8 results ·
● Live web index
U
ui.adsabs.harvard.edu
research
https://ui.adsabs.harvard.edu/abs/2023JWEIA.24205579W/abstract
* Sign in to ORCID to claim papers in the ADS.;). ## Feasibility of typhoon models and wind power spectra on response analysis of parked wind turbines. Typhoon may induce severe damages to wind turbines in both eyewall and outer vortex regions, and accurate typhoon simulation is important for the wind turbine response estimation. In this research, wind fields in these two regions are reproduced by applying two-dimensional or three-dimensional models for mean wind speed, and von Karman spectrum or Kaimal spectrum for the fluctuating wind speed. The results show that three-dimensional model excels in reproducing typhoon wind field, especially for supergradient wind. Mean responses of blade and tower are underestimated with two-dimensional model in eyewall region by 8∼24%, although these differences become negligible in the outer vortex region. Consequently, it is recommended to apply three-dimensional model for mean response estimation of wind turbines in the eyewall region, two-dimensional model in the outer vortex region for less computation time, and von Karman spectrum for the extreme response in the whole typhoon field.
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mdpi.com
article
https://www.mdpi.com/2073-4433/13/3/451
A CFD model was used to simulate the flow field around the wind turbine to analyze the aerodynamic response of the wind turbine with a typhoon load. In summary,
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typhoon-hil.com
article
https://www.typhoon-hil.com/blog/real-time-wind-turbine-simulation
# Before the Blades Turn: Real-Time Wind Turbine Simulation. Not only are wind turbines getting larger, but their control software is becoming increasingly complex, managing everything from grid compliance to fault ride-through requirements. Typhoon HIL’s real-time simulation and HIL testing help developers validate every part—before a turbine ever spins—ensuring better performance, higher efficiency, and lower risk. ## **Wind energy is on the rise, but can your wind turbine control system weather the storm?**. That’s where Hardware-in-the-Loop (HIL) simulation comes in, providing engineers a safe, cost-effective, and comprehensive environment to validate turbine controls long before any physical prototype is available. There is a great opportunity for improving the efficiency of the output, reliability of performance, as well as longevity of wind turbines, all through improvements in the software that controls them. This means that the controller tested in HIL simulation operates exactly as it would in the real system, but instead of driving a physical turbine, it interacts with a real-time simulation of the turbine, grid, and environment.
S
sciencedirect.com
article
https://www.sciencedirect.com/science/article/abs/pii/S0167610523002829
Accurate simulation of typhoon wind field, especially in eyewall region, is important for estimating aerodynamic loads and responses of wind turbines. Typhoon
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typhoon-hil.com
article
https://www.typhoon-hil.com/documentation/typhoon-hil-software-manual/Referen…
The Wind Turbine component contains a simplified model of the mechanical system and the aerodynamics of a wind turbine.
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sciencedirect.com
article
https://www.sciencedirect.com/science/article/abs/pii/S0951833923001120
A data-driven typhoon wind power spectrum model that is capable of describing spectrum at different typhoon stages, namely front outer vortex, front eyewall
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orbit.dtu.dk
article
https://orbit.dtu.dk/en/publications/typhoon-wind-and-turbulence-structure-an…
These wind fields were used as inflow conditions for wind turbine load simulations. Based on a limited number of wind turbine load simulations
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scholar.hit.edu.cn
research
https://scholar.hit.edu.cn/en/publications/on-structural-loads-and-responses-…
A high-fidelity numerical simulation framework was developed, integrating an advanced three-dimensional typhoon wind field model with the SWAN and ADCIRC models