Non-Linear Finite Element Analysis (FEA)

October 3rd - October 17th, 2016 07:00 PDT / 10:00 EDT / 15:00 BST / 16:00 CEST 2-Week Online Training Course - Three 2.5 hour session/week and two 2.5 hour session the 2nd weekEngineering Board PDH Credits: 12.5 hours*

new content - expanded to FIVE sessions

Note: Although the live sessions take place at these times, is is perfectly acceptable to take the course and follow only the course recordings. Full tutor interaction is available at any time using the online course discussion group.

Course Overview

Many problems facing designers and engineers are nonlinear in nature. The response of a structure cannot be simply assessed using linear assumptions.

Nonlinear behavior can take many forms and can be bewildering to the newcomer. All physical systems in the real world are inherently nonlinear in nature.

One of the most difficult tasks facing an engineer is to decide whether a nonlinear analysis is really needed and if so what degree of nonlinearity should be applied.

Looking at a bolt heavily loaded in an attachment fitting, it may be that the change in stiffness and load distribution path are critical in evaluating peak stress levels. Perhaps the assembly is in an overload condition and we need to check that plastic growth is stable and there is no ultimate failure – bent but not broken!

A flange on a connector arm may be under compressive load, but also sees heavy bending. We need to assess the resistance to buckling with deflection dependent loading paths and possible plastic behavior.

Whatever the nature of the challenge, the objective of this course is to break down the nonlinear problem into clearly defined steps, give an overview of the physics involved and show how to successfully implement practical solutions using Finite Element Analysis.

Course Process and Details

The course is completely code independent. No software is required.

Each topic in the class is treated as a building block and is presented using an overview of the physics and theory involved. The math is kept simple and the emphasis is on practical examples from real life to illustrate the topic. The mapping to Finite Element analysis techniques is shown with numerous workshops. The tutor will be running analysis interactively and involving the students in the process via Q and A periods during each session, follow up emails and a course bulletin board

Students are shown the various approximation methods and how to judge which are acceptable and appropriate for solving a wide range of practical problems. Practical considerations of types of nonlinearity, solutions available, elements to use and structural details are shown by numerous examples.

Of equal importance is the assessment and interpretation of results. This starts with ensuring a building block linear solution is feasible and accurate. Once this stage is completed then the degree of nonlinear complexity is gradually increased until an effective simulation of the real world event is developed.  A range of hints and tips are shown for a wide range of different nonlinear analysis types.

• Interaction is encouraged throughout the course. Students are welcome to send in problems from industry and these will be discussed as time permits.

• Full notes are provided for the students, together with personal passwords for e-learning backup material, bulletin board access, etc.

Who Should Attend?

This course is aimed at practicing engineers who wish to learn more about how to apply finite element techniques to nonlinear analysis in the most effective manner. Ideally a student should have some experience of FEA analysis, but this is not essential. The material that is presented is independent of any particular software package, making it ideally suited to current and potential users of all commercial finite element software systems. This course is a must for all engineers aiming to use FEA as a reliable predictive tool for nonlinear analysis.

Course Program

Note: This is a five-week course. Each session represents one 2.5 hour session.(Note: Sessions may last for 2.5-3 hours, including the Q&A sessions.)

Recordings of each session are made available to course attendees in the event they are unable to participate in one or more of the live meetings, or if they wish to review the material following each session.

The times and listed for each session are tentative; we try to schedule these sessions at times convenient for the majority of course attendees.

Session 1

• Background to non-linear analysis
• Linear versus non-linear
• Overview of types of non-linearity
• Geometric non-linearity
• Buckling
• Follower forces
• Material non-linearity
• Contact non-linearity
• Example – oil tank
• Session 1 homework

Session 2

• Review of homework from session 1
• Geometric non-linearity
• Background
• Theory
• Shallow Roof example
• Non-linear strategy
• Non-linear convergence
• Real world boundary conditions
• Scope of the analysis
• Session 2 homework

Session 3

• Review: Session 2 Homework
• Further Buckling
• Background and Theory
• Linear buckling example
• Non-linear Buckling
• Contact surface methods
• Background
• Types of contact
• Contact challenges

Session 4

• Further Nonlinear Material analysis
• Background
• Yield Failure theories
• Hardening Types
• Beyond Yield
• Examples
• Viscoelasticity
• Background
• Examples
• Hyperelastic material analysis
• Background
• Examples

Session 5

• Mesh adaptivity and element erosion
• Nonlinear transient analysis
• Implicit versus explicit analysis
• Explicit background
• Explicit rod example
• Explicit cylinder example
• Overview of Explicit analysis
• Lagrangian and Eulerian methods

*Note: While we will make every attempt to follow the course outline, the schedule may be shifted at some point. However, ample notice will be given prior to the start of the course date with regards to the course schedule.

Special Note(s):

Telephony surcharges may apply for attendees who are located outside of North America, South America and Europe. These surcharges are related to individuals who join the audio portion of the web-meeting by calling in to the provided toll/toll-free teleconferencing lines. We have made a VoIP option available so anyone attending the class can join using a headset (headphones w/ microphone) connected to the computer. There is no associated surcharge to utilize the VoIP option, and is actually encouraged to ensure NAFEMS is able to keep the e-Learning course fees as low as possible. Please send an email to the e-Learning coordinator (e-learning @ nafems.org ) to determine if these surcharges may apply to your specific case.

Just as with a live face-to-face training course, each registration only covers one person. If you plan to register a large group (10+), please send an email to e-learning @ nafems.org in advance for group discounts.

Product Details

Order Ref: eL174
Type: eLearning

Member Price
£241.00 | \$313.55 | €278.71
Non-member Price
£360.00 | \$468.38 | €416.33

Not Available to Attend this Time?

Would you like us to notify you when the next course on Non-Linear FEA is open for enrollment? If so, add yourself to the eLearning Waitlist!

Course Tutor:
Tony Abbey

Session 5 - Monday October 17th

Engineering Board PDH Credits

*It is your individual responsibility to check whether these e-learning courses satisfy the criteria set-out by your state engineering board. NAFEMS does not guarantee that your individual board will accept these courses for PDH credit, but we believe that the courses comply with regulations in most US states (except Florida, North Carolina, Louisiana, and New York, where providors are required to be pre-approved).