Research on Yaw Optimization Control Strategy of Floating Wind Farm Considering Wake Effect

doi:10.16628/j.cnki.2095-8188.2023.11.011

Abstract

Abstract:

The interaction of internal wakes in wind farms affects the inflow wind speed of downstream wind turbines.To reduce the impact of wake effects on the power generation of floating wind farms, a yaw optimization control strategy of floating wind farms considering wake effects is proposed.A Gaussian curl mixed wake model is established for the specificities of the wake recovery speed changes and the impact on the wake of downstream units under yaw conditions.Considering the influence of yaw conditions on the blade displacement,the blade root load, and platform motion, a range of unit yaw angles is set as a constraint condition.Using the least squares SLSQP optimization algorithm, the optimal yaw angle and power generation of each unit in the wind farm are obtained with the maximum overall power generation as the objective function and the yaw angle as the optimization variable.The simulation results show that the proposed control strategy can effectively improve the overall power generation of the wind farm.

Key words: floating wind farm, wake effect, Gaussian curl mixed wake model, yaw optimization control, power generation

CLC Number:

TM614

LI Binbin, WANG Xiaodong, LIU Yingming, ZHU Ruonan. Research on Yaw Optimization Control Strategy of Floating Wind Farm Considering Wake Effect[J]. LOW VOLTAGE APPARATUS, 2023, 0(11): 67-73.

Figures/Tables 11

References 15

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偏航角/(°)	叶根力矩/(kN·m)	降低率/%
0	5 850.756	0.00
5	5 798.556	0.89
10	5 688.350	1.90
15	5 470.466	3.83
20	5 235.108	4.30
25	4 940.697	5.62
30	4 606.827	7.67

参数	数值
风轮和轮毂直径、高度/m	126、3、90
切入、额定、切除风速/(m?s^-1)	3、11.4、25
切入、额定叶轮转速/(r?min^-1)	6.9、12.1
风轮、机舱、塔架质量/kg	11×10⁴、24×10⁴
平台底座总吃水深度/m	20
主浮筒在海平面以上高度/m	10
副浮筒在海平面以上高度/m	12
主、副浮筒直径/m	6.5、12

风速/(m·s^-1)	无尾流控制场发电量/MW	尾流控制整场发电量/MW	提升率/%
6	3.552 02	4.202 69	18.3
8	8.677 18	10.353 53	19.3
10	16.836 05	20.163 08	19.8
12	28.457 97	34.564 54	21.5