Dynamic Power Cable Layout Design for 15MW Floating Offshore Wind Turbines: Part 1 - Configuration Analysis and Optimization

Dynamic Power Cable Layout Design for 15MW Floating Offshore Wind Turbines: Part 1 - Configuration Analysis and Optimization

A lazy wave configuration was designed and validated for a dynamic power cable connected to a 15MW floating offshore wind turbine (FOWT) in the Ulsan offshore region. The design variables included the starting position, length, and total buoyancy of distributed buoyancy modules (DBMs). The starting...

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Bibliographic Details
Main Authors: Doyoung Kwon, Hyun Kyung Kim, Joonmo Choung
Format: Article
Language:English
Published: The Korean Society of Ocean Engineers 2025-06-01
Series:한국해양공학회지
Subjects:
floating offshore wind turbine
dynamic power cable
lazy wave
distributed buoyancy module
static load analysis
Online Access:https://doi.org/10.26748/KSOE.2025.014
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Summary:A lazy wave configuration was designed and validated for a dynamic power cable connected to a 15MW floating offshore wind turbine (FOWT) in the Ulsan offshore region. The design variables included the starting position, length, and total buoyancy of distributed buoyancy modules (DBMs). The starting position of the DBMs refers to the absolute distance along the dynamic power cable from the hang-off point, with nine levels considered. The DBM lengths were divided into eleven levels, and the total buoyancy was analyzed at two levels: 140% and 230% of the suspended weight of the dynamic power cable. One hundred and ninety-eight models were developed based on these parameters and subjected to parametric static analysis. Three-dimensional response surfaces for hang-off tension, Ez angle, and minimum bend radius (MBR) were compared to identify the optimal layouts. Two configurations were proposed for each buoyancy level, revealing a trade-off between the MBR and Ez angle: increased buoyancy improved MBR but negatively impacted Ez angle. This inverse relationship underscores the need for careful optimization. Future work will involve fully-coupled load analyses of the FOWT under ultimate and fatigue limit state conditions to assess the structural integrity and long-term performance in the extreme environment of Ulsan offshore waters.
ISSN:1225-0767
2287-6715

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