News & Events
A clear view on ANSYS 14.5 with in-depths
- October 1, 2020
- Posted by: Diwakar
- Category: ANSYS
ANSYS training imparts the skills to develop the product design and use the simulation methods to solve the most challenging product engineering problems. This training allows users to analyze large product models before actual manufacturing. The participants explore the software’s new innovations, including pre-processing functionalities; coupled physics capabilities; and high-performance computing advancements. The learning curve expands and allows the candidates to accomplish multiphysics workflows in structural, electromagnetics, and thermal domains.
By the end of the training the following skills are inculcated in you:
- Working of Finite Element Modeling (FEA)
- Implementing bottom-up and top-down construction in basic and advanced Solid Modeling
- Creating geometric entities and work planes
- Importing solid models and IGES files
- Meshing the solid models and defining their generation and density
- Applying loads in different disciplines
- Static and Advanced Structural Analysis
- Describing the terms used in thermal analysis
- Setting the analysis preferences among different types of thermal analysis
- Solutions and Postprocessor
- Calculate error estimation in solution
- Using ANSYS report generator
- Capturing data tables, lists, images, and animation for the report
Target audience
This training is recommended for the candidates who perform finite element analysis (FEA) of mechanical parts or fluids.
Prerequisites
While there is no formal prerequisite for this training, however candidates with a strong interest in product design and engineering are the ideal participants for this course.
- Introduction to FEA and Ansys
- Basic Solid Modeling
- Advanced Solid Modeling
- Finite Element Modeling (FEM) – I
- Finite Element Modeling (FEM) – II
- Solution And Postprocessor
- Static Structural Analysis
- Advanced Structural Analysis (Dynamic And Nonlinear)
- Advanced Structural Analysis
- Thermal Analysis
- Generating The Report Of Analysis
Introduction to FEA and Ansys
- Introduction to FEA
- General Working of FEA
- Nodes, Elements, and Element Shapes
- General Procedure of Conducting Finite Element Analysis
- FEA through ANSYS
- Effective Utilization of FEA
- FEA Software
- Advantages and Limitations of FEA Software
- Key Assumptions in FEA
- Assumptions Related to Geometry
- Assumptions Related to Material Properties
- Assumptions Related to Boundary Conditions
- Assumptions Related to Fasteners
- Types of Analysis
- Structural Analysis
- Thermal Analysis
- Fluid Flow Analysis
- Electromagnetic Field Analysis
- Coupled Field Analysis
- Important Terms and Definitions
- Strength (Resistance to Deformation)
- Load
- Stress
- Strain
- Elastic Limit
- Ultimate Strength
- Factor of Safety
- Lateral Strain and Poisson’s Ratio
- Bulk Modulus
- Creep
- Engineering Materials
- Introduction to ANSYS
- System Requirements
- Getting Started with ANSYS
- Interactive Mode
- Batch Mode
- Starting a New File Using the ANSYS Product Launcher window
- ANSYS Output Window
- ANSYS Multiphysics Utility Menu Window (ANSYS Session)
- Utility Menu
- Main Menu
- Graphics Area
- Standard Toolbar
- ANSYS Command Prompt
- Command Window Icon
- Raise Hidden Icon
- Reset Picking
- Contact Manager
- ANSYS Toolbar
- Model Control Toolbar
- User Prompt Information
- Current Settings
- Setting the Analysis Preferences
- Units in ANSYS
- Other Important Terms Related to ANSYS
- Dialog Boxes
- Graphics Display
- Panning, Zooming, and Rotating the Model
- Dividing the Graphics Area
- The Pan-Zoom-Rotate Dialog Box
- Graphics Picking
- Using Mouse Buttons for Picking
- ANSYS Database and Files
- Saving the File
- Resuming the File
- Clearing the Database
- Some Basic Steps in General Analysis Procedure
- Points to Remember while Performing an Analysis
- Exiting ANSYS
- Self-Evaluation Test
Basic Solid Modeling
- Solid Modeling in ANSYS
- Solid Modeling and Direct Generation
- Solid Modeling Methods
- Bottom-up Construction
- Top-down Construction
- Considerations before Creating a Model for Analysis
- Details Required
- Symmetry
- Creating Geometric Entities
- Creating Lines
- Creating Arcs
- Creating B-Spines
- Creating Fillets between Intersecting Lines
- Creating Areas
- Creating and Modifying Work planes
- Display Working Plane
- Show WP Status
- WP Settings
- Offset WP by Increments
- Offset WP to
- Align WP with
- Coordinate Systems in ANSYS
- Global Coordinate System
- Local Coordinate System
- Active Coordinate System
- Display Coordinate System
- Nodal Coordinate System
- Element Coordinate System
- Results Coordinate System
- Creating New Coordinate Systems
- Deleting Existing Coordinate
Advanced Solid Modeling
- Advanced Solid Modeling
- Creating Volumes
- Extruding Entities
- Extending the Line
- Creating Complex Solid Models by Performing Boolean Operations
- Modifying the Solid Model
- Scale
- Move
- Copy
- Reflect
- Deleting Solid Model Entities
- Importing Solid Models
- Importing the IGES File
- Importing Models from Pro/ENGINEER
- Importing the Model from Unigraphics
Finite Element Modeling (FEM) – I
- An Overview of the Finite Element Modeling
- Element Attributes
- Element Types
- Reasons Why ANSYS has a Large Element Library
- Real Constants
- Material Properties
- Multiple Attributes
- Assigning Multiple Attributes before Meshing
- Assigning Default Attributes before Meshing
- Modifying Attributes after Meshing
- Verifying Assigned Attributes
- Element Attributes Table
Finite Element Modeling (FEM) – II
- Finite Element Modeling (FEM) – II
- Mesh Generation
- Mesh Density
- Meshing the Solid Model
- Setting Element Attributes
- Defining the Mesh
- Defining the Entity to be Meshed
- Defining the Meshing Type
- Meshing the Model
- Refining the Mesh Locally
- Extruding the Mesh
- Transitional Pyramid Elements
- Requirements for Creating Pyramid Elements
- Creating Transitional Pyramid Elements (Hex-to-Tet Meshing)
- Converting Degenerate Tetrahedral (20 nodes) Elements into
- Non-degenerate (10 nodes) Tetrahedral Elements
- Plotting Pyramid Elements
- Meshing the Beam with Orientation Nodes
- Creating the Beam Mesh with Orientation Nodes
- Creating the Beam Mesh with Two Orientation Nodes
- Improving the Tetrahedral Element Meshes
- Improving Tetrahedral Meshed Volumes by Using Volumes
- Improving Tetrahedral Meshed Volumes by Using Detached Elements
- Some Additional Tips while Meshing the Model
- Applying Loads
- The Nodal Coordinate System
- Loads in Different Disciplines
- Types of Loads in ANSYS
- Load Steps, Sub steps, and Time
- Applying Loads
- Deleting Loads
- Deleting DOF Constraints
- Deleting all Loads and Load Step Options
- Deleting all Loads Applied on Solid Model
- Deleting all Loads Applied on Finite Element Model
Solution And Postprocessor
- Solution
- Defining the New Analysis Type
- Restarting the Analysis
- Setting Solution Controls
- Setting Analysis Options
- Solving the Analysis Problem
- Post processing the Result
- POST1 (General Postprocessor)
- POST26 (Time-history Postprocessor)
- Result Coordinate System (RSYS)
- Displaying the Deformed Shape of the Model
- Displaying the Minimum and Maximum Stresses
- Listing Reaction Forces
- Listing Stress Values at each Node
- Query Picking
- Path Operations
- Load Case Combinations
Static Structural Analysis
- Effect of self-weight on a cantilever beam
- Analysis of a bicycle handle
- Analysis of a stud (pin)
- Analysis of a master
Advanced Structural Analysis (Dynamic And Nonlinear)
- Advanced Structural Analysis
- Dynamic Analysis
- Performing the Modal Analysis
- Specifying the Analysis Type, Analysis Options, and Applying Loads
- Obtaining the Solution
- Reviewing Results
- Performing the Harmonic Analysis
- Specifying the Analysis Type, Analysis Options, and Applying Loads
- Obtaining the Solution
- Reviewing Results
- Performing the Transient Analysis
- Specifying the Analysis Type, Analysis Options, and Applying Loads
- Obtaining the Solution
- Reviewing Results
- Nonlinear Analysis
- Geometric Nonlinearity
- Material Nonlinearity
- Boundary Nonlinearity (Changing Status)
- Performing the Nonlinear Analysis
- Specifying the Analysis Type, Setting Solution Controls, and
- Applying Loads
- Obtaining the Solution
Advanced Structural Analysis
- Steel tubes and springs structure
- Modal analysis of an airplane wing
- Nonlinear analysis (material nonlinearity)
Thermal Analysis
- Thermal Analysis
- Important Terms Used in Thermal Analysis
- Heat Transfer Modes
- Thermal Gradient
- Thermal Flux
- Bulk Temperature
- Film Coefficient
- Emissivity
- Stefan–Boltzmann Constant
- Thermal Conductivity
- Specific Heat
- Types of Thermal Analysis
- Steady-State Thermal Analysis
- Transient Thermal Analysis
- Performing Steady-State Thermal Analysis
- Setting the Analysis Preference
- Creating or Importing a Solid Model
- Defining Element Attributes
- Meshing the Solid Model
- Specifying the Analysis Type, Analysis Options, and Applying Loads
- Solving the Analysis Problem
- Post processing Results
- Performing Transient Thermal Analysis
- Specifying the Analysis Type and Setting Solution Controls
Generating The Report Of Analysis
- Starting the ANSYS Report Generator
- Capturing Images for the Report
- Capturing Animations for the Report
- Capturing Data Tables for the Report
- Capturing Lists for the Report
- Compiling the Report
- Changing the Default Settings of the ANSYS Report Generator
- Error Estimation in Solution
- Percentage Error in Energy Norm (SEPC)
- Element Energy Error (SERR)
- Element Stress Deviations (SDSG)
- Maximum and Minimum Stress Bounds (SMXB and SMNB)