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Training

Finite Element Analysis

Our company provides an training program on finite element analysis to enrich your knowledge in that field. The duration of this program is for 14 days. Certification on this program also given after successful completion of fifteen days of training. The course details are given below.

Finite Element Analysis is a powerful, widely used and universally accepted technique. However, for those new to FEA there is a steep learning curve to overcome, with a bewildering array of:

  • element types
  • solution types
  • meshing methods
  • loading and constraint methods
  • pre-post processing options

This is before we get down to the engineering physics behind the problem, with associated classic traps and errors. What is needed is guidance via a thorough but practical assessment of the method and how to use it in the real world.

Content includes:

  • Background to FEA
  • Defining your objectives and planning your analysis
  • Making healthy models
  • Real-world constraints and loading
  • Engineering assessment – is your model realistic
  • Integrating with CAD and geometry
  1. Problem Description: This portion is the starting of the project which includes the description of the objectives of the analysis. Describe the failure criteria or engineering requirements against which the analysis will be compared. Include a physical description of the part to be analyzed. The overall dimensions, material, loading conditions, and description of the operation or application of the part should be included.
  2. FEA Code: Brief summary of the finite element program and computer system used for the analysis.
  3. Model Description and Assumptions: Include plots of the finite element model and a description of types of elements used, boundary conditions, applied loads and relevant engineering assumptions.
  4. Results and Analysis: Include the important results (displacement, mode shape, thermal, and/or stress contour plots). A discussion should be accompanied these plots, describing the behavior of the model and how it relates to the actual expected behavior of the part. Include tables showing the stresses and displacements (if structure analysis) for critical sections of the model. Include hand calculations, theoretical solutions and/or experimental results supporting the finite element results. A brief discussion of these calculations along with references should be included.
  5. Conclusions and recommendations: Describe what was learned from the analysis and what conclusions can be drawn. Summarize the results in conjunction with the failure criteria or engineering requirements. If the analysis shows an inadequate design, recommendation for design modifications would be included in this section.  FEA_training_plan