New AC–DC Power Factor Correction Architecture Suitable for High-Frequency Operation

Lim, Seungbum; Otten, David; Perreault, David J.

doi:10.1109/tpel.2015.2445927

Cited by 45 publications

(23 citation statements)

References 28 publications

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“…This is equal to 1.5δ at 28 MHz at room temperature in copper, indicating in this case that magnetic materials could be evaluated using F 1 2 for frequencies up to 28 MHz. The lower power of f ( 1 ⁄2 instead of 3 ⁄4) in the performance factor for this case indicates the diminishing value of litz wire over the HF frequency range, and in practice, litz wire is not usually worthwhile above the low end of the HF range (though it has been used effectively in the 5-10 MHz range, e.g., [23], [24]). …”

Section: Performance Factorsmentioning

confidence: 92%

Measurements and Performance Factor Comparisons of Magnetic Materials at High Frequency

Hanson

Belk

Lim

et al. 2016

IEEE Trans. Power Electron.

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175

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Abstract-The design of power magnetic components for operation at high frequency (HF, 3-30 MHz) has been hindered by a lack of performance data and by the limited design theory in that frequency range. To address these deficiencies, we have measured and present core loss data for a variety of commercially available magnetic materials in the HF range. In addition, we extend the theory of performance factor for appropriate use in HF design. Since magnetic materials suitable for HF applications tend to have low permeability, we also consider the impact of low permeability on design. We conclude that, with appropriate material selection and design, increased frequencies can continue to yield improved power density well into the HF regime.

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Section: Performance Factorsmentioning

confidence: 92%

Measurements and Performance Factor Comparisons of Magnetic Materials at High Frequency

Hanson

Belk

Lim

et al. 2016

IEEE Trans. Power Electron.

Self Cite

175

View full text Add to dashboard Cite

show abstract

“…1 along with the feedback approach used to provide output voltage control [15]. The system architecture comprises a linefrequency rectifier, a stack of capacitors across the rectifier output, a set of regulating converters having inputs connected to capacitors on the capacitor stack, and a multi-input isolated bus converter that combines the power from the outputs of the regulating converters to provide a single output.…”

Section: Stacked Ac-dc Converter Architecturementioning

confidence: 99%

“…5. The regulating converter is designed with single switch, diode, and small inductor, and operates around 3 -10 MHz frequency similar to the regulation-stage design illustrated in [12], [13], [15]. It is an "inverted" circuit in the sense that it is designed with "common positives" (i.e., the positive node of the converter's input voltage is common Capacitively-aided Fig.…”

Section: B System Characteristics Design Tradeoffs and Converter Dmentioning

confidence: 99%

“…5. This figure shows the implementation of the ac-dc isolated converter using a stacked grid interface architecture [15]. The regulating converters are designed as resonant-transition inverted buck converters operating at high frequency, and a multi-input capacitively-aided bus converter is utilized as a dc transformer [16].…”

Section: B System Characteristics Design Tradeoffs and Converter Dmentioning

confidence: 99%

“…Here we present an isolated ac-dc converter with a stacked architecture [14], [15] and utilizing a inverted resonant transition buck converter and a capacitively-aided isolated bus converter [16] to provide galvanic isolation and voltage transformation. The proposed ac-dc converter addresses converter miniaturization through high-frequency operation while main- taining good efficiency, and achieves reasonably high power factor consistent with line harmonic requirements [5], while dynamically buffering twice-line frequency energy at moderate voltages with large voltage swings [17]- [23].…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

High-frequency isolated ac-dc converter with stacked architecture

Lim

Bandyopadhyay

Perreault

2017

2017 IEEE Applied Power Electronics Conference and Exposition (APEC)

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Abstract-This paper presents a new isolated ac-dc power converter achieving both high power factor and converter miniaturization suitable for many low power ac-dc applications. The proposed ac-dc converter architecture comprises a line-frequency rectifier, a stack of capacitors, a set of regulating converters, and a multi-input isolated bus converter. Among many suitable circuit implementations, the prototype system utilizes the resonanttransition buck converter as a regulating converter, and the capacitively-aided isolated bus converter for the isolated bus converter. The converter is miniaturized by operating at high frequency (1 -10 MHz range), and it buffers the ac-line frequency energy with a pair of stacked ceramic capacitors (1 µF and 150 µF, 100 V rating) without a requirement for electrolytic capacitors. The prototype converter is implemented to operate from 120 Vac to 12 V, and up to 50 W output as an example isolated ac-dc converter for power supply applications. The prototype converter demonstrates with 88 % efficiency and 0.86 power factor, and provides 50 W/in 3 power density, which is five times higher than the power density of typical conventional designs.

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UPF‐isolated zeta converter‐based battery charger for electric vehicle

Kushwaha

Singh

2019

IET Electrical Systems in Transportation

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Conventional electric vehicle (EV) battery chargers suffer from severe power quality (PQ) issues at AC mains, due to non-linear nature of a diode-bridge rectifier, used for AC-DC conversion. Here, a power factor correction (PFC) circuit based on an isolated discontinuous conduction mode (DCM) zeta converter topology is designed and implemented for charging a 100 Ah, 48 V lead-acid EV battery. Test results, for charging an EV battery with constant current-constant voltage mode (CC-CV) control, are shown with a 1 kW zeta converter prototype. Test results show that the proposed zeta converter conforms to the improved PQ standard such as the IEC 61000-3-2, as well as, a unity power factor (UPF) input current with low harmonic distortion factor is achieved. Moreover, a smooth battery current is obtained during charging, even when there are fluctuations in the supply voltage hence enhanced lifetime of the battery is achieved.

show abstract

New AC–DC Power Factor Correction Architecture Suitable for High-Frequency Operation

Cited by 45 publications

References 28 publications

Measurements and Performance Factor Comparisons of Magnetic Materials at High Frequency

Measurements and Performance Factor Comparisons of Magnetic Materials at High Frequency

High-frequency isolated ac-dc converter with stacked architecture

UPF‐isolated zeta converter‐based battery charger for electric vehicle

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