Numerical simulation of the coupled dynamic response of asubmerged floating tunnel with mooring lines in regular waves

IF 0.7 Q4 ENGINEERING, OCEAN Ocean Systems Engineering-An International Journal Pub Date : 2015-06-01 DOI:10.12989/OSE.2015.5.2.109

C. Cifuentes, Seungjun Kim, Myeongbin Kim, W. S. Park

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引用次数: 35

Abstract

In the present study, the coupled dynamic response of a Submerged Floating Tunnel (SFT) and mooring lines under regular waves is solved by using two independent numerical simulation methods, OrcaFlex and CHARM3D, in time domain. Variations of Buoyancy to Weight Ratio (BWR), wave steepness/period, and water/submergence depth are considered as design and environmental parameters in the study. Two different mooring-line configurations, vertical and inclined, are studied to find an optimum design in terms of limiting tunnel motions and minimizing mooring-line tension. The numerical results are successfully validated by direct comparison against published experimental data. The results show that tunnel motions and tether tensions grow with wave height and period and decrease with submergence depth. The inclined mooring system is more effective in restricting tunnel motions compared to the vertical mooring system. Overall, the present study demonstrates the feasibility of this type of structure as an alternative to traditional bridges or under-seabed tunnels.

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潜沉式浮式隧道与系泊索在规则波浪中耦合动力响应的数值模拟

本文采用OrcaFlex和CHARM3D两种独立的时域数值模拟方法，求解了规则波作用下沉浮隧道与系泊索的耦合动力响应。浮重比(BWR)的变化、波浪陡度/周期和水/淹没深度在研究中被考虑为设计和环境参数。研究了垂直和倾斜两种不同的系缆结构，以寻找限制隧道运动和最小化系缆张力的最佳设计。通过与已发表的实验数据的直接比较，验证了数值结果的正确性。结果表明，隧道运动和锚索张力随波高和周期增大而增大，随淹没深度减小。与垂直系泊系统相比，倾斜系泊系统在限制隧道运动方面更有效。总的来说，本研究证明了这种结构作为传统桥梁或海底隧道的替代方案的可行性。

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来源期刊

Ocean Systems Engineering-An International Journal ENGINEERING, OCEAN-

自引率

22.20%

发文量

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.