Seakeeping performance of a rounded hull catamaran in waves using CFD approach

Fitriadhy, Ahmad; Razali, N.S.; AqilahMansor, N.

doi:10.15282/jmes.11.2.2017.4.0238

Cited by 12 publications

(15 citation statements)

References 23 publications

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“…Although, the pitch motion decreases from 3.851286 ⁰ to 0.622232 ⁰. The result also showed that the higher the Froude number, the more the slope of the post-peak descending region will be and the lower of Froude number was prone to down degrade the seakeeping performance of the 'deep-V' catamaran due to the higher response of heave and pitch motion (Fitriadhy, Razali, & AqilahMansor, 2017) and (Vakilabadi et al, 2014).…”

Section: Effect Of Froude Number (Fr)mentioning

confidence: 96%

Seakeeping Prediction of Deep-v High Speed Catamaran Using Computational Fluid Dynamics Approach

Fitriadhy¹,

Adam²,

Amalina³

et al. 2018

Sinergi

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Seakeeping is the dynamic response of the ship in waves that may affect to passenger’s uncomfortability due to a harsh environmental condition. Therefore, an extensive assessment of seakeeping performance in the initial step of ship design is necessarily required. The authors here proposed to analyze the seakeeping performance of ‘deep-V’ high speed catamaran using Computational Fluid Dynamics (CFD) approach. Several effects of Froude number (Fr), wave-length (

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Section: Effect Of Froude Number (Fr)mentioning

confidence: 96%

Seakeeping Prediction of Deep-v High Speed Catamaran Using Computational Fluid Dynamics Approach

Fitriadhy¹,

Adam²,

Amalina³

et al. 2018

Sinergi

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“…Referring to the transport model discussed above, the viscosity has been taken into account that presents the high gradients near solid wall layers. Therefore, it is very important to have a sufficient amount the number of grid points in the boundary layers to properly capture the high gradient [21]. Here, an appropriate estimation of cell meshing size, for Navier-Strokes simulation, depends on the wall variable + to measure the viscosity effect region as written in Eq.…”

Section: Turbulent Modelmentioning

confidence: 99%

“…This paper presents a CFD simulation approach for the extension work from [21,22] to access the performance of propeller by KT, KQ, and Ƞ of the propeller. Here, a commercial CFD software, namely NUMECA Fine TM /Turbo v12.2 is utilized by grid generation, flow solver and post-processing capabilities.…”

Section: Introductionmentioning

confidence: 99%

Prediction of Propeller Performance Using Computational Fluid Dynamics Approach

Adam

Fitriadhy

Kong

et al. 2019

EPI-IJE

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A reliable prediction approach to obtain a sufficient thrust and torque to propel the ship at desired forward speed is obviously required. To achieve this objective, the authors propose to predict the thrust coefficient (KT), torque coefficient (KQ) and efficiency (η) of the propeller in open-water model test condition using Computational Fluid Dynamics (CFD) simulation approach. The computational simulation presented in the various number of rotational speed (RPM) within the range of advance ratio J=0.1 up to 1.05. The higher value of J leads to a decrease in 10KQ and KT. While the η increased steadily at the lower value of J and decreased at the higher value of J. The results also showed that the propeller with 1048 rpm obtains a better efficiency at J=0.95 with η= 88.25%, 10KQ=0.1654 and KT= 0.0942. The computation result is very useful as preliminary data for propeller performance characteristics.

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“…The Froude number of 0.4 was also introduced as the situation in which lowering the lateral spacing notably enlarges the drag force [33]. Similarly in the case of encountering sea waves, the reduction in hull lateral separation intensifies dynamic trim and sinkage [34]. Or even when there is a relative motion between two neighboring bodies, the slower one experiences stronger hydrodynamic loads as well as greater trim and sinkage due to the interaction [35].…”

Section: Introductionmentioning

confidence: 99%

A new phenomenon in interference effect on catamaran dynamic response

Honaryar

Ghiasi

Liu

2021

International Journal of Mechanical Sciences

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Interference effect between catamaran demi-hulls has been considered as an adverse fluid-solid interaction; the narrower separation distance between the two hulls, the greater drag force acts upon the catamaran. However, this study is aimed at introducing a novel phenomenon contrasting outcome in semi-planing and planing regimes. As speed and accordingly the Froude number increase the catamaran transits across different modes, free surface profile becomes complicated and so does the interference effect as well as the prediction of catamaran dynamic response. The situation will be even more complex if demi-hull separation narrows where nonlinearity in interference effect is more pronounced. So, free-running tests in six degrees of freedom as well as obtaining fluid flow characteristics using computational fluid dynamics were conducted for a high-speed catamaran vehicle with asymmetric non-prismatic demi-hulls to tackle the problem. The results of catamaran dynamic response reveal that not only is drag reduced substantially up to 15%, but also trim angle diminishes by 30% as hulls separation distance decreases in semi-planing and planing modes. In other words, with increasing speed, and decreasing trim angle by 2.3 o , the current method achieved the goal of consequently reducing the risk of porpoising instability, without the increase of delivered power.

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Seakeeping performance of a rounded hull catamaran in waves using CFD approach

Cited by 12 publications

References 23 publications

Seakeeping Prediction of Deep-v High Speed Catamaran Using Computational Fluid Dynamics Approach

Seakeeping Prediction of Deep-v High Speed Catamaran Using Computational Fluid Dynamics Approach

Prediction of Propeller Performance Using Computational Fluid Dynamics Approach

A new phenomenon in interference effect on catamaran dynamic response

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