Autodesk Simulation Multiphysics

Transcription

1 Autodesk Simulation Multiphysics Course Length: 2 days This course will introduce you to performing computational fluid dynamics (CFD) analyses on 3-D models. All of the available load and constraint options for CFD analyses will be covered. You will learn how to evaluate the results of CFD analyses and create presentations of the results, including images, animations, and HTML reports. For information regarding the basics of the user interface, refer to the Autodesk Simulation Mechanical Part 1 course and Seminar Notes, which is a prerequisite to this course. The program Help files may also be consulted for basics not covered within this training course.

2 Table of Contents Introduction Overview Installing and Running Autodesk Simulation System Requirements Autodesk Simulation Help Subscription Center Web Links Tutorials Webcasts and Web Courses How to Receive Technical Support Updates Background of FEA What is Finite Element Analysis? Fluid Flow Review Equations Used in the Solution Limitations of CFD Basic FEA Concepts The General Flow of an Analysis Chapter 1: Autodesk Simulation Multiphysics Example Ball Valve Example Meshing the Model Setting up the Model Analyzing the Model Reviewing the Results Creating an Animation Generating a Report Chapter 2: Basics of Fluid Flow Analysis Fluid Flow Elements Meshing Options Fluid Generation Tetrahedral and Boundary Layer Meshes Example of Internal Fluid Generation and Boundary Layer Meshing Loading Options Prescribed Inlet/Outlets Prescribed Velocity Pressure/Traction

3 Load Curves Convergence Controls for the "Mixed GLS" and "Penalty" Formulation Options Output and Printout Intervals Convergence Controls for the "Segregated" Formulation Option Turbulence Surface Prescribed Turbulence Conditions Wall Roughness Reviewing the Results Exercise A: Venturi Model Chapter 3: Results Evaluation and Presentation Result Types Reaction Forces Velocity Pressure Vorticity Vorticity Precision Flow Rate Stress Presentation Options 3-D Visualization of 2-D Elements Slice Planes Particle Paths Streamlines Exercise B: 3-D Flow around a Building Chapter 4: Additional Loading Options Using a Fan Surface Fan Swirl Effects Example of Fan Surfaces Overview of Rotating Frames of Reference Applying a Rotating Frame of Reference Number of Rotating Frames of Reference Example of a Rotating Frame of Reference Exercise C: Fan Model

4 Chapter 5: Open Channel Flow Open Channel Flow Overview Loads Not Available for Open Channel Flow Analysis Initial Fluid Volume Results Unique to Open Channel Flow Volume of Fluid Open Channel Flow Example Extracting the Model Archive Defining the Initial Fluid Volume and Inlet/Outlet Surfaces Defining the Material and Analysis Parameters Performing the Analysis Animating the Results Chapter 6: Multiphysics Forced Convection (Uncoupled Fluid Flow and Heat Transfer) Natural Convection (Couple Fluid Flow and Thermal) Additional Program Installation Requirements Fluid Structural Interaction (FSI) Thermal Stress Joule Heating Result Options Pipe Tee Example Uncoupled Fluid/Thermal/Stress Fluid Part Creation and Meshing Setting up and Analyzing the Fluid Flow Model Reviewing the Fluid Flow Results Setting up and Analyzing the Thermal Model Reviewing the Thermal Results Setting up and Analyzing the Structural Model Reviewing the Structural Results Heat Exchanger Example Coupled Fluid/Thermal Opening and Meshing of the Model Setting up the Model Analyzing the Model Reviewing the Results Exercise D: Heat Sink Model

5 Self Study: Formulation Options, Porous Media, and Transient Mass Transfer Fluid Flow Formulation Options Mixed GLS Formulation: Segregated Formulation: Penalty Formulation: Porous Media Example of Flow through Porous Media Using Porous Media in a Steady or Unsteady Fluid Flow Analysis Example of Using Porous Media in a Steady Fluid Flow Analysis Self Study Exercise Flow through Porous Media with Gravity 2D Elements Transient Mass Transfer Overview Meshing Requirements Defining Species Loading Options Part-Based Loads Surface Based Loads Nodal Loads Analysis Parameters Result Types Species Concentration Mass Flux Mass Rate of Face

6 Cancellation Policy The following cancellation policy shall apply to all training engagements, Live Online, Consulting Services and Dedicated/ Custom Training: Company reserves the right to reschedule or cancel the date, time and location of its class at any time. In the event that a Training Class is cancelled by Company, Customer is entitled to a full refund. Company shall not be responsible for any other loss incurred by Customer as a result of a cancellation or reschedule. For Customer cancellations when written notice is received (i) at least ten (10) business days in advance of the class, the Customer is entitled to a full refund of its payment or reschedule enrollment, (ii) less than ten (10) business days, Customer shall not be entitled to a refund, but shall receive a class credit to be used within three (3) months of the date of the original class. Student substitutions are acceptable with at least two (2) days prior notice to the class, provided substitution meets course prerequisites and is approved by Company s Training Coordinator (trainingcoordinator@rand.com) For all Training orders, cancellation notices must be submitted to trainingcoordinator@rand.com. Company is not responsible for any error in the delivery of the notice. In the event of any reschedule of Consulting Services and/or Dedicated/Custom Training by Customer, Company will invoice Customer for all non-cancellable travel expenses. For full terms and conditions, go to imaginit.com/trainingtc. To request more information or to see training locations, visit imaginit.com/contact.