Numerical investigation of the six degrees of freedom hydrodynamic performance of a sailboat in wave conditions

Yitong Guan; Minghui Xu; Tairan Chen; Yana Wang

doi:10.1049/icp.2023.1946

Numerical investigation of the six degrees of freedom hydrodynamic performance of a sailboat in wave conditions

Yitong Guan, Minghui Xu, Tairan Chen^*, Yana Wang

^*Corresponding author for this work

School of Mechanical Engineering

Beijing Institute of Technology

Research output: Contribution to journal › Conference article › peer-review

Abstract

The hydrodynamic characteristics of sailboats in varying sea conditions are crucial for controlling the boats and complete the required movements. This paper investigates the six-element forces of Laser Radial sailboats under oblique sailing with firstorder waves. Numerical calculations employing the overlapping mesh technique and DFBI model provide insights into the sailboat's details. The study reveals significant findings: speed has a dominant influence on resistance, accounting for approximately 64% of the total. Wavelength factors contribute about 12%, while amplitude factors contribute about 24% at an 8-degree heel angle. As speed increases, resistance intensifies. Additionally, wavelength impacts the longitudinal pitching moment more obviously, while wave amplitude has a larger impact on the yawing moment.

Original language	English
Pages (from-to)	176-181
Number of pages	6
Journal	IET Conference Proceedings
Volume	2023
Issue number	13
DOIs	https://doi.org/10.1049/icp.2023.1946
Publication status	Published - 2023
Event	17th Asian Congress of Fluid Mechanics, ACFM 2023 - Beijing, China Duration: 8 Aug 2023 → 12 Aug 2023

Keywords

HYDRODYNAMIC
LASER RADIAL CLASS SAILBOAT
OBLIQUE SHIPPING
SIX DEGREES OF FREEDOM MOTION
WAVE CONDITIONS

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10.1049/icp.2023.1946

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title = "Numerical investigation of the six degrees of freedom hydrodynamic performance of a sailboat in wave conditions",

abstract = "The hydrodynamic characteristics of sailboats in varying sea conditions are crucial for controlling the boats and complete the required movements. This paper investigates the six-element forces of Laser Radial sailboats under oblique sailing with firstorder waves. Numerical calculations employing the overlapping mesh technique and DFBI model provide insights into the sailboat's details. The study reveals significant findings: speed has a dominant influence on resistance, accounting for approximately 64% of the total. Wavelength factors contribute about 12%, while amplitude factors contribute about 24% at an 8-degree heel angle. As speed increases, resistance intensifies. Additionally, wavelength impacts the longitudinal pitching moment more obviously, while wave amplitude has a larger impact on the yawing moment.",

keywords = "HYDRODYNAMIC, LASER RADIAL CLASS SAILBOAT, OBLIQUE SHIPPING, SIX DEGREES OF FREEDOM MOTION, WAVE CONDITIONS",

author = "Yitong Guan and Minghui Xu and Tairan Chen and Yana Wang",

note = "Publisher Copyright: {\textcopyright} The Institution of Engineering & Technology 2023.; 17th Asian Congress of Fluid Mechanics, ACFM 2023 ; Conference date: 08-08-2023 Through 12-08-2023",

year = "2023",

doi = "10.1049/icp.2023.1946",

language = "English",

volume = "2023",

pages = "176--181",

journal = "IET Conference Proceedings",

issn = "2732-4494",

publisher = "Institution of Engineering and Technology",

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T1 - Numerical investigation of the six degrees of freedom hydrodynamic performance of a sailboat in wave conditions

AU - Guan, Yitong

AU - Xu, Minghui

AU - Chen, Tairan

AU - Wang, Yana

N1 - Publisher Copyright: © The Institution of Engineering & Technology 2023.

PY - 2023

Y1 - 2023

N2 - The hydrodynamic characteristics of sailboats in varying sea conditions are crucial for controlling the boats and complete the required movements. This paper investigates the six-element forces of Laser Radial sailboats under oblique sailing with firstorder waves. Numerical calculations employing the overlapping mesh technique and DFBI model provide insights into the sailboat's details. The study reveals significant findings: speed has a dominant influence on resistance, accounting for approximately 64% of the total. Wavelength factors contribute about 12%, while amplitude factors contribute about 24% at an 8-degree heel angle. As speed increases, resistance intensifies. Additionally, wavelength impacts the longitudinal pitching moment more obviously, while wave amplitude has a larger impact on the yawing moment.

AB - The hydrodynamic characteristics of sailboats in varying sea conditions are crucial for controlling the boats and complete the required movements. This paper investigates the six-element forces of Laser Radial sailboats under oblique sailing with firstorder waves. Numerical calculations employing the overlapping mesh technique and DFBI model provide insights into the sailboat's details. The study reveals significant findings: speed has a dominant influence on resistance, accounting for approximately 64% of the total. Wavelength factors contribute about 12%, while amplitude factors contribute about 24% at an 8-degree heel angle. As speed increases, resistance intensifies. Additionally, wavelength impacts the longitudinal pitching moment more obviously, while wave amplitude has a larger impact on the yawing moment.

KW - HYDRODYNAMIC

KW - LASER RADIAL CLASS SAILBOAT

KW - OBLIQUE SHIPPING

KW - SIX DEGREES OF FREEDOM MOTION

KW - WAVE CONDITIONS

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U2 - 10.1049/icp.2023.1946

DO - 10.1049/icp.2023.1946

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AN - SCOPUS:85178558243

SN - 2732-4494

VL - 2023

SP - 176

EP - 181

JO - IET Conference Proceedings

JF - IET Conference Proceedings

IS - 13

T2 - 17th Asian Congress of Fluid Mechanics, ACFM 2023

Y2 - 8 August 2023 through 12 August 2023

ER -

Numerical investigation of the six degrees of freedom hydrodynamic performance of a sailboat in wave conditions

Abstract

Keywords

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