ANSYS BELGIUM TRAINING GUIDE Belgium/staticassets... · ANSYS BELGIUM TRAINING GUIDE ... • Intro...

ANSYS BELGIUMTRAINING GUIDE

32

ANSYS BELGIUM TRAINING GUIDE

Welcome to ANSYS Belgium’s training guide. In addition to the quality of the code, it is the

training and support services we provide that have made ANSYS® the world leader it is today.

The ANSYS® Workbench™ platform is the

framework upon which the industry’s broadest

and deepest suite of advanced engineering

simulation technology is built. An innovative

project schematic view ties together the

entire simulation process, guiding the user

through even more complex multiphysics

analyses with drag-and- drop simplicity.

ANSYS BELGIUM TRAINING GUIDE

ANSYS Belgium SA

Avenue Pasteur, 4

1300 Wavre

Belgium

Tel. : +32 (0)10 45 28 61

Fax: +32 (0)10 45 30 09

Email: [email protected]

Website: www.ansys-belgium.com

©2011 ANSYS, Inc. All Rights Reserved

With bi-directional CAD connectivity, powerful

highly-automated meshing, a project-level

update mechanism, pervasive parameter

management and integrated optimization

tools, the ANSYS® Workbench™ platform

delivers unprecedented productivity, enabling

simulation driven product development.

54

Table of contents

CFD worklow 6

ANSYS® DesignModeler™ 7

ANSYS® Meshing Platform 8

ANSYS® FLUENT® Solver 9

ANSYS® CFX® Solver 10

ANSYS® POLYFLOW® Solver 11

ANSYS® Mechanical™ Solver 12

Turbulence 13

Multiphase 14

User defined functions 15

GAMBIT® 16

ANSYS® Airpak® 17

Blow molding 18

Extrusion 19

Mixing 20

Viscoelastic 21

Additional courses 22

Registration and general terms 23

Access to ANSYS Belgium 24

Accommodations 26

Contacts 27

76

Problem Identification

1. Define goals

2. Identify domain

Pre-Processing

3. Geometry

4. Mesh

5. Physics

6. Solver Settings

Solve

7. Compute solution

Post Processing

8. Examine results

9. Update model

PrerequisitesThe course assumes you have no prior

experience of working with any CFD

package, although a background in

engineering /physics is assumed.

Learning ObjectivesThis course introduces the underlying

theory behind the CFD codes. This course

should not be seen as a replacement

to the introductory course but should

complement it.

Course agenda• Intro to CFD

• Mathematical Equations of CFD

• Overview of CFD Solution

Methodologies

• Discretization

• Solution Methods

• CFD Modelling of Turbulent Flows

CFD worklow I Regular training - 1 day

Problem identification

Pre-processing

Solve

Post processing




engineering/physics is assumed.

Flow volume automatically extracted from a manifold

ANSYS® DesignModeler™ I Regular training - 1 day

Learning objectivesThe ANSYS® DesignModeler™ training

course is for users who want to create

and modify geometry in preparation for

analysis in ANSYS® or ANSYS® Workbench™.

Trainees who attend this course will learn

• how to create and modify geometry in

preparation for analysis

• how to navigate within the Graphical

User Interface

• how to generate 2D sketches and

convert them into 2D or 3D models

• how to modify 2D and 3D geometry

• how to import existing CAD geometry

• how to model assemblies

• how to utilize parameters.

Each course chapter is followed by

“ hands-on “ workshops and exercises.

98

PrerequisitesA technical education and background are

recommended but an engineering degree

is not required.

Learning objectivesFor a given software you should be able to:

• Select appropriate physical models

• Define material properties

• Prescribe boundary and operating

conditions

• Set solver controls

• Set up solution convergence monitors

• Provide an initial solution

• Display and examine results.

Course agendaAll topics are covered using a combination

of lectures and hands-on sessions.

Recommended follow-on courses (depending upon the trainee’s interests and applications)

Automotive HVAC and Underhood,

Combustion, Dynamic Mesh, Heat Transfer,

Multiphase, Positive Displacement Pumps,

Spray and Particle Modeling, Turbulence,

UDFs

ANSYS® FLUENT® Solver I Regular training - 2 days

Prerequisites In order to use ANSYS® Meshing Platform,

it is necessary to have a geometric

model that has been created by another

application. In most cases trainees will have

attended the DesignModeler™ course on

the previous day and will therefore have

these skills. However trainees who do not

wish to learn DesignModeler™ should

make sure they are able to operate another

CAD tool so that they can create/modify

their model prior to meshing.

Learning objectivesBy the end of this course you should be

able to:

• work with ANSYS® Meshing Platform,

with full understanding of its GUI

• understand the different meshing

methods available for 2D and 3D

geometries

• create Tetrahedral Meshes

• create Hexahedral Meshes

• create inflation (boundary) layer meshes

near to walls

• apply advanced controls so as to refine

and coarsen the mesh in different

regions of the domain

• examine the quality of the mesh.

Practical workshopsA comprehensive range of hands-on

workshops are provided in which trainees

will be able to use the ANSYS® Meshing

Platform themselves, applying the skills

learnt in the previous lecture.

ANSYS® Meshing Platform I Regular training - 1 day

Example of all-hex meshing in the automotive industry

Hex meshing of a cell phone

Pressure contours

1110

PrerequisitesThe course assumes you have prior

experience of working with a mesh

generation software.

Course agenda• Overview of the software;

• Organization of the modules;

• Introduction to constitutive equations;

• Polydata:

- Tasks and sub-tasks

- Domain

- Material parameters

- Boundary conditions

- Remeshing.

• Listing file;

• Evolution method for the treatment of

the non-linearity

• Time-dependent flow

• Input of experimental rheology data in

Polymat

• Introduction to CFD-Post

All topics are covered using a combination



Blow Molding, Extrusion, Mixing,

Viscoelastic

ANSYS® POLYFLOW® Solver I Regular training - 2 days

PrerequisitesThe course assumes you have prior

experience of working with a mesh

generation software.

Learning objectivesProcessing:

For a given software you should be able to:

• select appropriate physical models

• define material properties

• prescribe boundary and operating

conditions

• set solver controls

• set up solution convergence monitors

• provide an initial solution

• display and examine results.




Combustion and Radiation, Customization

(of CFX® Pre, Solver and Post), Fluid-

Structure Interaction, Multiphase, Turbo

machinery

Particle tracking in a engine

ANSYS® CFX® Solver I Regular training - 2 days

Thickness distribution in a thermoformed dashboard

1312

PrerequisitesThis course assumes that the attendees

have some understanding of fluid dynamics,

heat transfer, turbulence and experience

with ANSYS® FLUENT®.

Learning objectives• Reynolds Averaged Navier-Stokes

(RANS) modeling approach

• Low Reynolds number turbulence

models in ANSYS® FLUENT®

• Large Eddy Simulation (LES) turbulence

model in ANSYS® FLUENT®

• Near wall treatment options within

ANSYS® FLUENT®

• Modeling turbulent flow problems with

ANSYS® FLUENT®

• Turbulent flow examples.

Course agendaLectures:

• Overview of Turbulence Model (Part 1)

• Overview of Turbulence Model (Part 2)

• Turbulence Modeling Options in

ANSYS® FLUENT®

• Modeling Turbulent Flow With ANSYS®

FLUENT®

• Turbulent Flow Examples.

Hands-On:

• Wavy Channel

• Compact Heat Exchanger.

Turbulence I Advanced ANSYS® FLUENT® - 1 day

Prerequisites A technical education and background are

recommended but an engineering degree

is not required.

Overview ANSYS® Mechanical™ provides solutions

for many types of analyses including

structural, thermal, modal, linear buckling

and shape optimization studies. ANSYS®

Mechanical™ is an intuitive mechanical

analysis tool that allows geometry to

be imported from a number of different

CAD systems. It can be used to verify

product performance and integrity from

the concept phase through the various

product design and development

phases. The use of ANSYS® Mechanical™

accelerates product development by

providing rapid feedback on multiple

design scenarios, which reduces the need

for multiple prototypes and product

testing iterations.

Course description This training course teaches trainees how

to effectively use ANSYS® Mechanical™

to build a mechanical simulation model,

analyze it and interpret the results.

Course Topics Include: Introduction,

Mechanical Basics, General Preprocessing,

Static Structural Analysis, Vibration Analysis,

Thermal Analysis, Linear Buckling Analysis,

Results Post processing, CAD & Parameters.

Each course chapter is followed by “hands-

on” workshops and exercises.


Heat Transfer, Structural Nonlinearies,

Dynamics, Rigid Body Flexible Body

Dynamics, Using Command Objects

ANSYS® Mechanical™ Solver I Regular training - 2 days

Linear dynamic analysis of a semi-submersible

Vortex structures generated by aircraft landing gear

1514

PrerequisitesThe course assumes you have previous

ANSYS® FLUENT® experience and a basic

knowledge of C-programming.

Learning ObjectivesBy the end of this course you should be

able to:

• create your own UDFs

• compile UDFs

• execute UDFs.

Course agendaThe topic is covered using a combination


Lectures:

• UDF Basics and Philosophy

• Compiled and Interpreted UDFs

• Accessing Variables from UDFs

• Use of UDFs in a number of

applications, such as setting boundary

conditions and source terms etc.

Workshop:

• Position Dependent Porous Media;

• Sinusoidal Wall Temperature Variation

User defined functions I Advanced ANSYS® FLUENT® - 1 day


experience of using ANSYS® FLUENT® and a

general appreciation of multiphase physics.

Learning objectivesBy the end of this course you should be

able to:

• differentiate and identify adequacies of

several multiphase models available in

ANSYS® FLUENT®

• identify and setup the most suitable

multiphase models for given applications.

Course agendaLectures:

• Introduction and Definitions

• The Mixture Model in ANSYS® FLUENT®

• The Eulerian Model in ANSYS® FLUENT®

• The VOF Model in ANSYS® FLUENT®

• UDF’s for Multiphase Flows

Hands-on:

• Heat and Mass Transfer with The

Mixture Model

• Modeling Uniform Fluidization in a

Fluidized Bed

• Horizontal Film Boiling

Multiphase I Advanced ANSYS® FLUENT® - 1 day

Fluidized bed

1716


experience of working with any of our

software.

Learning objectivesPreprocessing - By the end of this course

you should be able to:

• create 3d geometries using ANSYS®

Airpak®

• mesh 3d geometries using the

structured and unstructured grid

approach

• examine the quality of the mesh.

Processing - For a given problem you

should be able to:

• select appropriate physical models

• define material properties

• prescribe boundary and operating

conditions

• set solver controls

• set up solution convergence monitors;

• provide an initial solution.

Post processing

display and examine results.



Lectures and hands-on:

Introduction & Overview, Building Models

with ANSYS® Airpak®, Meshing, Physical

Modeling and Solving the Problem,

Post Processing, Transient Problems,

Miscellaneous Topics

ANSYS® Airpak® I Advanced - 2 day




engineering/physics is assumed.

OverviewGAMBIT® preprocessor provides a concise

and powerful set of solid modelling-based

geometry tools. Top-down geometry

construction using 3D primitives allows

you to create geometries fast.

Course objectivesThe aim of this two-day course is to

provide enough training for the user to

directly start building and meshing his

own models using GAMBIT®.

• Systematically go through the GUI and

point out all important features and

capabilities

• Create 2D and 3D geometry through

all available sources and also discuss

different strategies within geometry

creation and decomposition

• Mesh a variety of problems and discuss

the relevant use of different meshing

algorithms for different geometries

GAMBIT® I Advanced - 2 days

Hex mesh of a catalyst

Office ventilation

1918


experience of using ANSYS® POLYFLOW®.

Course objectivesT h i s c o u r s e i s a c o m p r e h e n s i v e

introduction to the numerical simulation

of extrusion and die design using ANSYS®

POLYFLOW®. It is essentially devoted to 2-D

and 3-D free surface flow problems of non-

Newtonian inelastic fluids.

We elaborate on the concept of free

surface in extrusion and the associated

numerical tools: initial conditions, direction

of motion, corner strategy (for 3-D free

surfaces), fixed and moving domains, re-

meshing algorithms, direct and inverse

extrusion problems.

We show how to define a simple problem

at the outset and how to handle non-

linearities through appropriate evolution

parameters . S e vera l 2 -D and 3-D

applications of technical importance are

discussed while sample problems are

solved by the trainees at a workstation.

Extrusion I Advanced ANSYS® POLYFLOW® - 1 day



Course objectivesThe purpose of this session is to introduce

ANSYS® POLYFLOW® blow molding

module. Models and numerical tools

will be presented. Several flow models

are available: 2-D and 3-D models with

calculation through the thickness and thin

shell elements as well. Their advantages

and limitations will be discussed. The most

important numerical tools will also be

shown: (i) the remeshing techniques with

their usage and (ii) the contact algorithm

with its geometric consequences.

The theoretical presentation is followed

by suggested exercises solved on

the computer, and which show the

various capabilities of these software

developments. During the exercises,

important features such as parison

extrusion, pinch-off, inflation and cooling

may be investigated. Numerical results will

be analysed and commented on.

Blow molding I Advanced ANSYS® POLYFLOW® - 1 day

Parison programming and extrusion blow molding using shell elements

Extrusion of a viscoelastic food material

2120



Course objectivesThis course is a comprehensive introduction

to the modeling and numerical simulation

of viscoelastic flows with the ANSYS®

POLYFLOW® software.

We introduce and comment on some

well-known viscoelastic phenomena,

such as the Weissenberg effect or the

swelling at die exit. Next, modeling

tools are introduced: Newtonian and

generalized Newtonian fluid models as

well as viscoelastic models. The properties

of the several models are discussed. The

numerical treatment is also introduced.

Finally, questions such as selection of

a model and definition of a flow case

are presented, as well as a few typical

applications. Exercises are solved by the

attendees on a workstation.

Viscoelastic I Advanced ANSYS® POLYFLOW® - 1 day



Course objectivesIn this training course, we will present

the capabilities of ANSYS® POLYFLOW®

with regards to solving complex flows

involving highly non-linear rheological

and thermal behaviors and how you

can take advantage of those results to

express them into an industrial and usable

language. Historically, this Polystat

module was developed to provide a

quantitative evaluation of a given mixing

process (laminar mixing, dispersion, and

segregation scale). However, as shown in

this session, the interest of this module

(a true statistical toolbox) is much larger:

determination of the RTD (residence time

distribution), the thermal degradation of a

polymer, among others.

After a brief theoretical introduction of

the mathematical tools, three tutorials

are analyzed in details to give a complete

overview of these Polystat module

capabilities: comparison of two mixers,

analysis of a glass furnac and post-processing

of an extrusion process simulation.

Mixing I Advanced ANSYS® POLYFLOW® - 1 day

Mixing screw Extrusion of a viscoelastic food material

2322

Registration and general terms

RegistrationSend an email to training-belgium@ansys.

com no later than two weeks prior the

course. Due to limitations in the number

of participants, early registration is advised.

Priority will be given on the basis of the

date of receipt.

Schedule Courses start at 9:00 a.m. and end at

about 5:30 p.m. Upon registration, a list

of hotels along with an access map will

be sent to the participants. Upon request,

ANSYS Belgium can organize personalized

courses in Belgium or on-site

AccommodationsUpon registration, a list of hotels along

with an access map will be sent to the

participant. Please make your own hotel

reservations mentioning your participation

at the seminar.

WithdrawalFor a full refund, a written notice of

withdrawal must be received two weeks

prior to the beginning of the course. If a

written notice of withdrawal is received

one week prior to the event, half of the

course fee will be refunded. The entire

course fee will be charged for later

withdrawals. However, substitutions may

be made at any time.

Course feeThe course fee is per person. It includes

attendance, class notes, lunch and day-

time refreshments. Hotel accommodations

are not included. There is no special fee for

academic institutions or trainees.

Special coursesOn-site courses can be organized outside

the regular schedule of courses and take

place at the client’s site. The availability of a

conference room, projectors, computers and

other materials are the client’s responsibility.

Upon request, Fluent Benelux can organize

personalized courses in Belgium or on-site.

Please contact us for details.

The list below shows the additional courses

available for our products. However if you

cannot see what you are looking for, please

contact us since the training need can

often be met using Focus Days.

Meshing tools: TGrid™, ANSYS® ICEM

CFD™ Tetra/Prism, ANSYS® ICEM CFD™ Hex

ANSYS® FLUENT®: Automotive HVAC

and Underhood, Combustion, Dynamic

Mesh, Heat Transfer, Multiphase, Positive

Displacement Pumps, Spray and Particle

Modeling, Turbulence , UDFs

ANSYS® CFX®: Combustion and Radiation,

Customization (of CFX® Pre, Solver

and Post), Fluid-Structure Interaction,

Multiphase, Turbo machinery

ANSYS® POLYFLOW®: Blow Molding,

Extrusion, Mixing, Viscoelastic

ANSYS® Mechanical™: Advanced

Structural Nonlinearities, Advanced Contact,

Fatigue, Fracture Mechanics, Heat Transfer

ANSYS® ED™ and ANSYS® AUTODYN®:

ANSYS® ED™ Material Modeling for Ductile

and Explosive Materials, ANSYS® ED™

Material Modeling for Brittle/Geological

and Composite Mater ia ls , ANSYS®

AUTODYN® User Subroutines

ANSYS® ANSOFT: Ansoft Designer®, HFSS™

Optimization: ANSYS®DesignXplorer™

Additional courses

ANSYS Belgium SAAvenue Pasteur, 41300 WavreBelgium

2524

If you are arriving by car:from Brussels:

• Take the motorway E 411 direction

Namur.

• Take exit n° 5 bis, Wavre Zoning Nord

and turn right, pass the bridge on top of

the motorway direction Zoning Nord

• Go straight ahead at the roundabout

and follow the Zoning Nord “Les

Collines” direction

• Turn right at the light. Once you are in

the zoning “Les collines”, follow the road,

then turn right at the next roundabout,

the building is located at number

4, avenue Pasteur. There are signed

pointing to the ANSYS® building.

from Namur:

• Take the mortorway E 411 direction

Brussels.

• Take exit n° 5 Bierges-Rixensart, turn

right and drive to the roundabout. From

there continue as explained

If you are arriving by train:For detailed train timetables in French,

English, Dutch and German, go to

www.sncb.be

Easy suggestions, with one or two changes:from Brussels - Central / Nord stations:

• Take the IC (Intercity) train direction

Leuven/Liège or Eupen (three departure

an hour), until Leuven. Duration: about

20 minutes

• At Leuven take the bus “De Lijn” 337

direction Wavre, departure every hour

‘07; the bus station “De Lijn” is next to

the railway station. Duration: about

45 minutes

• Ask for the bus stop “Zoning Nord”;

ANSYS Belgium is located in the Wavre

Nord Business Park. Walking distance:

3 minutes

from Brussels Airport:

• Take the IR (InterRegion train) or local

train direction Leuven (two departure

an hour). Duration: 15 minutes

• At Leuven take the bus “De Lijn” 337

direction Wavre, departure every hour

‘07; the bus station “De Lijn” is next to

the railway station. Duration: about

45 minutes

• Ask for the bus stop “Zoning Nord”;

ANSYS Belgium is located in the Wavre

Nord Business Park. Walking distance:

3 minutes

Access to ANSYS Belgium

You find hereafter the access plan to ANSYS Belgium.

If you are arriving by plane (Brussels airport):• by train: Take the rail link “Airport - City - Express” (three to four departures per hour; all

departing trains go through Brussels). Change at Brussels-Nord, and from there, continue as

explained above.

• by taxi: Please mention that you wish to reach ANSYS Belgium, in the Zoning Nord de

Wavre (E411 Highway exit 5 bis).

Brussels

NamurE411

5C.A. Wavre Nord

Rixensart - Bierges

Station ESSO

N257

Chaussée des c

ollines

A4

2726

Hotels located in the neighborhood of ANSYS BelgiumLeonardo Hotel Wavre

Rue de la Wastinne, 45

1300 WAVRE

Tel. : +32 (0)10/41.13.63

Fax: +32 (0)10/41.19.22

E-mail: [email protected]

http://www.leonardo-hotels.com

Single room: 115 € with breakfast (2010 rate - subject to change)

Please mention: special ANSYS rate

Free shuttle to Zoning Nord: to check with the hotel

Best Western Hotel Brussels East

Avenue Lavoisier, 12

1300 WAVRE

Tel. : +32 (0)10/88.74.30

Fax: +32 (0)10/22.57.01

http://www.bestwestern.be/overview.asp?hotelid=177

Single room: 81 € with breakfast (2010 rate - subject to change)

Walking distance from the office

Please mention: special ANSYS rate and make your reservation by mail :

[email protected]

Contacts

If you have any question about our Training

Services, please contact our local office:


Tel. : +32 (0)10 45 28 61

Fax: +32 (0)10 45 30 09

E-mail: [email protected]

Website: www.ansys-belgium.com

For more information about our company,

please visit our corporate website:

www.ansys.com

Accommodations

Please find hereafter suggested hotels

located in the neighborhood of ANSYS

Belgium.

Please make your own hotel reservation

mentioning your participation at the

seminar.

For more information about our company, please visit our corporate website :

www.ansys.com

CONTACTSIf you have any question about our Training Services, please contact our local office:


Tel. : +32 ( 0 )10 45 28 61Fax : +32 ( 0 )10 45 30 09

Email : [email protected]

Website : www.ansys-belgium.com

ANSYS BELGIUM TRAINING GUIDE Belgium/staticassets... · ANSYS BELGIUM TRAINING GUIDE ... • Intro...

Documents

Transcript of ANSYS BELGIUM TRAINING GUIDE Belgium/staticassets... · ANSYS BELGIUM TRAINING GUIDE ... • Intro...