TRAINING 2014
In Summa Innovation
Training Catalogue 2014
Exclusive BeNeLux agent of MSC.Software
Oeverkruid 15
4941 VV Raamsdonksveer
The Netherlands
T: +31 162 524000
mscsales@insumma.nl
www.insumma.nl
www.rendementmetsimulatie.nl
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TRAINING 2014
Content
Content................................................................................................................................................................................... 2
About MSC Software ............................................................................................................................................................ 4
Solutions ................................................................................................................................................................................ 4
Specialist for Acoustic calculations ........................................................................................................................................ 5
Specialist for material data and simulations of composites ................................................................................................... 5
MSC Ecosystems .................................................................................................................................................................. 6
Student Edition ...................................................................................................................................................................... 6
Research Assist Program ........................................................................................................................................................ 6
FEA Masters Program ............................................................................................................................................................. 6
Registered Consultants .......................................................................................................................................................... 6
Training .................................................................................................................................................................................. 7
Offering .................................................................................................................................................................................. 7
Registration ............................................................................................................................................................................ 7
Discounts................................................................................................................................................................................ 7
MSC Learning Center.............................................................................................................................................................. 7
Calendar and training fees ..................................................................................................................................................... 8
ACT101- Introduction into Actran ....................................................................................................................................... 9
Actran ..................................................................................................................................................................................... 9
ACT101- Introduction into Actran .......................................................................................................................................... 9
Adams .................................................................................................................................................................................. 10
ADM701 - Basic Full Simulation ........................................................................................................................................... 10
ADM703a – Advanced Modeling Elements and Techniques with Adams/Solver ................................................................ 11
ADM703b – Adams/Solver Theory: Achieving Robust, Converged Solutions ...................................................................... 11
ADM703c – Writing User Subroutines in Adams/Solver ...................................................................................................... 12
ADM704a – Advanced Parametric Model Building in Adams/View ..................................................................................... 13
ADM704b – Automating Tasks using Adams/View .............................................................................................................. 13
ADM710 - Flex Body Dynamics and Modal Stress Recovery using Adams ........................................................................... 14
ADM711 – Control System Integration with Adams using MATLAB and Easy5.................................................................... 15
ADM730 – Design of Experiments (DOE) and Stochastics (Monte Carlo) Analysis using Adams ......................................... 16
ADM740 – Vehicle Modelling and Simulation using Adams/Car .......................................................................................... 16
ADM750 – Gear, Belt, and Chain Modeling with Adams/Machinery ................................................................................... 18
Digimat ................................................................................................................................................................................. 19
DIG201 - Digimat Standard Training – Structural Engineering ............................................................................................. 19
DIG201 - Digimat Standard Training – Material Engineering ............................................................................................... 19
Dytran ................................................................................................................................................................................... 20
DYT101 - Introduction to Lagrangian Analysis Using Dytran ................................................................................................ 20
DYT102 - Introduction to Eulerian and Coupled Analysis Using Dytran ............................................................................... 21
Easy5 .................................................................................................................................................................................... 22
EAS101 - Easy5 Dynamic System Modelling Simulation and Analysis using Easy5 (Intro Class) ........................................... 22
EAS103 - Easy5 Modelling Simulation of Fluid Power Systems Using Easy5 ........................................................................ 23
EAS105 - Modelling Simulation of Gas Systems Using Easy5 ............................................................................................... 24
Flightloads ........................................................................................................................................................................... 25
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TRAINING 2014
FLD120 – Introduction to MSC Nastran Aeroelasticity using Flightloads and Patran ........................................................... 25
Marc ...................................................................................................................................................................................... 26
MAR101 – Marc Introductory Course .................................................................................................................................. 26
MAR102 - Marc/Mentat Advanced Course .......................................................................................................................... 26
MAR103 – Marc Experimental Elastomer Analysis .............................................................................................................. 26
MAR106 – Electromagnetic Analysis Using Marc ................................................................................................................. 27
MAR120 - Marc/Patran Introductory Course ....................................................................................................................... 28
MAR299 - Marc Programming Course ................................................................................................................................. 28
MSC Nastran ........................................................................................................................................................................ 29
NAS101 - Basic MSC.Nastran Linear Static, Normal Modes and Buckling Analysis .............................................................. 29
NAS102 - MSC.Nastran Dynamic Basic Analysis ................................................................................................................. 30
NAS103 - Nonlinear Analysis ................................................................................................................................................ 31
NAS104 - Thermal Analysis with MSC.Nastran ..................................................................................................................... 32
NAS105 - Practical Finite Element Modelling Techniques Using MSC.Nastran .................................................................... 32
NAS106 - Superelement Analysis with MSC.Nastran ........................................................................................................... 34
NAS107 - Optimisation with MSC.Nastran ........................................................................................................................... 35
NAS110 - Working with Custom MSC Nastran Solution Sequences using DMAP................................................................. 36
NAS120 - Linear Structural Analysis with MSC.Nastran and Patran ..................................................................................... 37
NAS122 - Dynamic Structural Analysis with MSC.Nastran and Patran ................................................................................. 37
NAS123 – MSC Nastran Implicit Nonlinear (SOL 600) Analysis ............................................................................................ 39
NAS126 – Explicit Nonlinear Analysis using MSC Nastran and Patran ................................................................................. 40
NAS400 - Implicit Nonlinear Analysis using MSC Nastran and Patran .................................................................................. 41
Patran ................................................................................................................................................................................... 42
PAT301 - Introduction to Patran .......................................................................................................................................... 42
PAT302 - Advanced use of Patran ........................................................................................................................................ 43
PAT304 – Introduction to Patran Command Language (PCL) ............................................................................................... 44
PAT318 - Durability and Fatigue Analysis using MSC.Fatigue............................................................................................... 44
PAT319 - Fatigue Analysis of Dynamically Responsive Systems using FEA ........................................................................... 45
PAT325 - Composites Analysis Using Laminate Modeller .................................................................................................... 46
SimXpert .............................................................................................................................................................................. 47
SMX101 - Introduction to SimXpert ..................................................................................................................................... 47
SMX120 - SimXpert Linear Static Analysis ............................................................................................................................ 48
SMX121 - SimXpert Motion Analysis .................................................................................................................................... 48
SMX126 - Introduction to SimXpert MD Explicit Workspace ............................................................................................... 49
SMX131 - SimXpert Templates ............................................................................................................................................. 50
Sinda .................................................................................................................................................................................... 51
SND501 - Network Thermal Analysis Using MSC Sinda ........................................................................................................ 51
SND502 - Thermal Analysis Using Patran with MSC Sinda ................................................................................................... 52
SND503 - Spacecraft Thermal Analysis Using THERMICA V4................................................................................................ 53
Contacts ............................................................................................................................................................................... 54
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TRAINING 2014
About MSC Software
Simulating Reality, Delivering Certainty
MSC Software is one of the ten original software companies and the worldwide leader in multidiscipline simulation. As a trusted
partner, MSC Software helps companies improve quality, save time and reduce costs associated with design and test of
manufactured products. Academic institutions, researchers, and students employ MSC technology to expand individual knowledge
as well as expand the horizon of simulation. MSC Software’s engineering simulation technology is used by leading manufacturers for
linear and nonlinear finite element analysis (FEA), acoustics, fluid-structure interaction (FSI), multi-physics, optimization, fatigue and
durability, multi-body dynamics, and control systems simulation. The company’s products accurately and reliably predict how
products will behave in the real world to help engineers design more innovative products - quickly and cost effectively.
MSC Software Corporation was formed in 1963 and was awarded the original contract from NASA to commercialize the finite
element analysis (FEA) software known as Nastran (NASA Structural Analysis). MSC pioneered many of the technologies that are
now relied upon by industry to analyse and predict stress and strain, vibration & dynamics, acoustics, and thermal analysis in our
flagship product, MSC Nastran. Today MSC is a privately owned company of the Symphony Technology Group and provides an
extensive range of CAE solutions.
Solutions
Over our rich history, MSC has developed or acquired many other well-known
CAE applications including Patran, Adams, Marc, Dytran, Fatigue, SimXpert,
SimDesigner, SimManager, Easy5, Sinda, and Actran. We are committed to the
continued development of new CAE technology that integrates disciplines and
technologies from standalone CAE tools into unified multi-discipline solvers and
user environments. These “next generation” products enable engineers to
improve the reliability and accuracy of their virtual prototypes by including
multi-physics and multi-discipline interactions. MSC is also the CAE industry’s
leader in extending simulation to the engineering enterprise. Our customers
recognize the need to scale the benefits of virtual prototyping and testing from
pockets of experts to mainstream engineering and product development, and
MSC offers the only Simulation Data and Process Management platform in the
world that has been successfully deployed in industries including automotive,
aerospace, shipbuilding, electronics, and more MSC Software employs 1,000
professionals in 20 countries.
MSC Software makes products that enable engineers to validate and optimize
their designs using virtual prototypes. Customers in almost every part of manufacturing use our software to complement, and in
some cases even replace the physical prototype “build and test” process that has traditionally been used in product design.
Structural Analysis and Finite Element Method (FEA)
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
MSC Nastran: Solver for multidisciplinary simulation such as linear and nonlinear structure analysis in the areas of statics,
dynamics, acoustics and optimisation.
Marc: Solution for advanced nonlinear structural analysis, contact, complex material models and multiphysics analysis
Multibody Dynamics (MBD)

Adams: Solver for simulation mechanical systems
Modelling

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Patran: Pre- and Postprocessor for modelling, Geometry manipulation and loads specification
SimXpert: Integrated multidisciplinary work environment for modelling, calculating, result processing, report generation
and automation
Entry solutions


MSC Nastran Desktop: Modular solution for structure analysis of any kind
FEA, AFEA, TFEA: Linear, nonlinear and thermal analysis
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
SimDesigner: CAD-integrated, multidisciplinary simulation solutions
Special Solutions



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MSC Fatigue: Calculation of endurance and lifespan
Dytran: Simulation of structures and fluids in the short time dynamics area
Sinda: Advanced Thermal Simulation
Easy5: Advanced Controls & Systems Simulation
Simulation Data Management (SDM)


SimManager: Web-based hardware independent system for the administration and automation of simulation data and
processes
MaterialCenter: Web-based Materials Lifecycle Management System for managing material models, data and processes
with full tracebility
Toolkits


Advanced Wind Turbine Modelling (AdWiMo): Customised tool for modelling of wind turbines
Adams Tracked Vehicle (ATV): Customised tool for modelling of tracked vehicles
Specialist for Acoustic calculations
Free Field Technologies (FFT) develops and supports the Actran family of acoustic CAE products. Actran is a
premier acoustics software solution for simulating acoustics, vibro-acoustics and aero-acoustics quickly,
easily, and accurately.
More information available at www.fft.be.
Specialist for material data and simulations of composites
The company e-Xstream is a specialist for micro mechanisms and multiscale simulation and
concentrates on the calculation of composites.
The Software Digimat is able to construct and simulate the reaction of non-linear composites. This is important for the users of
Finite Element (FE) - Software as they want to determine the influence of the microstructure of a material on the stability of the end
product.
In combination with the simulation tools of MSC, e-Xstream enables the simulation of a variety of materials. The core aspects lie
within the exact determination of material failure, micro mechanic material calculation and non-linear, multi scalable structure
modelling.
More information available at www.e-xstream.com
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TRAINING 2014
MSC Ecosystems
Student Edition
MSC Software's Student Editions provide students with the simulation tools to accurately and reliably predict how the designs will
behave in the real world. Employers are constantly relying on simulation software to help eliminate slow and costly physical testing,
and with experience right out of school, students will be ready to begin a career in no time! You can download free licences for MSC
Nastran, Patran, Adams, Marc and SimXpert. All licenses can be downloaded in the “student centre“ on the MSC Software website.
Students will need to present an electronic copy of a valid student ID.
More information available at http://www.mscsoftware.com/contents/Academia/Student-Center/Default.aspx
Research Assist Program
The MSC Software Research Assist Program is a new ecosystem development program aimed at stimulating innovation within
research and academic communities. Our mission is to collaborate with passionate researchers around the world to persistently
explore the horizon of engineering simulation together. By applying simulation methods in new ways, we can jointly develop the
technology and products of tomorrow.
More information available at www.mscsoftware.com/contents/Research-Assist-Program
FEA Masters Program
MSC has partnered with UNED, Spain's largest online university to offer you the chance to obtain an advanced degree in Finite
Element Method and CAE Simulation. The National Distance Education University (UNED) is the leader in the implementation of
cutting edge technologies applied to distance learning with over 205,000 students worldwide. It is one of the largest universities in
Europe. The course is designed to help you acquire knowledge, develop critical thinking and analytical skills at every stage of your
program. It helps prepare you for the multidisciplinary challenges you will face in the new global economy, and position yourself for
professional recognition, increased pay and new roles at your current or future employer.
More information available http://www.mscsoftware.com/Contents/FEAMasters/Default.aspx
Registered Consultants
The Registered Consultant program is intended to supplement the highly demanded MSC Software Global Engineering Services
Organization with independent consultants who join the team to deliver high value simulation results to MSC customers.
Consultants who are accepted into the Registered Consultant program become an extension of the MSC Engineering Services team.
Once accepted, consultants are eligible to receive many benefits including the opportunity to apply their skills by working on
assigned engineering simulation projects such as mentoring, on-site simulation projects, implementation, knowledge transfer, and
training for leading manufacturing companies around the world.
More information available at http://pages.mscsoftware.com/RegisteredConsultantProgram.html
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Training
Offering
MSC offers basic and specialised training in the use of our simulation tools to maximize your investments in our software. Whether
you need an introduction to our simulation tools or expert instruction in specialised applications, we offer the courses you want,
with the expertise you deserve.
The trainings in the Benelux will either be held in the In Summa Innovation office or onsite.
Flexible Training
Our Trainers will not only demonstrate the use of the software, they will also help you find the best solutions for your specific
needs.
To ensure this promise we offer three different types of training:
Public Classroom Training
All courses are available in our state-of-the-art classroom facilities and individual computer graphics laboratories at training
centres throughout the world. Our courses place heavy emphasis on hands-on computer laboratory work to accelerate practical
skills development for all MSC Software products.
Training at Your Facility
If you have a number of employees who need training, we offer the cost effective option of bringing our class to your facility.
Available worldwide, onsite training is ideal for groups of engineers or those who need customised instruction on MSC
products. To maximize productivity in the use of our simulation tools, instructors can tailor the curriculum with companyspecific or industry-specific examples, and address challenges and process issues familiar to attendees from your organization.
Customised Courses
If our standard seminar offerings do not meet your training requirements, MSC can develop a course or set of courses tailored
to your specific needs. A customised course might include a combination of topics from several standard courses or specialised
material not found in any of our standard seminars. MSC will work with your staff to design the course you need.
Registration
This Catalogue contains a selected range of courses that are offered in the United Kingdom. Some courses are already scheduled for
any further queries or to book training please contact us at info@insumma.nl .
To ensure that we can plan our courses adequately please contact us and register no later than 14 days prior to the planed begin of
the course.
Prices mentioned below are per person and a minimum of three attendees are required for a public classroom training to go ahead.
Prices for training at your facility or customised courses are negotiable.
Discounts
We offer discounts for companies who send more than one person to the same course on the same dates.
Every additional person receives a 20% discount.
MSC Learning Center
MSC Learning Center is a platform and ecosystem designed to provide easy, flexible and affordable access to learning simulation
software, leveraging content developed by both MSC and the market place. As part of the MSC Learning Center we offer from 2014
On-Demand Training Subscriptions on our on-line platform.
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TRAINING 2014
Calendar and training fees
Please contact mscsales@insumma.nl for information about scheduled and special trainings and training fees.
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TRAINING 2014
ACT101- Introduction into Actran
Actran
ACT101- Introduction into Actran
Objective
This seminar will cover the basic capabilities of Actran for Vibro-Acoustic and Aer-Acoustic application.
Content
 Introduction
 Actran general organisation, introduction concepts, introduction modelling process and launching
 Vibro-Acoustic direct simulation
 Vibro-Acoustic modal simulation
 Fluid/Structure coupling
 Random excitations
 Composite materials
 Modelling prestress effects
 Aero-Acoustic simulations
 Aero-Acoustics general organisation
 Aero-Acoustics advanced
 Workshops
Prerequisites
Basic theoretical knowledge of acoustics is recomended.
Dates
On Request
Duration
4 Days
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Adams
ADM701 - Basic Full Simulation
Objective
This seminar will cover the basic essentials required to get new users up and running with Adams.
Content
 Model Hierarchy
 Adams/View Interface
 Post Processing
 Co-ordinate systems
 Geometry Manipulation
 Measures
 Initial Conditions and Velocities
 Degree of Freedom Constraints
 Friction Modelling
 Motions
 Function Builder
 Forces
 Simulation Scripts
 Bushings
 Contact
 Sensors
 Design Variables
 Splines
 Simple Design Studies
Prerequisites
None
Dates
On Request
Duration
5 Days
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TRAINING 2014
ADM703a – Advanced Modeling Elements and Techniques with Adams/Solver
Objective
This seminar is intended for moderately experienced Adams users wanting to expand their knowledge of advanced modeling
elements and techniques in Adams/Solver. Advanced modeling elements are entities such as the discrete flex link in
Adams/View, the general constraint (GCON) and the differential equation (DIFF) elements. The use of these elements with
scripting & function expression logic, new SENSOR functionality and advanced function expressions in Adams/Solver will be
discussed.
Content
 Controlling model topology during simulation
 Differential equations for integrating quantities and describing system dynamics
 Implementing simple control algorithms
 Performing standalone Adams/Solver simulations in batch mode.
 Using Adams/Linear as a tool to inspect the system-level linear modes
 Implementing test data via splines
 Advanced simulation logic using SENSORs
 Complex constraints (GCON element)
Prerequisites
A working knowledge of Adams as covered in ADM701
Dates
On Request
Duration
1 Day
ADM703b – Adams/Solver Theory: Achieving Robust, Converged Solutions
Objective
This seminar is intended for experienced Adams users wanting to expand their knowledge of Adams/Solver theory. An emphasis
will be put on tying theoretical concepts back to Adams/Solver solution settings (ERROR, HMAX, SI2, MAXIT, etc.). Strategies for
creating robust models and sensible solution control settings will be a focus of the course. The various phases of solution
(statics, kinematics, dynamics) will be covered in detail and best practices for each will be identified.
Content
 Mathematical descriptions of constraints, body and forces
 Theoretical workings of the static, kinematic and dynamic solvers in Adams
 Numerical Methods for root finding, explicit and implicit integration
 DEBUG/EPRINT interpretation for model debugging
 Error handling strategies for statics and dynamics
 Solver settings for robust static analyses
 Integrator settings for robust dynamics
 Solution convergence techniques
 Modeling best practices
Prerequisites
A working knowledge of Adams as covered in ADM701 and ADM703a.
Dates
On Request
Duration
2 Days
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TRAINING 2014
ADM703c – Writing User Subroutines in Adams/Solver
Objective
This seminar is intended for experienced Adams users wanting to create Adams/Solver user subroutines. Initial setup with preexisting libraries is considered, followed by the types of Adams/Solver elements which can be over-ridden. Dealing with user
input is considered along with usage of the many built-in utility subroutines. Querying Adams/Solver for system state
information (displacements, velocities, forces, etc.) is covered in detail, followed by initialization (IFLAG) and differencing
(DFLAG) considerations. Callback subroutine functionality is presented for easy detection of simulation events (convergence,
simulation start/end, saving/reloading, etc.) and considerations for threadsafe computations are discussed.
Students are expected to be comfortable with simple programming tasks in Fortran; this class does not provide a formal nor
comprehensive introduction to the Fortran programming language.
Content
 Using existing Adams/Solver libraries
 Element types to over-ride, what is to be calculated
 Inputs using the PAR array
 Interface differences between Fortran and C
 Querying system states using utility subroutines
 Handling initialization and differencing calculations
 Callback subroutines
 Threadsafe computation considerations
Prerequisites
A working knowledge of Adams as covered in ADM701 and ADM703a. Moderate knowledge of Fortran programming language.
Dates
On Request
Duration
1 Day
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TRAINING 2014
ADM704a – Advanced Parametric Model Building in Adams/View
Objective
This seminar covers the process of building parametric models specifically for the use of design sensitivity and optimisation
studies.
Content
 Parametric Modelling
 Parametric Functions
 Expression builder
 Design Study
 Design of Experiments
 Optimisation
Prerequisites
A working knowledge of Adams as covered in ADM701
Dates
On Request
Duration
2 Days
ADM704b – Automating Tasks using Adams/View
Objective
This seminar covers the process of customising Adams through the use of macros and developing customer specific dialogue
boxes.
Content
 Command Language
 Conditional Constructs and Loops
 Macros
 Macro Syntax and Parameters
 Dialogue Boxes
 Plug-ins
Prerequisites
A working knowledge of Adams as covered in ADM701.
Dates
On Request
Duration
2 Days
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TRAINING 2014
ADM710 - Flex Body Dynamics and Modal Stress Recovery using Adams
Objective
You will learn how to use Adams/Flex to incorporate flexibility into your Adams models. The course is primarily focused on using
component modal synthesis via the Modal Neutral File (MNF) and Adams/View. Previous FEA experience is a plus, but not a
requirement. You will be comfortable using Adams/Flex after taking this course
Content
 Modal Flexibility: Theoretical background, combined rigid-flexible equations of motion
 Importing a flexible body into a rigid-body model
 Working with flexible body models in Adams/View (mode manager, connect flexible part to rigid parts, add forces/torques,
use measures)
 Adams/Solver dataset and Adams/View command language syntax
 Using flexible body models with stand-alone Adams/Solver (edit .adm files, generate .mtx files, submit simulations)
 Performing static, dynamic, and eigenvalue analyses
 Exporting loads from Adams/View
 Methods for optimizing MNFs
 Comparing results of rigid and flexible models (plotting, animation)
 Validating Adams/Flex results with FEM results and hand-calculations
 Modelling considerations
 Debugging
 Modelling contact with a flexible body
 Using a modal force (MFORCE) to define a pressure load
 Publishing simulation results on the web (generate movies, table of eigenvalues, snapshot images, include model files)
 Reviewing several application examples
 Reviewing/Discussing methods for generating MNF from FEA packages
 Adams/AutoFlex
Prerequisites
A working knowledge of Adams as covered in ADM701
Dates
On Request
Duration
2 Days
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ADM711 – Control System Integration with Adams using MATLAB and Easy5
Objectives
You will learn how to connect your Adams models to control systems developed in MATLAB or Easy5. Techniques for combining
linear, nonlinear, continuous, and sampled control systems with your Adams model will be presented, along with tutorials.
Converting your MATLAB or Easy5 model into a native Adams entity via Control System Import to run the combined model
completely within Adams will also be discussed. Other topics presented in the course include an overview of all System
Elements, including State Variables, Differential Equations, Linear State Equations, and General State Equations to develop
models (e.g., control systems) supplemental to your mechanical model.
Content
 Adams/Controls terminology
 Defining inputs/outputs for Adams models to tie to controls
 Adams Interface elements provided by Adams/Controls for MATLAB, and Easy5
 Function evaluation mode and co-simulation mode
 Interactive and batch mode simulations
 Using initialization commands
 Control system examples with differential equations, transfer functions, linear state equations, and general state equations
 Examples using Control System Import with Easy5 and MATLAB
Prerequisites
A working knowledge of Adams as covered in ADM701.
Dates
On Request
Duration
1 Day
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TRAINING 2014
ADM730 – Design of Experiments (DOE) and Stochastics (Monte Carlo) Analysis using Adams
Objective
This seminar is intended for users who want to learn about their model designs in an efficient manner. This is accomplished
using Design of Experiments (DOE) techniques for learning about the design and communication of the results across companies
and departments. An optimal DOE technique is demonstrated, setting users up for further studies such as optimization and
robustness analysis.
Content
 Create Factors and Responses in your model
 Parametrics
 Classicial DOEs
 Results interpretation
 Using the ASCII Conduit
 Using Adams/Insight
 Monte Carlo Analysis and Correlation
Prerequisite
A working knowledge of Adams as covered in ADM701.
Dates
On Request
Duration
1 Day
ADM740 – Vehicle Modelling and Simulation using Adams/Car
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Objective
This seminar is divided into two sections. The first covers the requirements for the standard user such as running suspension
tests, vehicle manoeuvres and interrogating the results. The second covers the process of modifying the standard templates and
building new functioning templates such as those for the steering, suspension and wheels.
Content
 Description about user modes and data hierarchy
 Overview of database hierarchy
 Learning the concept of subsystems and assemblies
 Create new suspension and full vehicle models
 Create user specific events with the Driving Machine
 Setup suspension and full vehicle simulations
 How to use handling and durability tire
 Perform suspension and full vehicle simulations
 Create plot configuration files
 Good practice in creating a fully parametric vehicle model
 Create and modify templates
 Create and modify different type of parts
 Learn how to use communicators
 Learn how to create new requests within the same subsystem as well as between different subsystems
 Create and modify different property files
 Create and modify automotive elements such as spring, dampers, bushings, bump stop, etc.
 Overview on how to implement flexible bodies
Prerequisite
A working knowledge of Adams as covered in ADM701. General vehicle knowledge (vehicle dynamics, suspension design, etc.)
preferred.
Dates
On Request
Duration
4 Days
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ADM750 – Gear, Belt, and Chain Modeling with Adams/Machinery
Objectives
You will learn how to build detailed models containing belts, chains or geras with Adams/Machinery.
Content
 Introducing the Adams/Machinery Wizard
 Adams/Machinery Database Structure for Components, Parametrics, etc.
 Creating Gear Systems:
o Spur, Helical & Bevel Gear Types
o Simplified, Detailed & 3D Contact Types
 Creating Belt Systems:
o Smooth, V-Grooved & Toothed Belts
o Pulley Types: Standard and Tensioners
o Actuator Types and System Outputs
 Creating Chain Drive Systems:
o Roller and Silent Types
o Compliance Methods: From Linear to User-Defined
o Tensioner/Guide Types: Rotational, Fixed and Translational
 Simulation Speed and Robustness Guidelines for Typical Machinery Systems
Prerequisites
A working knowledge of Adams as covered in ADM701.
Dates
On Request
Duration
1 Day
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TRAINING 2014
Digimat
DIG201 - Digimat Standard Training – Structural Engineering
Objective
This seminar provides an introduction to how to use a Digimat material model in a FE analysis of a plastic or composite part that
has fiber orientations predicted by an injection modelling or draping simulation. By using a Digimat material model the nonlinear material properties and the effects of the local microstructure of the composite or plastic can ve taken into account. The
following Digimat modules will be used: Digimat-MF, Digimat-MX, Digimat-CAE and DIgimat-MAP
Content
 Technical information on the way the program operates, e.g. licensing, file organization,etc.
 Introduction to the Digimat Graphical User Interface including the plug-in embedded in CAE codes
 Mean-field homogenization theory as well as the material models available in Digimat-MF
 Material database management and automatic calibration of Digimat materials
 Coupling of Digimat with FEA code in Digimat-CAE. Introduction to the different solution procedure (macro, hybrid, micro)
and presentation of the failure criteria definition
 Mapping of fiber orientation tensors, initial stresses/temperatures between two dissimilar meshes in Digimat-Map.
Theoretical aspects of the mapping procedure are explained
 Guided exercises to implement the different procedures presented during the course
Prerequisites
Basic theoretical knowledge of material constitutive model (elasticity, elasto-plasticity) is recomended. Good knowledge of one
FEA code is required.
Dates
On Request
Duration
2 Days
DIG201 - Digimat Standard Training – Material Engineering
Objective
This seminar provides an introduction to how to use a Digimat material model in a FE analysis of a plastic or composite part that
has fiber orientations predicted by an injection modelling or draping simulation. By using a Digimat material model the nonlinear material properties and the effects of the local microstructure of the composite or plastic can ve taken into account. The
following Digimat modules will be used: Digimat-MF, Digimat-MX, Digimat-CAE and DIgimat-MAP
Content
 Technical information on the way the program operates, e.g. licensing, file organization,etc.
 Introduction to the Digimat Graphical User Interface
 Mean-field homogenization theory as well as the material models available in Digimat-MF
 Material database management and automatic calibration of Digimat materials in Digimat-MX



Introduction to designing RVE (representative volume element) for various composite microstructures including composites
with; multiple reinforcing phases, clustering, and decohesion zones, among others, using Digimat-FE
Exporting the RVE into FEA solver to run a finite element analysis on the material and post-processing of the results in
Digimat-FE.
Guided exercises to implement the different procedures presented during the course
Prerequisites
Basic theoretical knowledge of material constitutive model (elasticity, elasto-plasticity) is recomended. Good knowledge of one
FEA code is recomended.
Dates
On Request
Duration
2 Days
19
TRAINING 2014
Dytran
DYT101 - Introduction to Lagrangian Analysis Using Dytran
Objective
Dytran is designed to solve transient dynamic problems involving a high degree of nonlinearity. This seminar provides an
introduction to the Lagrangian capabilities of Dytran. The primary emphasis is on how to use the program to solve engineering
problems. The major capabilities of the program are covered in detail. The process of performing an analysis is discussed in its
entirety, from initial modelling to the postprocessing of results. Hands-on workshops and example problems reinforce the
material covered in the lectures. Advice is offered on modelling techniques, meshing, and evaluation of results. In addition,
techniques to minimize the cost of analyses are discussed. By the end of the seminar, attendees should be able to apply Dytran
to the solution of practical engineering problems in structural mechanics.
Content
 Overview of Dytran capabilities
 Differences between Lagrangian and Eulerian technology
 Overview of contact and Euler/Lagrange coupling techniques
 Typical applications
 Explicit transient dynamic analysis
 Introduction to explicit solution techniques
 Explicit versus implicit technology
 When to use explicit technology
 Input definition
 Overview of the input file
 Input file formats and data generation
 Running the analysis
 Modelling
 Description of the Dytran files
 Example input file
 Restarts and rezones
 Executing Dytran
 Basic concepts of Lagrange
 Element Library
 Material Models
 Lagrangian Loading Conditions
 Lagrangian Body Conditions
 Concept of Surfaces
 Contact
 Rigids
Prerequisites
Experience with a general-purpose finite element analysis application is recommended
Dates
On Request
Duration
1.5 Days
20
TRAINING 2014
DYT102 - Introduction to Eulerian and Coupled Analysis Using Dytran
Objective
Dytran is a coupled Euler-Lagrange code designed to solve fluid-structure interaction problems. This seminar complements the
DYT101 seminar, provides an introduction to the Eulerian processor, and shows how it can be coupled to the Lagrangian, or
structural parts, of the model. The emphasis of this seminar is on using the programs to solve engineering problems. The
capabilities of the program, including typical applications, are covered in detail. Hands-on workshops and example problems
reinforce the lecture material. Advice is offered on modelling techniques, choice of material models, and evaluation of results.
In addition, techniques to reduce the cost of analyses are discussed. By the end of the course, attendees should have a basic
understanding of how to solve fluid-structure interaction problems using an Euler-Lagrange approach.
Content
 When to use Eulerian and Euler-Lagrange coupling
 Typical applications
 Basic concepts of Euler
 Finite volume method
 General connectivity
 Computational cycle
 Euler mesh
 Euler loading, boundary and initial conditions
 Material models
 Workshop example on Euler
 General coupling of Fluid-Structure Interaction
 Arbitrary Lagrange Euler coupling
 Output requests
 Post processing
Prerequisites
DYT101 is recommended.
Dates
On Request
Duration
1.5 Days
21
TRAINING 2014
Easy5
EAS101 - Easy5 Dynamic System Modelling Simulation and Analysis using Easy5 (Intro Class)
Objective
This course gives the engineer a basic understanding of the Easy5 modelling, simulation, and analysis environment. Students
learn to represent an existing dynamic system on screen using predefined modelling blocks and components, empirical table
data, and user-defined FORTRAN components. Students learn to calculate stable operating points using the Easy5 Steady-State
Analysis, and are introduced to fixed- and variable-step integration used during simulation. The class also covers the Easy5 set of
linear analyses, including, in part, transfer function calculation, frequency response generation, and root locus analysis.
Content
 Model Building
 Linear Analysis
 Analysis Tool & Methodology
 Simulation and Integration
 Data Tables and the Matrix Editor
 Operating Point and Steady State Analysis
 Easy5 Architecture
 Writing Code in Easy5
Prerequisites
An engineering background, knowledge of FORTRAN, and an understanding of differential equations.
Dates
On Request
Duration
1.5 Days
22
TRAINING 2014
EAS103 - Easy5 Modelling Simulation of Fluid Power Systems Using Easy5
Objective
This course has been designed to give the hydraulics engineer a basic understanding of the issues and difficulties surrounding
modelling and simulation of fluid power systems. It is geared towards the user who already has a general understanding of the
Easy5 modelling, simulation and analysis environment as well as knowledge in the area of hydraulics design.
Content
 General Theory of Hydraulic Modelling in Easy5
 Modelling an Open Loop Oil Cooling System
 Obtain Initial Operating Points
 Fluid properties
 Modelling a Closed Loop Oil Cooling System
 Difficulties in obtaining steady state
 Building a Piloted Servo Valve
 Building valves from primitive hydraulic components
 Use steady state scan to parameterize models
 Linear analysis
 Model a Raise/Lower Valve for a Hydraulic Lift
 Using HC library components to create larger component
 Reverse flow in a hydraulic system
 Minimizing number of pressure states
 Simulating Water hammer Effects
 Disaster Recovery - How to handle problem models
Prerequisites
Working knowledge of Easy5 and a basic understanding of the Thermal Hydraulics library.
Dates
On Request
Duration
1.5 Days
23
TRAINING 2014
EAS105 - Modelling Simulation of Gas Systems Using Easy5
Objective
This course will teach you how to use Easy5 to model pneumatic systems and valves. It will review some fundamentals that are
usually not well understood and provide advanced instructions for features in Easy5.
Content
 General Theory of Pneumatic Modelling in Easy5
 Modelling a Simple Pneumatic Pressure Regulator
 Practice basic Easy5 skills
 Obtain Initial Operating Points
 Difficulties in Obtaining Steady State
 Use Steady State to parameterize models
 Modelling a Flow Control Valve
 Building Valves from Primitive Pneumatic Components
 Building an Electro pneumatic Pressure Regulator
 Data Tables and the Matrix Editor
 Linear Analysis
 Model a Temperature Control System with Heat Exchangers
 Simulation and Numerical Integration
 Macro Code Development
 Sorting and Solving Implicit Loops
 Modelling and Development with Discrete Components
 Modelling Discontinuities with Switch States
 Additional topics as interest and time allows including:
 Debugging models
 How to define and use your own fluid property set
Prerequisites
Completion of introductory class and/or a working knowledge of Easy5.
Dates
On Request
Duration
1.5 Days
24
TRAINING 2014
Flightloads
FLD120 – Introduction to MSC Nastran Aeroelasticity using Flightloads and Patran
Objective
This seminar is intended for engineers concerned with structural loads, flying qualities, and aeroelastic stability of flexible
aircraft and missiles. The objective of the seminar is to familiarize the engineer with an integrated approach to the state-of-theart MSC Nastran applications in aeroelastic analyses and their implementation via the FlightLoads User Interface and process
management tool. An overview of the aeroelastic capability is followed by discussion of the available aerodynamic theories and
case studies of the three available aeroelastic solutions: static aeroelasticity, flutter, and dynamic aeroelasticity. Highly detailed
workshops are used throughout.
Content

Introduction to Aeroelasticity

What is Aeroelasticity

Aeroelastic Analysis Types

Aeroelastic Modeling

Splines

Aeroelastic Solution Sequences

Introduction to FlightLoads and Dynamics

What is FlightLoads

FlightLoads: A Brief Description of the Features

FlightLoads: Latest Developments

Aerodynamic Theories

Doublet Lattice Method

Zona51

Subsonic Slender Body Theory

Splines

Surface Splines

Linear Splines

Theory of Static Aeroelastic Analysis

Aerodynamic Loads

Linearization: Elastic Deformation

The Flexible Aircraft

Theory of Static Aeroelastic Analysis

Stability Derivatives: Lateral Directional Trim

Monitor Points

Aeroelastic Response Analysis

Dynamic Equations

Random Response Analysis
Prerequisites
NAS 101: Introduction to MSC Nastran
NAS 102: MSC Nastran Dynamics Analysis
PAT 301: Introduction to Patran
Dates
On Request
Duration
5 Days
25
TRAINING 2014
Marc
MAR101 – Marc Introductory Course
Objective
An introduction in the use of Marc and Mentat (Classic and New versions) through a series of lectures, demonstrations and
workshops.
Content
 Overview of Marc and its Capabilities
 Review of the Fundamentals of the Finite Element Method
 The Implications of Running a Geometrically Nonlinear Analysis
 Nonlinear Incremental Solution Procedures
 Iterative Convergence Methods
 Interpreting Results from Nonlinear Analyses
 Best Practice in Contact Analyses
 Solver Choice and Parallel Analysis Options, Dynamic Analysis (Harmonic, Transient)
Prerequisites
A basic knowledge of statics and strength of materials is highly recommended. No previous finite element analysis experience is
required.
Dates
On Request
Duration
3 Days
MAR102 - Marc/Mentat Advanced Course
Objective
The purpose of this course is to enhance the knowledge of a current Marc and Mentat user in more advanced techniques
through a series of lectures, demonstrations and workshops.
Content
 Review of Nonlinear Analysis Procedures
 Geometric Nonlinearity and Buckling Methods
 Element Technology and Correct Usage
 Materially Nonlinear Analysis (plasticity, hyperelasticity, failure, damage, etc.)
 Diagnosing a Failing Nonlinear Analysis
Optional Topics (depending on interest of participants) Include:
 Composite Analysis (Including Progressive Failure and Crack Growth)
 Heat Transfer and Thermal Stress Analysis (Steady State, Transient, Coupled)
 Dynamic Analysis (Harmonic, Transient)
Prerequisites
MAR101 Marc/Mentat Introductory Course
Dates
On Request
Duration
2 Days
MAR103 – Marc Experimental Elastomer Analysis
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TRAINING 2014
Objective
The purpose of this course is to provide a fundamental understanding of how material testing and finite element analysis are
combined to improve the design of rubber and elastomeric products.
Content
 Introduction
 Overview of Elastomer Testing and Analysis
 Measurement and Modelling principals
 Curve Fitting of Uniaxial Material Data
 Curve Fitting of Multi Mode Material Data
 Simulations with Specimen Data
 Tips and best practice for elastomer simulations
Prerequisites
A basic knowledge of statics and strength of materials is highly recommended. Previous finite element analysis experience is
recommended. Knowledge of elastomeric materials.
Dates
On request
Duration
2 Days
MAR106 – Electromagnetic Analysis Using Marc
Objective
This course provides an overview of general electromagnetic theory and the typical problems that Marc can handle. It provides
a quick review of Marc nonlinear methodology and contact analysis as well as of Marc Structural and thermal analysis. Each
workshop shows detailed step by step finite element modeling in Mentat and is a quick, simple and efficient way of learning
Mentat. The post-processing section of each workshop problem illustrates how finite element results can be interpreted, and
how they can be used to obtain other practical quantities. Relevant short notes at the end of a workshop help in getting
additional information about Marc and Mentat.
Content
 Main theory of EM and Electrostatic workshop
 Joule-thermal-structural and Magnetostatics=structural workshop
 Piezoelectric, magnetostatic-thermal and magnetodynamics workshop
Prerequisites
MAR101 Marc/Mentat Introductory Course
Dates
On request
Duration
3 Days
27
TRAINING 2014
MAR120 - Marc/Patran Introductory Course
Objective
An introduction to the use of Marc within Patran, using a series of lectures, demonstrations and workshops.
Content
 Overview of Marc and its Capabilities
 Review of the Fundamentals of the Finite Element Method
 The Implications of Running a Geometrically Nonlinear Analysis
 Nonlinear Incremental Solution Procedures
 Iterative Convergence Methods
 Interpreting Results from Nonlinear Analyses
 Best Practice in Contact Analyses
 Solver Choice and Parallel Analysis Options
Prerequisites
PAT301 or equivalent experience with Patran.
Dates
On Request
Duration
4 Days
MAR299 - Marc Programming Course
Objective
The purpose of this course is to teach the current Marc and Mentat user to use Python and Fortran to control and automate both
the Marc solver process, as well as the Mentat pre/post processing environment through a series of lectures, demonstrations and
workshops.
Content
 Review of User Subroutines Available for Use with Marc
 Review of Python Functions Available for use with Mentat
 Fundamentals of the Marc and Mentat Programming Structures
 Examples of Material Failure, Loading, Result Creation, etc. will be Considered for Marc
 Examples of Automating Model Changes and Result Extraction/Evaluation will be Considered for Mentat
Prerequisites
Working Knowledge of Marc and Mentat. Basic Knowledge of Programming
Dates
On request
Duration
2 Days
28
TRAINING 2014
MSC Nastran
NAS101 - Basic MSC.Nastran Linear Static, Normal Modes and Buckling Analysis
Objective
The purpose of this seminar is to introduce the new MSC.Nastran user to the basic ASCII input requirements for linear static and
normal modes analysis of structures. Many important features of MSC.Nastran are illustrated with numerous example
problems. MSC.Nastran data structure and element library, modelling practices, model debugging, and guidelines for efficient
solutions are discussed. This seminar (or NAS120) provides the foundation required for intermediate and advanced MSC.Nastran
applications.
Content
 Introduction to finite element theory and finite element modelling
 Overview of MSC.Nastran input data
 MSC.Nastran solution sequences
 Case control section
 Output requests, Data selection
 Subcase definition
 Bulk data section
 Coordinate systems, Geometry, Constraints
 Material properties, Elements
 Intermediate modelling practices
 Set notations, Rigid elements, Model debugging, Symmetry, Modelling recommendations, Parameters
 Natural frequencies and normal modes
 Governing equations, Methods of computation
 MSC.Nastran entries for normal modes analysis
 Buckling theory
 MSC.Nastran entries for buckling analysis
 Linear contact and permanent glue
 Introduction to the file management section
 Restarts, Databases
 Overview of advanced capabilities
Prerequisites
A basic knowledge of statics and strength of materials is highly recommended.
No previous finite element analysis experience is required.
Dates
On Request
Duration
4 Days
29
TRAINING 2014
NAS102 - MSC.Nastran Dynamic Basic Analysis
Objective
This workshop is a comprehensive presentation of the dynamic capabilities available in MSC.Nastran. It covers fundamental and
advanced topics with an emphasis on practical applications and example problems. A comprehensive presentation of the
dynamic capabilities available in MSC.Nastran is presented in this workshop. These dynamic analysis capabilities include normal
mode analysis, transient response analysis and frequency response analysis. Theoretical derivations of the mathematics used in
dynamic analysis are presented only as they pertain to the proper understanding of the use of each capability.
Content
 Review of Fundamentals
 Dynamic Modelling Input
 Normal Mode Analysis
 Reduction in Dynamic Analysis
 Rigid Body Modes
 Damping
 Transient Response Analysis
 Frequency Response Analysis
 Direct Matrix Input
 Dynamic Equations of Motion
 Residual Vector Methods
 Enforced Motion
 Shock and Response Spectrum Analysis
 Random Response Analysis
 Complex Eigenvalue Analysis
 Normal Mode Analysis Using Parts Superelement
 Extra Points, Transfer Functions, and NOLINs
 Normal Modes of Preloaded Structures
 Dynamic Design Optimization
 Test-Analysis Correlation
Prerequisites
Basic MSC.Nastran Linear Static Analysis seminar or equivalent experience
Dates
On request
Duration
4 Days
30
TRAINING 2014
NAS103 - Nonlinear Analysis
Objective
This seminar provides a working knowledge of the nonlinear capabilities of MSC.Nastran for static and dynamic analysis. Both
geometric and material nonlinearity are discussed in detail. Nonlinear features of MSC.Nastran elements are explained and
several examples are presented. Some practical guidelines for nonlinear analysis are also given.
Content
 Nonlinear static analysis strategies
 Newton-Raphson method - Advancing schemes
 Stiffness update schemes
 Line search - Convergence and divergence
 Restarts
 Geometric nonlinear analysis
 Large rotations - Follower forces
 Linear and nonlinear buckling analysis
 Material types
 Nonlinear elastic
 Hyperelastic (Green elastic) - Elastoplastic
 Creep- Temperature dependent
 Nonlinear elements
 Small strain elements - Large strain elements
 Contact (interface) elements – Gap - Slideline
 Nonlinear transient analysis
 Integration schemes
 Mass, damping, and load superelement specification
 Restarts
 Superelements
 Special topics
 Nonlinear modal analysis - Composite elements
Prerequisites
A working knowledge of linear static analysis as covered in NAS101.
Experience with dynamic analysis and superelement analysis is recommended.
Dates
On request
Duration
4 Days
31
TRAINING 2014
NAS104 - Thermal Analysis with MSC.Nastran
Objective
This seminar describes the latest heat transfer and thermal stress analysis capabilities beginning with Version 68. Program
inputs and interpretation of results for conduction, convection, and radiation analyses are covered in detail. The seminar
attempts to provide a balance between theory, its development within the context of MSC.Nastran, and practical application.
Example problems are used to clarify the information presented
Content
 MSC.Nastran communication
 Input data formats - Executive control statements
 Case control statements - Parameter statements
 Overview of heat transfer capabilities
 Conduction - Convection - Radiation
 The MSC.Nastran thermal model
 Geometry - grid points and elements - Material properties
 Boundary conditions - surface elements - Thermal "loads"
 Thermal transients
 NASTRAN input data
 Steady state analysis (SOL 153)
 NLPARM statement - Free and forced convection
 Thermal loads - Radiation boundary condition
 Radiation view factors - Radiation enclosure analysis - Spectral exchange
 Transient analysis (SOL 159)
 TSTEPNL statement - Transient load methodology
 Control nodes - Temperature boundary conditions - Phase change
 Thermal stress analysis
 Restarts
 Multimode heat transfer analysis
 Thermal system analysis
 Miscellaneous topics
Prerequisites
Basic knowledge of heat transfer fundamentals. NAS101 or equivalent experience is recommended.
Dates
On Request
Duration
3 Days
NAS105 - Practical Finite Element Modelling Techniques Using MSC.Nastran
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TRAINING 2014
Objective
This seminar provides practical advice and guidance in using MSC.Nastran for a variety of structural applications. Special
MSC.Nastran techniques that can be used to obtain better results at less cost are discussed. Participants will increase their
engineering productivity by modelling difficult shapes more easily, finding errors quickly, and running problems more efficiently.
Content
 Element techniques
 Review of available options - Theoretical considerations and modern practices
 Accuracy versus shape and mesh size - Modelling tricks - Mesh transitions and special connections
 Constraints and boundary conditions
 The "R" constraints - Singularities - detection and cure - Symmetry methods
 Diagnosing modelling problems
 Available diagnostic messages - Graphical methods - Useful output options - Free-body checks - Redundant analysis
methods
 Recommendations for dynamic modelling
 Performance of reduction techniques - Using the SUPORT entry - Approximating frequencies using static analysis - Hints to
evaluate the quality of modal solutions
 Superelements made easy
 Single-level models - Basic input - Basic restarts - Modal synthesis techniques - Global-local analysis techniques
 Nonlinear analysis
 Using linear analysis to model nonlinear behaviour
 Overview of cyclic symmetry
 Overview of composites
Prerequisites
NAS101 or equivalent experience. Working knowledge of finite element analysis applications.
Dates
On Request
Duration
3 Days
33
TRAINING 2014
NAS106 - Superelement Analysis with MSC.Nastran
Objective
One thing that has been consistently demonstrated in finite element analysis is that demand will always exceed existing
capabilities. This limit on hardware, combined with budget limitations (large runs are expensive), results in limitations on the
ability of engineers to solve large, complicated problems. A solution to these limitations is the use of superelements in
MSC.Nastran.
Using superelements, one can check segments of the model independently and use the reduced matrices from the check runs in
the final full model analysis. Superelements allow different groups to work on different parts of the model. This seminar
describes how to perform static and dynamic analysis using superelement techniques. Special attention is paid to restarts in
superelement analysis and applying superelements to dynamic analysis, including component modal synthesis. The final day
describes techniques for the use of secondary superelements focusing especially on the use of external superelements.
Content
 Defining Superelements and Terminology
 Loads, Constraints, Parameters, and Case Control
 Multilevel Superelement Analysis
 Component Modes, Reduction, and Assembly
 Model Checkout Tools
 Database and Restarts
 Dynamic Analysis with Superelements
 Nonlinear Analysis
 External Superelement
 Image Superelements
Prerequisites
NAS101 or equivalent experience. MSC.Nastran Dynamic Analysis seminar (NAS102) is recommended.
Dates
On Request
Duration
2 Days
34
TRAINING 2014
NAS107 - Optimisation with MSC.Nastran
Objective
MSC.Nastran features a comprehensive design sensitivity and optimisation capability. It is possible to design for a variety of
user-defined objectives such as minimum weight or maximum frequency. This seminar covers the theoretical and practical
aspects of MSC.Nastran design sensitivity and optimisation: emphasis is placed on using the program to solve practical
engineering problems. The capabilities of the program, including typical applications, are covered in detail. The concept of a
design model is introduced. The process of optimising a structure is discussed from initial modelling to interpretation of results.
Numerous example problems reinforce the material covered in the lectures.
Content
 What is design optimisation? - The basic optimisation problem statement
 Introduction to numerical optimisation
 The concept of a design space - Constrained and unconstrained minimisation techniques
 Convergence testing - Numerical aspects of interest to the design engineer
 Analysis versus design modelling - Design model definition procedure - choosing the design variables, objective, and
constraints
 Interpretation and utilisation of optimisation results
 Topology Optimisation
 Shape Optimisation
 Topography Optimisation
 Design variable linking and reduced basis formulations - Formulation of synthetic design variable to property relations Formulation of synthetic responses
 Dynamic response
 Special Modelling topics
 Multi Model Optimisation
 Superelement optimisation
 Non-linear Optimisation
 Aeroelastic Optimisation
Prerequisite
NAS101 or equivalent experience.
Dates
On Request
Duration
3 days
35
TRAINING 2014
NAS110 - Working with Custom MSC Nastran Solution Sequences using DMAP
Objective
Direct Matrix Abstraction Programming (DMAP) is a macro language used to build and modify solution sequences in
MSC.Nastran. The DMAP language contains powerful matrix instructions as well as flexible scalar variable (parameter) operations.
The File Management Section (FMS) is used for the attachment, initialisation, and manipulation of databases. The objective of
this seminar is to present DMAP and database application techniques and to prepare attendees to develop DMAP and solution
sequence alter packages. This seminar also provides experienced users with the knowledge to perform sophisticated tasks in
MSC.Nastran. Such tasks include the creation of DMAP sequences with subDMAPs and the creation of a solution sequence
(delivery) database. Details are presented on the structured solution sequence (SOLs 100 through 200), DMAP structure, and
Nastran Data Definition Language (NDDL).
Content













Introduction
Overview of DMAP
Parameters
DMAP Modules
SUBDMAPs
DMAP Alters
U set Partitioning and Merging
Additional Common Modules
Output Modules
Storing and Retrieving from the Database
ISHELL – Spawning Process
Modifying Delivering Database
Adding User SubDMAP to Delivering Database
Prerequisites
NAS101 or equivalent experience. Experience with additional solution sequences and super-element analysis is helpful.
Dates
On Request
Duration
3 Days
36
TRAINING 2014
NAS120 - Linear Structural Analysis with MSC.Nastran and Patran
Objective
This seminar introduces basic finite element analysis techniques for linear static, normal modes, and buckling analysis of
structures using MSC.Nastran and Patran. MSC.Nastran data structure, the element library, modelling practices, model
validation, and guidelines for efficient solutions are discussed and illustrated with examples and workshops. Patran will be an
integral part of the examples and workshops and will be used to generate and verify illustrative MSC.Nastran models, manage
analysis submission requests, and visualise results. This seminar (or NAS101) provides the foundation required for intermediate
and advanced MSC.Nastran applications.
Content
 Introduction to finite element theory and finite element modelling
 Anatomy of the MSC.Nastran input file
 Model generation and verification using Patran
 Creating geometric representation of structure
 Defining material and element properties
 Constraining the model
 Loading the model
 Meshing the model
 Model verification
 Generating and submitting a ready-to run MSC.Nastran input file
 Linear static analysis
 Normal modes analysis
 Buckling analysis
 Importing an existing MSC.Nastran input file into Patran
 MSC.Nastran output files and their interpretation
 Results visualisation using Patran
 Model debugging tools and recommendations
 Tips for solving large problems
Prerequisites
A basic knowledge of statics and strength of materials is highly recommended.
No previous finite element analysis experience is required.
Dates
Duration
On Request
On Request
5 Days
NAS122 - Dynamic Structural Analysis with MSC.Nastran and Patran
Objective
This course covers an integrated approach to dynamic analysis using Patran and MSC.Nastran. The student will learn how to
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TRAINING 2014
identify the nature of the dynamic problem, set up the problem appropriately in Patran and execute it using MSC.Nastran.
Details of the MSC.Nastran theory and methodology will be covered which allow the student greater insight into the process.
Finally extensive use of Patran will be made to explore the results of the analysis in depth.
Content
 Review of Fundamentals in Dynamics
 Dynamic Modelling Input
 Normal Modes Analysis
 Reduction Techniques
 Rigid Body Modes
 Dynamic Matrix Assembly
 Transient Response
 Frequency Response
 Interactive Frequency Response
 Enforced Motion
 Pre-Stiffened Normal Modes
 Random Response
Prerequisites
PAT301 and NAS101 seminar or NAS120 seminar
Dates
On Request
Duration
5 Days
38
TRAINING 2014
NAS123 – MSC Nastran Implicit Nonlinear (SOL 600) Analysis
Objectives
This seminar presents how to perform implicit nonlinear analysis using MSC.Nastran SOL 600. MSC.Nastran SOL600 is the
nonlinear capabilities of Marc delivered in an MSC.Nastran user interface. SOL 600 provides FEA capability for the analysis of 3D
contact and highly nonlinear problems.
Content
 Overview of Nonlinear Analysis Using Msc.Nastran Sol 600
 Numerical Concepts in Nonlinear Analysis
 Element Library, Mesh Considerations, and Analysis Procedures
 Analysis Setup and the Analysis Form
 Analysis Setup for Non-Patran Users
 Introduction to Choice of Elements
 Choice of Element Integration
 Materials
 Overview and Contact Body Interactions
 Contact Body Definition
 Resolving Convergence Problems
 Buckling and Post-buckling Analysis
 Structural Dynamics
Prerequisites
NAS101 or equivalent is recommended
Dates
On Request
Duration
3 Days
39
TRAINING 2014
NAS126 – Explicit Nonlinear Analysis using MSC Nastran and Patran
Objectives
NAS126 is an introductory course in dynamics simulation using Explicit nonlinear analysis. Students will prepare short duration
structural dynamic analyses using MSC Nastran finite element models. Students will learn how to create and/or modify material
properties, loads, and boundary and initial conditions for dynamic simulation models. They will also learn how to set up the jobs
for running the models and review the results for these models.
Content
 Explicit Transient Dynamic Analysis
 Input file format
 Patran Graphical User Interface
 Running MSC Nastran SOL 700
 Lagrange Basics
 Element Library
 Material Models
 Lagrangian Loading Conditions
 Lagrangian Boundary Conditions
 Contact Definition and Analysis
Prerequisites
NAS120, or (PAT301 and NAS101), or equivalent
Dates
On Request
Duration
3 Days
40
TRAINING 2014
NAS400 - Implicit Nonlinear Analysis using MSC Nastran and Patran
Objectives
NAS400 covers various aspects of implicit nonlinear analysis using MSC Nastran and Patran. This includes large
deformation, advanced nonlinear material, contact, analysis chaining, heat transfer, and nonlinear transient dynamics.
Content
 Overview of MSC Nastran
 Overview of Implicit Analysis with SOL 400
 Sources of Nonlinearity
 Concepts in Nonlinear Analysis
 Chaining of Different Analysis Types
 Boundary Condition Changes
 Advanced Nonlinear Material Models in MSC Nastran
 Large Strain Elastic-Plastic
 Nonlinear Elastic
 Hyperelastic
 Composite
 Creep
 Shape Memory Alloy
 Advanced Nonlinear Elements in MSC Nastran
 Contact Bodies and Contact Body Interactions
 Heat Transfer
 Nonlinear Structural Dynamics
Prerequisites
Basic knowledge in Nastran (NAS101, NAS120 and NAS103) is required.
Dates
On Request
Duration
3 Days
41
TRAINING 2014
Patran
PAT301 - Introduction to Patran
Objective
PAT301 is the introductory course for new Patran users. Students will master the basic skills required to use Patran in typical
MCAE applications. PAT301 emphasises practical skills development through comprehensive, hands-on laboratory sessions.
Students will learn to build analysis models using Patran, define material properties, create boundary conditions, access Patran's
material libraries for material properties, submit their job for analysis and postprocess results in varying formats.
Content
 Take a model through the complete design and analysis cycle
 Import CAD geometry and use it to create new geometry in Patran
 Learn graphics manipulation, imaging, and viewing techniques
 Practice using the different meshing techniques: isomesher, paver, and tetmesher
 Verify your finite element model
 Apply loads and boundary conditions
 Learn advanced techniques:
 Apply distributed pressure loads
 Vary thicknesses
 Use groups and lists to filter and group entities
 Submit analysis
 View and manipulate results
Prerequisites
No previous experience is required but an understanding of FE techniques is desirable.
Dates
On Request
Duration
5 Days
42
TRAINING 2014
PAT302 - Advanced use of Patran
Objective
PAT302 provides an in-depth examination of the advanced features of Patran. Sample topics covered by PAT302 include:
advanced Patran features usage for meshing and mesh refinement, use of various Patran Command Language (PCL) files for
session customisation, application of advanced geometric construction techniques, definition of fields to represent spatially
varying functions for loads and boundary conditions, generation of constraint equations (MPCs) to define physical relationships,
and creation of sophisticated multi-effect graphical images..
Content
 User interface shortcuts and advanced capabilities to your Patran efficiency and help you customize your work environment

Wildcards, keywords, list processor syntax, and command line options

Database/model manipulation using group transformation and database merge capabilities

Customizing the toolbar and start-up environment
 Discover advanced geometry modelling and CAD access features

Advanced construction and editing techniques

Repair non-topologically congruent (i.e. "dirty") geometry
 Apply advanced finite element modelling capabilities

Mapped, automated and 2.5-D meshing, mesh smoothing

Global-local and thermal-structural modelling using FEM fields

Advanced Surface Mesher

Advanced node and element editing techniques
 Post-processing and advanced graphical results display

Advanced capabilities of results, Insight, XY plot, and text report

Numerical methods: data averaging and extrapolation

Using multiple Insight tools
 Patran Command Language (PCL) Basics

PCL programming in conjunction with Patran modelling

PCL syntax, directives, operators, variables, arrays and libraries

Write a PCL routine to automate parameterised geometry creation
Prerequisites
PAT301 or equivalent experience in the use of Patran.
Dates
On Request
Duration
4 Days
43
TRAINING 2014
PAT304 – Introduction to Patran Command Language (PCL)
Objective
PAT304 provides students with a comprehensive overview of the MSC.Patran Command Language (PCL) for site integration and
user programming. Topics include basic PCL syntax, creation of user interface objects (widgets) such as forms, buttons,
slidebars, etc., spawning remote processes from the MSC.Patran session, usage of database access calls, handling interrupts
from an event-driven system, compiling, debugging, and code management. Students will build practical skills by performing
17 PCL programming exercises in multiple laboratory sessions. Exercises include the development of PCL code to create a fully
parameterised finite element analysis model for use in shape optimization and design studies.
Content
 File I/O (create and parse a text file)
 Spawn UNIX command from Patran (i.e. start your own analysis code processing)
 Parametric Modelling (i.e. build same part but vary length, width or radius of part)
 Dynamic memory allocation
 Create a Graphical User Interface (GUI)
 General PCL syntax and usage
Prerequisites
PAT301 or compatible experience. Familiarity with C or Fortran or Pascal.
Dates
On Request
Duration
5 Days
PAT318 - Durability and Fatigue Analysis using MSC.Fatigue
Objective
This course introduces basics and advanced methods for evaluation and estimation of fatigue life using MSC Fatigue.
Aimed at the MBS or FE analyst with no previous experience of fatigue analysis, the course is an ideal introduction to the basic
concepts of total life, crack initiation, crack propagation and vibration fatigue methods. The theoretical background is covered
along with practical issues regarding the integration to MBS/FE environment and the usage of MSC Fatigue.
A variety of examples and hands-on sessions provide detailed coverage of the software user interface including loading,
materials, and results visualisation capabilities.
Content
 Intro to Fatigue Analysis: Historical Background and modern computational methods
 Stress-life (S-N) method: similitude, rainflow cycle counting, linear damage summation, Factors influencing fatigue life
 MSC Fatigue User Interface: Modules and Capabilities
 Fatigue analysis of welds
 Strain-Life (e-N) method: uniaxial theory, plastic correction rules, factors influencing fatigue life
 Introduction to multiaxial theory: biaxial assessment and factor of safety
 Temperature Corrected Fatigue, theory and examples
 Elements of Dynamic analysis: choice of the domain, from quasi static approximation to Frequency domain,
 Elements of Component Modal Synthesis and Multi Body Dynamics: examples with Adams/flex/durability
 Duty cycle analysis, ATV example
 Fatigue in the Frequency domain, theory and examples
 Accelerated Fatigue Simulation, theory and examples
Prerequisites
No prior knowledge of fatigue analysis techniques or Patran is required, a basic knowledge of FE and strength of materials is
desirable.
Dates
On Request
Duration
3 Days
44
TRAINING 2014
PAT319 - Fatigue Analysis of Dynamically Responsive Systems using FEA
Objective
Fatigue analysis is too often presented as a task to be undertaken only by so-called “fatigue experts”. The first part of this course
will show that the basic principles of fatigue life estimation are relatively straightforward and certainly within the role of typical
stress, dynamics and FEA design engineers. The second part of the course will cover vibration fatigue. This topic brings together
structural dynamics, FEA and fatigue analysis in order to show how systems with dynamic (resonant) response can be assessed
for fatigue life.
Content
 General Introduction to FE Based Fatigue
 Basic Fatigue Analysis & Materials Consideration
 Basic Fatigue Analysis & Loading Considerations
 Calculation of Stress Concentration Factor
 Strain-Life Fatigue, Crack Propagation and Derivative Methods
 Fatigue, Fracture & Damage Tolerance
 Introduction to crack growth analysis-LEFM Failure criteria
 Determination of critical crack lengths
 Basics of Random Process Theory & Frequency Analysis
 Statistical characterization of random processes
 Vibration Fatigue Solvers
 Time Based Methods
 Multi Body Dynamics (MBD) Simulation Methods
 Introduction to Non-linear Frequency Domain Phenomena
Prerequisites
No prior knowledge of fatigue analysis techniques or dynamics is required.
Dates
On Request
Duration
3 Days
45
TRAINING 2014
PAT325 - Composites Analysis Using Laminate Modeller
Objective
This seminar will familiarise students with the use of Patran and Laminate Modeller in composite design and analysis.
Composite materials theory is introduced, along with its integration into the FE method.
Content
 Introduction to Laminate Modeller
 Introduction to Composite Materials
 Review of Material Constitutive Laws and Laminate Stiffness
 Creation of Composite Model in Patran
 Failure Criteria for Composites
 Postprocessing of Composite Analysis Results
 Creation of Ply Materials, and Layups with Laminate Modeller
 Plies on Doubly Curved Surfaces
 Shear Algorithms
 Draping Algorithms
 Creating Splits in Plies
 Manufacturing Integration
 Exporting Flat Pattern
 Springback Analysis
 Exercise Session
 Optimisation of Composites
Prerequisites
A degree in engineering, material science or equivalent experience Familiarity with Patran
Dates
On Request
Duration
3 Days
46
TRAINING 2014
SimXpert
SMX101 - Introduction to SimXpert
Objective
SMX101 is the introductory course for new SimXpert users. Students will master the basic skills required to use SimXpert in
typical MCAE applications. They will be introduced to the Structures, Motion, Thermal, and Crash Workspaces. A brief
introduction to building and running templates is also included. SMX101 emphasizes practical skills development through
comprehensive, hands-on laboratory sessions. Students will learn to build analysis models using SimXpert, define material
properties, create boundary conditions, apply loads, and submit their job for analysis and postprocess results.
Content
• Take a model through the complete design and analysis cycle
• Learn graphics manipulation, imaging, and viewing techniques
• Import CAD geometry and manipulate it in SimXpert
• Practice using the different meshing techniques including morphing
• Learn how to verify and check the quality of a finite element model
• Study various ways to create Connections
• Nonlinear analysis of a bolt model
• Integration of Motion and Structures Workspaces
• Overview of Crash and Thermal Workspaces
• Macro creation
• Running and Building Templates
Prerequisites
A basic knowledge of statics and strength of materials is recommended
Dates
On Request
Duration
3 Days
47
TRAINING 2014
SMX120 - SimXpert Linear Static Analysis
Objective
SMX120 is the introductory course for the SimXpert Structures Workspace. Students will master the basic skills required to use
SimXpert in typical Structural applications. SMX120 emphasizes practical skills development through comprehensive, hands-on
laboratory sessions. Students will learn to build analysis models using SimXpert, define material properties, create boundary
conditions, apply loads, and submit their job for analysis and postprocess results.
Content
 Take a model through the complete design and analysis cycle
 Learn to import and edit Nastran input files
 Examine uses of different element types
 Become familiar with the contents of the Nastran output files
 Learn techniques to assess mesh quality
 Overview material types, including composites
 Investigate contact
Prerequisites
A basic knowledge of statics and strength of materials is recommended • Although not required, a working knowledge of
SimXpert such as that provided in the SMX101 class is recommended
Dates
On Request
Duration
3 Days
SMX121 - SimXpert Motion Analysis
Objective
SMX121 is an introductory course in motion simulation using the Motion Workspace in SimXpert. Students will prepare motion
models utilizing CAD geometry in SimXpert. Students will learn to create connections between parts, model contact and friction,
model forces, and apply specific motion to parts in order to create motion models. Students will also learn to review motion
results from these models using animations and charts. Finally, the course demonstrates the modelling of flexible bodies in a
motion simulation through interaction with the SimXpert Structures Workspace.
Content
 Import of CAD models into SimXpert
 Parts in SimXpert Motion Workspace
 Result Animations
 Charting Result Data
 Connections between motion parts
 Contact
 Forces, including spring dampers
 Applied Motion
 Flexible Body Simulation with Structures Workspace
Prerequisites
No prior familiarity with SimXpert is required.
Dates
On Request
Duration
3 Days
48
TRAINING 2014
SMX126 - Introduction to SimXpert MD Explicit Workspace
Objective
SMX126 is an introductory course in dynamics simulation using the MD Explicit Workspace in SimXpert. Students will prepare
short duration structural dynamics models utilizing the imported Nastran finite element models. Students will learn how to
create and/or modify material and part properties, loads, and boundary and initial conditions for dynamic simulation models.
They will also learn how to set up the jobs for running the models with the MD Explicit solver, and review the results for these
models using State Plot and Chart.
Content
 Overview of Explicit Dynamic Analysis in SimXpert
 Overview of SimXpert
 Theory, briefly
 Import of Nastran models into SimXpert
 Parts in SimXpert MD Explicit workspace
 Material Models for Explicit Dynamic Analysis
 Elements in MD Explicit
 Loads and Boundary Conditions
 Contact Bodies and Contact Properties
 Initial Conditions
 Selection of Time Steps
 Explicit Analysis set-up, including nonlinear parameters
 Display of Explicit Analysis Results
 Hands on Workshops
Prerequisites
No prior familiarity with SimXpert is required
Dates
On Request
Duration
3 Days
49
TRAINING 2014
SMX131 - SimXpert Templates
Objective
SMX131 is a course that focuses on the SimXpert Template Builder workspace. Students will gain the skills to create simulation
templates that automate complex and/or repetitive analysis procedures. In the SimXpert Template Builder learners will build
templates that utilize several different workspaces and test them in the Template Execution environment. Students will also be
able to create actions, the basic building blocks of templates, and use the various connection, branching, and looping tools to
add complexity to a template. Publishing templates to the enterprise via the SimManager portal is also explored.
Content
 Explore the Template Builder workspace
 Run a simple Structures template in Template Execution window
 Build a simple template using built-in actions and connection tool
 Record a macro (template) and then edit it in Template Builder
 Build a template containing choice and loop tools
 Create a new embedded script action (using RADE language)
 Create a new core script action (using Python language)
 Execute some additional templates and explore various levels of automation
 Learn how publishing and retrieving templates via the SimManager portal allows sharing across the enterprise
Prerequisites
SMX101 is recommended before taking SMX131
Dates
On Request
Duration
3 Days
50
TRAINING 2014
Sinda
SND501 - Network Thermal Analysis Using MSC Sinda
Objective
The intent of this course is to provide users with comprehensive exposure to the MSC Sinda thermal analysis program. A
combination of lecture and hands-on instruction is used to teach how to create MSC Sinda thermal models involving real world
thermal boundary conditions.
Content
• Thermal Modeling Using MSC Sinda. A combination of lecture and hands-on instruction is used to teach how to create MSC
Sinda thermal models involving real world thermal boundary conditions.
• Numerical Methods in MSC Sinda. The finite difference numerical methods used in the steady state and transient solutions of
MSC Sinda ,convergence, stability, control constants and errors.
• Advanced MSC Sinda. Steady state or transient. The Fortran file, key variables and arrays. The Pre-Preprocess (PPP mode) and
lab problems with global variables.
• MSC Sinda for PATRAN and other Graphical Modelers. Graphical pre-post processors, how tocreate geometry in 3-D, add
boundary conditions, and post process the results.
Prerequisites
A basic knowledge of thermal analysis is desirable
Dates
On request
Duration
5 Days
51
TRAINING 2014
SND502 - Thermal Analysis Using Patran with MSC Sinda
Objective
This course will allow users to explore some of the more in-depth features of creating advanced MSC Sinda thermal models
from a finite element model builder. Students will use Patran to build the lab problems.
Content
 Using MSC Sinda skeleton files
 Adding FORTRAN to graphically built models
 Creating groups
 Excel material files
 Advanced mesh control
 Modeling time and temperature dependent properties
 Advanced geometry manipulation
 Report generation - using the new Thermal Studio
 Manipulating models and views
 Importing and running large models
 Adding contacts between surfaces
 Importing, simplifying and using CAD geometry
 Exploring materials and properties
 Radiation super elements and primitives - for fast and accurate radiation modeling
 Radiation enclosures
 Special features and applications
 Linking to radiation codes such as THERMICA, Nevada, TRASYS, and TSS
 Using thermal data for stress analysis
Prerequisites
The training material assumes some experience with finite element models.
Dates
On Request
Duration
3 Days
52
TRAINING 2014
SND503 - Spacecraft Thermal Analysis Using THERMICA V4
Objective
Thermica is a comprehensive spacecraft thermal design system that transparently incorporates the MSC Sinda thermal analyzer
into a powerful state-of-the-art graphical user environment. Thermica version 4 is a major upgrade to the previous versions of
Thermica that have been used for more than two decades on dozens of major space programs. V4 has a completely new GUI
that runs in Windows, Linux and other workstations as native code and graphics. This new user interface has a Windows XP look
and feel and is easy and intuitive to learn. The new model builder has links to CAD and Nastran and a powerful new shape based
meshing tool. Photo-like animations of spacecrafts traveling to and orbiting other texture mapped planets can be viewed
interactively and recorded as movie files. Results such as temperature, heat fluxes and view factors can be graphically visualized
on these animations and also in interactive 2D plots. Powerful kinematic motion such as deployment of solar arrays and
arbitrary moving surfaces can be modeled. Missions to the moon, Mars and other planets can be completely simulated using
time-position-velocity data from external codes such as Satellite Tool Kit (STK).
Content
•Understanding the process flow.
•Model building process in V4.
•Using CAD files for building models.
•Using Nastran files for model building and exporting Thermica models to Nastran.
•Orbit definition including using external data from STK to define these.
•Kinematic motions with moving bodies and arbitrary motions such as solar panels deploying.
•Mission setup where a model, mesh, orbit and motion are put together. Real time animations and mission viewing options.
•Computing radiation exchange factors and orbital heating.
•Generation of a Sinda thermal model.
•Accuracy checks on ray tracing runs.
•Post processing of temperatures, view factors and orbital heating using 3D animations of the spacecraft and planets.
•Recording animations as standard or High Definition (HD) movies.
•2D interactive plotting of temperatures, view factors and orbital heating.
Prerequisites
None
Dates
On request
Duration
3 Days
53
TRAINING 2014
Contacts
Exclusive BeNeLux agent of MSC.Software
Oeverkruid 15
4941 VV Raamsdonksveer
The Netherlands
T: +31 162 524000
mscsales@insumma.nl
www.insumma.nl
www.rendementmetsimulatie.nl
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