This course brings together theoretical and computational stress analysis through Finite Element simulations, allowing delegates to appreciate how the two disciplines interact in practice and what their strengths and limitations are. Read more Read less
The examination of Finite Element Analysis (FEA) for various practical applications (eg engineering components, composite structures, rotating disks, cracked geometries) in conjunction with relevant case studies will allow delegates to combine theoretical understanding with practical experience in order to develop their skills to model and analyse complex engineering problems.
At a glance
- Duration5 days
- LocationCranfield Campus
- Cost£1,500. Concessions available
Course structureLectures, Practical Finite Element Tutorial sessions in PC lab, Lab tours.
What you will learn
On successful completion of this short course you will be able to:
- Develop a strong foundation on stress analysis and demonstrate the ability to analyse a range of structural problems
- Understand the fundamentals of Finite Element Analysis, be able to evaluate methodologies applied to the analysis of structural members (beams, plates, shells, struts), and critically evaluate the applicability and limitations of the methods and the ability to make use of original thought and judgement when approaching structural analysis
- Demonstrate an in-depth awareness of current practice through case studies of engineering problems
- Develop skills in using the most widely applied commercial finite element software package (ABAQUS) and some of its advanced functions
- Understand the importance of mesh sensitivity analysis and validation of finite element models.
Stress Analysis: Introduction to stress analysis of components and structures, Ductile and brittle materials, Tensile data analysis, Material properties, Isotropic/kinematic hardening, Dynamic strain aging, Complex stress and strain, Stress and strain transformation, Principal stresses, Maximum shear stress, Mohr’s circle, Constitutive stress-strain equations, Fracture and yield criteria, Constraint and triaxiality effects, Plane stress and plane strain conditions, Thin walled cylinder theory, Thick walled cylinder theory (Lame Equations), Compound cylinders, Plastic deformation of cylinders, Introduction to computational stress analysis.
Finite Element Analysis: Introduction to FEA, Types of elements, Integration points, Meshing, Mesh convergence, Visualisation, Results interpretation, Beam structures under static and dynamic loading, Stress concentration in steel and composite plates, Tubular assemblies, 2D and 3D modelling of solid structures, Axisymmetry and symmetry boundary conditions, CS1: Stress and strain variation in a pressure vessel subjected to different loading conditions, CS2: Prediction and validation of the stress and strain fields ahead of the crack tip (case studies are indicative).
Who should attend
Those involved in the design and analysis of engineering components and structures, structural engineers, pipeline engineers, PhD students and Post-docs who are working on FEA related projects.
Concessions10% reduced fee:
- multiple bookings
- Cranfield Alumni
- if booked 8 weeks before the start of the course.
- PhD students
Accommodation options and prices
This is a non-residential course. If you would like to book accommodation on campus, please contact Mitchell Hall or Cranfield Management Development Centre directly. Further information regarding our accommodation on campus can be found here.
Alternatively you may wish to make your own arrangements at a nearby hotel.
Location and travel
Cranfield University is situated in Bedfordshire close to the border with Buckinghamshire. The University is located almost midway between the towns of Bedford and Milton Keynes and is conveniently situated between junctions 13 and 14 of the M1.
London Luton, Stansted and Heathrow airports are 30, 90 and 90 minutes respectively by car, offering superb connections to and from just about anywhere in the world.
Read our Professional development (CPD) booking conditions.