Simulation of a Ship and Tension Leg Platform Wind Turbine Collision

This paper describes model testing of a Tension Leg Platform Wind Turbine (TLPWT) with non-rotating blades to better understand its motion and tendon responses when subjected to combined wind and unidirectional regular wave conditions. The TLPWT structure is closely based on the National Renewable Energy Laboratory (NREL) 5 MW concept. Multiple free decay tests were performed to evaluate the natural periods of the model in the key degrees of freedom, whilst Response Amplitude Operators (RAOs) were derived to show the motion and tendon characteristics. The natural periods in surge and pitch motions evaluated from the decay tests had a relatively close agreement to the theoretical values. Overall, the tested TLPWT model exhibited typical motion responses to that of a generalised TLP with significant surge offsets along with stiff heave and pitch motions. The maximum magnitudes for the RAOs of surge motion and all tendons occurred at the longest wave period of 1.23 s (~13.0 s at full-scale) tested in this study. From the attained results, there was evidence that static wind loading on the turbine structure had some impact on the motions and tendon response, particularly in the heave direction, with an average increase of 13.1% in motion amplitude for the tested wind conditions. The wind had a negligible effect on the surge motion and slightly decreased the tendon tensions in all tendons. The results also showed the set-down magnitudes amounting to approximately 2–5% of the offset. Furthermore, the waves are the dominant factor contributing to the set-down of the TLPWT, with a minimal contribution from the static wind loading. The results of this study could be used for calibrating numerical tools such as CFD codes.

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Spoke Dimension on the Motion Performance of a Floating Wind Turbine with Tension-Leg Platform

Shock and Vibration ◽

10.1155/2016/8913873 ◽

2016 ◽

Vol 2016 ◽

pp. 1-16

Author(s):

H. F. Wang ◽

Y. H. Fan

Keyword(s):

Wind Turbine ◽

Good Choice ◽

Offshore Wind ◽

Experimental Result ◽

Offshore Wind Turbine ◽

Tension Leg Platform ◽

Irregular Wave ◽

Wind Turbine System ◽

Floating Offshore Wind Turbines ◽

Tower Structure

The tension-leg platform (TLP) supporting structure is a good choice for floating offshore wind turbines because TLP has superior motion dynamics. This study investigates the effects of TLP spoke dimensions on the motion of a floating offshore wind turbine system (FOWT). Spoke dimension and offshore floating TLP were subjected to irregular wave and wind excitation to evaluate the motion of the FOWT. This research has been divided into two parts: (1) Five models were designed based on different spoke dimensions, and aerohydroservo-elastic coupled analyses were conducted on the models using the finite element method. (2) Considering the coupled effects of the dynamic response of a top wind turbine, a supporting-tower structure, a mooring system, and two models on a reduced scale of 1 : 80 were constructed and experimentally tested under different conditions. Numerical and experimental results demonstrate that the spoke dimensions have a significant effect on the motion of FOWT and the experimental result that spoke dimension can reduce surge platform movement to improve turbine performance.

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Study of Floating Wind Turbine with Modified Tension Leg Platform Placed in Regular Waves

Energies ◽

10.3390/en12040703 ◽

2019 ◽

Vol 12 (4) ◽

pp. 703 ◽

Cited By ~ 3

Author(s):

Juhun Song ◽

Hee-Chang Lim

Keyword(s):

Wind Turbine ◽

Real Data ◽

Offshore Wind ◽

Scale Model ◽

Offshore Wind Turbine ◽

Wave Loads ◽

Tension Leg Platform ◽

Mooring Lines ◽

Floating Wind Turbine ◽

Wave Conditions

In this study, the typical ocean environment was simulated with the aim to investigate the dynamic response under various environmental conditions of a Tension Leg Platform (TLP) type floating offshore wind turbine system. By applying Froude scaling, a scale model with a scale of 1:200 was designed and model experiments were carried out in a lab-scale wave flume that generated regular periodic waves by means of a piston-type wave generator while a wave absorber dissipated wave energy on the other side of the channel. The model was designed and manufactured based on the standard prototype of the National Renewable Energy Laboratory (NREL) 5 MW offshore wind turbine. In the first half of the study, the motion and structural responses for operational wave conditions of the North Sea near Scotland were considered to investigate the performance of a traditional TLP floating wind turbine compared with that of a newly designed TLP with added mooring lines. The new mooring lines were attached with the objective of increasing the horizontal stiffness of the system and thereby reducing the dominant motion of the TLP platform (i.e., the surge motion). The results of surge translational motions were obtained both in the frequency domain, using the response amplitude operator (RAO), and in the time domain, using the omega arithmetic method for the relative velocity. The results obtained show that our suggested concept improves the stability of the platform and reduces the overall motion of the system in all degrees-of-freedom. Moreover, the modified design was verified to enable operation in extreme wave conditions based on real data for a 100-year return period of the Northern Sea of California. The loads applied by the waves on the structure were also measured experimentally using modified Morison equation—the formula most frequently used to estimate wave-induced forces on offshore floating structures. The corresponding results obtained show that the wave loads applied on the new design TLP had less amplitude than the initial model and confirmed the significant contribution of the mooring lines in improving the performance of the system.

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Effects of Hull Flexibility on the Structural Dynamics of a Tension Leg Platform Floating Wind Turbine

Journal of Offshore Mechanics and Arctic Engineering ◽

10.1115/1.4044725 ◽

2019 ◽

Vol 142 (1) ◽

Cited By ~ 1

Author(s):

Carlos Eduardo Silva de Souza ◽

Erin E. Bachynski

Keyword(s):

Wind Turbine ◽

Fatigue Damage ◽

Structural Response ◽

Wave Excitation ◽

Short Term ◽

Tension Leg Platform ◽

Flexible Beams ◽

Fatigue Damage Accumulation ◽

Vertical Deformations ◽

Motion Amplitude

Abstract Dynamic analysis of floating wind turbines often considers the hull as a rigid body. This paper explores the consequences of modeling the pontoons of a tension leg platform (TLP) wind turbine as flexible beams. The analysis is based on numerical simulations of free decays, structural response to wave excitation, and short-term fatigue damage accumulation at tower base and tendons. In addition, the importance of hydroelastic effects due to the pontoons’ vertical deformations is evaluated. Pontoon flexibility changed the platform natural periods and motion amplitude significantly, and the adoption of flexible pontoons reduced the predicted fatigue damage in the tower base and tendons. On the other hand, hydroelasticity had negligible consequences for motion and load responses considered here.

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Hydrodynamic design of a free-float capable tension leg platform for a 10 MW wind turbine

Ocean Engineering ◽

10.1016/j.oceaneng.2019.106888 ◽

2020 ◽

Vol 197 ◽

pp. 106888 ◽

Cited By ~ 2

Author(s):

Emre Uzunoglu ◽

C. Guedes Soares

Keyword(s):

Wind Turbine ◽

Tension Leg Platform

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Response dynamics of a free-float capable tension leg platform for a 10 MW wind turbine at the Northern Iberian Peninsula

Developments in Renewable Energies Offshore ◽

10.1201/9781003134572-47 ◽

2020 ◽

pp. 408-416

Author(s):

E. Uzunoglu ◽

C. Guedes Soares

Keyword(s):

Wind Turbine ◽

Iberian Peninsula ◽

Response Dynamics ◽

Tension Leg Platform ◽

Northern Iberian Peninsula

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Coupled Dynamic Analysis of a Tension Leg Platform Floating Offshore Wind Turbine

Journal of Offshore Mechanics and Arctic Engineering ◽

10.1115/1.4044075 ◽

2019 ◽

Vol 142 (1) ◽

Cited By ~ 1

Author(s):

Teng Wang ◽

Hui Jin ◽

Xiaoni Wu

Keyword(s):

Dynamic Analysis ◽

Wind Turbine ◽

Offshore Wind ◽

Wind Loads ◽

Offshore Wind Turbine ◽

Wave Loads ◽

Tension Leg Platform ◽

Floating Offshore Wind Turbine ◽

Turbulent Wind ◽

Coupled Dynamic Analysis

The dynamic response of a tension leg platform (TLP) floating offshore wind turbine (FOWT) was analyzed with considering the aero-hydro characteristic of the whole floating wind turbine system including the wind turbine, TLP platform, and tethers. The “aero-hydro” coupled dynamic analysis was conducted in ansys-aqwa with a dynamic link library (DLL) calculating the aerodynamics loading at every steptime based on the blade element momentum theory. Results from the coupled dynamic analysis of TLP FOWT under the condition of turbulent wind and regular wave show that the wind loads influence mainly the low-frequency response of the TLP FOWT. The wind loads have a large impact on the offsets of the TLP away from the initial position while the wave loads influence mainly the fluctuation amplitude of the TLP FOWT. The average TLP pitch response under the wind load is significantly larger due to the large wind-induced heeling moment on the wind turbine. In addition, the tension of tethers at the upwind end is greater than that at the downwind end. The wind loads could reduce effectively the average tension of the tethers, and the tension of tethers is significantly affected by the pitch motion. Results from the coupled dynamic analysis of TLP FOWT under the condition of turbulent wind and irregular wave show that the surge and pitch of TLP result in an obvious increase of thrust of the turbine and the amplitude of torque fluctuation, more attention should be paid to the pitch and surge motion of TLP FOWT.

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