Frequency stability in microgrid: Control strategies and analysis of BESS aging effects

Gaetano Zizzo; Giorgio Graditi; Maria Valenti; Gabriella Ferruzzi; Roberto Ciavarella

Frequency stability in microgrid: Control strategies and analysis of BESS aging effects

Gaetano Zizzo, Giorgio Graditi, Maria Valenti, Gabriella Ferruzzi, Roberto Ciavarella

Ingegneria

Risultato della ricerca: Other

8 Citazioni (Scopus)

Abstract

In order to ensure a thorough analysis, all components placed in a microgrid would have to be considered to guarantee an effective energy management. To this aim, various algorithms are used both to preserve and restore power systems after significant disturbances. However, these models frequently do not evaluate components performance decline with the age and, consequently, they don't consider actual values during microgrid analysis, potentially affecting obtained results. In particular, evaluating energy storage systems aging and their effects has rarely been addressed in prior works. The present article proposes a model to maintain power system/microgrid stability after disturbances using a load shedding algorithm that also consider storage system aging effects. Furthermore, our scheme estimates when the microgrid system begins to suffer for the energy storage aging.

Lingua originale	English
Pagine	295-299
Numero di pagine	5
Stato di pubblicazione	Published - 2016

All Science Journal Classification (ASJC) codes

Automotive Engineering
Mechanical Engineering
Control and Optimization
Electrical and Electronic Engineering

Accesso al documento

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Cita questo

Zizzo, G., Graditi, G., Valenti, M., Ferruzzi, G., & Ciavarella, R. (2016). Frequency stability in microgrid: Control strategies and analysis of BESS aging effects. 295-299.

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AU - Zizzo, Gaetano

AU - Graditi, Giorgio

AU - Valenti, Maria

AU - Ferruzzi, Gabriella

AU - Ciavarella, Roberto

PY - 2016

Y1 - 2016

N2 - In order to ensure a thorough analysis, all components placed in a microgrid would have to be considered to guarantee an effective energy management. To this aim, various algorithms are used both to preserve and restore power systems after significant disturbances. However, these models frequently do not evaluate components performance decline with the age and, consequently, they don't consider actual values during microgrid analysis, potentially affecting obtained results. In particular, evaluating energy storage systems aging and their effects has rarely been addressed in prior works. The present article proposes a model to maintain power system/microgrid stability after disturbances using a load shedding algorithm that also consider storage system aging effects. Furthermore, our scheme estimates when the microgrid system begins to suffer for the energy storage aging.

AB - In order to ensure a thorough analysis, all components placed in a microgrid would have to be considered to guarantee an effective energy management. To this aim, various algorithms are used both to preserve and restore power systems after significant disturbances. However, these models frequently do not evaluate components performance decline with the age and, consequently, they don't consider actual values during microgrid analysis, potentially affecting obtained results. In particular, evaluating energy storage systems aging and their effects has rarely been addressed in prior works. The present article proposes a model to maintain power system/microgrid stability after disturbances using a load shedding algorithm that also consider storage system aging effects. Furthermore, our scheme estimates when the microgrid system begins to suffer for the energy storage aging.

KW - Automotive Engineering

KW - Control and Optimization

KW - Electrical and Electronic Engineering

KW - Mechanical Engineering

KW - energy storage

KW - frequency control

KW - load shedding

KW - microgrid

KW - storage aging

KW - Automotive Engineering

KW - Control and Optimization

KW - Electrical and Electronic Engineering

KW - Mechanical Engineering

KW - energy storage

KW - frequency control

KW - load shedding

KW - microgrid

KW - storage aging

UR - http://hdl.handle.net/10447/241624

UR - https://ieeexplore.ieee.org/document/7526033

M3 - Other

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