Dynamic Responses of a Scaled Tension Leg Platform, Wind Turbine Support Structure in a Wave Tank

Jimmy Murphy; Richard O’Shea; Keith O’Sullivan; Vikram Pakrashi

doi:10.4028/www.scientific.net/KEM.569-570.563

Paper Titles

Non-Linear Aeroelastic Stability of Wind Turbines
p.531

Fatigue Analysis of Offshore Wind Turbines on Fixed Support Structures
p.539

Advanced Tools for Damage Detection in Wind Turbines
p.547

Damage Identification in a Laboratory Offshore Wind Turbine Demonstrator
p.555

Dynamic Responses of a Scaled Tension Leg Platform, Wind Turbine Support Structure in a Wave Tank
p.563

Simulation of the Stochastic Wave Loads Using a Physical Modeling Approach
p.571

Failure Analysis of Wind Turbines by Probability Density Evolution Method
p.579

Generalized Stochastic Constraint TARMA Models for In-Operation Identification of Wind Turbine Non-Stationary Dynamics
p.587

Numerical Modeling to Aid in the Structural Health Monitoring of Wave Energy Converters
p.595

HomeKey Engineering MaterialsKey Engineering Materials Vols. 569-570Dynamic Responses of a Scaled Tension Leg...

Dynamic Responses of a Scaled Tension Leg Platform, Wind Turbine Support Structure in a Wave Tank

Abstract:

Understanding the dynamic behaviour of offshore wind and wave energy devices is extremely important in relation to the maintenance and management of these marine assets. Since experimentation in sea may often be difficult, expensive or unnecessary at a conceptual or at pre-commercial stage, scaled experimentation in wave tanks can be central to the understanding and assessment of their dynamic responses. This paper presents scaled dynamic testing in a wave tank of a tension leg platform for supporting a wind turbine for different regular wave conditions and sea states characterised by the Bretschneider spectra. The dynamic response of the device was monitored at different locations on the device using load cells and with a camera based motion recognition system. For the analysis, a frequency response function based approach was considered to illustrate the response of the device under varied wave loading conditions. The experimentation does not assume any underlying theoretical model, apart from the consideration of Froude scaling conditions to attempt to link experimentation conditions with actual conditions. The results are important for characterisation of theoretical models and fitting parameters of such theoretical models, while identifying the limits and potential challenges of applying linear dynamic analysis in these situations. The findings are also important for establishing system identification and control strategies for undesirable levels of dynamic response. The fitted models based on physical modelling, when combined with scaled experimental responses, can also be helpful in better estimating extreme responses of the devices.

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Periodical:

Key Engineering Materials (Volumes 569-570)

Pages:

563-570

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.569-570.563

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Online since:

July 2013

Authors:

Jimmy Murphy, Richard O’Shea, Keith O’Sullivan, Vikram Pakrashi

Keywords:

Monitoring of Renewable Energy Systems, Scaled Dynamic Testing, Tension Leg Platform, Wave Tank

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