评估LCL滤波器光伏逆变器中谐振电流引起的可靠性退化

With the increasing deployment of photovoltaic (PV) systems, LCL -type grid-connected inverters have become prevalent due to their superior harmonic attenuation. However, conventional reliability assessments often overlook the impact of resonant currents arising from control-loop instability or parameter drift, which can significantly accelerate the degradation of key components. This paper presents a comprehensive reliability evaluation framework for LCL -type PV inverters that better reflects realistic operating conditions. An electrothermal model is developed that accounts for temperature-dependent power losses, IGBT thermal coupling, and capacitor degradation. Monte Carlo simulation and Weibull distribution are employed to derive converter lifetime under annual mission profiles. Experimental validation confirms that resonant currents introduce substantial electrical stress, and damping failure can reduce the B_10 lifetime by up to 55.5%. Furthermore, the study establishes quantitative relationships between resonant frequency, total harmonic distortion (THD), and converter reliability, revealing that higher resonant frequencies improve capacitor lifetime. Furthermore, the integration of reliability considerations offers valuable insights into the design optimization of LCL -type PV converters.