Vertical reactive power flexibility through distributed energy resources for a reactive energy management

Abstract

The transition of the power grid with fewer reactive power sources demands new solutions to locally compensate reactive power in order to reduce transmission losses in the extra high voltage grid. The capability of high voltage clusters to meet these requirements is evaluated in this paper taking different approaches into account. The feasible contribution of distributed energy resources to provide reactive power is analyzed for two high voltage clusters, which are based on real network data. The load flow is carried out for every hour of a year. Two different reactive power characteristics are introduced and analyzed towards their possible reactive power flexibility. Current German guidelines limit the possible reactive power of the distributed energy resources, while they have a bigger potential as shown with the second characteristic. Furthermore, an economic comparison with mechanically switched capacitors is performed. A specific reactive power exchange boundary is chosen to achieve comparable situations. The costs calculation considers investment, operating and maintenance costs. Each network cluster has its own economic solution. In general, the costs of reactive power supply from distributed energy resources rises with the period of use. Nevertheless, it is shown that distributed energy resources could fulfill an economical competitive reactive power management.