An Integrated Methodology for the Design of Mooring Systems and Risers of Floating Production Platforms

Girón, Aldo Roberto Cruces; Corrêa, Fabrício Nogueira; Jacob, Breno Pinheiro; Senra, Stael Ferreira

doi:10.1115/omae2012-83702

Cited by 3 publications

(2 citation statements)

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“…In general, such tools use a timedomain solution method and a rigorous representation of the lines using FE models, taking into account any nonlinearities in the system's dynamic response. In the literature [210][211][212], descriptions of different coupling formulations investigated for the fully coupled analysis of FPS (referred to as "weak coupling" WkC and "strong coupling" StC) have been presented. The WkC formulation focuses on the hull equations of motion: forces operating on the right-hand side of the hull equations perform the coupling between the hydrodynamic model of the hull and the hydrodynamic/structural model of the lines.…”

Section: Coupled Methodologymentioning

confidence: 99%

Mathematical Modelling of Bonded Marine Hoses for Single Point Mooring (SPM) Systems, with Catenary Anchor Leg Mooring (CALM) Buoy Application—A Review

Amaechi

Wang

2021

JMSE

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The application of mathematical analysis has been an essential tool applied on Catenary Anchor Leg Mooring (CALM) buoys, Wave Energy Converters (WEC), point absorber buoys, and various single point mooring (SPM) systems. This enables having mathematical models for bonded marine hoses on SPM systems with application with CALM buoys, which are obviously a requisite for the techno-economic design and operation of these floating structures. Hose models (HM) and mooring models (MM) are utilized on a variety of applications such as SPARs, Semisubmersibles, WECs and CALM buoys. CALM buoys are an application of SPM systems. The goal of this review is to address the subject of marine hoses from mathematical modeling and operational views. To correctly reproduce the behavior of bonded marine hoses, including nonlinear dynamics, and to study their performance, accurate mathematical models are required. The paper gives an overview of the statics and dynamics of offshore/marine hoses. The reviews on marine hose behavior are conducted based on theoretical, numerical, and experimental investigations. The review also covers challenges encountered in hose installation, connection, and hang-off operations. State-of-the-art, developments and recent innovations in mooring applications for SURP (subsea umbilicals, risers, and pipelines) are presented. Finally, this study details the relevant materials that are utilized in hoses and mooring implementations. Some conclusions and recommendations are presented based on this review.

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Section: Coupled Methodologymentioning

confidence: 99%

Mathematical Modelling of Bonded Marine Hoses for Single Point Mooring (SPM) Systems, with Catenary Anchor Leg Mooring (CALM) Buoy Application—A Review

Amaechi

Wang

2021

JMSE

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“…The interaction between the hydrodynamic behavior of the vessel and the riser should be based on the coupled formulation Det Norske Veritas (2010a). Several studies have been conducted on the integrated design of the riser and mooring line (Cruces Girón et al 2012;Girón et al 2013Girón et al , 2014).…”

Section: Article Highlightsmentioning

confidence: 99%

Evaluation of the Safe and Failure Zones of Mooring and Riser Systems in a CALM Oil Terminal

Hasanvand

Edalat

2021

J. Marine. Sci. Appl.

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The mooring and riser system is the most critical part of an offshore oil terminal. Traditionally, these two parts are designed separately without considering the nonlinear interaction between them. Thus, the present paper aims to develop an integrated design process for riser systems with a lazy-S configuration and mooring systems in the offshore catenary anchor leg mooring (CALM) oil terminal. One of the important criteria considered in this integrated design is the offset diagram and safe operation zone (SAFOP) related to the mooring system and the riser, respectively. These two diagrams are obtained separately by different analyses; therefore, codes or standards are available separately for two components. In this methodology, the diagrams of both risers and mooring lines are incorporated into a single spiral, thus identifying the safe and failure zones of risers and the mooring lines of the oil terminal. This, in turn, leads to substantial benefits in terms of overall system response, cost reduction, and safety to the offshore oil terminal. To implement this process, three different riser lengths with the lazy-S configuration are considered at three different sea depths at the terminal installation site. For each condition, the integrated design of the mooring system and riser is executed according to the derived procedure. Then, coupled dynamic models, wherein both buoys and hoses are included, are developed using OrcaFlex. Results show that the criteria of the relevant regulations are not satisfied by reducing the length of the riser relative to the designed size. Further, as water depth increases, this type of riser configuration shows good coupled performance while interacting with the mooring system. In the cross offset mode, the maximum margin is created between the offset diagram and the SAFOP diagram, while the most critical dynamic response of the tanker and terminal system occurs in the near and far modes. Therefore, with this method, the best position for the riser direction with the tanker direction is 90° in the best case.

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Sensitivity Analysis of the Dynamic Response of CALM Oil Terminal, in The Persian Gulf Region Under Different Operation Parameters

حسنوند¹,

عدالت²

2020

marine-engineering

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This paper analyzes CALM terminal sensitivity under various operating parameters such as water depth, chain mass, current velocity, wave period, hawser length as well as terminal displacement in different directions, and the impact of tanker presence on the behavior of the riser (lazy S) during unloading/loading operations. The hydrodynamic response characteristics of the tanker and CALM buoy are calculated using ANSYS-AQWA software and the outputs are imported in OracleFlex software for simulation of the probable operating scenarios considering the terminal, tanker, mooring lines and Environmental conditions. The results indicate that the terminal dynamic response is most sensitive to the current velocity changes. It is also concluded that for the riser, when Near offset, an effective tension and for far offset, the bending moment includes critical states. The bending moment at the hang-off the riser and the effective tension at PLEM receive the most impact from the interactive mode of operation between the tanker and the terminal.

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An Integrated Methodology for the Design of Mooring Systems and Risers of Floating Production Platforms

Cited by 3 publications

References 0 publications

Mathematical Modelling of Bonded Marine Hoses for Single Point Mooring (SPM) Systems, with Catenary Anchor Leg Mooring (CALM) Buoy Application—A Review

Mathematical Modelling of Bonded Marine Hoses for Single Point Mooring (SPM) Systems, with Catenary Anchor Leg Mooring (CALM) Buoy Application—A Review

Evaluation of the Safe and Failure Zones of Mooring and Riser Systems in a CALM Oil Terminal

Sensitivity Analysis of the Dynamic Response of CALM Oil Terminal, in The Persian Gulf Region Under Different Operation Parameters

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