2009 IEEE ENERGY CONVERSION CONGRESS AND EXPOSITION, VOLS 1-6

Gerard Hurley

2009 IEEE ENERGY CONVERSION CONGRESS AND EXPOSITION, VOLS 1-6

Gerard Hurley

Electrical & Electronic Engineering

Research output: Chapter in Book or Conference Publication/Proceeding › Conference Publication › peer-review

Abstract

Autonomous photovoltaic systems require an energy buffer to match the generation with the time distribution of demand, as photovoltaic is time and weather dependent. The Valve Regulated Lead Acid (VRLA) battery is commonly used for photovoltaic storage because of its low cost, low maintenance, and wide availability. A Hybrid Energy Storage System (HESS) integrates the VRLA battery and ultracapacitor, drawing on their respective advantages at appropriate times. By combining an ultracapacitor with a VRLA battery, the power density of the overall system is increased. The ultracapacitor operates under high power conditions reducing the strain of large current draw from the VRLA battery. This paper outlines a methodology to optimize the combination of VRLA batteries and ultracapacitors in the photovoltaic system taking the load demand, solar irradiation, and ambient temperature into account. A photovoltaic system is simulated in Matlab Simulink to analyze the results of the optimization.

Original language	English (Ireland)
Title of host publication	Optimization of Autonomous Hybrid Energy Storage System for Photovoltaic Applications
Number of pages	8
Publication status	Published - 1 Sep 2009

Authors (Note for portal: view the doc link for the full list of authors)

Authors
Glavin, ME,Chan, PKW,Hurley, WG,

Cite this

@inproceedings{132dc1650a6443e8ad0a64428b79f43d,

title = "2009 IEEE ENERGY CONVERSION CONGRESS AND EXPOSITION, VOLS 1-6",

abstract = "Autonomous photovoltaic systems require an energy buffer to match the generation with the time distribution of demand, as photovoltaic is time and weather dependent. The Valve Regulated Lead Acid (VRLA) battery is commonly used for photovoltaic storage because of its low cost, low maintenance, and wide availability. A Hybrid Energy Storage System (HESS) integrates the VRLA battery and ultracapacitor, drawing on their respective advantages at appropriate times. By combining an ultracapacitor with a VRLA battery, the power density of the overall system is increased. The ultracapacitor operates under high power conditions reducing the strain of large current draw from the VRLA battery. This paper outlines a methodology to optimize the combination of VRLA batteries and ultracapacitors in the photovoltaic system taking the load demand, solar irradiation, and ambient temperature into account. A photovoltaic system is simulated in Matlab Simulink to analyze the results of the optimization.",

author = "Gerard Hurley",

year = "2009",

month = sep,

day = "1",

language = "English (Ireland)",

booktitle = "Optimization of Autonomous Hybrid Energy Storage System for Photovoltaic Applications",

}

TY - GEN

T1 - 2009 IEEE ENERGY CONVERSION CONGRESS AND EXPOSITION, VOLS 1-6

AU - Hurley, Gerard

PY - 2009/9/1

Y1 - 2009/9/1

N2 - Autonomous photovoltaic systems require an energy buffer to match the generation with the time distribution of demand, as photovoltaic is time and weather dependent. The Valve Regulated Lead Acid (VRLA) battery is commonly used for photovoltaic storage because of its low cost, low maintenance, and wide availability. A Hybrid Energy Storage System (HESS) integrates the VRLA battery and ultracapacitor, drawing on their respective advantages at appropriate times. By combining an ultracapacitor with a VRLA battery, the power density of the overall system is increased. The ultracapacitor operates under high power conditions reducing the strain of large current draw from the VRLA battery. This paper outlines a methodology to optimize the combination of VRLA batteries and ultracapacitors in the photovoltaic system taking the load demand, solar irradiation, and ambient temperature into account. A photovoltaic system is simulated in Matlab Simulink to analyze the results of the optimization.

AB - Autonomous photovoltaic systems require an energy buffer to match the generation with the time distribution of demand, as photovoltaic is time and weather dependent. The Valve Regulated Lead Acid (VRLA) battery is commonly used for photovoltaic storage because of its low cost, low maintenance, and wide availability. A Hybrid Energy Storage System (HESS) integrates the VRLA battery and ultracapacitor, drawing on their respective advantages at appropriate times. By combining an ultracapacitor with a VRLA battery, the power density of the overall system is increased. The ultracapacitor operates under high power conditions reducing the strain of large current draw from the VRLA battery. This paper outlines a methodology to optimize the combination of VRLA batteries and ultracapacitors in the photovoltaic system taking the load demand, solar irradiation, and ambient temperature into account. A photovoltaic system is simulated in Matlab Simulink to analyze the results of the optimization.

M3 - Conference Publication

BT - Optimization of Autonomous Hybrid Energy Storage System for Photovoltaic Applications

ER -

2009 IEEE ENERGY CONVERSION CONGRESS AND EXPOSITION, VOLS 1-6

Abstract

Authors (Note for portal: view the doc link for the full list of authors)

Fingerprint

Cite this