Difference between revisions of "Examples"

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The following examples are provided to illustrate how users could use FEAP to solve some basic problems.
The following alphabetical list of examples are provided to illustrate how users could use FEAP to solve some basic problems.
 
 


== Contact Problems ==
== Contact Problems ==


== Coupled Thermo-mechanical Analyses ==
== Coupled Thermo-mechanical Analyses ==
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FEAP has a simple [[Lysmer-Kuhlemeyer]] boundary element that can be used to approximate a non-reflecting
FEAP has a simple [[Lysmer-Kuhlemeyer]] boundary element that can be used to approximate a non-reflecting
boundary in a transient computation.
boundary in a transient computation.


== Plate buckling ==
== Plate buckling ==
[[Plate buckling]] and shell buckling computations came be made using FEAP's linear shell element.
[[Plate buckling]] and shell buckling computations came be made using FEAP's linear shell element.
== Spin boundary condition ==
A [[Spin boundary]] condition is possible via the use of the SPIN command within a LOAD GROUp


== Static Analyses ==
== Static Analyses ==

Revision as of 11:14, 29 June 2023

The following alphabetical list of examples are provided to illustrate how users could use FEAP to solve some basic problems.

Contact Problems

Coupled Thermo-mechanical Analyses

Hill-Mandel Computations

FEAP has a facility for computing Hill-Mandel averages, stress and tangent tensor components. To use this facility one needs to have a periodic mesh.

Isogeometric Analyses

J-Integral Computation

FEAP has a facility for computing J Integrals (energy release rates) in elastic problems. The feature is slightly experimental so please verify that you are getting sensible answers for your class of problems before relying on it.

Lysmer-Kuhlemeyer boundary conditions

FEAP has a simple Lysmer-Kuhlemeyer boundary element that can be used to approximate a non-reflecting boundary in a transient computation.

Plate buckling

Plate buckling and shell buckling computations came be made using FEAP's linear shell element.

Spin boundary condition

A Spin boundary condition is possible via the use of the SPIN command within a LOAD GROUp

Static Analyses

Thermal Analyses

Example of a hollow thermal tube with external temperatures and inner fluxes

Example of a 3D hollow thermal tube with external temperatures and inner fluxes