Heave and Pitch Motion Performances of a Ship Towing System Incorporated with Symmetrical Bridle Towline Model

EPI International Journal of Engineering Pub Date : 2019-06-27 DOI:10.25042/EPI-IJE.022019.06

A. Fitriadhy, N. A. Aldin, N. A. Mansor, Nur Aqilah Hanis Zalizan

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Abstract

An investigation on vertical motion characteristics of a ship towing system incorporated with symmetrical bridle towline configuration set a real challenge for the naval architect engineer. This paper presents a Computational Fluid Dynamic (CFD) approach to analyse heave and pitch motion performances in waves. Several towing parameters such as various towline length and towing’s velocity have been taken into account. Here, 1B (barge) is employed in the simulation; and designated as a towed ship. The results revealed that the subsequent increase of the towline lengths has been basically proportional with the increase of her heave motion; while inversely decrease in pitch motions. In addition, the effect of the extending towline length = 1.0 to 3.0 resulted in insignificant effect to the towline tension. However, the increase of the towing’s velocity from 0.509 m/s to 0.728 m/s has led to significantly increase her heave motion and the towline tension by 40.46% and 24%, respectively; meanwhile, the pitch motion barge has sufficiently decreased by 35.94%. This simulation has been beneficial for the towing operator to ensure a higher level of the safety navigation of ship towing system.

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基于对称缰绳模型的船舶拖曳系统的升沉和俯仰运动特性

采用对称绳带结构的船舶拖曳系统的垂直运动特性研究对造船工程师来说是一个真正的挑战。本文提出了一种计算流体动力学(CFD)方法来分析波浪中的升沉和俯仰运动特性。考虑了拖曳线长度和拖曳速度等拖曳参数。在这里，模拟采用1B(驳船);并被指定为拖船。结果表明，拖绳长度的后续增加基本与船的升沉运动的增加成正比;而音调运动则相反地减小。此外，拖绳长度= 1.0 ~ 3.0对拖绳张力的影响不显著。然而，拖曳速度从0.509 m/s增加到0.728 m/s，导致其升沉运动和拖缆张力分别显著增加40.46%和24%;同时，桨距运动驳船已充分降低35.94%。该仿真结果有利于船舶拖航人员提高船舶拖航系统的安全航行水平。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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EPI International Journal of Engineering

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