КВАЗИДИНАМИЧЕСКОЕ МОДЕЛИРОВАНИЕ СТАРЕНИЯ ЕМКОСТИ Li-ION НАКОПИТЕЛЕЙ

P.Yu. Gubin; K.V. Ryndina; A.A. Nesterov

doi:10.14529/power200107

Authors

P.Yu. Gubin Ural Federal University, Ekaterinburg, Russian Federation
K.V. Ryndina Ural Federal University, Ekaterinburg, Russian Federation
A.A. Nesterov RTSoft-SG, Ekaterinburg, Russian Federation

DOI:

https://doi.org/10.14529/power200107

Keywords:

energy storage system, degradation, aging, simulation, Li-Ion energy storage system, state of charge, depth of discharge, storage system operating cycle

Abstract

Li-Ion energy storage systems are currently becoming more and more interesting in terms of their application in power systems engineering. There appeared a new range of tasks that can be solved using such devices appears, i.e. the electrical energy consumption losses reduction, peak loads reduction to meet the network transmission capacity requirements, application in renewable generation systems. However, the neglection of relatively fast and irreversible aging leads to excessively optimistic economic and technical assessments of their implementation, which necessitates to make allowance for their degradation.

The article provides the quasi-dynamic Li-Ion storage systems degradation simulation methodology which allows, unlike others, evaluating the aging degree for systems with uneven charge and discharge graph at the stage of preliminary analysis. The results of the methodology testing are also given.

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