A transactive energy management system for future community needs
Transactive energy (TE) is emerging as one of the most innovative approaches for the transformation of existing electricity grids towards the future smart grid as the penetration level of distributed generation (DG) is increasing in power systems. TE based local energy trading (LET) is one of the...
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Format: | Thesis-Doctor of Philosophy |
Language: | English |
Published: |
Nanyang Technological University
2020
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Online Access: | https://hdl.handle.net/10356/143463 |
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Institution: | Nanyang Technological University |
Language: | English |
Summary: | Transactive energy (TE) is emerging as one of the most innovative approaches
for the transformation of existing electricity grids towards the future smart grid
as the penetration level of distributed generation (DG) is increasing in power
systems. TE based local energy trading (LET) is one of the novel concepts in
the area of distribution networks. Peer-to-peer (P2P) energy trading is a kind
of LET, and it is one of the promising approaches for implementing decentralized
electricity market paradigms. A proper business model is required to manage LET.
The pricing mechanism is crucial because the agreed energy price determines the
benefits of LET. Since the physical network or grid is used for energy transfer,
power losses are inevitable, and grid-related costs always occur during energy
transactions. These grid-related aspects should be considered while designing a
business model for LET. A proper market clearing mechanism is necessary to
facilitate energy transactions among different parties. Designing a proper market
clearing mechanism with a specific objective considering the privacy of agents and
different aspects of physical networks is a challenging task.This thesis presents the study of different types of TE based energy trading and
management schemes for future smart grids. The focus of the thesis is to develop
market clearing algorithms for TE based LET and P2P energy trading. The contributions
in this thesis are broadly divided into three parts. The first part proposes
a novel game-theoretic approach for P2P energy trading among the prosumers in a
community microgrid. The objective of trading is to maximize individual welfare.The proposed approach models the price competition among the sellers as a noncooperative
game. The evolutionary game theory is used to model the dynamics of
the buyers for selecting sellers. The proposed approach is applied to a small community
microgrid with photovoltaic (PV) and energy storage systems. Simulation
results show that P2P energy trading provides significant financial and technical
benefits to the community, and it is emerging as an alternative to cost-intensive
energy storage systems.
The second part proposes a decentralized algorithm for LET in microgrids with
an integrated pricing mechanism considering welfare maximization and network
voltage management through local information exchange among neighbors. The
proposed algorithm ensures that the energy transactions do not violate voltage
constraints in a physical network, and agents’ privacy is preserved. A two-stage
approach is proposed to achieve fast convergence and increase the practicability
of the algorithm. The efficacy of the proposed approach is demonstrated using
illustrative case studies.
The final part presents a decentralized market-clearing mechanism for the P2P
energy trading considering the privacy of the agents, power losses as well as the
utilization fees for using the third party owned network. Grid-related costs in the
P2P energy trading are considered by calculating network utilization fees using
an electrical distance approach. The effectiveness of the proposed decentralized
approach for market clearing in the P2P energy trading is demonstrated using
illustrative scenarios. |
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