Optimal Energy and Flexibility Dispatch of Grid-Connected Microgrids
Doktorsavhandling, 2022
Two types of test systems were used for the simulations studies: 1) distribution grids with grid-connected MGs and 2) building MGs (BMGs). The distribution test systems included the 12-kV electrical distribution grid of the Chalmers campus and a 12.6-kV 33-bus standard test system, while the BMGs were based on real residential buildings i.e., the HSB LL building and the Brf Viva buildings. Results of the Chalmers’ test case showed that the MGs’ economic optimization could reduce the annual cost for the DSO by up to 2%. Centralized coordination, where the MG resources were scheduled by the DSO, led to an even higher reduction, although it also led to sub-optimal solutions for the MGs. Decentralized coordination was applied on the 33-bus network with a bilevel optimization framework for energy and flexibility dispatch. Two types of FSs were integrated in the bilevel model i.e., the baseline (FS-B) and the capacity limitation (FS-C). The latter has found to be more promising, as it could offer economic incentives for both the DSO and the MGs. In the studies of the BMGs, the BESs were modeled considering both degradation and real-life operation characteristics derived from measurements conducted at the buildings. Results showed that the annual building energy and BES degradation cost could be reduced by up to 3% compared to when the impact of BES degradation was neglected in the energy scheduling. With the participation of the BMG in FS-C provision, the building’s operation cost could be further reduced depending on the flexibility price. A 24-h simulation of the BMG’s operation yielded an economic value of flexibility of at least 7% of its daily energy and peak power cost, while the DSO could benefit from the FS assuming that the dispatched flexibility could be used to reduce the subscription fee that guarantees a certain power level. For frequent flexibility provision i.e., multiple times within a year, the value of flexibility for the MG operator could be reduced due to the BES degradation.
To demonstrate the practical use of the proposed model, an energy management system was designed to integrate the model and employ it to optimize the energy schedule of the BMGs’ BESs and energy exchange with the main grid. The energy dispatch was performed in real-time based on the model’s decisions in real demonstration cases. The demonstration results showed the benefits of the model in that it helped reduce the energy cost of the BMG both in short term and in long term. The model can also be used by the MG operators to quantify the potential and assess the value of microgrid flexibility. Moreover, with the help of this model, the MG can be employed as a flexible resource and reduce the operation cost of the connected distribution grid.
flexibility
microgrids
Battery energy storage
optimization.
energy scheduling
energy management
distribution network
Författare
Kyriaki Antoniadou-Plytaria
Chalmers, Elektroteknik, Elkraftteknik
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Artikel i vetenskaplig tidskrift
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Proceedings of 2019 IEEE PES Innovative Smart Grid Technologies Europe, ISGT-Europe 2019,;(2019)
Paper i proceeding
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IEEE International Conference on Smart Energy Systems and Technologies (SEST),;(2019)
Paper i proceeding
Two types of test systems were used for the simulations studies: 1) distribution grids with grid-connected microgrids, including the electrical distribution grid of the Chalmers campus, and 2) building microgrids based on real residential buildings i.e., the HSB LL building and the Brf Viva buildings. The buildings were also used to demonstrate the practical use of the model, which was integrated in an energy management system designed to control in real-time the power of the buildings’ batteries according to the model’s decisions.
The thesis’ results showed that the model can reduce the microgrid’s operation costs, which can offer financial benefits to the electricity customers if the model is used by future microgrid and building operators. It was also shown that the model can accurately quantify and reliably dispatch the microgrid’s flexibility. Therefore, distribution grid operators can also use the model to take advantage of the microgrid’s flexibilities and reduce the operation costs of their distribution grids.
Ämneskategorier
Elektroteknik och elektronik
ISBN
978-91-7905-700-8
Doktorsavhandlingar vid Chalmers tekniska högskola. Ny serie: 5166
Utgivare
Chalmers