Hydrodynamic performance of vegetation surrogates in hydraulic studies: a comparative analysis of seaweed blades and their physical models

Davide Vettori; Vladimir Nikora

doi:10.1080/00221686.2018.1562999

Hydrodynamic performance of vegetation surrogates in hydraulic studies: a comparative analysis of seaweed blades and their physical models

Davide Vettori^* (Corresponding Author), Vladimir Nikora

^*Corresponding author for this work

Engineering

Research output: Contribution to journal › Article › peer-review

16 Citations (Scopus)

Abstract

Vegetation surrogates have been extensively used in laboratory experiments for studying flow–vegetation interactions. However, it remains unclear how accurately the surrogates replicate the prototype vegetation in terms of hydrodynamic performance, even when similarity conditions are followed. To address this matter, we compare the hydrodynamic performance of seaweed blades of the species Saccharina latissima with performance of their surrogates, which were designed based on similarity considerations. To assess the hydrodynamic performance of samples, we measured flow velocities upstream and downstream of the samples, their vertical movements, and the drag forces exerted on them. The obtained data reveal that the mechanisms governing flow–blade interactions are essentially the same for live blades and their surrogates. Even though the surrogates successfully replicate many aspects of live blade dynamics, they experience weaker drag force and reconfiguration, likely because of their simplified morphologies that differed from the live blades at small scales. To enhance similarity in hydrodynamic performances, we suggest employing comprehensive similarity conditions at all relevant scales.

Original language	English
Pages (from-to)	248-261
Number of pages	14
Journal	Journal of Hydraulic Research
Volume	58
Issue number	2
Early online date	11 Mar 2019
DOIs	https://doi.org/10.1080/00221686.2018.1562999
Publication status	Published - Feb 2020

Bibliographical note

Funding
The work described in this publication was undertaken during the PhD study of Davide Vettori at the University of Aberdeen funded by a scholarship from the Northern Research Partnership, Scotland

Acknowledgements
The authors gratefully acknowledge the assistance of Elisa Bozzolan, Euan Judd, Henry Lecallet, and Olivia McCabe in collecting datasets used in this publication. The authors also thank Stuart Cameron and Euan Judd for support in developing video analysis routines, David Attwood and Hamish Biggs for their assistance during seaweed collection and transportation to the University of Aberdeen, and technicians Roy Gillanders and Benjamin Stratton for meticulous technical support of the experiments. Very useful comments provided by two anonymous reviewers, the Associate Editor and Editor helped to improve the final version of the paper.

Keywords

Drag coefficient
flow–biota interactions
hydraulic models
similarity theory
turbulent wakes
velocity measurements

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Cite this

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title = "Hydrodynamic performance of vegetation surrogates in hydraulic studies: a comparative analysis of seaweed blades and their physical models",

abstract = "Vegetation surrogates have been extensively used in laboratory experiments for studying flow–vegetation interactions. However, it remains unclear how accurately the surrogates replicate the prototype vegetation in terms of hydrodynamic performance, even when similarity conditions are followed. To address this matter, we compare the hydrodynamic performance of seaweed blades of the species Saccharina latissima with performance of their surrogates, which were designed based on similarity considerations. To assess the hydrodynamic performance of samples, we measured flow velocities upstream and downstream of the samples, their vertical movements, and the drag forces exerted on them. The obtained data reveal that the mechanisms governing flow–blade interactions are essentially the same for live blades and their surrogates. Even though the surrogates successfully replicate many aspects of live blade dynamics, they experience weaker drag force and reconfiguration, likely because of their simplified morphologies that differed from the live blades at small scales. To enhance similarity in hydrodynamic performances, we suggest employing comprehensive similarity conditions at all relevant scales.",

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author = "Davide Vettori and Vladimir Nikora",

note = "Funding The work described in this publication was undertaken during the PhD study of Davide Vettori at the University of Aberdeen funded by a scholarship from the Northern Research Partnership, Scotland Acknowledgements The authors gratefully acknowledge the assistance of Elisa Bozzolan, Euan Judd, Henry Lecallet, and Olivia McCabe in collecting datasets used in this publication. The authors also thank Stuart Cameron and Euan Judd for support in developing video analysis routines, David Attwood and Hamish Biggs for their assistance during seaweed collection and transportation to the University of Aberdeen, and technicians Roy Gillanders and Benjamin Stratton for meticulous technical support of the experiments. Very useful comments provided by two anonymous reviewers, the Associate Editor and Editor helped to improve the final version of the paper.",

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N2 - Vegetation surrogates have been extensively used in laboratory experiments for studying flow–vegetation interactions. However, it remains unclear how accurately the surrogates replicate the prototype vegetation in terms of hydrodynamic performance, even when similarity conditions are followed. To address this matter, we compare the hydrodynamic performance of seaweed blades of the species Saccharina latissima with performance of their surrogates, which were designed based on similarity considerations. To assess the hydrodynamic performance of samples, we measured flow velocities upstream and downstream of the samples, their vertical movements, and the drag forces exerted on them. The obtained data reveal that the mechanisms governing flow–blade interactions are essentially the same for live blades and their surrogates. Even though the surrogates successfully replicate many aspects of live blade dynamics, they experience weaker drag force and reconfiguration, likely because of their simplified morphologies that differed from the live blades at small scales. To enhance similarity in hydrodynamic performances, we suggest employing comprehensive similarity conditions at all relevant scales.

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Hydrodynamic performance of vegetation surrogates in hydraulic studies: a comparative analysis of seaweed blades and their physical models

Abstract

Bibliographical note

Keywords

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