Assessment of aerodynamic roughness parameters of turbulent boundary layers over barnacle-covered surfaces
Assessment of aerodynamic roughness parameters of turbulent boundary layers over barnacle-covered surfaces
Full-scale drag penalty predictions of flows over rough walls require surface roughness characterisation from laboratory experiments or numerical simulations. In either approach, it is necessary to determine the so-called equivalent sand-grain roughness height (k
s ). There are several steps involved in determining this aerodynamic roughness lengthscale, but its procedure typically includes a combination of measurement of wall-shear stress (τ
w ) using direct or indirect methods as well as analysis of velocity profiles. Indirect methods usually rely on assumptions made about flow and its scaling including the validity of universal outer-layer similarity. However, the implications of the underlying assumptions involved in full-scale drag prediction are unclear. In this work, we carry out wind tunnel measurements over a realistic rough surface (from a fouled ship-hull) to evaluate the impact of different methods with an emphasis on using the outer-layer similarity hypothesis for full-scale drag predictions. Wall-shear stress is measured using an in-house floating-element drag balance (DB), and velocity profiles are obtained using particle image velocimetry (PIV), allowing the evaluation of k
s , and the associated wake parameters through several methods. The aerodynamic roughness parameters hence obtained are used for full-scale drag penalty calculations. It is observed that the predicted drag penalty can vary by over 15 % among the different methods highlighting the care that should be taken when employing such methods.
drag, roughness, turbulent boundary layers
Medjnoun, Takfarinas
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Amaro Matoso Aguiar Ferreira, Manuel
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Reinartz, Ralf
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Nugroho, Bagus
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Monty, Jason
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Hutchins, Nicholas
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Ganapathisubramani, Bharathram
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November 2023
Medjnoun, Takfarinas
49775b3f-b926-4bb9-b667-07a84ed46fd6
Amaro Matoso Aguiar Ferreira, Manuel
2c006e7a-7ec5-4549-a805-f6708e004265
Reinartz, Ralf
274c181e-c593-4932-9387-99cf1325670c
Nugroho, Bagus
c6d997e4-c95b-4247-891c-e0f4b6cdfe28
Monty, Jason
c9e9f228-23ab-453d-95bb-4bd5251a653b
Hutchins, Nicholas
fa48cbc6-6a5d-43ec-89d8-55bf8c74738e
Ganapathisubramani, Bharathram
5e69099f-2f39-4fdd-8a85-3ac906827052
Medjnoun, Takfarinas, Amaro Matoso Aguiar Ferreira, Manuel, Reinartz, Ralf, Nugroho, Bagus, Monty, Jason, Hutchins, Nicholas and Ganapathisubramani, Bharathram
(2023)
Assessment of aerodynamic roughness parameters of turbulent boundary layers over barnacle-covered surfaces.
Experiments in Fluids, 64 (11), [169].
(doi:10.1007/s00348-023-03709-5).
Abstract
Full-scale drag penalty predictions of flows over rough walls require surface roughness characterisation from laboratory experiments or numerical simulations. In either approach, it is necessary to determine the so-called equivalent sand-grain roughness height (k
s ). There are several steps involved in determining this aerodynamic roughness lengthscale, but its procedure typically includes a combination of measurement of wall-shear stress (τ
w ) using direct or indirect methods as well as analysis of velocity profiles. Indirect methods usually rely on assumptions made about flow and its scaling including the validity of universal outer-layer similarity. However, the implications of the underlying assumptions involved in full-scale drag prediction are unclear. In this work, we carry out wind tunnel measurements over a realistic rough surface (from a fouled ship-hull) to evaluate the impact of different methods with an emphasis on using the outer-layer similarity hypothesis for full-scale drag predictions. Wall-shear stress is measured using an in-house floating-element drag balance (DB), and velocity profiles are obtained using particle image velocimetry (PIV), allowing the evaluation of k
s , and the associated wake parameters through several methods. The aerodynamic roughness parameters hence obtained are used for full-scale drag penalty calculations. It is observed that the predicted drag penalty can vary by over 15 % among the different methods highlighting the care that should be taken when employing such methods.
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Biofouling_Roughness___ExpInFluids___Accepted
- Accepted Manuscript
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s00348-023-03709-5
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More information
Accepted/In Press date: 13 September 2023
e-pub ahead of print date: 13 October 2023
Published date: November 2023
Additional Information:
Funding Information:
The authors gratefully acknowledge the financial support from the Engineering and Physical Sciences Research Council through their grants (Ref No: EP/P009638/1 and Ref No: EP/P021476/1).
Publisher Copyright:
© 2023, The Author(s).
Keywords:
drag, roughness, turbulent boundary layers
Identifiers
Local EPrints ID: 484715
URI: http://eprints.soton.ac.uk/id/eprint/484715
ISSN: 0723-4864
PURE UUID: c4dace9a-0907-406f-bde8-1404a8ba932b
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Date deposited: 20 Nov 2023 17:45
Last modified: 18 Mar 2024 03:52
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Contributors
Author:
Takfarinas Medjnoun
Author:
Manuel Amaro Matoso Aguiar Ferreira
Author:
Ralf Reinartz
Author:
Bagus Nugroho
Author:
Jason Monty
Author:
Nicholas Hutchins
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