一种适用于异常电网条件下并网逆变器的先进频率自适应锁相环

The necessity to expand the use of distributed renewable energy sources (DERS) with grid-connected inverters has emphasized the critical role of phase-locked loop (PLL) controllers in swiftly and accurately acquiring grid voltage phase angles, particularly under abnormal grid conditions. Frequency adaptive PLL has gained popularity due to its low computational burden, fast phase angle detection, and excellent harmonic rejection at nominal grid frequency. Unfortunately, due to spectral leakage at abnormal frequencies, conventional frequency adaptive PLLs bears inaccuracies in both magnitude and phase angle estimation. To resolve this situation, this study proposes an advanced frequency-adaptive PLL (AFA-PLL), which can work under abnormal grid frequencies or harmonics and avoid spectral leakage by implementing a variable window length phase detector. To achieve frequency adaptivity, the AFA-PLL innovatively employs a Fourier transformation-based sliding-mode controller (FTSMC). FTSMC utilizes a recursive interpretation of Fourier transform method by filtering the double frequency oscillations of the abnormal grid. Therefore, making the AFA-PLL highly capable of coping with abnormalities rapidly and effectively. Through extensive simulations and experiments under various abnormal grid conditions, the superior performance of the AFA-PLL is validated, which shows a 56 ms transient response, ±0.03 Hz oscillations and 3.23%. harmonics. Moreover, comprehensive comparison studies with recently proposed PLLs are conducted to further verify its effectiveness.