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Validation of the VECTIS steady-state solver

Validation of the VECTIS steady-state solver
Validation of the VECTIS steady-state solver
Wind speed measurements are obtained from anemometers located on research ships. Even though the anemometers are usually positioned in well-exposed locations the presence of the ship’s hull and superstructure distorts the airflow to the anemometer and biases the wind speed measurements. Previous studies have shown biases of up to 10 % for bow-on flows, and that the biases generally increase for other wind directions. Corrections for the effects of the flow distortion are vital, as these data are used for satellite validation and in climate related studies. Therefore, the computational fluid dynamics (CFD) package VECTIS is used to numerically simulate the airflow over ships and derive corrections for this effect.

A VECTIS simulation of one ship at one wind direction currently takes approximately one month to perform on a typical UNIX workstation. Therefore, it would be impractical to study the airflow over a large number of research ships and/or a large number of wind directions. A faster method (the “steady-state solver”) for VECTIS simulations has been available for some time, but requires significant increases in computational speed and memory which have only recently become widely available. This report presents a comparison of VECTIS simulations using the steady-state solver with both previous VECTIS studies and in situ wind speed measurements.

Use of the steady-state solver requires a higher mesh density but also cuts model convergence times from weeks to days, allowing fine-resolution models to be run without impractical time constraints. The results of this study show that in regions where the flow distortion is high, the increased mesh density results in significant improvement in the comparison between modelled and in-situ wind speeds.
airflow distortion, computational fluid dynamics, CFD, RRS Discovery, wind speed measurement, VECTIS
4
National Oceanography Centre Southampton
Moat, B.I.
497dbb18-a98f-466b-b459-aa2c872ad2dc
Yelland, M.J.
3b2e2a38-334f-430f-b110-253a0a835a07
Moat, B.I.
497dbb18-a98f-466b-b459-aa2c872ad2dc
Yelland, M.J.
3b2e2a38-334f-430f-b110-253a0a835a07

Moat, B.I. and Yelland, M.J. (2006) Validation of the VECTIS steady-state solver (National Oceanography Centre Southampton Internal Document, 4) Southampton, UK. National Oceanography Centre Southampton 15pp.

Record type: Monograph (Project Report)

Abstract

Wind speed measurements are obtained from anemometers located on research ships. Even though the anemometers are usually positioned in well-exposed locations the presence of the ship’s hull and superstructure distorts the airflow to the anemometer and biases the wind speed measurements. Previous studies have shown biases of up to 10 % for bow-on flows, and that the biases generally increase for other wind directions. Corrections for the effects of the flow distortion are vital, as these data are used for satellite validation and in climate related studies. Therefore, the computational fluid dynamics (CFD) package VECTIS is used to numerically simulate the airflow over ships and derive corrections for this effect.

A VECTIS simulation of one ship at one wind direction currently takes approximately one month to perform on a typical UNIX workstation. Therefore, it would be impractical to study the airflow over a large number of research ships and/or a large number of wind directions. A faster method (the “steady-state solver”) for VECTIS simulations has been available for some time, but requires significant increases in computational speed and memory which have only recently become widely available. This report presents a comparison of VECTIS simulations using the steady-state solver with both previous VECTIS studies and in situ wind speed measurements.

Use of the steady-state solver requires a higher mesh density but also cuts model convergence times from weeks to days, allowing fine-resolution models to be run without impractical time constraints. The results of this study show that in regions where the flow distortion is high, the increased mesh density results in significant improvement in the comparison between modelled and in-situ wind speeds.

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More information

Published date: 2006
Additional Information: Internal Document deposted at request of B.I. Moat
Keywords: airflow distortion, computational fluid dynamics, CFD, RRS Discovery, wind speed measurement, VECTIS

Identifiers

Local EPrints ID: 41394
URI: http://eprints.soton.ac.uk/id/eprint/41394
PURE UUID: 9b3b8c55-7f71-4e91-8f46-70bd879672e5

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Date deposited: 31 Aug 2006
Last modified: 15 Mar 2024 08:29

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Contributors

Author: B.I. Moat
Author: M.J. Yelland

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