National Conference on Recent Trends in Power Engineering Indian Institute of Technology Madras, Chennai 600 036, Indiaa 29-30 December 2015 REVIEW OF MICRO INVERTER CIRCUIT TOPOLOGY AND INFLUENCE OF TEMPERATURE P.Elanchezhian*, V.Kumar Chinnaiyan**, R.Sudhir Kumar* * Central Power Research Institute, Bangalore, Karnataka, India 560080; elanchezhian_srf@cpri.in **Professor & HOD, EEE Department, KPR Institute of Engineering and Technology, Coimbatore. Micro inverter The interleaved flyback converter reduces the ripple current RMS through the input bulk electrolytic capacitor, which increases the life of the capacitor. Output current ripple also reduces by interleaving action resulting in low output current THD. The input and output current waveform of the interleaved flyback converter at 50% duty cycle operation of the flyback MOSFET is show Introduction The Photovoltaic (PV) systems have been realized using different architectures, starting with the string and centralized PV system to the modular PV system. Presently, decentralized inverters are being developed at the PV panel power level (known as AC – PV Modules). Such new PV systems are becoming more attractive and many expect this will be the trend of the future. The AC-Module PV system consists of an inverter attached to one PV panel. Micro inverters temperature is strongly correlated with ambient temperature and PV module temperature, and moderately correlated with irradiance and AC power. Fig. 4. Flyback and SCR bridge I/O waveform Methods 1. Micro inverter vs Central inverter Fig. 2. Block Diagram of Micro inverter Figure illustrates measurement of the grid voltage required for Phase-Locked Loop (PLL), output current control, and system islanding. The inverter output voltage measurement is required for synchronization inverter output to grid voltage and system islanding. The grid current is measured to make sure the inverter supplies the sinusoidal current in phase with the grid. PV voltage and flyback MOSFET current is measured for MPP detection. In addition, two MOSFET currents are measured for load balancing of both converters Fig. 5. Failure count of components in existing system 3. Simulation and Results Fig. 1. Typical micro inverter solar PV system Moving from centralized inverters to distributed inverters optimizes the energy harvest. Incorporating converters into the solar panel modules reduces installation costs. Improves system reliability from 5 to 20 years by reducing converter temperatures and removing fans. Replacing hard-switching techniques with soft switching improves efficiency and reduces heat dissipation. Standardized designs (hardware and software) improve reliability and reduce costs – from cottage industry to mass production. Eliminates electrolytic capacitors (due to high failure rate) – designs require higher voltages to reduce current, which allows use of lower capacitance non-electrolytic capacitors. Micro inverters tend to be lower powered (only a few hundred watts), which tends to lower internal temperatures and improve reliability Fig. 6. Matlab Simulation and Waveforms 4. Conclusions The main conclusions follow It is also embedded with MPPT which is designed for harvesting maximum solar power from the PV module. Output of individual model can be measured and overall output is increased both healthy and partial shading conditions. Individual panel performance can be measured. The PV module back sheet temperature is generally higher for lower power producing PV module brands. However, if the temperature of PV modules is similar, AC power output effects on the micro inverter temperature become important. Even. One may expect thermal behavior to be different on a roof mounted system than on a dual-axis tracker, since the gap between roof surface and PV module back sheet is about 10 inches and micro inverters are installed halfway in the gap. Fig. 3. Overall circuit diagram of micro inverter