Self-Contained Power Systems with a Kinetic Energy Storage

  • Konstantin L. KOVALEV
  • POLTAVETS Vladimir N. POLTAVETS
  • Irina P. KOLCHANOVA
DOI: https://doi.org/10.24160/0013-5380-2019-9-30-40
Keywords: electric power engineering, renewable energy sources, hybrid power installations, kinetic energy storage, flywheel, HTSC levitation system

Abstract

Dependence of renewable energy sources on the climatic conditions during a year is one of the main problems associated with their utilization, a circumstance that does not allow the amount of energy produced by them to be predicted with sufficient accuracy and entails significant fluctuations of their AC power output, voltage, and frequency. The presently available technologies do not make it possible to achieve stable operation of power systems fully based on the use of renewable energy sources. High-quality electric power cannot be produced without parallel connection of conventional sources and energy storage systems. The article presents a review of foreign developments of kinetic energy storages used at hybrid power plants, and describes Russia’s first energy storage equipped with a magnetic HTSC levitation system with the energy storage capacity more than 5 MJ.

Author Biographies

Konstantin L. KOVALEV

KOVALEV Konstantin L. (National Research University «Moscow Aviation Institute» — NRU «MAI», Moscow, Russia) – Professor, Head of the Department, Dr. Sci. (Eng.)

POLTAVETS Vladimir N. POLTAVETS

POLTAVETS Vladimir N. (NRU «MAI», Moscow, Russia) – Leading Scientist, Cand. Sci. (Eng.)

Irina P. KOLCHANOVA

KOLCHANOVA Irina P. (NRU «MAI», Moscow, Russia) – Senior Scientist

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Published
2019-09-01
Issue
No 9 (2019): №9 2019
Section
Article