Abstract
The two common mechanisms of load-shedding and renewable curtailment can prevent provisional overloading and excessive generation and the subsequent unacceptable voltage and frequency deviation in standalone microgrids (MGs), which makes MGs less resilient and reliable. However, instead of enabling load-shedding or renewable curtailment, such overloading or over-generation problems can be alleviated more efficiently and cost-effectively by provisionally interconnecting the neighboring MGs to exchange power amongst themselves. In such a scheme, the interconnected MGs can supply their local demand, as well as a portion of the demand of the adjacent MGs. In order to implement this strategy, a three-phase ac link can be used as the power exchange network, while each MG is coupled to the link through a back-to-back power electronics converter, in order to maintain the autonomy of each MG if they are eachoperated under different standards. This paper proposes a suitable decentralized power management strategy without a communication link between the MGs to achieve power-sharing amongst them and alleviate unacceptable voltage and frequency deviation along with the required control technique for the power electronic converters, which can be implemented at the primary level based on the measurement of the local parameters only. To this end, one of the converters should always regulate the dc link voltage while the other converter should operate in droop control mode when the MG is healthy and in constant PQ mode when overloaded or over-generating. Suitable status detection and mode transition algorithms and controllers were also developed and are proposed in this paper. The performance of the proposed power exchange and control mechanisms were evaluated and verified via PSIM®-based numerical simulation studies. The stability and sensitivity of the proposed power exchange topology are also analyzed against several critical design and operational parameters.
Highlights
A microgrid (MG) system is a small-scale electricity grid that consists of dispatchable and non-dispatchable distributed energy resources (DERs) and distributed loads
MGs usually operate under droop control in the autonomous mode, through which preferred power-sharing can be achieved amongst its DERs by properly regulating the voltage magnitude and frequency
The results show each MG’s frequency, the power exchanged at the output of the line-side converter (LSC) of each results show each MG’s frequency, the power exchanged at the output of the LSC of each
Summary
A microgrid (MG) system is a small-scale electricity grid that consists of dispatchable and non-dispatchable distributed energy resources (DERs) and distributed loads. MGs can operate in grid-connected or off-grid (autonomous) modes. MGs usually operate under droop control in the autonomous mode, through which preferred power-sharing can be achieved amongst its DERs by properly regulating the voltage magnitude and frequency. The local controllers of droop-controlled DERs will adjust the output power continuously to maintain the MG’s voltage magnitude and frequency within the acceptable range and ensure its stability [4,5]. The temporary deficiency in the power generation capability of an MG versus its demand is referred to as overloading. This can be addressed by load-shedding for the voltage frequency and magnitude’s return to acceptable limits. Both load-shedding and curtailing renewable sources are uneconomical and undesirable, which reduces the reliability and resilience of the system
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