Frequency domain analysis of Froude-Krylov and diffraction forces on TLP

IF 0.7 Q4 ENGINEERING, OCEAN Ocean Systems Engineering-An International Journal Pub Date : 2016-09-25 DOI:10.12989/OSE.2016.6.3.233
Ebrahim Malayjerdi, M. R. Tabeshpour
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引用次数: 7

Abstract

. Tension Leg Platform (TLP) is a floating structure that consists of four columns with large diameter. The diffraction theory is used to calculate the wave force of floating structures with large dimensions (TLP). In this study, the diffraction and Froude-Krylov wave forces of TLP for surge, sway and heave motions and wave force moment for roll, pitch degrees of freedom in different wave periods and three wave approach angles have been investigated. From the numerical results, it can be concluded that the wave force for different wave approach angle is different. There are some humps and hollows in the curve of wave forces and moment in different wave periods (different wavelengths). When wave incidents with angle 0 degree, the moment of diffraction force for pitch in high wave periods (low frequencies) is dominant. The diffraction force for heave in low wave periods (high wave frequencies) is dominant. The phase difference between Froude-Krylov and diffraction forces is important to obtain total wave force.
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TLP上的Froude-Krylov力和衍射力频域分析
. 张力腿平台是一种由四根大直径柱组成的浮动结构。采用衍射理论计算了大尺寸浮体结构的波浪力。在本研究中,研究了不同波浪周期和三种波浪进近角下,张力腿平台在浪涌、摇摆和升沉运动时的衍射波力和弗劳德-克雷洛夫波力以及横摇、俯仰自由度运动时的波力力矩。数值结果表明,不同的波浪进近角对波浪力的影响是不同的。在不同波周期(不同波长)的波浪力和力矩曲线上有一些隆起和凹陷。当波浪以0度角入射时,高波周期(低频)的节距绕射力力矩占主导地位。在低波周期(高波频率)下,波浪的衍射力占主导地位。弗劳德-克雷洛夫力和衍射力之间的相位差对于获得总波浪力很重要。
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来源期刊
Ocean Systems Engineering-An International Journal
Ocean Systems Engineering-An International Journal ENGINEERING, OCEAN-
自引率
22.20%
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0
期刊介绍: The OCEAN SYSTEMS ENGINEERING focuses on the new research and development efforts to advance the understanding of sciences and technologies in ocean systems engineering. The main subject of the journal is the multi-disciplinary engineering of ocean systems. Areas covered by the journal include; * Undersea technologies: AUVs, submersible robot, manned/unmanned submersibles, remotely operated underwater vehicle, sensors, instrumentation, measurement, and ocean observing systems; * Ocean systems technologies: ocean structures and structural systems, design and production, ocean process and plant, fatigue, fracture, reliability and risk analysis, dynamics of ocean structure system, probabilistic dynamics analysis, fluid-structure interaction, ship motion and mooring system, and port engineering; * Ocean hydrodynamics and ocean renewable energy, wave mechanics, buoyancy and stability, sloshing, slamming, and seakeeping; * Multi-physics based engineering analysis, design and testing: underwater explosions and their effects on ocean vehicle systems, equipments, and surface ships, survivability and vulnerability, shock, impact and vibration; * Modeling and simulations; * Underwater acoustics technologies.
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