Finite Element Analysis
Project description
FElupe - Finite Element Analysis
FElupe is a Python 3.7+ finite element analysis package focussing on the formulation and numerical solution of nonlinear problems in continuum mechanics of solid bodies. Its name is a combination of FE (finite element) and the german word Lupe (magnifying glass) as a synonym for getting an insight how a finite element analysis code looks like under the hood.
Installation
Install Python, fire up a terminal and run
pip install felupe[all]
where [all]
installs all optional dependencies. By default, FElupe only depends on numpy
and scipy
. In order to make use of all features of FElupe, it is suggested to install all optional dependencies.
Hello, FElupe!
A quarter model of a solid cube with hyperelastic material behaviour is subjected to a uniaxial elongation applied at a clamped end-face. This involves the creation of a mesh, a region as well as a displacement field (encapsulated in a field container). Furthermore, the boundary conditions are created by a template for a uniaxial loadcase. A Neo-Hookean material formulation is applied on a solid body. A step generates the consecutive substep-movements of a given boundary condition. The step is added to a job. During evaluation, each substep of each step is solved by an iterative Newton-Rhapson procedure. Finally, the solution of the last step is exported as a VTK file. For more details beside this high-level code snippet, please have a look at the documentation.
import felupe as fem
# create a hexahedron-region on a cube
region = fem.RegionHexahedron(fem.Cube(n=11))
# add a mixed field container (with displacement, pressure and volume ratio)
field = fem.FieldsMixed(region, n=3, values=(0, 0, 1))
# apply a uniaxial elongation on the cube
boundaries = fem.dof.uniaxial(field, clamped=True)[0]
# define the constitutive material behaviour and create a solid body
umat = fem.ThreeFieldVariation(fem.NeoHooke(mu=1, bulk=5000))
solid = fem.SolidBody(umat, field)
# prepare a step with substeps
move = fem.math.linsteps([0, 2, -0.4, 0], num=10)
step = fem.Step(
items=[solid],
ramp={boundaries["move"]: move},
boundaries=boundaries
)
# add the step to a job, evaluate all substeps and create a plot
job = fem.CharacteristicCurve(steps=[step], boundary=boundaries["move"])
job.evaluate(filename="result.xdmf")
fig, ax = job.plot(
xlabel="Displacement $u$ in mm $\longrightarrow$",
ylabel="Normal Force $F$ in N $\longrightarrow$",
)
https://user-images.githubusercontent.com/5793153/194673269-a5e1e98a-56bd-4066-b655-6bd039da5264.mp4
Documentation
The documentation is located here.
Changelog
All notable changes to this project will be documented in this file. The format is based on Keep a Changelog, and this project adheres to Semantic Versioning.
License
FElupe - finite element analysis (C) 2022 Andreas Dutzler, Graz (Austria).
This program is free software: you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation, either version 3 of the License, or (at your option) any later version.
This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details.
You should have received a copy of the GNU General Public License along with this program. If not, see https://www.gnu.org/licenses/.
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