Hull-propeller-rudder interactions: time-accurate data of a scaled model ship in waves
Hull-propeller-rudder interactions: time-accurate data of a scaled model ship in waves
Accurate prediction of ship powering performance is essential as it plays a pivotal role in achieving optimal ship design and maximising energy-saving potential. Typically, a combination of computational and experimental methods is employed. With great progress in the use of computational simulations, there is an equivalent need to acquire high-quality experimental measurements and insights gained from towing tank tests. This paper introduces a newly constructed, instrumented geosim of the benchmark KRISO Container Ship (KCS) hull form and details representative results from four distinct test campaigns that encompass both free-running and towed conditions. These tests were conducted in calm water, regular waves, and irregular waves, with evaluations at various drift angles to thoroughly assess the hull’s performance under different maritime conditions. The synchronised measurements of wave environment, model motions, forces and moments of the hull and its appendages, facilitate a time-accurate understanding of performance, rather than merely capturing average behaviour. This provides a deeper insight into the complex interactions between the hull, propeller, and rudder, and how that affects the power demand in real voyages. The collected data from experiments helps validate CFD codes and also observe real physics, which is impossible from any virtual test run with numerical simulations.
Energy efficiency, Experimental uncertainty, Free running model tests, Hull-propeller-rudder interaction, Model testing, Synchronised measurements, Testing facilities
Turnock, Stephen
d6442f5c-d9af-4fdb-8406-7c79a92b26ce
Hosseinzadeh, Saeed
47ee65b8-f6a8-4c4f-b99c-146eb389464b
Zhang, Yifu
201620b2-8af6-4747-8f3a-923c92fea4f1
Bowker, James
7e0d368b-4c3b-4daf-a831-57158eacd738
Buckland, Dickon
8b8019f2-b2f5-4803-88f6-307b3c61c19d
Gregory, Magnus
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Townsend, Nicholas
3a4b47c5-0e76-4ae0-a086-cf841d610ef0
19 September 2024
Turnock, Stephen
d6442f5c-d9af-4fdb-8406-7c79a92b26ce
Hosseinzadeh, Saeed
47ee65b8-f6a8-4c4f-b99c-146eb389464b
Zhang, Yifu
201620b2-8af6-4747-8f3a-923c92fea4f1
Bowker, James
7e0d368b-4c3b-4daf-a831-57158eacd738
Buckland, Dickon
8b8019f2-b2f5-4803-88f6-307b3c61c19d
Gregory, Magnus
b446f2df-f5a7-42b8-871e-4fffd1ff5108
Townsend, Nicholas
3a4b47c5-0e76-4ae0-a086-cf841d610ef0
Turnock, Stephen, Hosseinzadeh, Saeed, Zhang, Yifu, Bowker, James, Buckland, Dickon, Gregory, Magnus and Townsend, Nicholas
(2024)
Hull-propeller-rudder interactions: time-accurate data of a scaled model ship in waves.
Ocean Engineering, 312, [119258].
(doi:10.1016/j.oceaneng.2024.119258).
Abstract
Accurate prediction of ship powering performance is essential as it plays a pivotal role in achieving optimal ship design and maximising energy-saving potential. Typically, a combination of computational and experimental methods is employed. With great progress in the use of computational simulations, there is an equivalent need to acquire high-quality experimental measurements and insights gained from towing tank tests. This paper introduces a newly constructed, instrumented geosim of the benchmark KRISO Container Ship (KCS) hull form and details representative results from four distinct test campaigns that encompass both free-running and towed conditions. These tests were conducted in calm water, regular waves, and irregular waves, with evaluations at various drift angles to thoroughly assess the hull’s performance under different maritime conditions. The synchronised measurements of wave environment, model motions, forces and moments of the hull and its appendages, facilitate a time-accurate understanding of performance, rather than merely capturing average behaviour. This provides a deeper insight into the complex interactions between the hull, propeller, and rudder, and how that affects the power demand in real voyages. The collected data from experiments helps validate CFD codes and also observe real physics, which is impossible from any virtual test run with numerical simulations.
Text
1-s2.0-S0029801824025964-main
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More information
Accepted/In Press date: 12 September 2024
e-pub ahead of print date: 19 September 2024
Published date: 19 September 2024
Keywords:
Energy efficiency, Experimental uncertainty, Free running model tests, Hull-propeller-rudder interaction, Model testing, Synchronised measurements, Testing facilities
Identifiers
Local EPrints ID: 494841
URI: http://eprints.soton.ac.uk/id/eprint/494841
ISSN: 0029-8018
PURE UUID: 2c294fe4-8a6d-4208-8a85-62bfb8097deb
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Date deposited: 17 Oct 2024 16:35
Last modified: 18 Oct 2024 02:07
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Contributors
Author:
Saeed Hosseinzadeh
Author:
Yifu Zhang
Author:
James Bowker
Author:
Magnus Gregory
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