Finite Element Primer for Engineers: Part 3
Mike Barton & S. D. Rajan
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Contents
• Introduction to the Finite Element Method (FEM)
• Steps in Using the FEM (an Example from Solid
Mechanics)
• Examples
• Commercial FEM Software
• Competing Technologies
• Future Trends
• Internet Resources
• References
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Information Available from Various Types of FEM Analysis
• Static analysis
» Deflection
» Stresses
» Strains
» Forces
» Energies
• Dynamic analysis
» Frequencies
» Deflection (mode
shape)
» Stresses
» Strains
» Forces
» Energies
• Heat transfer analysis
»Temperature
» Heat fluxes
» Thermal gradients
» Heat flow from
convection faces
• Fluid analysis
» Pressures
» Gas temperatures
» Convection coefficients
» Velocities
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Example FEM Application Areas
• Automotive industry
• Aerospace industry
» Static analyses
» Static analyses
» Modal analyses
» Modal analyses
» Transient dynamics
» Aerodynamics
» Heat transfer
» Transient dynamics
» Mechanisms
» Heat transfer
» Fracture mechanics
» Fracture mechanics
» Metal forming
» Creep and plasticity analyses
» Crashworthiness
» Composite materials
» Aeroelasticity
• Architectural
» Metal forming
» Soil mechanics
» Crashworthiness
» Rock mechanics
» Hydraulics
» Fracture mechanics
» Hydroelasticity
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Variety of FEM Solutions is Wide and Growing Wider
• The FEM has been applied to a richly diverse array of scientific
and technological problems.
• The next few slides present some examples of the FEM applied
to a variety of real-world design and analysis problems.
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• This example shows an intravenous pump modeled
using hexahedral elements.
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Car tires require sophisticated analysis because of their complex geometry, large
deformations, nonlinear material behavior, and varying contact conditions. Brick
elements are used to represent the tread and steel bead, while shell elements are
used in the wall area. Membrane elements are used to represent the tire cords.
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This guitar features two strips of
graphite running the length of the
neck. This FEM model was used to
study how much the neck moved
when string forces were applied and
moisture content
changed.
Using the FEM calculations,
designers could try different
reinforcement scenarios to increase
neck stability.
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Dynamic analysis of a tuning fork, to find it's first eight modes of vibration.
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Contents
• Introduction to the Finite Element Method (FEM)
• Steps in Using the FEM (an Example from Solid
Mechanics)
• Examples
• Commercial FEM Software
• Competing Technologies
• Future Trends
• Internet Resources
• References
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Commercially Available FEM Software Suites
• Here we present a survey of some of the better-known
integrated FEM software packages. These integrated
systems allow users to perform all facets of FEM analysis,
including modeling, meshing, solution and post-processing.
• The Internet provides a vast new resource for individuals
interested in the FEM. See the Reference section of this
paper for interesting FEM links to start your Internet
research.
• In addition to the integrated FEM packages listed below,
many vendors offer dedicated software for solid modeling,
mesh generation, FE equation generation and solution, and
post-processing.
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Commercially Available FEM Software Suites (cont.)
(partial list)
Software Package
Introduced
Comments
ABAQUS
1978
General purpose, with special emphasis on advanced linear and nonlinear structures and heat transfer applications.
ADINA 7.0
1975
Optimized for structural and heat transfer applications. Limited element library. Extensive material model library.
ALGOR
1984
First FEM package available for PC use.
ANSYS/LS-DYNA
N/A
For solving highly nonlinear structural dynamics problems (impact, large deformation, nonlinear materials, etc.)
ANSYS/MECHANICAL
1970
Probably the best-known and most widely-used FEM software. Complete structures/thermal/acoustics modleing.
ANSYS/Multiphysics
N/A
Coupled-field, multidisciplinary FEM program.
ELFEN
N/A
Includes linear and nonlinear buckling, modal analysis, transient heat transfer analysis, impact and fragmentation.
GENESIS
N/A
Fully integrated finite element analysis and numerical optimization software for structural analysis.
LUSAS
N/A
Includes automatic meshing, advanced non-linear analysis, and composites analysis.
MARC 6.2
1970
3D automated contact analysis capabilities suited for studying tough manufacturing problems, (metal forming/ etc.)
MSC/FEA
1971
MSC participated in the 1965 development of NASA's public-domain FEM code, NASTRAN.
MSC/NASTRAN for Windows
N/A
Handles stress, vibration, dynamic, nonlinear, heat transfer, and fluid flow analyses of mechanical components.
NISA/DISPLAY
1973
A family of general purpose FEM programs for PCs and workstations. Modular design.
PAM
1973
FEM software optimized to study restraint systems (PAM-SAFE), impacts (PAM-SHOCK) and metal forming.
SAMCEF
1965
One of the oldest FEM codes available. A powerful FEM package for structural and heat transfer analysis.
STARDYNE
1967
The world's first commercially available Finite Element Analysis software.
STARS
N/A
Integrated, general-purpose, finite element software. Developed by NASA.
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Contents
• Introduction to the Finite Element Method (FEM)
• Steps in Using the FEM (an Example from Solid
Mechanics)
• Examples
• Commercial FEM Software
• Competing Technologies
• Future Trends
• Internet Resources
• References
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Technologies That Compete With the FEM
• Other numerical solution methods:
– Finite differences
» Approximates the derivatives in the differential equation using
difference equations.
» Useful for solving heat transfer and fluid mechanics problems.
» Works well for two-dimensional regions with boundaries parallel
to the coordinate axes.
» Cumbersome when regions have curved boundaries.
– Weighted residual methods (not confined to a small subdomain):
» Collocation
» Subdomain
» Least squares*
» Galerkin’s method*
– Variational Methods* (not confined to a small subdomain)
* Denotes a method that has been used to formulate finite element
solutions.
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Technologies that Compete With the FEM (cont.)
• Prototype Testing
» Reliable. Well-understood.
» Trusted by regulatory agencies (FAA, DOT, etc.)
» Results are essential for calibration of simulation software.
» Results are essential to verify modeled results from simulation.
» Non destructive testing (NDT) is lowering costs of testing in
general.
» Expensive, compared to simulation.
» Time consuming.
» Development programs that rely too much on testing are
increasingly less competitive in today’s market.
» Faster product development schedules are pressuring the quality of
development test efforts.
» Data integrity is more difficult to maintain, compared to
simulation.
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Contents
• Introduction to the Finite Element Method (FEM)
• Steps in Using the FEM (an Example from Solid
Mechanics)
• Examples
• Commercial FEM Software
• Competing Technologies
• Future Trends
• Internet Resources
• References
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Future Trends in the FEM and Simulation
• The FEM in particular, and simulation in general, are becoming
integrated with the entire product development process (rather than just
another task in the product development process):
– FEM cannot become the bottleneck.
• A broader range of people are using the FEM:
– Not just hard-core analysts.
• Increased data sharing between analysis data sources (CAD, testing,
FEM software, ERM software.)
• FEM software is becoming easier to use:
– Improved GUIs, automeshers.
– Increased use of sophisticated shellscripts and “wizards.”
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Future Trends in the FEM and Simulation (cont.)
• Enhanced multiphysics capabilities are coming:
– Coupling between numerous physical phenomena.
» Ex: Fluid-structural interaction is the most common example.
» Ex: Semiconductor circuits, EMI and thermal buildup vary with current
densities.
• Improved life predictors, improved service estimations.
• Increasing use of non-deterministic analysis and design methods:
– Statistical modeling of material properties, tolerances, and anticipated loads.
– Sensitivity analyses.
• Faster and more powerful computer hardware. Massively parallel processing.
•Decreasing reliance on testing.
• FEM and simulation software available via Internet subscription.
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Contents
• Introduction to the Finite Element Method (FEM)
• Steps in Using the FEM (an Example from Solid
Mechanics)
• Examples
• Commercial FEM Software
• Competing Technologies
• Future Trends
• Internet Resources
• References
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Selected FEM Resources on the Internet
• The internet offers virtually unlimited resources to persons
interested in the FEM.
• The following links are a small sample of FEM sites on the
Internet which the author has found useful. Thousands more
(at least!) are readily available.
• Most commercial FEM developers have extensive presence
on the Internet, with web pages that include company
histories, descriptions of software products, and example FEM
solutions.
• Other good FEM resources on the web originate with
academia, government, and discussion and user groups.
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Selected FEM Resources on the Internet (cont.)
• http://www.ansys.net
•http://www.engineeringzones.com - A website created to educate people in the latest
engineering technologies, manufacturing techniques and software tools. Exellent FEM
links, including links to all commercial providers of FEM software.
• http://www.comco.com/feaworld/feaworld.html - Extensive FEM links, categorized
by analysis type (mechanical, fluids, electromagnetic, etc.)
• http://www.engr.usask.ca/%7Emacphed/finite/fe_resources/fe_resources.html Lists many public domain and shareware programs.
• http://sog1.me.qub.ac.uk/ - Home page of the the Finite Element Research Group at
The Queen's University of Belfast. Excellent set of FEM links.
• http://www.tenlinks.com/cae/ - Hundreds of links to useful and interesting CAE cited,
including FEM, CAE, free software, and career information.
•http://www.gorni.eng.br/ - Extensive FEM links.
• http://www.nafems.org/ - National Agency for Finite Element Methods and Standards
(NAFEMS).
•http://www.6dof.com/
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Contents
• Introduction to the Finite Element Method (FEM)
• Steps in Using the FEM (an Example from Solid
Mechanics)
• Examples
• Commercial FEM Software
• Competing Technologies
• Future Trends
• Internet Resources
• References
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References
Cashman, J., 2000. “Future of Engineering Simulation,” ANSYS
Solutions, Vol. 2, No. 1, pp. 3-4.
Chandrupatla, T. R. and Ashok D. Belegundu, 1997. Introduction to
Finite Elements in Engineering, Prentice Hall, Upper Saddle River,
New Jersey.
Kardestuncer, H., 1987. Finite Element Handbook, McGraw-Hill,
New York.
Krouse, J., 2000. “Physical Testing Gets a Bum Rap,” ANSYS
Solutions, Vol. 2, No. 2, p. 2.
Lentz, J., 1994. Finite Element Analysis Cross Training, unpublished
lecture notes, Honeywell Engines and Systems, Phoenix, Az.
Nikishkov, G.V., 1998. Introduction to the Finite Element Method,
unpublished lecture notes, University of Arizona, Tucson, Az.
Rajan, S.D., 1998. Finite Elements for Engineers, unpublished
lecture notes, Arizona State University, Tempe, Az.
Segerlind, L. J., 1984. Applied Finite Element Analysis, John Wiley
and Sons, New York.
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