Development of interlink wear estimation method for mooring chain of floating structures: Validation and new approach using three-dimensional contact response

Development of interlink wear estimation method for mooring chain of floating structures: Validation and new approach using three-dimensional contact response

Long-term operation of mooring systems is one of the challenging issues of floating structures such as floating offshore wind turbines (FOWTs). For integrity assessment, fatigue and its affecting factors have generated considerable recent research interest as the occurrence of a large number of moor...

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Veröffentlicht in:Marine structures 2021-05, Vol.77, p.102927, Article 102927
Hauptverfasser: Takeuchi, Takaaki, Utsunomiya, Tomoaki, Gotoh, Koji, Sato, Iku
Format: Artikel
Sprache:eng
Schlagworte:
Chains
Diameters
Dynamic analysis
Dynamic response analysis
Finite element analysis
Floating offshore wind turbine
Floating structures
Mass
Mass-spring systems
Model accuracy
Mooring
Mooring chain
Mooring systems
Offshore
Offshore energy sources
Offshore operations
Offshore structures
Spring
Three dimensional models
Turbine engines
Turbines
Wear
Wear estimation
Wind power
Wind turbines
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container_title Marine structures
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creator Takeuchi, Takaaki
Utsunomiya, Tomoaki
Gotoh, Koji
Sato, Iku
description Long-term operation of mooring systems is one of the challenging issues of floating structures such as floating offshore wind turbines (FOWTs). For integrity assessment, fatigue and its affecting factors have generated considerable recent research interest as the occurrence of a large number of mooring chain failures at a high rate has been reported. By contrast, only few studies on the effect of nonuniform volume loss of mooring chain links due to wear can be found because of difficulties to estimate wear amounts quantitatively. Considering this issue, in this paper, validation of the quantitative interlink wear estimation method is investigated by applying to a spar-type floating structure. Firstly, the method is presented which consists of the material test, derivation of an interlink wear estimation formula with FE analysis, and calculation of mooring chain response with coupled dynamic analysis using a mass-spring model. To improve insufficient accuracy due to the mass-spring model around a clump weight and the touchdown point, the method is further modified by using a 3-D rigid-body link model. The estimation results and comparison show that the modified method distinguishing between rolling and sliding can calculate the interlink wear amount closer to the chain diameter measurements and more reasonable than the method using the conventional mass-spring model. •The quantitative interlink wear estimation method is investigated by comparison with the measurements.•The method includes the material test, derivation of estimation formula and mooring chain response.•The wear estimation by the conventional mass-spring model causes overestimation.•The method modified by the three-dimensional link model estimates the wear amount closer to the chain diameter measurements.
doi_str_mv 10.1016/j.marstruc.2020.102927
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subjects Chains
Diameters
Dynamic analysis
Dynamic response analysis
Finite element analysis
Floating offshore wind turbine
Floating structures
Mass
Mass-spring systems
Model accuracy
Mooring
Mooring chain
Mooring systems
Offshore
Offshore energy sources
Offshore operations
Offshore structures
Spring
Three dimensional models
Turbine engines
Turbines
Wear
Wear estimation
Wind power
Wind turbines
title Development of interlink wear estimation method for mooring chain of floating structures: Validation and new approach using three-dimensional contact response
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