_Pressure_Drop". Select SI units . Choose Internal Analysis . Select Water as the fluid. Keep default wall parameters and click Finish . Step 3: Insert Boundary Conditions
The opening tutorial usually features an electronic enclosure or a valve mechanism. You will learn: How to use the to set up a project. Defining the fluid type (e.g., Air, Water). Water). Before launching the simulation
Before launching the simulation, ensure your 3D CAD model is "watertight."
The classic first exercise. You learn to run an internal flow analysis through a ball valve. The tutorial walks you through:
: Define if walls are perfectly insulated or have rough surfaces. Step 3: Define Boundary Conditions
Access the settings to find a slider numbered from 1 to 7.
If your goals oscillate rapidly and never flatten out, your physical problem might be inherently unsteady (turbulent vortex shedding). Try changing your project settings from Steady-State to Transient (Time-Dependent) .