Mathematical Model of Flexible Link Dynamics in Marine Tethered Systems Considering Torsion and its Influence on Tension Force

IF 2 3区工程技术 Q2 ENGINEERING, MARINE

Polish Maritime Research Pub Date : 2023-06-01 DOI:10.2478/pomr-2023-0032

Konstantin Trunin

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引用次数: 0

Abstract

Abstract The rigidity in bending of a flexible link (is an important characteristic that should be considered during regular service conditions. The tension and bending with torsion of wire ropes are also significant factors. This study proposed a method to calculate the vectors of the generalised forces of bending of flexible links. One of the causes of torsional stresses in the power plant of underwater tethered systems is the interaction with ship equipment, such as spiral winding on the winch drum, friction on the flanges of the pulleys or winch drums, and bends on various blocks and rolls that cause torsion. The source of torsional stresses in the FL may also be related to manufacturing, storage, transportation, and its placement on the ship’s winch drums. Torsion can lead to a decrease in the tensile strength due to load redistribution between power elements, or even a violation of their structure. In some cases, torsion significantly affects the movement of the underwater tethered system as a whole. The development of a mathematical model to describe the marine tethered systems dynamics, taking into account the effect of torsion, is important and relevant. The mathematical model of the marine tethered systems dynamics was improved and solved by accounting for the generalised forces of the torsion rigidity of the flexible link, using an algorithm and computer program. The influence of the bending and torsional rigidity of the FL on its deflection and tensile strength were considered based on the example of two problems. The developed program’s working window image shows the simulated parameters and the initial position of the flexible link. The results show that torsion has almost no effect on the shape of the a flexible link’s deflection in the X0Z plane, but leads to a deviation from the X0Z plane when calculating the static deflection of the flexible link. When the carrier vessel is stationary and the submersible vehicle has no restrictions on movement and has positive buoyancy, torsion leads to a three-dimensional change in the shape of the flexible link both in the X0Z plane and in the X0Y plane. The tension force of the flexible link along its length is distributed unevenly, and the torsion of the flexible link can lead to significant changes in its shape, the trajectory of towed objects, and the forces acting on the elements of the marine tethered systems

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考虑扭转的船用系链系统柔性连杆动力学数学模型及其对张力的影响

摘要柔性连杆的弯曲刚度是在正常使用条件下应考虑的一个重要特性。钢丝绳的张力和弯曲与扭转也是重要的因素。本文提出了一种计算柔性连杆广义弯曲力矢量的方法。水下系绳系统动力装置中产生扭转应力的原因之一是与船舶设备的相互作用，如绞车卷筒上的螺旋缠绕、滑轮或绞车卷筒法兰上的摩擦以及各种块和卷筒上的弯曲引起扭转。FL中扭转应力的来源也可能与制造、储存、运输及其在船舶绞车滚筒上的放置有关。由于功率元件之间的负载重新分配，甚至是其结构的破坏，扭转可能导致抗拉强度的降低。在某些情况下，扭转显著影响水下系索系统作为一个整体的运动。发展一个数学模型来描述海洋系索系统的动力学，考虑到扭转的影响，是重要的和相关的。通过计算柔性连杆扭转刚度的广义力，对海洋系索系统动力学数学模型进行了改进，并利用算法和计算机程序进行了求解。结合这两个问题的算例，考虑了FL的弯曲刚度和扭转刚度对其挠度和抗拉强度的影响。开发的程序工作窗口图像显示了仿真参数和柔性连杆的初始位置。结果表明，扭转对柔性连杆在X0Z平面上的挠度形状几乎没有影响，但在计算柔性连杆的静态挠度时，会导致与X0Z平面的偏差。当载船静止，潜航器运动不受限制且浮力为正时，扭转会导致柔性连杆在X0Z平面和X0Y平面上的形状发生三维变化。柔性连杆的张力沿其长度分布不均匀，柔性连杆的扭转会导致其形状、被拖物体的轨迹以及作用在海洋系索系统元件上的力发生显著变化

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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来源期刊

Polish Maritime Research 工程技术-工程：海洋

CiteScore

3.70

自引率

45.00%

发文量

审稿时长

>12 weeks

期刊介绍： The scope of the journal covers selected issues related to all phases of product lifecycle and corresponding technologies for offshore floating and fixed structures and their components. All researchers are invited to submit their original papers for peer review and publications related to methods of the design; production and manufacturing; maintenance and operational processes of such technical items as: all types of vessels and their equipment, fixed and floating offshore units and their components, autonomous underwater vehicle (AUV) and remotely operated vehicle (ROV). We welcome submissions from these fields in the following technical topics: ship hydrodynamics: buoyancy and stability; ship resistance and propulsion, etc., structural integrity of ship and offshore unit structures: materials; welding; fatigue and fracture, etc., marine equipment: ship and offshore unit power plants: overboarding equipment; etc.