Evaluating the advantages of compressed air energy storage, demand response program and dynamic rating technologies in the risk-constrained optimal scheduling of wind-based power system

This paper provides a risk-constrained stochastic day-ahead scheduling model for a power system integrated with smart technologies. Multiple uncertainties including wind speed, ambient temperature, sun irradiation and load demand are covered by the stochastic method. On the other hand, the downside risk constraint (DRC) is used to involve risks associated with uncertainties. Smart technologies including dynamic line/transformer rating (DLR and DTR), compressed air energy storage (CAES) unit and demand response program (DRP) are integrated into the power system to create a flexible system to decrease total cost, emissions, wind curtailment and load shedding as main aims of this work. AC power flow framework is used in this study to show the impact of smart technologies on the voltage profile of the test system. The benefits of the proposed model are surveyed through different case studies implemented on the IEEE 24-bus system. The results demonstrate that with smart technologies 100 % of wind power is absorbed which is in line with the goals of this work. Also, the voltage profile is smoother with smart technologies. Moreover, results show that the operator can properly handle the risk of uncertainties with the DRC approach.