The role of inertia for grid flexibility under high penetration of variable renewables-A review of challenges and solutions

Several studies show that grid-integrated renewable energy (RE) sources have the potential to replace conventional synchronous generators in the network. This means the grid will experience low conventional inertia that is currently provided by synchronous generators. Low, unpredictable and time-changing inertia in the power system, as a result of high penetration of non-synchronous RE sources, can cause rapid frequency oscillations. The rapid and unpredictable frequency oscillations are the major source of stability challenges in the power system. Therefore, this research presents a comprehensive literature survey on the role of inertia for grid flexibility under high penetration of non-synchronous RE sources to the power system. As inertia is becoming a timechanging quantity, inertia estimation techniques have been gaining popularity as solutions to stability challenges faced by the power system. Related to time-changing inertia, the following are discussed in this survey research. First, synthetic inertia provision in the network and the need for inertia estimation are intensively discussed. Second, the importance of prior knowledge of the system inertia, which will help operators to apply suitable control strategies to mitigate stability challenges, is also addressed. Third, the significance of co-existence, coordination and optimization of both conventional synchronous generator's inertia and synthetic inertia, as a key feature towards reliable and flexible grid in low inertia environment, are also emphasized. Finally, technical challenges, key issues, and further research needs are highlighted.

Automated summary

Integrating renewable energy sources into the grid has the potential to replace traditional synchronous generators, leading to challenges related to low, unpredictable, and time-changing inertia. The research emphasizes the importance of inertia estimation techniques and synthetic inertia provision in the network. It also discusses the significance of prior knowledge of system inertia and the coordination and optimization of conventional synchronous generator's inertia and synthetic inertia for grid reliability and flexibility.