Numerical Investigation into Freak Wave Effects on Deepwater Pipeline Installation

Xu, Peng; Du, Zhixin; Gong, Sha

doi:10.3390/jmse8020119

Cited by 9 publications

(9 citation statements)

References 30 publications

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“…The mechanical properties and motion states, such as the mass, buoyancy, and displacement of the mooring line, are concentrated on the adjacent mass nodes, while the tensile properties of the mooring line are characterized by the spring segment. To analyze the tension behavior of each spring segment, the force equilibrium equation can be established to calculate the effective tension of the spring segment for the mooring line, which is given by [15] T e = T w (ε…”

Section: Mooring Line Modelmentioning

confidence: 99%

“…Li et al [14] investigated the influences of freak waves on semi-submersible platform motion and mooring stiffness. Xu et al [15] and Xu and Gong [16] numerically generated a series of freak waves and obtained the response behaviors of offshore pipelines for the installation stage under a freak wave. Pan et al [17] experimentally explored the influence of freak waves on the response characteristics of mooring square columns in the frequency domain.…”

Section: Introductionmentioning

confidence: 99%

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Numerical Investigation into the Dynamic Responses of Floating Photovoltaic Platform and Mooring Line Structures under Freak Waves

Xu,

Zhang,

et al. 2024

JMSE

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Floating photovoltaics (PVs) are progressively constructed in the ocean sea; therefore, the effect that freak waves have on their structural design needs to be considered. This paper developed a dedicated numerical model coupling the floating PV platform and mooring line structures to investigate their dynamic responses under freak waves. A feasible superposition approach is presented to generate freak wave sequences via the combination of transient waves and random waves. A large floating PV platform moored by twenty lines for a water depth of 45 m was designed in detail according to the actually measured ocean environmental and geological conditions. The global time domain analyses of the floating PV mooring structures were implemented to obtain dynamic responses, including PV platform motions and the mooring line configuration and tension under freak waves. A comparison of the response results with those caused by random waves was conducted to illustrate the intuitive evidence of the freak wave effects, which offer a significant reference for the preliminary design of the floating PV platform and mooring line structures.

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Section: Mooring Line Modelmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Numerical Investigation into the Dynamic Responses of Floating Photovoltaic Platform and Mooring Line Structures under Freak Waves

Xu,

Zhang,

et al. 2024

JMSE

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“…Instead, through the product safety directives, drilling ships and oil and gas equipment onboard has been covered through the International Convention for the Safety of Life at Sea (SOLAS) and more specifically through the Code for the construction and equipment of Mobile Offshore Drilling Units of the International Maritime Organization (the MODU code). The MODU code has been developed to protect any ship as a vessel, and its integrity and stability in the first place in terms of navigation [32][33][34][35], emphasizing the additional requirements caused by drilling activities [36], but does not include requirements for the drilling of subsea wells or the procedures for their control (such drilling operations are subject to control by the coastal state). The MODU code is used in relation to the EU/EEA product safety directives as follows: (1) Protection against explosions; (2) Protection of pressure equipment; (3) Protection of personnel who works with machinery:…”

Section: Explicit Exclusions From Eu/eea Product Safety Directivesmentioning

confidence: 99%

Proper Use of Technical Standards in Offshore Petroleum Industry

Brkić

Praks

2020

JMSE

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Ships for drilling need to operate in the territorial waters of many different countries which can have different technical standards and procedures. For example, the European Union and European Economic Area EU/EEA product safety directives exclude from their scope drilling ships and related equipment onboard. On the other hand, the EU/EEA offshore safety directive requires the application of all the best technical standards that are used worldwide in the oil and gas industry. Consequently, it is not easy to select the most appropriate technical standards that increase the overall level of safety and environmental protection whilst avoiding the costs of additional certifications. We will show how some technical standards and procedures, which are recognized worldwide by the petroleum industry, can be accepted by various standardization bodies, and how they can fulfil the essential health and safety requirements of certain directives. Emphasis will be placed on the prevention of fire and explosion, on the safe use of equipment under pressure, and on the protection of personnel who work with machinery. Additionally considered is how the proper use of adequate procedures available at the time would have prevented three large scale offshore petroleum accidents: the Macondo Deepwater Horizon in the Gulf of Mexico in 2010; the Montara in the Timor Sea in 2009; the Piper Alpha in the North Sea in 1988.

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“…Subsea pipeline resilience can be defined as the pipeline's capacity to withstand manmade and natural hazards, and this resilience plays a significant role in the design process [3]. These hazards could include accidental pulling with fishing gear, damages caused by terrorist activity, earthquakes, extreme climate and environmental conditions and unforeseen installation or operational loads [4][5][6]. The increasing demand and growth of energy consumption affect the design and installation of ever-longer subsea pipelines at increasing depths.…”

Section: Introductionmentioning

confidence: 99%

The Optimization of a Subsea Pipeline Installation Configuration Using a Genetic Algorithm

Karabaić,

Kršulja,

Maričić

et al. 2024

JMSE

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The most commonly used subsea pipeline installation method is the S-Lay method. A very important and complex task in an S-Lay installation engineering analysis is to find the optimal pipelay vessel installation configuration for every distinctive pipeline route section. Installation loads in the pipeline are very sensitive to small changes in the configuration of the pipeline supports during laying and other influential parameters, such as the tensioner force, stinger angle, trim and draft of the pipelay vessel. Therefore, the process of an engineering installation analysis is very demanding, and there is a need for an automated optimization process. For that purpose, installation engineering methodology criteria and requirements are formalized into a nonlinear optimization problem with mixed continuous and discrete variables. A special tailored multi-objective genetic algorithm is developed that can be adjusted to any desired combination of criteria and offshore standards’ requirements. The optimization algorithm is applied to the representative test cases. The optimization procedure efficiency and quality of the achieved solution prove that the developed genetic algorithm operators and the whole optimization approach are adequate for the presented application.

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Numerical Investigation into Freak Wave Effects on Deepwater Pipeline Installation

Cited by 9 publications

References 30 publications

Numerical Investigation into the Dynamic Responses of Floating Photovoltaic Platform and Mooring Line Structures under Freak Waves

Numerical Investigation into the Dynamic Responses of Floating Photovoltaic Platform and Mooring Line Structures under Freak Waves

Proper Use of Technical Standards in Offshore Petroleum Industry

The Optimization of a Subsea Pipeline Installation Configuration Using a Genetic Algorithm

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