Numerical analysis of fishtailing motion, buoy kissing and pullback force in a catenary anchor leg mooring (CALM) moored tanker system

Numerical analysis of fishtailing motion, buoy kissing and pullback force in a catenary anchor leg mooring (CALM) moored tanker system

The catenary anchor leg mooring (CALM) sys tem is one of the most complex hydrodynamic systems in terms of hydrodynamic theory. This complexity comes from a large amount of interaction between the buoy, its mooring legs, hawsers, and the moored tanker. A dynamic simulation analysis of a CALM moored...

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Main Authors: Ju X., Amaechi C.V., Dong B., Meng X., Li J.
Other Authors: 56348761500
Format: Article
Published: Elsevier Ltd 2024
Subjects:
Catenary anchor leg mooring
Fishtailing
Floating buoy
Hydrodynamic
Mooring
Offshore floating structure
Tanker
Buoys
Mooring cables
Numerical analysis
Offshore oil well production
Time domain analysis
Catenary anchor leg moorings
Fishtailing motion
Floating structures
Hawsers
Hydrodynamic systems
Mooring system
Offshore floating
environmental conditions
floating structure
hydrodynamics
mooring system
numerical method
offshore structure
Hydrodynamics
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Institution: Universiti Tenaga Nasional
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spelling my.uniten.dspace-342332024-10-14T11:18:33Z Numerical analysis of fishtailing motion, buoy kissing and pullback force in a catenary anchor leg mooring (CALM) moored tanker system Ju X. Amaechi C.V. Dong B. Meng X. Li J. 56348761500 57204818354 57742899200 57742413200 57972919200 Catenary anchor leg mooring Fishtailing Floating buoy Hydrodynamic Mooring Offshore floating structure Tanker Buoys Mooring Mooring cables Numerical analysis Offshore oil well production Time domain analysis Catenary anchor leg moorings Fishtailing Fishtailing motion Floating buoy Floating structures Hawsers Hydrodynamic systems Mooring system Offshore floating Offshore floating structure environmental conditions floating structure hydrodynamics mooring system numerical method offshore structure Hydrodynamics The catenary anchor leg mooring (CALM) sys tem is one of the most complex hydrodynamic systems in terms of hydrodynamic theory. This complexity comes from a large amount of interaction between the buoy, its mooring legs, hawsers, and the moored tanker. A dynamic simulation analysis of a CALM moored tanker system is carried out in this research. A double spring hydrodynamic response system model composed of �Anchoring-Buoy� and �Hawser-Tanker� established for the CALM system in the given environmental conditions with the method of time domain coupling simulation, correlation, and comprehensive analysis simulations of the fishtailing motion, buoy kissing, hawser capacity, and pullback force. A numerical analysis shows that without pullback force, fishtailing occurs often. A pullback force of 800 kN in line with the tanker's centerline effectively reduces the yaw motion and preserves a safe distance between the tanker and the buoy, so fishtailing occurs less often, and buoy kissing does not occur. Thus, the pullback force of 800 kN represents astern propulsion and a pullback tug, as it significantly improves the behavior of the moored tanker in relation to the buoy. Therefore, it is recommended that a tug is always present while a tanker is moored to the CALM system. � 2023 Final 2024-10-14T03:18:33Z 2024-10-14T03:18:33Z 2023 Article 10.1016/j.oceaneng.2023.114236 2-s2.0-85151633777 https://www.scopus.com/inward/record.uri?eid=2-s2.0-85151633777&doi=10.1016%2fj.oceaneng.2023.114236&partnerID=40&md5=3522ae8253258f4b219965205a06fc87 https://irepository.uniten.edu.my/handle/123456789/34233 278 114236 All Open Access Hybrid Gold Open Access Elsevier Ltd Scopus
institution Universiti Tenaga Nasional
building UNITEN Library
collection Institutional Repository
continent Asia
country Malaysia
content_provider Universiti Tenaga Nasional
content_source UNITEN Institutional Repository
url_provider http://dspace.uniten.edu.my/
topic Catenary anchor leg mooring
Fishtailing
Floating buoy
Hydrodynamic
Mooring
Offshore floating structure
Tanker
Buoys
Mooring
Mooring cables
Numerical analysis
Offshore oil well production
Time domain analysis
Catenary anchor leg moorings
Fishtailing
Fishtailing motion
Floating buoy
Floating structures
Hawsers
Hydrodynamic systems
Mooring system
Offshore floating
Offshore floating structure
environmental conditions
floating structure
hydrodynamics
mooring system
numerical method
offshore structure
Hydrodynamics
spellingShingle Catenary anchor leg mooring
Fishtailing
Floating buoy
Hydrodynamic
Mooring
Offshore floating structure
Tanker
Buoys
Mooring
Mooring cables
Numerical analysis
Offshore oil well production
Time domain analysis
Catenary anchor leg moorings
Fishtailing
Fishtailing motion
Floating buoy
Floating structures
Hawsers
Hydrodynamic systems
Mooring system
Offshore floating
Offshore floating structure
environmental conditions
floating structure
hydrodynamics
mooring system
numerical method
offshore structure
Hydrodynamics
Ju X.
Amaechi C.V.
Dong B.
Meng X.
Li J.
Numerical analysis of fishtailing motion, buoy kissing and pullback force in a catenary anchor leg mooring (CALM) moored tanker system
description The catenary anchor leg mooring (CALM) sys tem is one of the most complex hydrodynamic systems in terms of hydrodynamic theory. This complexity comes from a large amount of interaction between the buoy, its mooring legs, hawsers, and the moored tanker. A dynamic simulation analysis of a CALM moored tanker system is carried out in this research. A double spring hydrodynamic response system model composed of �Anchoring-Buoy� and �Hawser-Tanker� established for the CALM system in the given environmental conditions with the method of time domain coupling simulation, correlation, and comprehensive analysis simulations of the fishtailing motion, buoy kissing, hawser capacity, and pullback force. A numerical analysis shows that without pullback force, fishtailing occurs often. A pullback force of 800 kN in line with the tanker's centerline effectively reduces the yaw motion and preserves a safe distance between the tanker and the buoy, so fishtailing occurs less often, and buoy kissing does not occur. Thus, the pullback force of 800 kN represents astern propulsion and a pullback tug, as it significantly improves the behavior of the moored tanker in relation to the buoy. Therefore, it is recommended that a tug is always present while a tanker is moored to the CALM system. � 2023
author2 56348761500
author_facet 56348761500
Ju X.
Amaechi C.V.
Dong B.
Meng X.
Li J.
format Article
author Ju X.
Amaechi C.V.
Dong B.
Meng X.
Li J.
author_sort Ju X.
title Numerical analysis of fishtailing motion, buoy kissing and pullback force in a catenary anchor leg mooring (CALM) moored tanker system
title_short Numerical analysis of fishtailing motion, buoy kissing and pullback force in a catenary anchor leg mooring (CALM) moored tanker system
title_full Numerical analysis of fishtailing motion, buoy kissing and pullback force in a catenary anchor leg mooring (CALM) moored tanker system
title_fullStr Numerical analysis of fishtailing motion, buoy kissing and pullback force in a catenary anchor leg mooring (CALM) moored tanker system
title_full_unstemmed Numerical analysis of fishtailing motion, buoy kissing and pullback force in a catenary anchor leg mooring (CALM) moored tanker system
title_sort numerical analysis of fishtailing motion, buoy kissing and pullback force in a catenary anchor leg mooring (calm) moored tanker system
publisher Elsevier Ltd
publishDate 2024
_version_ 1814060072185102336

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