Optimal Subhourly Electricity Resource Dispatch Under Multiple Price Signals With High Renewable Generation Availability
For power system operators, it provides a method to reduce operating costs in high-renewable grids by jointly optimizing energy and ramping costs.
This paper proposes a system-wide optimal resource dispatch strategy that simultaneously considers energy, power, and ramping price signals, achieving over 25% cost savings in a 50% renewables scenario for the North America Western Interconnection in 2024.
This paper proposes a system-wide optimal resource dispatch strategy that enables a shift from a primarily energy cost-based approach, to a strategy using simultaneous price signals for energy, power and ramping behavior. A formal method to compute the optimal sub-hourly power trajectory is derived for a system when the price of energy and ramping are both significant. Optimal control functions are obtained in both time and frequency domains, and a discrete-time solution suitable for periodic feedback control systems is presented. The method is applied to North America Western Interconnection for the planning year 2024, and it is shown that an optimal dispatch strategy that simultaneously considers both the cost of energy and the cost of ramping leads to significant cost savings in systems with high levels of renewable generation: the savings exceed 25% of the total system operating cost for a 50% renewables scenario.