Cargando…

Thrust enhancement and degradation mechanisms due to self-induced vibrations in bio-inspired flying robots

Bio-inspired flying robots (BIFRs) which fly by flapping their wings experience continuously oscillating aerodynamic forces. These oscillations in the driving force cause vibrations in the motion of the body around the mean trajectory. In other words, a hovering BIFR does not remain fixed in space;...

Descripción completa

Detalles Bibliográficos
Autores principales: Deb, Dipan, Huang, Kevin, Verma, Aakash, Fouda, Moatasem, Taha, Haithem E.
Formato: Online Artículo Texto
Lenguaje:English
Publicado: Nature Publishing Group UK 2023
Materias:
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC10600193/
https://www.ncbi.nlm.nih.gov/pubmed/37880321
http://dx.doi.org/10.1038/s41598-023-45360-4
_version_ 1785125936700588032
author Deb, Dipan
Huang, Kevin
Verma, Aakash
Fouda, Moatasem
Taha, Haithem E.
author_facet Deb, Dipan
Huang, Kevin
Verma, Aakash
Fouda, Moatasem
Taha, Haithem E.
author_sort Deb, Dipan
collection PubMed
description Bio-inspired flying robots (BIFRs) which fly by flapping their wings experience continuously oscillating aerodynamic forces. These oscillations in the driving force cause vibrations in the motion of the body around the mean trajectory. In other words, a hovering BIFR does not remain fixed in space; instead, it undergoes oscillatory motion in almost all directions around the stationary point. These oscillations affect the aerodynamic performance of the flier. Assessing the effect of these oscillations, particularly on thrust generation in two-winged and four-winged BIFRs, is the main objective of this work. To achieve such a goal, two experimental setups were considered to measure the average thrust for the two BIFRs. The average thrust is measured over the flapping cycle of the BIFRs. In the first experimental setup, the BIFR is installed at the end of a pendulum rod, in place of the pendulum mass. While flapping, the model creates a thrust force that raises the model along the circular trajectory of the pendulum mass to a certain angular position, which is an equilibrium point and is also stable. Measuring the weight of the BIFR and the equilibrium angle it obtains, it is straightforward to estimate the average thrust, by moment balance about the pendulum hinge. This pendulum setup allows the BIFR model to freely oscillate back and forth along the circular trajectory about the equilibrium position. As such, the estimated average thrust includes the effects of these self-induced vibrations. In contrast, we use another setup with a load cell to measure thrust where the model is completely fixed. The thrust measurement revealed that the load cell or the fixed test leads to a higher thrust than the pendulum or the oscillatory test for the two-winged model, showing the opposite behavior for the four-winged model. That is, self-induced vibrations have different effects on the two BIFR models. We felt that this observation is worth further investigation. It is important to mention that aerodynamic mechanisms for thrust generation in the two and four-winged models are different. A two-winged BIFR generates thrust through traditional flapping mechanisms whereas a four-winged model enjoys a clapping effect, which results from wing-wing interaction. In the present work, we use a motion capture system, aerodynamic modeling, and flow visualization to study the underlying physics of the observed different behaviors of the two flapping models. The study revealed that the interaction of the vortices with the flapping wing robots may play a role in the observed aerodynamic behavior of the two BIFRs.
format Online
Article
Text
id pubmed-10600193
institution National Center for Biotechnology Information
language English
publishDate 2023
publisher Nature Publishing Group UK
record_format MEDLINE/PubMed
spelling pubmed-106001932023-10-27 Thrust enhancement and degradation mechanisms due to self-induced vibrations in bio-inspired flying robots Deb, Dipan Huang, Kevin Verma, Aakash Fouda, Moatasem Taha, Haithem E. Sci Rep Article Bio-inspired flying robots (BIFRs) which fly by flapping their wings experience continuously oscillating aerodynamic forces. These oscillations in the driving force cause vibrations in the motion of the body around the mean trajectory. In other words, a hovering BIFR does not remain fixed in space; instead, it undergoes oscillatory motion in almost all directions around the stationary point. These oscillations affect the aerodynamic performance of the flier. Assessing the effect of these oscillations, particularly on thrust generation in two-winged and four-winged BIFRs, is the main objective of this work. To achieve such a goal, two experimental setups were considered to measure the average thrust for the two BIFRs. The average thrust is measured over the flapping cycle of the BIFRs. In the first experimental setup, the BIFR is installed at the end of a pendulum rod, in place of the pendulum mass. While flapping, the model creates a thrust force that raises the model along the circular trajectory of the pendulum mass to a certain angular position, which is an equilibrium point and is also stable. Measuring the weight of the BIFR and the equilibrium angle it obtains, it is straightforward to estimate the average thrust, by moment balance about the pendulum hinge. This pendulum setup allows the BIFR model to freely oscillate back and forth along the circular trajectory about the equilibrium position. As such, the estimated average thrust includes the effects of these self-induced vibrations. In contrast, we use another setup with a load cell to measure thrust where the model is completely fixed. The thrust measurement revealed that the load cell or the fixed test leads to a higher thrust than the pendulum or the oscillatory test for the two-winged model, showing the opposite behavior for the four-winged model. That is, self-induced vibrations have different effects on the two BIFR models. We felt that this observation is worth further investigation. It is important to mention that aerodynamic mechanisms for thrust generation in the two and four-winged models are different. A two-winged BIFR generates thrust through traditional flapping mechanisms whereas a four-winged model enjoys a clapping effect, which results from wing-wing interaction. In the present work, we use a motion capture system, aerodynamic modeling, and flow visualization to study the underlying physics of the observed different behaviors of the two flapping models. The study revealed that the interaction of the vortices with the flapping wing robots may play a role in the observed aerodynamic behavior of the two BIFRs. Nature Publishing Group UK 2023-10-25 /pmc/articles/PMC10600193/ /pubmed/37880321 http://dx.doi.org/10.1038/s41598-023-45360-4 Text en © The Author(s) 2023 https://creativecommons.org/licenses/by/4.0/Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article’s Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article’s Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.0/ (https://creativecommons.org/licenses/by/4.0/) .
spellingShingle Article
Deb, Dipan
Huang, Kevin
Verma, Aakash
Fouda, Moatasem
Taha, Haithem E.
Thrust enhancement and degradation mechanisms due to self-induced vibrations in bio-inspired flying robots
title Thrust enhancement and degradation mechanisms due to self-induced vibrations in bio-inspired flying robots
title_full Thrust enhancement and degradation mechanisms due to self-induced vibrations in bio-inspired flying robots
title_fullStr Thrust enhancement and degradation mechanisms due to self-induced vibrations in bio-inspired flying robots
title_full_unstemmed Thrust enhancement and degradation mechanisms due to self-induced vibrations in bio-inspired flying robots
title_short Thrust enhancement and degradation mechanisms due to self-induced vibrations in bio-inspired flying robots
title_sort thrust enhancement and degradation mechanisms due to self-induced vibrations in bio-inspired flying robots
topic Article
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC10600193/
https://www.ncbi.nlm.nih.gov/pubmed/37880321
http://dx.doi.org/10.1038/s41598-023-45360-4
work_keys_str_mv AT debdipan thrustenhancementanddegradationmechanismsduetoselfinducedvibrationsinbioinspiredflyingrobots
AT huangkevin thrustenhancementanddegradationmechanismsduetoselfinducedvibrationsinbioinspiredflyingrobots
AT vermaaakash thrustenhancementanddegradationmechanismsduetoselfinducedvibrationsinbioinspiredflyingrobots
AT foudamoatasem thrustenhancementanddegradationmechanismsduetoselfinducedvibrationsinbioinspiredflyingrobots
AT tahahaitheme thrustenhancementanddegradationmechanismsduetoselfinducedvibrationsinbioinspiredflyingrobots