From contact stiffness and friction to surface-to-surface, node-to-node and bolt pretension elements, this two-day course is designed to analyze contact models that cannot be readily solved using default settings.

Prerequisite: Basic Structural Nonlinearities

Course Topics Include:

• Contact Overview
• Typical Applications & Contact Classifications
• Contact Stiffness
• Basic Concepts & Determining a Value
• Friction Contact and Auto Timestepping
• Surface-to-Surface Elements
• Advanced Options for Special Problems
• Rigid Surface Considerations
• Creating without the Contact Wizard & Troubleshooting
• Node-to-Node Elements
• Node-to-Surface Elements
• Bolt Pretension Elements
• PRETS179 Element and Typical Procedure

Each course chapter is followed by "hands-on" workshops and exercises.

Focuses on element selection and the wide range of constitutive models available in ANSYS. Rate-independent plasticity, viscoplasticity/creep, and hyperelasticity are some of the topics which will be discussed. Geometric instability problems and element birth and death will also be covered.

Attendees will learn the appropriate element formulations to use, the input of nonlinear material parameters, and the applicability of the various constitutive models for engineering use.

Prerequisite: Basic Structural Nonlinearities

Course Topics Include:

• Introduction
• 18x Continuum Elements
• 18x Beam Elements
• 18x Shell Elements
• Advanced Rate-Independent Plasticity
• Creep
• Viscoplasticity
• Hyperelasticity
• Viscoelasticity
• Shape Memory Alloy
• Gaskets
• Geometric Instability: Buckling
• Element Birth and Death

Each course chapter is followed by "hands-on" workshops and exercises.

The course is intended both for new users of AQWA and intermediate users who are only required to attend the second two days.

The course will cover the general use of features within the AQWA Suite and introduce new advanced capabilities in AQWA. An introduction to the expanded Cable Dynamics capabilities will also be included. The latter is licensed as an additional module and permits coupled cable dynamics associated with deeper waters to be addressed.

Programs covered include:

• AQWA-LINE: Wave Diffraction/Radiation Analysis

• AQWA-LIBRIUM: Equilibrium and Stability Analysis

• AQWA-FER: Frequency Domain Analysis. Short Crested Waves + Cable Dynamics

• AQWA-NAUT: Non-linear Analysis in Time Domain (regular waves) + Cable Dynamics

• AQWA-DRIFT: Time Domain Analysis in Irregular Waves for Mooring Systems + Cable Dynamics

• AQWA-Graphical Supervisor: Mesh Generation, Model Visualisation, Animation, Post Processing, Graphing, Analysis Functions and Cable Dynamics.

Prerequisites

The three day course will be of major benefit to all engineers intending to perform hydrodynamic analysis of offshore structures using AQWA. No previous AQWA exposure is required but some knowledge of naval architecture or offshore engineering is desirable. The 2 day intermediate level will be of benefit to existing AQWA users both to introduce the many new capabilities and as a refresher course.

Format

The lectures are interspersed with "Hands on Sessions" that demonstrate the application of each of the modules.

For private courses we recommend a maximum of four attendees.

Topics Covered

Day 1 (first day of full course)

Introduction to AQWA programs and their capabilities
AQWA analysis procedures
Overview of AQWA input data
Element types and definitions in AQWA

Workshops:

Mesh generation using AQWA-GS
AQWA-LINE data preparation and analysis
Finding equilibrium position using AQWA-LIBRIUM and AGS

Day 2 (first day of intermediate course)

New features
Multiple structure definition and hydrodynamic interaction
Added mass and damping
Environment definition
Mooring systems
Frequency domain analysis

Workshops:

Performing frequency domain analysis using AQWA-FER and AGS for both long crested and short crested waves.

Day 3

Time domain analysis in regular and irregular waves for moored structures. AQWA-NAUT and AQWA-DRIFT
Convolution
Cable Dynamics Stand Alone & Fully Coupled

Workshops:

AQWA-NAUT analysis for regular waves
AQWA-DRIFT analysis for irregular waves
Data post-processing using AGS
Animation in AGS

Trouble shooting
Question & Answer Session related to user defined problems.
Workshop - Coupled Cable Dynamics.

Note that order of topics listed above may change during the course.

Getting Started - ASAS Modular Courses

The ASAS suite is formulated into a number of packages covering general finite element analysis, offshore structure analysis and non-linear analysis (with offshore specific features). The training courses are structured so that individuals can attend parts which are relevant to them. Thus new, intermediate level or advanced users can all benefit. Depending on the requirements courses last from one to five days. The topics below provide an outline of materials covered for the majority of ASAS modules/packages.

A major part of the course will center on the workshop and tutorial sessions.

Prerequisites

The courses will be of major benefit to all engineers working or intending to work with ASAS. As a pre-requisite it is expected that attendees have had some exposure to ASAS or a similar system. Also those engineers wishing to perform non-linear analysis (ship impact/compliant structures etc.) using ASAS(NL) will find the course particularly beneficial.

Format

The description below relates to the full ASAS suite including modeling using FEMGV, basic ASAS, ASAS-OFFSHORE modules and ASAS(NL). Depending on your requirements, the contents and/or duration can be modified as necessary. For example a standard ASAS-OFFSHORE course is 3 days and a standard ASAS(NL) course is 2 days. Lectures are interspersed with "Hands on Sessions" that demonstrate the applicability of ASAS to real life problems.

For private courses we recommend a maximum of four attendees.

Topics Covered

Basic ASAS
Overview

Program structure
Capabilities
Performing analyses - project concept
Finite element types
Boundary conditions
Loading

Model Generation using FEMGV

Topology definition
Properties
Creating ASAS data files

Performing Analysis

Creating models and managing analyses
Use of @file
Using ASAS Visualizer
Using FEMGV

Tutorials

ASAS-Visualizer
FEMGV for results post-processing

Dynamic Analysis

Natural Frequency

Post processing

Use of ASAS-POST
AXL-ASAS interface

Tutorial

Report Formatting using AXL interface

ASAS-OFFSHORE
Overview

Wave/Mass loading
BEAMST (code checks)
AXL Post processor interface

Tutorials

Code Check Analysis
Using AXL for post processing
Using Visualizer for post-processing

Dynamic Analysis

Dynamic Response in relation to Offshore Analysis

Tutorial

Dynamic Analysis

Introduction to Advanced features

Soil-Pile-Structure Interaction - SPLINTER
Fatigue of Jackets - FATJACK

ASAS(NL)
Overview

Sources of Non-Linear analysis
Pitfalls & problems
ASAS(NL) capabilities

Non-Linear Solution Procedures

Incremental
Iterative
Variable load methods
Solution control

Tutorial

Converting from Linear to Non-Linear
Using new ASAS 14 presentation tools

Types of Non-Linear Analysis

Material non-linearities
Plasticity models
Composite failure

Coupled Wave-Structure Interaction

Tutorial

Compliant structure analysis

This course is designed for new users who want to become proficient with AUTODYN. You will focus on learning core-modeling skills in this comprehensive, hands-on course. After completing the course you will be well prepared to work effectively on a wide range of transient dynamics applications.

Prerequisites

• A basic knowledge of dynamics and strength of materials (material modeling) is highly recommended.
• Knowledge of the physics of transient dynamics events is also recommended.

Format

This is a three-day course for AUTODYN held at our offices around the world at regular intervals throughout the year. Due to the number of hands-on exercises and scope of materials covered, attendance is limited to 6 people.

Course Outline:

1. Introduction

2. AUTODYN User Interface

3. Problem Setup
   • Hands-on (2D Cylinder Impact)

4. Lagrange Solvers
   • Solids, Shells, Beams
   • Lagrange Joins
   • Hands-on (3D Shell/Beam Structure)

5. AUTODYN in Workbench
   • Hands-on (3D Bullet Impact)

6. Lagrange-Interactions
   • Hands-on (2D Fragment Impact)
   • Hands-on (3D Sheet Metal Forming)
   • Hands-on (3D Helmet Impact)

7. Euler Solvers
   • Hands-on (2D Jet Penetration)
   • Hands-on (3D Urban Blast)

8. ALE Solver

9. Mesh-free Solver
   • Hands-on (3D Bird Strike)

10. Material Models
    • Equations of State
    • Material strength
    • Hands-on (Simple stress wave)
    • Material failure
    • Concrete, hyper-elastic and orthotropic materials
    • Layered shells
    • Rigid materials
    • Reactive materials
    • Hands-on (Detonation)
    • Material libraries
    • Material modelling guidelines

11. Euler-Lagrange Interactions
    • Hands-on (2D Contact Charge)
    • Hands-on (3D Pipe Bomb)
    • Hands-on (3D Ship Blast)
    • Hands-on (3D Mine Blast)

12. Tutorial Problems

The Material Modelling in ANSYS AUTODYN advanced training course will cover advanced topics that are not covered during our introductory training courses. The course will cover advanced aspects of material modelling for metals, ceramics, concrete, and fibre composites under dynamic shock wave loading. The course will last 1 day with the majority of the time dedicated to lectures. Hands-on example calculations will be used to demonstrate some of the key points.

This 1 day advanced ANSYS AUTODYN training course will the use of user subroutines. Topics covered will include an introduction to AUTODYN's user-subroutines capabilities, compilers and debugging environment and several example user subroutines for typical applications.

The ANSYS AUTODYN in Workbench training course covers an overview of DesignModeler and meshing for use with ANSYS AUTODYN for explicit dynamics simulations. The course will last 1 day with the majority of the time dedicated to hands-on example calculations.

The AUTODYN Workshop course is made available for attendees of the AUTODYN Introductory Training course, who wish to work with the assistance of our technical staff to set up simulations of a specific problem of interest. It is offered on the day after the AUTODYN Introductory Training course is held.

Prerequisites

• The AUTODYN Introductory Training course

This course is designed to expose ANSYS CFX users to advanced topics in CFD and fluid flow. The course covers the governing equations, boundary conditions, and numerical topics such as discretization and Convergence ( pertinent to ANSYS CFX). Specialized topics in heat transfer, turbulence modeling, non-Newtonian effects, buoyancy, and compressible flows are covered.

ANSYS CFX is a fluid analysis software tool that combines CAD input, automatic meshing and a fast solution algorithm. The ANSYS CFX Combustion and Radiation course is a two-day advanced course covering modeling approaches for combustion & radiation, usage of models available in ANSYS CFX, and useful tips for modeling. Students should have completed the Introductory course or have experience running ANSYS CFX.

The ANSYS CFX User Fortran course is a one-day advanced course that will enable you to customise your simulations through use of ANSYS CFX Command Language (CCL), ANSYS CFX Expression Language (CEL), Embedded Perl in CCL, User CEL functions and Junction Box routines.

ANSYS CFX is a fluid analysis software tool that combines CAD input, automatic meshing and a fast solution algorithm. The ANSYS CFX Introductory Course is a three-day course and consists of lectures and "hands-on" practical examples. Basics of geometry creation, grid generation, physical model specification, solution, and post-processing are covered. Please note that only introductory material and related applications will be addressed.

Includes Introduction to DesignModeler and Meshing Application training.

The Jump Start program is a one-on-one course comprised of basic theories and problem setup using ANSYS CFX pertaining to a particular area of student's interest. Guidance in grid generation, assistance with solution strategies and advanced modeling techniques are also provided.

ANSYS CFX is a fluid analysis software tool that combines CAD input, automatic meshing and a fast solution algorithm. The ANSYS CFX Multiphase course is a two-day advanced course covering modeling approaches for multiphase flows, usage of models available in ANSYS CFX, and useful tips for modeling. Students should have completed the Introductory course or have experience running ANSYS CFX.

This course covers advanced topics in turbulence modeling, viz, two equation turbulence models like k-epsilon, k-omega, SST, wall functions, 2nd order Reynolds Stress models, a discussion of large eddy simulation, Detached eddy simulation and transition modeling. The course includes modeling tips and practical examples.

This day involves working on the user's own problem with the guidance of an instructor to show how to best setup ANSYS CFX to solve the user's application problem on his/her own geometry.

It is advisable to provide the geometry in advance of the actual training day to allow the instructor to examine the files and do a small amount of prepatory work in advance if necessary.

The User Supervised Day allows the trainee to continue to use the ANSYS CFX software on the type of problems of interest to the trainee. These problems would consist of additional tutorials or simple problems suggested by the instructor. The instructor is available to provide guidance and discuss best approaches to setting up the problems.

ANSYS CFX-BladeGen provides turbomachinery designers with a complete system for 3-Dimensional (3-D) blade design and evaluation. The ANSYS CFX-BladeGen Introductory Training Course is a one day offering which includes importing geometry from a preliminary design package, using ANSYS CFX-BladeGen for rapid design/modifications and Blade Analysis using ANSYS CFX-BladeGen Plus.

ANSYS CFX-TASCflow is an advanced, fully coupled, algebraic multigrid CFD package. The ANSYS CFX-TASCflow Introductory Training Course is a two-day course covering problem setup, solution and post processing analysis. The introductory training is done with small groups, not exceeding 6 trainees in a session.

Optional Thursday and Friday sessions are available where participants will be trained further in their particular area of application; guidance in grid generation and assistance with solution strategies are also provided. These sessions are one on one sessions with participant and trainer.

Courses are flexible and some customization may be available. Please inquire.

The ICEM CFD Hexa for ANSYS CFX training course is for users needing advanced meshing techniques for complex geometries to generate structured or unstructured hexahedral meshes for use with ANSYS CFX software.

Course Topics Include:

• Navigating within the Graphical User Interface
• Importing CAD models
• Preparing model
• Hexa meshing for structured or unstructured volume grids

Each course chapter is followed by "hands-on" workshops.

ICEM CFD Hexa is the industry leading general-purpose hexahedral meshing tool offered through ANSYS. The ICEM CFD Hexa Introductory training course is a one day offering which includes, importing CAD geometry using direct CAD interfaces, geometry manipulation tools, generating hexahedral meshes, mesh editing and exporting to ANSYS CFX.

ICEM CFD is a meshing tool which can start from geometry in many formats and easily create tetrahedral meshes for use in ANSYS CFX.

The ICEM CFD Introductory training course is a one day offering which covers importing geometry, geometry repair and modification tools, generating tetrahedral and prism meshes, mesh editing and exporting to ANSYS CFX.

Hands-on workshops accompany each topic in order to maximize the benefit of the course.

The ICEM CFD/AI*Environment training course is for users needing advanced meshing techniques for complex geometries. It is now geared to cover the pre-processing needs for all analytical applications including computational fluid dynamics, finite element (structural), electromagnetics and other simulation modeling.

Course Topics Include:

• Navigating within the Graphical User Interface
• Creating/manipulating geometry
• Importing CAD models
• Preparing model
• Tetra/hybrid meshing from original CAD and/or existing surface mesh
• Prism element extrusion for boundary layer mesh
• Hexa meshing for structured volume grids
• Creating connectors, welds
• Mesh editing/quality improvement
• Prescribing material properties, loads and constraints
• Hands on session using trainees' own geometries

Each course chapter is followed by "hands-on" workshops. Topics will be covered on an as needed basis.