Virtual impedance comprehensive control method for inductive power filtering system

What is claimed is: 1. A virtual impedance comprehensive control method for an inductive power filtering system, comprising: providing the inductive power filtering system comprising an industrial power distribution network, a novel inductively filtered rectifier transformer (IFRT), an industrial rectifier load, a filtering branch, and a current and voltage sensor, wherein the filtering branch comprises a passive filtering device and a voltage source inverter, the passive filtering device is connected with the voltage source inverter through the current and voltage sensor, the novel IFRT has a three-winding structure, and its grid winding adopts a star wiring, and is connected with a power grid through system impedance; two secondary windings of the novel IFRT adopt an inductive type or a self-coupling type according to whether there is an electrical connection between the two windings or not, and the passive filtering device consists of two banks of single-tuned filters with a series resonance characteristic; the voltage source inverter adopts a two-level topology, and AC port voltage of the voltage source inverter is required to meet the following control rule: V C = K · ∑ n = 2 ∞ ⁢ I Sn + K Rn · ∑ n = 5 , 7 ⁢ I fn where K is a harmonic damping control coefficient, K Rn is a zero impedance control coefficient, I Sn and I fn are harmonic current of grid side of the novel IFRT and the filtering branch respectively, and V C is the voltage of the AC port of the voltage source inverter; and regulating the zero impedance control coefficient K Rn to change a magnitude of a total impedance value of a filtering winding and the passive filtering device to meet a zero impedance condition for implementation of inductive filtering, that is: Z 3n +Z fn ≈0 where Z 3n is equivalent impedance of the filtering winding of the novel IFRT, and Z fn is equivalent impedance of the filtering branch; wherein voltage of the filtering branch is as follows: V fn = ( r fn + j ⁢ ⁢ ω n ⁢ L tn ︸ Z ftn + K Rn ) · I fn , Where ω n L tn =ω n L fn −(1/ω n C fn ), ω n is the nth harmonic angular frequency, L fn and C fn are reactance and capacitance values of the nth single-tuned filter, and r fn is internal resistance of a reactor and a transmission line; the K Rn is controlled to be −|Z fn |, and then the voltage of the filtering branch is 0. 2. The virtual impedance comprehensive control method for the inductive power filtering system according to claim 1 , wherein the virtual impedance comprehensive control method for the inductive power filtering system specifically comprises the following steps: Step 1: controlling harmonic damping of the inductive power filtering system to obtain a first output signals; Step 2: controlling zero impedance of the inductive power filtering system to obtain a second output signals; Step 3: controlling a DC voltage of the inductive power filtering system to obtain a third output signals; and Step 4: superposing the first output signals, the second output signals and the third output signals to obtain a control signal, and performing Pulse Width Modulation (PWM) on the control signal to provide a pulse signal for a main circuit. 3. The virtual impedance comprehensive control method for the inductive power filtering system according to claim 2 , wherein Step 1 specifically comprises the following steps: Step 11: sampling a voltage signal of phase A at grid side, and generating a synchronous phase angle to provide a phase reference for dq transformation by means of a phase-locked loop (PLL); Step 12: sampling and causing current signals of phases A, B and C at the grid side to undergo dq transformation for which the phase reference is provided by a fundamental voltage signal and pass through a low-pass filter to obtain two groups of DC signals, performing dq inverse transformation to convert them into current under an abc coordinate to obtain a fundamental wave, and performing subtraction with the sampled current signals of the three phases to obtain harmonic current signals; and Step 13: multiplying the harmonic current signals by the harmonic damping control coefficient to obtain the first output signals. 4. The integrated virtual impedance control method for the inductive power filtering system according to claim 2 , wherein Step 2 specifically comprises the following steps: Step 21: sampling and causing current signals of phases a, b and c of the filtering branch to undergo dq transformation for which a phase reference is provided by a fifth harmonic voltage signal and pass through a low-pass filter, then performing dq inverse transformation to obtain fifth harmonic current, and multiplying the fifth harmonic current by a fifth zero impedance control coefficient; Step 22: sampling and causing current signals of phases a, b and c of the filtering branch to undergo dq transformation for which a phase reference is provided by a