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Impact of leeway and rudder angles on ship resistance: a numerical planar motion mechanism approach

Impact of leeway and rudder angles on ship resistance: a numerical planar motion mechanism approach
Impact of leeway and rudder angles on ship resistance: a numerical planar motion mechanism approach
Driven by environmental policies, the maritime sector is increasingly utilising sustainable energy sources, with wind energy emerging as a primary strategy for achieving zero-carbon emissions. These wind-propulsion devices augment the ship’s propulsion, while the lateral force they generate causes a yawing moment that induces a leeway angle and added resistance. This study uses computational fluid dynamics (CFD) simulations to investigate the hydrodynamic behaviour of a ship at various leeway and rudder angles. It also examines how the leeway angle affects the wave-making resistance coefficient at different speeds. Model-scale evaluations were first performed with 0° rudder and 0° leeway (straight-ahead) at ship speeds from 8 to 14 knots. Then, the effects of various leeway and rudder angles were investigated at 11 and 14 knots. The combination of a 10° leeway angle with a 20° rudder angle was identified as the worst-case scenario, causing approximately a 100% increase in total resistance at 11 knots and a 40% increase at 14 knots in calm water. Understanding the hydrodynamic behaviour under these conditions is crucial for improving ship design and operational strategies, ultimately contributing to zero-carbon maritime transportation goals.
Wave resistance, Computational fluid dynamics (CFD), Wind-assisted propulsion, Leeway angle, Ship resistance
0029-8018
Goksu, Burak
77eceeae-bf22-425e-bc80-37b77a80f695
Garad, Suraj
5af7662d-a6a1-463d-aa77-45a2e726f87a
Pandini, Stefano
244cf16d-d858-43f3-9d73-6ccd064c01ac
Sirolla, Edoardo
8e98cc0f-f642-4624-80e7-fa094612e054
Palin, Robert
c44e680c-0d75-4280-8504-4ee1f1c695d3
Townsend, Nicholas
3a4b47c5-0e76-4ae0-a086-cf841d610ef0
Tezdogan, Tahsin
7e7328e2-4185-4052-8e9a-53fd81c98909
Goksu, Burak
77eceeae-bf22-425e-bc80-37b77a80f695
Garad, Suraj
5af7662d-a6a1-463d-aa77-45a2e726f87a
Pandini, Stefano
244cf16d-d858-43f3-9d73-6ccd064c01ac
Sirolla, Edoardo
8e98cc0f-f642-4624-80e7-fa094612e054
Palin, Robert
c44e680c-0d75-4280-8504-4ee1f1c695d3
Townsend, Nicholas
3a4b47c5-0e76-4ae0-a086-cf841d610ef0
Tezdogan, Tahsin
7e7328e2-4185-4052-8e9a-53fd81c98909

Goksu, Burak, Garad, Suraj, Pandini, Stefano, Sirolla, Edoardo, Palin, Robert, Townsend, Nicholas and Tezdogan, Tahsin (2025) Impact of leeway and rudder angles on ship resistance: a numerical planar motion mechanism approach. Ocean Engineering, 338, [121952]. (doi:10.1016/j.oceaneng.2025.121952).

Record type: Article

Abstract

Driven by environmental policies, the maritime sector is increasingly utilising sustainable energy sources, with wind energy emerging as a primary strategy for achieving zero-carbon emissions. These wind-propulsion devices augment the ship’s propulsion, while the lateral force they generate causes a yawing moment that induces a leeway angle and added resistance. This study uses computational fluid dynamics (CFD) simulations to investigate the hydrodynamic behaviour of a ship at various leeway and rudder angles. It also examines how the leeway angle affects the wave-making resistance coefficient at different speeds. Model-scale evaluations were first performed with 0° rudder and 0° leeway (straight-ahead) at ship speeds from 8 to 14 knots. Then, the effects of various leeway and rudder angles were investigated at 11 and 14 knots. The combination of a 10° leeway angle with a 20° rudder angle was identified as the worst-case scenario, causing approximately a 100% increase in total resistance at 11 knots and a 40% increase at 14 knots in calm water. Understanding the hydrodynamic behaviour under these conditions is crucial for improving ship design and operational strategies, ultimately contributing to zero-carbon maritime transportation goals.

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More information

Accepted/In Press date: 17 June 2025
e-pub ahead of print date: 27 June 2025
Published date: 27 June 2025
Keywords: Wave resistance, Computational fluid dynamics (CFD), Wind-assisted propulsion, Leeway angle, Ship resistance

Identifiers

Local EPrints ID: 503380
URI: http://eprints.soton.ac.uk/id/eprint/503380
DOI: doi:10.1016/j.oceaneng.2025.121952
ISSN: 0029-8018
PURE UUID: 1cea9481-252d-43bd-89cb-b4f314590edc
ORCID for Nicholas Townsend: ORCID iD orcid.org/0000-0001-6996-3532
ORCID for Tahsin Tezdogan: ORCID iD orcid.org/0000-0002-7032-3038

Catalogue record

Date deposited: 30 Jul 2025 16:30
Last modified: 18 Sep 2025 02:08

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Contributors

Author: Burak Goksu
Author: Suraj Garad
Author: Stefano Pandini
Author: Edoardo Sirolla
Author: Robert Palin
Author: Nicholas Townsend ORCID iD
Author: Tahsin Tezdogan ORCID iD

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