https://github.com/d-nemeth/holey-column
Science Score: 26.0%
This score indicates how likely this project is to be science-related based on various indicators:
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○CITATION.cff file
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✓codemeta.json file
Found codemeta.json file -
✓.zenodo.json file
Found .zenodo.json file -
○DOI references
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○Academic publication links
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○Academic email domains
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○Institutional organization owner
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○JOSS paper metadata
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○Scientific vocabulary similarity
Low similarity (6.0%) to scientific vocabulary
Repository
Basic Info
- Host: GitHub
- Owner: d-nemeth
- License: mit
- Language: Python
- Default Branch: main
- Size: 48.8 KB
Statistics
- Stars: 0
- Watchers: 1
- Forks: 0
- Open Issues: 0
- Releases: 0
Metadata Files
README.md
holey-column
Running the codes
Any code with import abaqus in its header needs to be run from Abaqus CAE to execute, using File > Run Script.
If simulations fail part way or in the data extraction stage, data can still be salvaged from the .odb file either via Abaqus or using the code in the utility folder.
simulations
Main folder, contains codes for running simulations in Abaqus. Scripts should be run in Abaqus only after defining the relevant geometry parameters, velocities and viscosities in the script headers.
Compression Wave Analysis
- Run
compression_speed_by_interpolation.py- Determines the compression wave arrival times according to the final method described in our report (by finding the inflection point of the U2 vs time curve). - Run
compression_wave_analysis_v2.py- Determines compression wave speeds and produces figures by plotting the node coordinates and the corresponding compression wave arrival times.
Buckling and Self-Contact Wave Analysis
Run bucklingwave_v2.py - Calculates wave speeds and produces figures by plotting the node coordinates and the corresponding wave arrival times. Also produces figures that compare all three wave phenomena (in terms of viscosity and indenter speed)
Owner
- Login: d-nemeth
- Kind: user
- Repositories: 1
- Profile: https://github.com/d-nemeth