Mode-displacement method for structural dynamic analysis of bio-inspired structures: A palm-tree stem subject to wind effects

Biological materials (orthotropic materials), like wood, can offer good mechanical properties with a minimum amount of material, making their internal structure the suitable one to be applied on bio-inspired structures. The knowledge of the exceptional structural performance of palm trees, and speci...

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Published in	Wood material science and engineering Vol. 18; no. 2; pp. 379 - 393
Main Authors	Plaza, A., Vargas-Silva, G., Iriarte, X., Ros, J.
Format	Journal Article
Language	English
Published	Abingdon Taylor & Francis 04.03.2023 Taylor & Francis Ltd
Subjects	Accuracy Arecaceae Bio-inspired structures Biological effects Biological materials Biomimetics Computer applications Computing costs Degrees of freedom dynamic load Dynamic loads exponential integrator finite element analysis Finite element method materials science Mathematical models Mechanical loading Mechanical properties model reduction orthotropic materials palm tree dynamics Slenderness ratio Time integration Trees Wind effects Wind speed wood
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Abstract	Biological materials (orthotropic materials), like wood, can offer good mechanical properties with a minimum amount of material, making their internal structure the suitable one to be applied on bio-inspired structures. The knowledge of the exceptional structural performance of palm trees, and specially its response to different loading conditions, provides useful information when lightweight structures with high slenderness ratio are desired. Recent researches focused on the analysis of palm trees subject to static loading conditions, ignoring the fluctuating nature of the wind speed. The purpose of this study is to simulate in a computational efficient way the effect of dynamic loading conditions applied on palm trees. Using the mode displacement method, the number of degrees of freedom of a dynamic finite element analysis can be drastically reduced with a minimal loss of accuracy. It was applied to simulate the behavior of structures comprised of an orthotropic material subject to a stochastic dynamic load. The influence of the number of selected degrees of freedom has also been studied. In addition, an exponential integration method is proposed to perform the time integration procedure. The results obtained show that a properly reduced model suitably represents the full finite element model without any appreciable loss of accuracy; it is also shown that computational cost can be drastically reduced. This method could give an appropriate computational representation of the behavior of orthotropic structures, and it could be used for studying more complex bio-inspired structures.
AbstractList	Biological materials (orthotropic materials), like wood, can offer good mechanical properties with a minimum amount of material, making their internal structure the suitable one to be applied on bio-inspired structures. The knowledge of the exceptional structural performance of palm trees, and specially its response to different loading conditions, provides useful information when lightweight structures with high slenderness ratio are desired. Recent researches focused on the analysis of palm trees subject to static loading conditions, ignoring the fluctuating nature of the wind speed. The purpose of this study is to simulate in a computational efficient way the effect of dynamic loading conditions applied on palm trees. Using the mode displacement method, the number of degrees of freedom of a dynamic finite element analysis can be drastically reduced with a minimal loss of accuracy. It was applied to simulate the behavior of structures comprised of an orthotropic material subject to a stochastic dynamic load. The influence of the number of selected degrees of freedom has also been studied. In addition, an exponential integration method is proposed to perform the time integration procedure. The results obtained show that a properly reduced model suitably represents the full finite element model without any appreciable loss of accuracy; it is also shown that computational cost can be drastically reduced. This method could give an appropriate computational representation of the behavior of orthotropic structures, and it could be used for studying more complex bio-inspired structures.
Author	Plaza, A. Vargas-Silva, G. Iriarte, X. Ros, J.
Author_xml	– sequence: 1 givenname: A. orcidid: 0000-0002-4929-1246 surname: Plaza fullname: Plaza, A. email: aitor.plaza@unavarra.es organization: Universidad Pública de Navarra/Nafarroako Unibertsitate Publikoa – sequence: 2 givenname: G. orcidid: 0000-0002-2472-9440 surname: Vargas-Silva fullname: Vargas-Silva, G. organization: Angelo State University – sequence: 3 givenname: X. orcidid: 0000-0001-8215-1176 surname: Iriarte fullname: Iriarte, X. organization: Universidad Pública de Navarra/Nafarroako Unibertsitate Publikoa – sequence: 4 givenname: J. orcidid: 0000-0002-9223-3498 surname: Ros fullname: Ros, J. organization: Universidad Pública de Navarra/Nafarroako Unibertsitate Publikoa
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SubjectTerms	Accuracy Arecaceae Bio-inspired structures Biological effects Biological materials Biomimetics Computer applications Computing costs Degrees of freedom dynamic load Dynamic loads exponential integrator finite element analysis Finite element method materials science Mathematical models Mechanical loading Mechanical properties model reduction orthotropic materials palm tree dynamics Slenderness ratio Time integration Trees Wind effects Wind speed wood
Title	Mode-displacement method for structural dynamic analysis of bio-inspired structures: A palm-tree stem subject to wind effects
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