Supercapacitor-based grid fault ride-through system

摘要

The supercapacitor-based grid fault ride-through system provides a dynamic model of a wind generation system including a Voltage Source Converter (VSC), which functions as a Static Compensator (STATCOM). The power control capability of the STATCOM is extended by incorporating energy stored in a supercapacitor. The system implements a vector control technique based on the decoupling of real and reactive power. Simulation results show that a fixed speed induction generator is capable of withstanding a significant grid fault when aided by the supercapacitor-based grid fault ride-through system. Moreover, the induction generator regains its pre-fault status immediately after the fault is cleared.

主权项

1. A supercapacitor-based grid fault ride-through system, comprising:
a voltage source converter (VSC) including a DC-link input electrical circuit for receiving input electrical power from a power source, a voltage pulse width modulation (PWM) modulation index control input, a phase control input, and an output electrical circuit adapted for connection to a power grid for providing output electrical power to the power grid; a voltage controller connected to the voltage PWM modulation index control input; a current controller connected to the phase control input, said voltage controller and said current controller each being a proportional-integral (PI) controller; means for detecting a fault from the power grid, the means for fault detecting being connected to the voltage and current controllers, wherein said means for detecting a fault from said power grid comprises means for sensing deviation of voltage magnitude at a local bus connected to the power grid and means for sensing deviation of voltage phase angle at the local bus connected to the power grid; a supercapacitor having an electrical connection to the DC-link input electrical circuit of the voltage source converter, said supercapacitor providing storage of electrical energy for real and reactive power exchange; a bidirectional DC-DC converter including a pair of switches connected between the electrical connection of the supercapacitor and the input electrical circuit of the voltage source converter, the DC-DC bidirectional converter, via the switch pair, selectively switching the electrical connection of the supercapacitor to the voltage source converter, wherein when a fault is detected by the means for detection, responsively, the voltage and current controllers regulate the voltage source converter during a time period of the fault using the electrical energy stored in the supercapacitor, thereby enabling the voltage source converter to independently provide compensating real power and reactive power to the power grid during the fault, wherein each said proportional-integral (PI) controller comprises: means for generating a summation of a VSC output quadrature reference current and an actual VSC output quadrature current, the VSC output quadrature reference current being based on a summation of a pre-fault reference voltage and a during fault actual voltage at the local bus; means for generating a summation of a VSC output direct reference current and an actual VSC output direct current at the local bus, the VSC output direct reference current being based on a summation of a pre-fault reference phase angle and a during fault actual phase angle at the local bus; means for generating a quadrature error signal exq and a direct error signal exd based on the quadrature VSC output current summations, the direct VSC output current summations, and an inductive reactance of the VSC; and means for generating voltage PWM modulation index and phase angle control signals based on the quadrature error signal exq, the direct error signal exd, and a voltage Vdc at the DC-link input electrical circuitry, the PWM modulation index and phase control signals being characterized by relations:m=exd2+exq2Vd⁢⁢c⁢⁢and⁢⁢Ψ=tan-1⁡(exqexd),where m is the voltage PWM modulation control signal and Ψ is the phase angle control signal; and
means for routing the m and Ψ control signals to the VSC, thereby controlling modulation index and phase angle defined by pulse width modulation of the VSC.