Effects of Wind-Wave Misalignment on a Wind Turbine Blade Mating Process: Impact Velocities, Blade Root Damages and Structural SafetyAssessment

Amrit Shankar Verma , Zhiyu Jiang , Zhengru Ren , Zhen Gao , Nils Petter Vedvik

Journal of Marine Science and Application ›› 2020, Vol. 19 ›› Issue (2) : 218 -233.

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Journal of Marine Science and Application ›› 2020, Vol. 19 ›› Issue (2) : 218 -233. DOI: 10.1007/s11804-020-00141-7
Research Article

Effects of Wind-Wave Misalignment on a Wind Turbine Blade Mating Process: Impact Velocities, Blade Root Damages and Structural SafetyAssessment

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Abstract

Most wind turbine blades are assembled piece-by-piece onto the hub of a monopile-type offshore wind turbine using jack-up crane vessels. Despite the stable foundation of the lifting cranes, the mating process exhibits substantial relative responses amidst blade root and hub. These relative motions are combined effects of wave-induced monopile motions and wind-induced blade root motions, which can cause impact loads at the blade root’s guide pin in the course of alignment procedure. Environmental parameters including the wind-wave misalignments play an important role for the safety of the installation tasks and govern the impact scenarios. The present study investigates the effects of wind-wave misalignments on the blade root mating process on a monopile-type offshore wind turbine. The dynamic responses including the impact velocities between root and hub in selected wind-wave misalignment conditions are investigated using multibody simulations. Furthermore, based on a finite element study, different impact-induced failure modes at the blade root for sideways and head-on impact scenarios, developed due to wind-wave misalignment conditions, are investigated. Finally, based on extreme value analyses of critical responses, safe domain for the mating task under different wind-wave misalignments is compared. The results show that although misaligned wind-wave conditions develop substantial relative motions between root and hub, aligned wind-wave conditions induce largest impact velocities and develop critical failure modes at a relatively low threshold velocity of impact.

Keywords

Wind turbine blade / Wind-wave misalignment / Monopile / Marine operation / Finite element analysis / T-bolt connections

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Amrit Shankar Verma, Zhiyu Jiang, Zhengru Ren, Zhen Gao, Nils Petter Vedvik. Effects of Wind-Wave Misalignment on a Wind Turbine Blade Mating Process: Impact Velocities, Blade Root Damages and Structural SafetyAssessment. Journal of Marine Science and Application, 2020, 19(2): 218-233 DOI:10.1007/s11804-020-00141-7

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Funding

Delft University of Technology

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