Publication detail

Hybrid Photovoltaic Systems with Accumulation—Support for Electric Vehicle Charging

MASTNÝ, P. MORÁVEK, J. VOJTEK, M. DRÁPELA, J.

Original Title

Hybrid Photovoltaic Systems with Accumulation—Support for Electric Vehicle Charging

Type

journal article in Web of Science

Language

English

Original Abstract

The paper presents the concept of a hybrid power system with additional energy storage to support electric vehicles (EVs) charging stations. The aim is to verify the possibilities of mutual cooperation of individual elements of the system from the point of view of energy balances and to show possibilities of utilization of accumulation for these purposes using mathematical modeling. The description of the technical solution of the concept is described by a mathematical model in the Matlab Simulink programming environment. Individual elements of the assembled model are described in detail, together with the algorithm of the control logic of charging the supporting storage system. The resulting model was validated via an actual small-scale hybrid system (HS). Within the outputs of the mathematical model, two simulation scenarios are presented, with the aid of which the benefits of the concept presented were verified.

Keywords

electric vehicle; fast charging stations; hybrid energy system; accumulation; Matlab

Authors

MASTNÝ, P.; MORÁVEK, J.; VOJTEK, M.; DRÁPELA, J.

Released

22. 6. 2017

Publisher

MDPI AG

Location

Switzerland

ISBN

1996-1073

Periodical

ENERGIES

Year of study

10

Number

834

State

Swiss Confederation

Pages from

1

Pages to

24

Pages count

24

URL

Full text in the Digital Library

BibTex

@article{BUT137490,
  author="Petr {Mastný} and Jan {Morávek} and Martin {Vojtek} and Jiří {Drápela}",
  title="Hybrid Photovoltaic Systems with Accumulation—Support for Electric Vehicle Charging",
  journal="ENERGIES",
  year="2017",
  volume="10",
  number="834",
  pages="1--24",
  doi="10.3390/en10070834",
  issn="1996-1073",
  url="http://www.mdpi.com/1996-1073/10/7/834"
}