Optimal offering and operation strategy for hybrid power plants in hour-ahead mFRR energy activation markets with guaranteed service provision

Optimal offering and operation strategy for hybrid power plants in hour-ahead mFRR energy activation markets with guaranteed service provision

Utility-scale renewable hybrid power plants (HPPs) have emerged as promising electricity generation resources by combining multiple renewable generation technologies and storage. However, due to overplanting and co-location, storage size is usually smaller than that of renewable resources, which imp...

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Bibliographic Details
Main Authors: Rujie Zhu, Kaushik Das, Oskar Lindberg, Poul E. Sørensen, Anca D. Hansen
Format: Article
Language:English
Published: Elsevier 2025-08-01
Series:International Journal of Electrical Power & Energy Systems
Subjects:
Hybrid wind–battery plants
mFRR energy activation market
Decision-dependent uncertainty
Robust optimization
Energy management system
Online Access:http://www.sciencedirect.com/science/article/pii/S0142061525003436
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Summary:Utility-scale renewable hybrid power plants (HPPs) have emerged as promising electricity generation resources by combining multiple renewable generation technologies and storage. However, due to overplanting and co-location, storage size is usually smaller than that of renewable resources, which imposes challenges for HPP in providing reliable balancing services. This paper presents a novel model for optimizing the offering and operation of HPPs in hour-ahead manual frequency restoration reserve (mFRR) energy activation markets, with a focus on guaranteed service provision. The model takes into account uncertainties from wind power generation as decision-independent uncertainties, and considers the uncertainties related to the activation of mFRR to be influenced by the offering decisions, leading to decision-dependent uncertainties. The proposed model utilizes a robust two-level optimization approach, where the first level focuses on hour-ahead offering and operation, and the second level handles generation re-scheduling. Then, to ensure the computational efficiency with 15 min resolution, a modified column and constraint generation algorithm is proposed to solve the model. A comparative analysis reveals that the HPP with the proposed model can deliver upward and downward mFRR in 94% and 99% of the activated time, respectively. It meets transmission system operators’ required 90% reliability.
ISSN:0142-0615

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