Wear-Out Failure Analysis of an Impedance-Source PV Microinverter Based on System-Level Electrothermal Modeling

In this paper, the wear-out performance of an impedance-source photovoltaic (PV) microinverter (MI) is evaluated and improved based on two different mission profiles. The operating principle and hardware implementation of the MI are first described. With the experimental measurements on a 300-W MI prototype and system-level finite-element method simulations, the electrothermal models are built for the most reliability-critical components, i.e., power semiconductor devices and capacitors. The dependence of the power loss on the junction/hotspot temperature is considered, the enclosure temperature is taken into account, and the thermal cross-coupling effect between components is modeled. Then, the long-term junction/hotspot temperature profiles are derived and further translated into components’ annual damages with the lifetime and damage accumulation models. After that, the Monte Carlo simulation and Weibull analysis are conducted to obtain the system wear-out failure probability over time. It reveals that both the mission profile and the thermal cross-coupling effect have a significant impact on the prediction of system wear-out failure, and the dc-link electrolytic capacitor is the bottleneck of long-term reliability. Finally, the multimode control with a variable dc-link voltage is proposed, and a more reliable dc-link electrolytic capacitor is employed, which results in a remarkable reliability improvement for the studied PV MI.

[1]  M. Liserre,et al.  Toward Reliable Power Electronics: Challenges, Design Tools, and Opportunities , 2013, IEEE Industrial Electronics Magazine.

[2]  Josef Lutz,et al.  Model for Power Cycling lifetime of IGBT Modules - various factors influencing lifetime , 2008 .

[3]  M. Matsuichi,et al.  Fatigue of metals subjected to varying stress , 1968 .

[4]  Antonio Testa,et al.  Reliability Assessment of Power MOSFETs Working in Avalanche Mode Based on a Thermal Strain Direct Measurement Approach , 2016, IEEE Transactions on Industry Applications.

[5]  Jan Abraham Ferreira,et al.  Improved analytical modeling of conductive losses in magnetic components , 1994 .

[6]  H. Oldenkamp,et al.  The Return of the AC-Module Inverter , 2009 .

[7]  Roman Kosenko,et al.  Wide Input Voltage Range Photovoltaic Microconverter With Reconfigurable Buck–Boost Switching Stage , 2017, IEEE Transactions on Industrial Electronics.

[8]  Annette Muetze,et al.  A Power Supply Achieving Titanium Level Efficiency for a Wide Range of Input Voltages , 2017, IEEE Transactions on Power Electronics.

[9]  E. W. C. Wilkins,et al.  Cumulative damage in fatigue , 1956 .

[10]  Huai Wang,et al.  Prediction of bond wire fatigue of IGBTs in a PV inverter under long-term operation , 2015, 2015 IEEE Applied Power Electronics Conference and Exposition (APEC).

[11]  Khai D. T. Ngo,et al.  A PWM method for reduction of switching loss in a full-bridge inverter , 1995 .

[12]  Andrii Chub,et al.  High-Performance Quasi-Z-Source Series Resonant DC–DC Converter for Photovoltaic Module-Level Power Electronics Applications , 2017, IEEE Transactions on Power Electronics.

[13]  Shaohua Lin,et al.  A Foster Network Thermal Model for HEV/EV Battery Modeling , 2011, IEEE Transactions on Industry Applications.

[14]  F. Blaabjerg,et al.  A review of single-phase grid-connected inverters for photovoltaic modules , 2005, IEEE Transactions on Industry Applications.

[15]  Huai Wang,et al.  Reliability oriented design of a grid-connected photovoltaic microinverter , 2017, 2017 IEEE 3rd International Future Energy Electronics Conference and ECCE Asia (IFEEC 2017 - ECCE Asia).

[16]  S. Harb,et al.  Reliability of Candidate Photovoltaic Module-Integrated-Inverter (PV-MII) Topologies—A Usage Model Approach , 2013, IEEE Transactions on Power Electronics.

[17]  Andrii Chub,et al.  Asymmetrical PWM control of galvanically isolated impedance-source series resonant DC-DC converters , 2016, 2016 10th International Conference on Compatibility, Power Electronics and Power Engineering (CPE-POWERENG).

[18]  J. Kolar,et al.  Comparative Life Cycle Cost Analysis of Si and SiC PV Converter Systems Based on Advanced η-ρ-σ Multiobjective Optimization Techniques , 2017 .

[19]  Raja Ayyanar,et al.  Accelerated Testing of Module-Level Power Electronics for Long-Term Reliability , 2017 .

[20]  Raja Ayyanar,et al.  Accelerated Testing of Module-Level Power Electronics for Long-Term Reliability , 2017, IEEE Journal of Photovoltaics.

[21]  P. L. Dowell,et al.  Effects of eddy currents in transformer windings , 1966 .

[22]  Garmanage,et al.  Metallized Film Capacitor Lifetime Evaluation and Failure Mode Analysis , 2015 .

[23]  Frede Blaabjerg,et al.  Reliability of Capacitors for DC-Link Applications in Power Electronic Converters—An Overview , 2014, IEEE Transactions on Industry Applications.

[24]  Leopoldo G. Franquelo,et al.  Grid-Connected Photovoltaic Systems: An Overview of Recent Research and Emerging PV Converter Technology , 2015, IEEE Industrial Electronics Magazine.

[25]  Huai Wang,et al.  Mission Profile Based System-Level Reliability Analysis of DC/DC Converters for a Backup Power Application , 2018, IEEE Transactions on Power Electronics.

[26]  Yvonne Feierabend,et al.  Fundamentals Of Thermal Fluid Sciences , 2016 .

[27]  Paul Williams,et al.  A status review of photovoltaic power conversion equipment reliability, safety, and quality assurance protocols , 2018 .

[28]  Hui Li,et al.  Exploring the LCL Characteristics in GaN-Based Single-L Quasi-Z-Source Grid-Tied Inverters , 2017, IEEE Transactions on Industrial Electronics.

[29]  Sam G. Parler,et al.  Deriving Life Multipliers for Electrolytic Capacitors , 2004 .

[30]  Fang Z. Peng,et al.  Z-source resonant DC-DC converter for wide input voltage and load variation , 2010, The 2010 International Power Electronics Conference - ECCE ASIA -.

[31]  F. Blaabjerg,et al.  Reliability-oriented design and analysis of input capacitors in single-phase transformer-less photovoltaic inverters , 2013, 2013 Twenty-Eighth Annual IEEE Applied Power Electronics Conference and Exposition (APEC).

[32]  Roman Kosenko,et al.  Shade-tolerant photovoltaic microinverter with time adaptive seamless P-V curve sweep MPPT , 2017, 2017 19th European Conference on Power Electronics and Applications (EPE'17 ECCE Europe).

[33]  Johann W. Kolar,et al.  Comparative Life Cycle Cost Analysis of Si and SiC PV Converter Systems Based on Advanced $\eta$- $\rho$-$\sigma$ Multiobjective Optimization Techniques , 2017, IEEE Transactions on Power Electronics.

[34]  Hua Li,et al.  Lifetime investigation and prediction of metallized polypropylene film capacitors , 2013, Microelectron. Reliab..

[35]  Kaveh Azar Thermal Measurements in Electronics Cooling , 1997 .

[36]  Charles R. Sullivan,et al.  Accurate prediction of ferrite core loss with nonsinusoidal waveforms using only Steinmetz parameters , 2002, 2002 IEEE Workshop on Computers in Power Electronics, 2002. Proceedings..

[37]  A. Testa,et al.  A Reliability Model for Power MOSFETs Working in Avalanche Mode Based on an Experimental Temperature Distribution Analysis , 2012, IEEE Transactions on Power Electronics.

[38]  Jürgen Biela,et al.  PV-Module-Integrated AC Inverters (AC Modules) With Subpanel MPP Tracking , 2017, IEEE Transactions on Power Electronics.

[39]  David T. Billings,et al.  Using Linear Superposition to Solve Multiple Heat Source Transient Thermal Problems , 2007 .

[40]  Yantao Song,et al.  Survey on Reliability of Power Electronic Systems , 2013, IEEE Transactions on Power Electronics.

[41]  A. Albertsen,et al.  Electrolytic Capacitor Lifetime Estimation , 2010 .

[42]  Frede Blaabjerg,et al.  Transitioning to Physics-of-Failure as a Reliability Driver in Power Electronics , 2014, IEEE Journal of Emerging and Selected Topics in Power Electronics.

[43]  Christopher Bailey,et al.  Mission Profile-Based Reliability Design and Real-Time Life Consumption Estimation in Power Electronics , 2015, IEEE Transactions on Power Electronics.