Design Considerations
Solar Micro-Inverter | Solar Panel System Design
Schematic Block Diagram for Solar Micro-Inverters
Photovoltaic (PV) installations tied to the grid are usually built with arrays of modules connected in series to string inverters. A rapidly growing architecture, the microinverter, converts power from one PV module to the AC grid and is usually designed for a max output power in the range of 180-300W. Microinverter’s have advantages in terms of ease of installation, localized maximum power point tracking (MPPT) and redundancy that provides robustness to failure.
At the heart of the inverter is an MPPT algorithm which can be implemented through a microcontroller or an MPPT controller. The controller executes the very precise algorithms required to keep the panel at the maximum power extraction point while adjusting the dc-dc and dc-ac conversion to produce the output ac voltage for the grid. In addition, the controller is responsible for being locked in frequency to the grid. The controller is also programmed to perform the control loops necessary for all the power management functions. The PV maximum output power is dependent on the operating conditions and varies from moment to moment due to temperature, shading, soilage, cloud cover, and time of day so tracking and adjusting for this maximum power point is a continuous process. The controller contains advanced peripherals like high precision PWM outputs and ADCs for implementing control loops. The ADC measures variables, such as the PV output voltage and current, and then adjusts the DC/DC converter and DC/AC inverter by changing the PWM duty cycle depending on the load. Complex schemes exist to track the true maximum even in partially-shaded PV modules.
Real time processors designed to read the ADC and adjust the PWM within a single clock cycle are desirable. Communications on a simple system can be handled by a single processor, more elaborate systems with complex reporting on monitoring may require a secondary processor. Current sensing is done through through flux-gate sensors or shunt resistors. For safety reasons, isolation between the processor and the current and voltage may be required, as well as on the communications bus to the outside world. Delta-Sigma Modulators which include integrated isolation are desirable. MOSFET/IGBT drivers which can handle the higher voltages and include integrated sensing are also desired. The bias supply uses DC-DC converters to provide power to the electronics on the inverter. Sometimes, communications capability is included so users can monitor the converter, report on power and operating conditions and provide firmware updates. Typically Power Line Communication (PLC) to reduce wiring or wireless (Bluetooth, ZigBee/IEEE802.15.4, 6loWPAN) networking options are used.
The Safety MCUs offer an ARM Cortex-R4F based solution and are certified suitable for use in systems that need to achieve IEC61508 SIL-3 safety levels. These MCUs also offer integrated floating point, 12 bit ADCs, motor-control-specific PWMs and encoder inputs via its flexible HET Timer co-processor. Hercules Safety MCUs can also be used to implement scalar and vector-control techniques and support a range of performance requirements.
For more information on this solution, please go to TI website http://www.ti.com/solution/solar-micro-inverter-diagram
Van-Tung Phan, Ph.D 