Detection method and characterization of Ramp event of wind speed and wind power based on Swinging Door Algorithm

doi:10.7523/j.ucas.2023.014

Abstract

Abstract: The ramp event of wind speed is a large increase or decrease in wind speed within a short period, causing a huge change in wind farm power, affecting the safe operation of the grid and even triggering accidents such as frequency reduction and voltage collapse. This paper selects the simultaneous data of wind turbines and meteorological towers in wind farms, identifies the climbing events by the Swinging Door Algorithm (SDA), analyzes the duration, magnitude and change rate of the ramp events, and discusses the influence of mountainous terrain on the climbing events. In this paper, the recognition algorithm of the ramp event of wind speed and power is designed based on the Swinging Door Algorithm, and the algorithm parameters are taken as the time threshold 4h, wind speed threshold 6m s-1 and power threshold 1000kW. For the recognition of ramp events of other wind turbines, this paper suggests using 2/3 value of the difference between rated wind speed and cut-in wind speed as the wind speed threshold parameter and 2/3 value of rated power as the power threshold parameter. The terrain influence on the ramp event is significant, and the ramp event is more related to the altitude and average wind speed at the turbine, and the time proportion of the ramp event under different terrain is distributed in the range of 6.5% to 9.8%, with the average value of 7.8%.

Key words: Ramping event, detection method, Swinging Door Algorithm, wind farm

CLC Number:

P49
P412

LIANG Zhi, ZHANG Zhe, SHI Yu, LIU Lei. Detection method and characterization of Ramp event of wind speed and wind power based on Swinging Door Algorithm[J]. Journal of University of Chinese Academy of Sciences, DOI: 10.7523/j.ucas.2023.014.

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