Another hot topic regarding recent

Another hot topic regarding recent PV inverters is the use of different multilevel converter topologies to en- able medium-voltage (MV) grid connection. Most commercial topologies shown in Figure 3 are in fact multilevel converters (e.g., three-level H-bridge, three-level NPC, three-level T-type, and their derivatives). However, all of these converters connect to LV grids since PV strings cannot surpass the 1,000-V limit due to the module insulation standard. Therefore, to be able to connect to MV grids, the multilevel converters must be able to support several individual strings at the dc side and connect them somehow in series through the converter power stages to the output. Several alternative topologies have been introduced to achieve a high number of levels and reach MV operation. An ad- vantage of using multilevel converters as PV inverters is related to the output waveform’s high quality, which reduces the grid connection filter requirements, leading to a compact design for low-power applications (usually domestic rooftops). In addition, the use of multilevel converters can lead to avoidance of the additional boost converter in the input or the step-up transformer in the output, eliminating the additional power conversion stages and improving the efficiency of the system. On the other hand, some multilevel converter topologies, such as the cascaded H-bridge converter or the modular multilevel converter, can take advantage of splitting the PV array system to achieve higher efficiency values using independent MPPT algorithms. This could be interesting for central inverters of PV medium- and high-power plants. Another research focus involves developing PV inverters with additional energy storage capability usually based on batteries. These hybrid systems present the advantages of improving the frequency and voltage regulation, storing the energy if it is not demanded by local loads, and supplying this energy when required, increasing the overall system operation (usually called peak load shaving). These systems are mainly focused for stand-alone systems, household applications, or weak grid-connected applications of large PV plants. The use of hybrid PV batteries can already be found as a commercial product for household applications (see, for instance, the Sunny Boy 3600/5000 Smart Energy by SMA). This trend emerges as an important field of development for the future. On the other hand, it is important to note that the high penetration of PV systems has led to the consideration of future regulations following the path already written by the wind energy sector. In this way, future regulations about LV ride-through and reactive power compensation could be also applied to medium and large PV systems. This issue will become particularly important for large PV plants normally using conventional two-level, three-phase central inverters. Future regulations may force the power con- version stage to upgrade and motivate the introduction of more advanced multilevel converters and include energy storage to meet grid codes and pro- vide the system operational flexibility.