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Dynamic behavior of a tension leg platform offshore wind turbine under environmental loads
732 viewed

Dynamic behavior of a tension leg platform offshore wind turbine under environmental loads

Ebrahimi, A

Dynamic behavior of a tension leg platform offshore wind turbine under environmental loads

Ebrahimi, A ; Sharif University of Technology

732 Viewed
  1. Type of Document: Article
  2. Abstract:
  3. In order to evaluate the dynamic behavior of floating offshore wind turbines, the authors consider two approaches. A numerical method is used to investigate Tension Leg Platform (TLP) offshore wind turbine response behavior under a parked condition. This code considers nonlinearities due to changes in the tension of tethers. The off-diagonal components of stiffness, damping and mass matrices are considered to calculate coupling. This code solves the nonlinear equation of motion at each time step. However, in order to validate the data generated by the code, a scaled-down model was fully tested in the marine laboratory. The importance of these series of experiments is due to the fact that this model possesses a unique design and specifications to which no other model can be compared. Measurement of three degrees of freedom under environmental load is the goal of the experiments. Also, the results clearly show that the direction of encountering waves is an extremely important factor. It can be concluded that wind loads can dampen the oscillation of the model and prevent the impact of large loads on the tethers. The results show that the discrepancy between experimental and numerical results, with different degrees of freedom, is sufficiently acceptable
  4. Keywords:
  5. Floating platform ; Model test ; Offshore wind turbine ; Sea wave load ; Tension leg platform ; Wind load ; Aerodynamic loads ; Codes (symbols) ; Degrees of freedom (mechanics) ; Equations of motion ; Experiments ; Fluid structure interaction ; Loads (forces) ; Tetherlines ; Wind stress ; Numerical solution ; Sea waves ; Damping ; Dynamic property ; Numerical model ; Stiffness ; Wave direction ; Wind power ; Wind turbine
  6. Source: Scientia Iranica ; Vol. 21, issue. 3 , 2014 , pp. 480-491 ; ISSN : 1026-3098
  7. URL: http://www.scientiairanica.com/en/ManuscriptDetail?mid=205