Abstract
Microgrids feature a high penetration of inverter-interfaced distributed energy resources (DERs). The low inertia characteristic and fast dynamics of DERs pose challenges to conventional decoupled static economic operation and dynamic control design within microgrids. Hence, this paper proposed virtual inertia scheduling (VIS) for microgrids, aiming to ensure both economy and security. First, a unified framework for device-level control and grid-level operation is introduced, with VIS serving as a key application to address low inertia issues. VIS actively harnesses the controllability and flexibility of DERs to effectively manage microgrid inertia. It updates the conventional economic operation framework by incorporating the virtual inertia/damping cost, transient performance constraints, and stability constraints. Control parameters for DERs are formulated as additional decision variables. Then, VIS is specified in microgrids, followed by explication and linearization of dynamic constraints. An efficient workflow is developed to facilitate the integration of data-driven methods into microgrid-VIS, involving data generation, cleaning, and labeling to alleviate computational burdens. Time-domain simulations are further integrated for correction, validation, and performance guarantee. Finally, VIS is verified in an islanded microgrid modified from the IEEE 123-bus system. Results demonstrate that VIS effectively addresses the low inertia challenges in DER-penetrated microgrids, balancing economic considerations and dynamic performance.
Recommended Citation
B. She et al., "Virtual Inertia Scheduling (VIS) for Microgrids with Static and Dynamic Security Constraints," IEEE Transactions on Sustainable Energy, Institute of Electrical and Electronics Engineers, Jan 2024.
The definitive version is available at https://doi.org/10.1109/TSTE.2024.3481239
Department(s)
Electrical and Computer Engineering
Publication Status
Early Access
Keywords and Phrases
distributed energy resource (DER); Economic dispatch; microgrid; stability constraints; virtual inertia scheduling (VIS)
International Standard Serial Number (ISSN)
1949-3037; 1949-3029
Document Type
Article - Journal
Document Version
Citation
File Type
text
Language(s)
English
Rights
© 2024 Institute of Electrical and Electronics Engineers, All rights reserved.
Publication Date
01 Jan 2024
