Voltage regulation in low-voltage (LV) distribution grids is essential to increase the penetration of photovoltaic (PV) rooftop units.Hence, PV inverters are commonly embedded with volt-var (VV) and volt-watt (VW) control functions to support the grid voltage regulation within the grid codes.Such an approach usually increases the LV grid hosting capacity (HC) by 1.
5 to 2 times at the cost of energy curtail.Thus, the use of decentralized battery energy storage systems (BESS) near to nodes sensible to overvoltage become appealing, as it stores energy without creating current circulation within the grid.However, there are still gaps in sizing of decentralized BESSs and in quantifying their improvement in terms of HC.
Thus, this solo jec 10 paper contributes with a comprehensive study that evaluates the HC of a generic LV grid comprised of PV units with embedded VV and VW control functions, and proposes a methodology to guide the sizing of small 006719f decentralized BESS used to increase the grid HC.Using OpenDSS software, the VV and VW control functions are evaluated and compared with a base scenario where PV units operate at a unity power factor.The active power curtailment is used to size decentralized BESS to absorb excess energy, avoiding PV active power derating.
Results show that BESS units, sized at about 5-10% of the PV power capacity, can reduce revenue impacts and increase HC by over 30% in LV grids.