Voltage balancing of a 320-V, 12-F electric double-layer capacitor bank combined with a 10-kW bidirectional isolated DC-DC converter

double-layer capacitors (EDLCs) have attributes that feature high power density, quick charge/discharge time, long life cycle, and environmental friendliness. These attributes accord for increased appeal in employing the EDLCs as energy-storage devices in renewable energy systems, industrial applica...

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Main Authors: Tan N.M.L., Inoue S., Kobayashi A., Akagi H.
Other Authors: 24537965000
Format: Article
Published: 2023
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spelling my.uniten.dspace-308632023-12-29T15:54:54Z Voltage balancing of a 320-V, 12-F electric double-layer capacitor bank combined with a 10-kW bidirectional isolated DC-DC converter Tan N.M.L. Inoue S. Kobayashi A. Akagi H. 24537965000 12769863300 26324311700 7102912290 Bidirectional isolated dc-dc converter Electric double-layer capacitor (EDLC) Voltage balancing Automobiles Capacitance Capacitors Control system stability DC-DC converters Dielectric devices Electric automobiles Electric discharges Electric network analysis Electric vehicles HVDC power transmission Hybrid systems Industrial applications Life cycle Power converters A centers Bidirectional isolated dc-dc converter Charge/discharge Dc converters Double-layer capacitors Electric double-layer capacitor (EDLC) Energy-storage systems Environmental friendliness Experimental verifications High power densities Hybrid electric vehicles Long lives Low ripples Rated voltages Renewable energy systems Self-starting Static energies Storage devices Voltage balancing Voltage-balancing circuits Renewable energy resources double-layer capacitors (EDLCs) have attributes that feature high power density, quick charge/discharge time, long life cycle, and environmental friendliness. These attributes accord for increased appeal in employing the EDLCs as energy-storage devices in renewable energy systems, industrial applications, and hybrid electric vehicles as compared to other mature static energy-storage devices. This paper describes the construction of a 320-V, 12-F EDLC energy-storage bank connected to a bidirectional isolated dc--dc converter. Two types of EDLC bank configurations are considered with emphasis on their voltage-balancing circuits. Subsequently, this paper proposes a voltage-balancing circuit based on a center-tapped transformer, and includes its experimental verifications. It also discusses the charge--discharge and self-starting operation of the EDLC energy-storage system. During the charge--discharge operation, a low ripple current flowing in the EDLC bank is observed, leading to a theoretical analysis. The EDLC bank is also successfully charged to its rated voltage without any external dc charging circuit. � 2008 IEEE. Final 2023-12-29T07:54:53Z 2023-12-29T07:54:53Z 2008 Article 10.1109/TPEL.2008.2005388 2-s2.0-59749088838 https://www.scopus.com/inward/record.uri?eid=2-s2.0-59749088838&doi=10.1109%2fTPEL.2008.2005388&partnerID=40&md5=eba824d6405ff4479e00bd8853c658e4 https://irepository.uniten.edu.my/handle/123456789/30863 23 6 2755 2765 Scopus
institution Universiti Tenaga Nasional
building UNITEN Library
collection Institutional Repository
continent Asia
country Malaysia
content_provider Universiti Tenaga Nasional
content_source UNITEN Institutional Repository
url_provider http://dspace.uniten.edu.my/
topic Bidirectional isolated dc-dc converter
Electric double-layer capacitor (EDLC)
Voltage balancing
Automobiles
Capacitance
Capacitors
Control system stability
DC-DC converters
Dielectric devices
Electric automobiles
Electric discharges
Electric network analysis
Electric vehicles
HVDC power transmission
Hybrid systems
Industrial applications
Life cycle
Power converters
A centers
Bidirectional isolated dc-dc converter
Charge/discharge
Dc converters
Double-layer capacitors
Electric double-layer capacitor (EDLC)
Energy-storage systems
Environmental friendliness
Experimental verifications
High power densities
Hybrid electric vehicles
Long lives
Low ripples
Rated voltages
Renewable energy systems
Self-starting
Static energies
Storage devices
Voltage balancing
Voltage-balancing circuits
Renewable energy resources
spellingShingle Bidirectional isolated dc-dc converter
Electric double-layer capacitor (EDLC)
Voltage balancing
Automobiles
Capacitance
Capacitors
Control system stability
DC-DC converters
Dielectric devices
Electric automobiles
Electric discharges
Electric network analysis
Electric vehicles
HVDC power transmission
Hybrid systems
Industrial applications
Life cycle
Power converters
A centers
Bidirectional isolated dc-dc converter
Charge/discharge
Dc converters
Double-layer capacitors
Electric double-layer capacitor (EDLC)
Energy-storage systems
Environmental friendliness
Experimental verifications
High power densities
Hybrid electric vehicles
Long lives
Low ripples
Rated voltages
Renewable energy systems
Self-starting
Static energies
Storage devices
Voltage balancing
Voltage-balancing circuits
Renewable energy resources
Tan N.M.L.
Inoue S.
Kobayashi A.
Akagi H.
Voltage balancing of a 320-V, 12-F electric double-layer capacitor bank combined with a 10-kW bidirectional isolated DC-DC converter
description double-layer capacitors (EDLCs) have attributes that feature high power density, quick charge/discharge time, long life cycle, and environmental friendliness. These attributes accord for increased appeal in employing the EDLCs as energy-storage devices in renewable energy systems, industrial applications, and hybrid electric vehicles as compared to other mature static energy-storage devices. This paper describes the construction of a 320-V, 12-F EDLC energy-storage bank connected to a bidirectional isolated dc--dc converter. Two types of EDLC bank configurations are considered with emphasis on their voltage-balancing circuits. Subsequently, this paper proposes a voltage-balancing circuit based on a center-tapped transformer, and includes its experimental verifications. It also discusses the charge--discharge and self-starting operation of the EDLC energy-storage system. During the charge--discharge operation, a low ripple current flowing in the EDLC bank is observed, leading to a theoretical analysis. The EDLC bank is also successfully charged to its rated voltage without any external dc charging circuit. � 2008 IEEE.
author2 24537965000
author_facet 24537965000
Tan N.M.L.
Inoue S.
Kobayashi A.
Akagi H.
format Article
author Tan N.M.L.
Inoue S.
Kobayashi A.
Akagi H.
author_sort Tan N.M.L.
title Voltage balancing of a 320-V, 12-F electric double-layer capacitor bank combined with a 10-kW bidirectional isolated DC-DC converter
title_short Voltage balancing of a 320-V, 12-F electric double-layer capacitor bank combined with a 10-kW bidirectional isolated DC-DC converter
title_full Voltage balancing of a 320-V, 12-F electric double-layer capacitor bank combined with a 10-kW bidirectional isolated DC-DC converter
title_fullStr Voltage balancing of a 320-V, 12-F electric double-layer capacitor bank combined with a 10-kW bidirectional isolated DC-DC converter
title_full_unstemmed Voltage balancing of a 320-V, 12-F electric double-layer capacitor bank combined with a 10-kW bidirectional isolated DC-DC converter
title_sort voltage balancing of a 320-v, 12-f electric double-layer capacitor bank combined with a 10-kw bidirectional isolated dc-dc converter
publishDate 2023
_version_ 1806425682601836544
score 13.222552