Modeling and Control of a Microgrid Using a Hybrid Energy Storage System with Supercapacitors

Abstract

Lead-acid batteries have traditionally been used for energy storage in microgrid applications. Implementing an Energy Management System (EMS)-controlled supercapacitor (SC) and lead-acid battery hybrid energy storage system (HESS) has been shown to reduce operational costs by extending battery lifetimes. The SCs can be controlled to provide the high-frequency, power-dense component of the load power, which reduces the daily cyclical stress and state-of-charge (SOC) depletion of the lead-acid batteries; however, the HESS must be appropriately sized based on cost constraints, available power sources, and load demand. The enabling theory and design of a SIMULINK model of a DC microgrid are discussed in this thesis. The results obtained from this model illustrate the energy exchange between microgrid components, demonstrate some of the potential benefits of implementing a HESS, and provide useful data for battery and SC sizing. The DC microgrid model is scalable and can use any user-defined combination of source and load profiles. In islanded mode, the lead-acid battery and SC banks need to be unrealistically large to provide adequate power to the load. In grid-connected mode, the HESS sizing requirements are significantly reduced, and the overall energy savings of the system are improved.

Document Details

Document Type

Technical Report

Publication Date

Jun 01, 2018

Accession Number

AD1060044

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