N-switched-capacitor buck converter: topologies and analysis

Jiao, Yanping; Luo, Fang Lin

doi:10.1049/iet-pel.2010.0104

Cited by 28 publications

(19 citation statements)

References 14 publications

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“…However, the input current is pulsating and voltage regulation is poor. Hybrid switched capacitor step-down convertor have been developed to solve the problem of conventional switched capacitor step down converts [27][28][29][30][31][32]. A hybrid switch capacitor converter made of first stage switched capacitor convertor followed by a second stage traditional buck convertor is shown in Figure 12.…”

Section: Switched-capacitor Step Down Convertersmentioning

confidence: 99%

A Review of Non-Isolated High Step-Down Dc-Dc Converters

Farooq¹,

Malik²,

Sun³

et al. 2015

IJSH

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Section: Switched-capacitor Step Down Convertersmentioning

confidence: 99%

A Review of Non-Isolated High Step-Down Dc-Dc Converters

Farooq¹,

Malik²,

Sun³

et al. 2015

IJSH

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“…Recently, switched-capacitor dc-dc converters have been used to multiply or divide voltage. The integration between switched-capacitor (SC) principles and traditional converters has been a good option to increase the rated conversion of conventional structures, as verified in [13]- [16] for dc-dc converter, [17] for rectifier and [18] for inverters. Some disadvantages of SC circuits, as parasitic elements, hard switching and peak of current, limited their power.…”

Section: Introductionmentioning

confidence: 99%

Transformerless Step-Up Inverter Based On Switched-Capacitor Converter Technology

Lazzarin¹,

Pont²,

Waltrich³

2017

Eletrônica de Potência

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-In this paper the integration between a voltage source inverter (VSI) and a switched capacitor converter (SCC) is proposed to generate a sinusoidal waveform with a double peak voltage value at the converter output terminal, without the use of a transformer or a dc-dc boost converter. The novel structure (VSI-SCC) is designed as a transformerless step-up inverter with linear gain. VSI and SCC models are individually characterized to integrate both structures in only one model. To validate the theoretical analysis a prototype was designed for a power of 1 kW, considering a dc input voltage of 200 V and an ac output voltage of 220 V (rms). In this prototype the VSI converter supplies 110 V (rms) to the SCC converter, and this converter step-up it to 220 V (rms). Furthermore, open and closed-loop control were also tested in the prototype reaching a maximum efficiency of 90%.

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“…Static converters based on the switched-capacitor (SC) have been an important research topic for many years. Currently, the number of topologies that use this principle is growing and the SC has been employed in low and high power dc-dc converters [9][10][11][12][13], resonant SC dc-dc converters [14][15][16][17], charge balancing circuits for batteries [18] and hybrid converters as rectifiers [19], inverters [20,21], multilevel converters [22,23], unidirectional dc-dc converters [24][25][26], bidirectional dc-dc converters [27] and indirect ac-ac converters [28,29]. Interesting studies on models, dynamics, efficiency and design of SC converters are presented in [30][31][32][33][34][35][36].…”

Section: Introductionmentioning

confidence: 99%

Split‐phase switched‐capacitor ac–ac converter

Lazzarin¹,

Moccelini²,

Barbi³

2015

IET Power Electronics

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This study proposes an ac-ac direct static power converter based on the switched-capacitor (SC) principle, aimed at supplying a split-phase system from an ac single-phase voltage source. The main advantages of the proposed split-phase SC converter are (i) the provision of three output voltages, two being equal to the input voltage and one being twice the input voltage, (ii) balanced output voltages even under unbalanced loads, (iii) the absence of magnetic elements in the power circuit, (iv) the stress voltages in all components being equal to the input voltage, (v) the ability to be bidirectional, (vi) high efficiency and (vii) high power density. These characteristics make the proposed converter suitable for modern applications where a split-phase system needs to be generated from a renewable energy source, distributed generation system, uninterruptible power supply (UPS), battery bank, electric/hybrid vehicle, smart grid or even the electrical grid itself. To verify the performance of the proposed converter, a 1 kW prototype was built and tested with standard voltages, such as 110 V input voltage and 110 V/110 V/220 V output voltages. The efficiency, output voltage regulation, tests with input voltages of 16.6, 60 and 400 Hz and other experimental results are reported herein.

show abstract

N-switched-capacitor buck converter: topologies and analysis

Cited by 28 publications

References 14 publications

A Review of Non-Isolated High Step-Down Dc-Dc Converters

A Review of Non-Isolated High Step-Down Dc-Dc Converters

Transformerless Step-Up Inverter Based On Switched-Capacitor Converter Technology

Split‐phase switched‐capacitor ac–ac converter

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