Fluid–Body Interactions in Fish-Like Swimming

Dipanjan Majumdar; Chandan Bose; Prerna Dhareshwar; Sunetra Sarkar

doi:10.1007/978-981-15-5862-7_41

Fluid–Body Interactions in Fish-Like Swimming

Dipanjan Majumdar, Chandan Bose, Prerna Dhareshwar, Sunetra Sarkar^*

^*Corresponding author for this work

Metallurgy and Materials

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

Abstract

The present study focuses on formulating a fluid–structure interaction (FSI) framework by coupling a finite element analysis (FEA) based structural solver and a lumped vortex method (LVM) based potential flow solver to study the coupled dynamics involved in the undulatory and oscillatory swimming of fishes. The caudal fin of a carangiform fish is modelled as a continuous cantilever beam with a periodic support motion. The effect of the actuation frequency on the thrust coefficient is investigated. A significant increase in the aerodynamic thrust is noticed for the support motion frequencies nearing to the structural natural frequencies of the beam. Next, the whole fish body, considering the full-body undulations, is modelled as a continuous free-free beam. This model incorporates a time-dependent actuating moment varying along the length of the body which can be attributed to the muscle moments generated by the fish. A parametric study is carried out to obtain maximum thrust output for the muscle power input in terms of the actuation moment. It is observed that the generated thrust increases significantly when the frequency of the actuation moment approaches towards the natural frequencies of the free-free beam. A comparative study of the average thrust coefficient is carried out for these two cases.

Original language	English
Title of host publication	Advances in Structural Vibration
Subtitle of host publication	Select Proceedings of ICOVP 2017
Editors	Subashisa Dutta, Esin Inan, Santosha Kumar Dwivedy
Publisher	Springer
Pages	509-519
Number of pages	11
Edition	1
ISBN (Electronic)	9789811558627
ISBN (Print)	9789811558610, 9789811559822
DOIs	https://doi.org/10.1007/978-981-15-5862-7_41
Publication status	Published - 12 Oct 2020
Event	13th International Conference on Vibrational Problems, ICoVP 2017 - Guwahati, India Duration: 29 Nov 2017 → 2 Dec 2017

Publication series

Name	Lecture Notes in Mechanical Engineering
ISSN (Print)	2195-4356
ISSN (Electronic)	2195-4364

Conference

Conference	13th International Conference on Vibrational Problems, ICoVP 2017
Country/Territory	India
City	Guwahati
Period	29/11/17 → 2/12/17

Bibliographical note

Publisher Copyright:
© 2021, Springer Nature Singapore Pte Ltd.

ASJC Scopus subject areas

Automotive Engineering
Aerospace Engineering
Mechanical Engineering
Fluid Flow and Transfer Processes

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10.1007/978-981-15-5862-7_41Licence: None: All rights reserved

Cite this

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title = "Fluid–Body Interactions in Fish-Like Swimming",

abstract = "The present study focuses on formulating a fluid–structure interaction (FSI) framework by coupling a finite element analysis (FEA) based structural solver and a lumped vortex method (LVM) based potential flow solver to study the coupled dynamics involved in the undulatory and oscillatory swimming of fishes. The caudal fin of a carangiform fish is modelled as a continuous cantilever beam with a periodic support motion. The effect of the actuation frequency on the thrust coefficient is investigated. A significant increase in the aerodynamic thrust is noticed for the support motion frequencies nearing to the structural natural frequencies of the beam. Next, the whole fish body, considering the full-body undulations, is modelled as a continuous free-free beam. This model incorporates a time-dependent actuating moment varying along the length of the body which can be attributed to the muscle moments generated by the fish. A parametric study is carried out to obtain maximum thrust output for the muscle power input in terms of the actuation moment. It is observed that the generated thrust increases significantly when the frequency of the actuation moment approaches towards the natural frequencies of the free-free beam. A comparative study of the average thrust coefficient is carried out for these two cases.",

author = "Dipanjan Majumdar and Chandan Bose and Prerna Dhareshwar and Sunetra Sarkar",

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Majumdar, D, Bose, C, Dhareshwar, P & Sarkar, S 2020, Fluid–Body Interactions in Fish-Like Swimming. in S Dutta, E Inan & SK Dwivedy (eds), Advances in Structural Vibration: Select Proceedings of ICOVP 2017. 1 edn, Lecture Notes in Mechanical Engineering, Springer, pp. 509-519, 13th International Conference on Vibrational Problems, ICoVP 2017, Guwahati, India, 29/11/17. https://doi.org/10.1007/978-981-15-5862-7_41

Fluid–Body Interactions in Fish-Like Swimming. / Majumdar, Dipanjan; Bose, Chandan; Dhareshwar, Prerna et al.
Advances in Structural Vibration: Select Proceedings of ICOVP 2017. ed. / Subashisa Dutta; Esin Inan; Santosha Kumar Dwivedy. 1. ed. Springer, 2020. p. 509-519 (Lecture Notes in Mechanical Engineering).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

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N2 - The present study focuses on formulating a fluid–structure interaction (FSI) framework by coupling a finite element analysis (FEA) based structural solver and a lumped vortex method (LVM) based potential flow solver to study the coupled dynamics involved in the undulatory and oscillatory swimming of fishes. The caudal fin of a carangiform fish is modelled as a continuous cantilever beam with a periodic support motion. The effect of the actuation frequency on the thrust coefficient is investigated. A significant increase in the aerodynamic thrust is noticed for the support motion frequencies nearing to the structural natural frequencies of the beam. Next, the whole fish body, considering the full-body undulations, is modelled as a continuous free-free beam. This model incorporates a time-dependent actuating moment varying along the length of the body which can be attributed to the muscle moments generated by the fish. A parametric study is carried out to obtain maximum thrust output for the muscle power input in terms of the actuation moment. It is observed that the generated thrust increases significantly when the frequency of the actuation moment approaches towards the natural frequencies of the free-free beam. A comparative study of the average thrust coefficient is carried out for these two cases.

AB - The present study focuses on formulating a fluid–structure interaction (FSI) framework by coupling a finite element analysis (FEA) based structural solver and a lumped vortex method (LVM) based potential flow solver to study the coupled dynamics involved in the undulatory and oscillatory swimming of fishes. The caudal fin of a carangiform fish is modelled as a continuous cantilever beam with a periodic support motion. The effect of the actuation frequency on the thrust coefficient is investigated. A significant increase in the aerodynamic thrust is noticed for the support motion frequencies nearing to the structural natural frequencies of the beam. Next, the whole fish body, considering the full-body undulations, is modelled as a continuous free-free beam. This model incorporates a time-dependent actuating moment varying along the length of the body which can be attributed to the muscle moments generated by the fish. A parametric study is carried out to obtain maximum thrust output for the muscle power input in terms of the actuation moment. It is observed that the generated thrust increases significantly when the frequency of the actuation moment approaches towards the natural frequencies of the free-free beam. A comparative study of the average thrust coefficient is carried out for these two cases.

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ER -

Fluid–Body Interactions in Fish-Like Swimming

Abstract

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Conference

Bibliographical note

ASJC Scopus subject areas

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