Abstract
To reduce the influence of wind power output uncertainty on power system stability, demand response (DRPs) and energy storage systems (ESSs) are introduced while solving scheduling optimization problems. To simulate wind power scenarios, this paper uses Latin Hypercube Sampling (LHS) to generate the initial scenario set and constructs a scenario reduction strategy based on Kantorovich distance. Since DRPs and ESSs can influence the distribution of demand load, this paper constructs a joint scheduling optimization model for wind power, ESSs and DRPs under the objective of minimizing total coal cost, and constraints of power demand and supply balance, users’ demand elasticity, thermal units’ startup-shutdown, thermal units’ output power climbing and wind power backup service. To analyze the influences of ESSs and DRPs on system wind power consumption capacity, example simulation is made in a 10 thermal units system with a 1000 MW wind farm and 400 MW energy storage systems under four simulation scenarios. The simulation results show that the introduction of DRPs and ESSs could promote system wind power consumption capacity with significantly economic and environment benefits, which include less coal consumption and less pollutant emission; and the optimization effect reaches the optimum when DRPs and ESSs are both introduced.
Highlights
China’s wind power industry has been in rapid development since 2005
Energy storage systems are both power sources and loads; in valley load period, energy storage systems (ESSs) could charge as a load, and in peak periods ESSs could discharge as a power source
Four energy storage systems are added into the scheduling system and the electricity price in peak load period and valley load period are increased and decreased by 25% respectively
Summary
China’s wind power industry has been in rapid development since 2005. By the end of 2013, the total installed wind power capacity reached 94.41 GW, ranking first in the world. Energy storage systems (ESSs) can achieve peak shifting, decrease the influence of wind power uncertainty and improve wind power utilization rate. Considering time-of-use price (TOU price) and ESSs both have the capacity to influence demand load distribution, this paper tries to optimize the power system scheduling problem from power generation side and load demand side, which means optimizing units’ combined output structure and demand load distribution at the same time. DRSs and ESSs to the wind power consumption optimization model, and optimizes real-time outputs of thermal units and wind turbines, real-time charging-discharging behavior of energy storage systems to achieve the system’s maximum energy-saving benefits.
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