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Reinforcement learning algorithm-based self-correction control method for double-fed induction wind power generator

A self-calibration control and wind turbine technology, applied in the direction of motor generator control, electronic commutation motor control, control generator, etc., can solve the problems of complex implementation, unmodeled, large steady-state error, etc., to achieve enhanced robustness Rod and adaptability, good dynamic performance, easy engineering to realize the effect

Inactive Publication Date: 2017-06-20
SOUTH CHINA UNIV OF TECH
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Problems solved by technology

[0003] Due to the strong randomness and time-varying nature of wind energy, and the system contains dynamic parts that are not modeled or cannot be modeled accurately, the doubly-fed power generation system becomes a multivariable, nonlinear, and strongly coupled system, so it is difficult to use only traditional vector control Meet the requirements of the control system for high adaptability and high robustness
At present, various control schemes are used, but the control effect is not very ideal. For example, the neural network control scheme is adopted. This control scheme improves the control performance, but the steady-state error is relatively large.
However, the fuzzy sliding mode control strategy is used to combine fuzzy control and sliding mode control. Although a good control effect has been achieved, the implementation is more complicated.

Method used

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  • Reinforcement learning algorithm-based self-correction control method for double-fed induction wind power generator
  • Reinforcement learning algorithm-based self-correction control method for double-fed induction wind power generator
  • Reinforcement learning algorithm-based self-correction control method for double-fed induction wind power generator

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Embodiment

[0097] For the doubly-fed induction wind power generator, verify the correctness and effectiveness of the controller designed by the present invention.

[0098] The doubly-fed induction wind turbine selects the following parameters for simulation verification: the rated power of the doubly-fed wind turbine is P=9MW (=6*1.5MW), R s =0.007pu, R r =0.005pu, L s =3.071pu, L r =3.056pu,L m = 2.9pu,n p =3, these parameters can be substituted into the above formulas (1)~(10) to calculate the corresponding parameters of the doubly-fed wind turbine. The parameters of the two PI controllers are: proportional gain: K p =6.9; Integral gain: K i =408, the parameter of RL-P controller is: weight value μ 1 = 0.001, discount factor α = 0.6, γ = 0.001, action search speed β = 0.9; the parameters of the RL-Q controller are: weight value μ 2 =0.001, discount factor α=0.6, γ=0.001, action search speed β=0.9.

[0099] (1) Reactive power regulation

[0100] Apply the algorithm provided by...

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Abstract

The invention discloses a reinforcement learning algorithm-based self-correction control method for a double-fed induction wind power generator. According to the method, an RL controller is added to a PI controller of a vector control system based on PI control to dynamically correct the output of the PI controller; the RL controller comprises an RL-P controller and an RL-Q controller; and the RL-P controller and the RL-Q controller are used for correcting active and reactive power control signals respectively. The Q learning algorithm is introduced to the method to be used as the reinforcement learning core algorithm; the reinforcement learning control algorithm is insensitive to a mathematical model and an operating state of a controlled object while the learning capability has relatively high adaptivity and robustness on parameter changes or external interference, so that output of the PI controller can be optimized rapidly and automatically online; and by virtue of the reinforcement learning algorithm-based self-correction control method, high dynamic performance is achieved, and the robustness and the adaptivity of the control system are obviously reinforced.

Description

technical field [0001] The invention relates to a self-calibration control method of a doubly-fed induction wind power generator, in particular to a self-calibration control method of a doubly-fed induction wind power generator based on a reinforcement learning (Reinforcement Learning, RL) algorithm. Background technique [0002] Variable-speed constant-frequency double-fed power generation is a power generation method commonly used in wind power generation at present, and its generator uses a double-fed induction generator (DFIG). When the unit works below the rated wind speed, by adjusting the rotor speed of the generator, the best blade tip speed ratio is maintained to achieve the maximum capture of wind energy. Its control system often adopts vector control based on stator field orientation to realize decoupling control of generator active and reactive power. [0003] Due to the strong randomness and time-varying nature of wind energy, and the system contains dynamic pa...

Claims

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Application Information

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Patent Type & Authority Applications(China)
IPC IPC(8): H02P21/14
CPCH02P21/14
Inventor 余涛程乐峰李靖王克英
Owner SOUTH CHINA UNIV OF TECH
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