A Study on Forced Vibration of Double Bottom Structure due to Whipping on an Ultra Large Container Ship

Kawasaki, Yohei; Okada, Tetsuo; Kobayakawa, Hiroaki; Amaya, Ichiro; Miyashita, Tetsuji; Nagashima, Tomoki; Neki, Isao

doi:10.1115/omae2017-61149

Cited by 7 publications

(1 citation statement)

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“…Because wellboats have a special structural design with longitudinal framing and double bottoms, it is crucial to assess their structural integrity [1]. The transverse elements of the double-bottom structure, referred to as floors, are essential.…”

Section: Introductionmentioning

confidence: 99%

Structural Influence of the Cargo Holds of a 3000 m3 Wellboat on a Double-Bottom Floor

Silva-Campillo,

Pérez-Arribas

2024

JMSE

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In order to reduce weight and facilitate maintenance, servicing and inspection, ship structures usually have openings and cutouts. However, these modifications frequently weaken the plates’ ability to buckle. In this work, the combined effects of geometric discontinuities (such as openings and cutouts) under diverse in-plane loads (such as horizontal compression, vertical compression, biaxial compression, and in-plane edge shear loading) are taken into consideration as the perforated plates located in the double-bottom floor of a 3000 m3 wellboat are investigated for their linear and elastic buckling behavior. In order to assess the effects of various stiffening methods and their interactions with different load scenarios, as well as fluctuating plate slenderness ratios, the research combines experimental and numerical analyses. This thorough study identifies the best stiffening technique and suggests alternative geometries that minimize structural weight through topology optimization. The research’s findings are helpful in comprehending the mechanisms underlying structural failure and in offering design and recommendation guidelines that enhance hull inspections and the assessment of structural flaws.

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Section: Introductionmentioning

confidence: 99%

Structural Influence of the Cargo Holds of a 3000 m3 Wellboat on a Double-Bottom Floor

Silva-Campillo,

Pérez-Arribas

2024

JMSE

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Statistical Characteristics of Whipping Response of a Large Container Ship Under Various Sea States and Navigational Conditions Based on Full-Scale Measurements

Miyashita¹,

Okada

Kawamura

et al. 2020

Lecture Notes in Civil Engineering

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Simulation of whipping response of a large container ship fitted with a linear generator on board in irregular head seas

Yang

Okada

Kobayakawa³

et al. 2017

J Mar Sci Technol

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There is plenty of energy contained in the ocean waves, and great efforts have been made over recent decades, to make full use of these sustainable energy resources. As a novel device to utilize ocean wave energy, the authors propose in this paper a whipping energy converter, which utilizes a linear generator extracting power from ship's whipping and springing (hull girder 2-node vibration) responses. The device is designed resonant to the hull girder 2-node vibration frequency. Numerical simulation of the responses of the whipping energy converter was carried out under irregular head sea condition, using time domain ship motion analysis by Rankine source method and subsequent 3-dimensional whole ship FE analysis, and the main parameters of the whipping energy converter was studied. A 14,000 TEU large container ship was utilized in this study, because large container ship is prone to constant whipping and springing responses in real seas. As a result, it was found that the whipping energy converter can effectively generate power from the whipping and springing responses, and at the same time, the whipping energy converter functions as a dynamic damper. With the piston weight of 5~10 tons, the whipping vibration is visibly reduced, while if the piston weight is about 100 tons, the spectral peak is reduced to less than one-third. This implies that the whipping energy converter contributes to the prevention of fatigue damage due to whipping and springing, which is an imminent concern in the design of large container ships. It was also found that larger power generation can be expected as the piston weight is heavier, and the bow is the most effective location for this device.

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A Study on Forced Vibration of Double Bottom Structure due to Whipping on an Ultra Large Container Ship

Cited by 7 publications

References 0 publications

Structural Influence of the Cargo Holds of a 3000 m3 Wellboat on a Double-Bottom Floor

Structural Influence of the Cargo Holds of a 3000 m3 Wellboat on a Double-Bottom Floor

Statistical Characteristics of Whipping Response of a Large Container Ship Under Various Sea States and Navigational Conditions Based on Full-Scale Measurements

Simulation of whipping response of a large container ship fitted with a linear generator on board in irregular head seas

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