Finite element analysis (FEA) has been one of the successful tools in studying mechanical behavior of biological materials. There are many instances where creating FE models requires extensive time and effort. Such instances include finite element analysis of tree branches with complex geometries and varying mechanical properties. Once a FE model of a tree branch is created, the model is not applicable to another branch, and all the modeling steps must be repeated for each new branch with a different geometry and, in some cases, material. In this paper, we describe a new and novel program “Immediate-TREE” and its associated guided user interface (GUI). This program provides researchers a fast and efficient tool to create finite element analysis of a large variety of tree branches. Immediate-TREE automates the process of creating finite element models with the use of computer-generated Python files. Immediate-TREE uses tree branch data (geometry, mechanical, and material properties) and generates Python files. Files were then run in finite element analysis software (abaqus) to complete the analysis. Immediate-TREE is approximately 240 times faster than creating the same model directly in the FEA software (abaqus). This new process can be used with a large variety of biological applications including analyses of bones, teeth, as well as known biological materials.
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December 2017
Research-Article
Automated Finite Element Analysis of Tree Branches
Zahra Shahbazi,
Zahra Shahbazi
Mechanical Engineering Department,
Manhattan College,
Riverdale, NY 10463
e-mail: zahra.shahbazi@manhattan.edu
Manhattan College,
Riverdale, NY 10463
e-mail: zahra.shahbazi@manhattan.edu
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Devon Keane,
Devon Keane
Mechanical Engineering Department,
Manhattan College,
Riverdale, NY 10463
e-mail: dkeane01@manhattan.edu
Manhattan College,
Riverdale, NY 10463
e-mail: dkeane01@manhattan.edu
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Domenick Avanzi,
Domenick Avanzi
Mechanical Engineering Department,
Manhattan College,
Riverdale, NY 10463
e-mail: davanzi01@manhattan.edu
Manhattan College,
Riverdale, NY 10463
e-mail: davanzi01@manhattan.edu
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Lance S. Evans
Lance S. Evans
Biology Department,
Laboratory of Plant Morphogenesis,
Manhattan College,
Riverdale, NY 10463
e-mail: lance.evans@manhattan.edu
Laboratory of Plant Morphogenesis,
Manhattan College,
Riverdale, NY 10463
e-mail: lance.evans@manhattan.edu
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Zahra Shahbazi
Mechanical Engineering Department,
Manhattan College,
Riverdale, NY 10463
e-mail: zahra.shahbazi@manhattan.edu
Manhattan College,
Riverdale, NY 10463
e-mail: zahra.shahbazi@manhattan.edu
Devon Keane
Mechanical Engineering Department,
Manhattan College,
Riverdale, NY 10463
e-mail: dkeane01@manhattan.edu
Manhattan College,
Riverdale, NY 10463
e-mail: dkeane01@manhattan.edu
Domenick Avanzi
Mechanical Engineering Department,
Manhattan College,
Riverdale, NY 10463
e-mail: davanzi01@manhattan.edu
Manhattan College,
Riverdale, NY 10463
e-mail: davanzi01@manhattan.edu
Lance S. Evans
Biology Department,
Laboratory of Plant Morphogenesis,
Manhattan College,
Riverdale, NY 10463
e-mail: lance.evans@manhattan.edu
Laboratory of Plant Morphogenesis,
Manhattan College,
Riverdale, NY 10463
e-mail: lance.evans@manhattan.edu
Contributed by the Computers and Information Division of ASME for publication in the JOURNAL OF COMPUTING AND INFORMATION SCIENCE IN ENGINEERING. Manuscript received August 28, 2016; final manuscript received April 17, 2017; published online June 15, 2017. Editor: Bahram Ravani.
J. Comput. Inf. Sci. Eng. Dec 2017, 17(4): 041008 (9 pages)
Published Online: June 15, 2017
Article history
Received:
August 28, 2016
Revised:
April 17, 2017
Citation
Shahbazi, Z., Keane, D., Avanzi, D., and Evans, L. S. (June 15, 2017). "Automated Finite Element Analysis of Tree Branches." ASME. J. Comput. Inf. Sci. Eng. December 2017; 17(4): 041008. https://doi.org/10.1115/1.4036556
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