Abstract
Renewable energy sources (RES) like wind and PV are dependent on weather conditions and geographic location and as results their stochastic behavior can significantly influence power systems performance. These effects will be more relevant in case of large-scale penetration of RES. Therefore, modern power plants based on RES should both deliver power as conventional generators and contribute to support the grid services by providing ancillary services and in this way applications of advanced technology are very important to reach this goal. Active power and frequency controls are known as essential ancillary services that should be provided by generation units in large power plants. Therefore, controlling this type of grid interactive power plants is critical issue to achieve large-scale integration of RES in distributed power systems. In consequence, it is necessary to take advantages of new technologies and advanced control concepts in order to configure more intelligent and flexible generation systems, which should be able to improve the performance and stability of grid. A brief review on conventional active power/frequency control issues and complete investigation on adapted scenarios of active power/frequency control considering liberalized markets, high penetration of RES and coexistence of AC and DC networks will be explained in this chapter.
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Rakhshani, E., Rodriguez, P. (2014). Active Power and Frequency Control Considering Large-Scale RES. In: Hossain, J., Mahmud, A. (eds) Large Scale Renewable Power Generation. Green Energy and Technology. Springer, Singapore. https://doi.org/10.1007/978-981-4585-30-9_9
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DOI: https://doi.org/10.1007/978-981-4585-30-9_9
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