Wireless Input-Voltage-Sharing Control Strategy for Input-Series Output-Parallel (ISOP) System Based on Positive Output-Voltage Gradient Method

Chen, Wu; Wang, Guangjiang; Ruan, Xinbo; Wei, Jiang; Gu, Wei

doi:10.1109/tie.2014.2308147

Cited by 111 publications

(39 citation statements)

References 26 publications

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“…There have been many reports on analysis of the converters in ISOP connection [7][8][9][10]. On the other hand, when nonregulated dc-dc converters, which do not perform voltage constant control, are connected by ISOP, it is possible to avoid a voltage concentration in the steady state as stated in (3).…”

Section: Structure With Multicell Dc-dc Converters Connected By Imentioning

confidence: 99%

“…If the voltage unbalance is large, overvoltage may stop control of the cell converters or even break them. There have been many reports on analysis of the converters in ISOP connection [7][8][9][10]. While methods to compensate the input voltage unbalance by some controlling process have been proposed, no instances of nonregulated dc-dc converters are included there.…”

Section: Structure With Multicell Dc-dc Converters Connected By Imentioning

confidence: 99%

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Highly Efficient dc–dc Transformer Based on Multicell Converter Topology for Next Generation dc Distribution System

Hayashi¹,

Takai

Matsumoto³

et al. 2016

Electrical Engineering Japan

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A multicell dc-dc transformer (DCX) with an efficiency of 98.0% is developed for a next generation dc distribution system. Input series output parallel (ISOP) and input parallel output series (IPOS) connection topologies of highly efficient dc-dc cell converters have been applied to realize DCXs that have arbitrary I/O voltages and a high transfer factor. The behavior of a DCX based on multicell topology using nonregulated dc-dc converters is analyzed, and the voltage stress in each cell converter is discussed quantitatively considering the variation in converter circuit parameters. Further, the availability of the applied topology and the validity of the analysis are confirmed by fabricating a prototype of a 384 V to 12 V 2400 W DCX. The multicell topology contributes to realizing a low-carbon society pushing the promotion of highly efficient, space-saving, and low cost dc power supplies with standardized, highly efficient cell converter modules. C⃝ 2016 Wiley Periodicals, Inc. Electr Eng Jpn, 198(4): 98-110, 2017; Published online in Wiley Online Library (wileyonlinelibrary.com).

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Section: Structure With Multicell Dc-dc Converters Connected By Imentioning

confidence: 99%

Section: Structure With Multicell Dc-dc Converters Connected By Imentioning

confidence: 99%

Highly Efficient dc–dc Transformer Based on Multicell Converter Topology for Next Generation dc Distribution System

Hayashi¹,

Takai

Matsumoto³

et al. 2016

Electrical Engineering Japan

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“…To form an SC module, the input ends and the output ends of each module are connected in series. Thus the module is based on an input-series-output-series (ISOS) converter [29][30][31]. The schematic diagram of a three-cell SC module is shown in Fig.…”

Section: Proposed Topology and Algorithmmentioning

confidence: 99%

Novel bifunctional converter‐based supercapacitor energy storage module with active voltage equalizing technology

Wei

Zhao

2016

IEEJ Transactions Elec Engng

Self Cite

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A bifunctional converter module for supercapacitor energy storage based on an input-series-output-series (ISOS) circuit is proposed in this paper. Compared to the existing topologies, the proposed circuit acts both as a supercapacitor cell voltage equalizer and as an output voltage regulator. During the charging process, series-connected flyback converters transfer energy from fully charged cells to the string via a bypass. Therefore, the fully charged cells maintain the rated terminal voltage, and the charging speed of the rest of the cells increases. During the discharging process, the output voltage of the module can be regulated with the same set of converters. The working principles during the discharging/charging processes are analyzed. The designs of the flyback converter and the control system are presented. A prototype consisting of three submodules is implemented. Experimental results verify the effectiveness of the proposed topology.

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“…However, excellent power sharing can only be achieved for modules with identical parameters. The exact sharing of the power can be achieved with the control in [3]- [10]. The relationship of IVS and OCS are revealed in [3], indicating that IVS can be achieved when OCS is obtained and vice versa.…”

Section: Introductionmentioning

confidence: 99%

“…A decentralized control [10] without communication among individual modules is used to achieve the power sharing. However, the output voltage of the converter is affected by its input voltage, and the output regulation characteristic suffers from individual input voltages especially when the total input voltage range is wide.…”

Section: Introductionmentioning

confidence: 99%

Decentralized Inverse-Droop Control for Input-Series–Output-Parallel DC–DC Converters

Sha

Liao

2015

IEEE Trans. Power Electron.

113

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Input-series-output-parallel (ISOP) DC-DC converters are suited for high input-voltage and low output-voltage applications. This letter presents a decentralized inverse-droop control for this configuration. Each module is self-contained and no central controller is needed, thus improving the system modularity, reliability and flexibility. With the proposed inverse-droop control, the output voltage reference rises as the load becomes heavy. Even though the input voltages is not used in the inverse-droop loop, the power sharing including input voltage sharing (IVS) and output current sharing (OCS) can still be well achieved. Besides, the output voltage regulation characteristic is not affected by the variation of input voltage. The operation principle is introduced, and stability of the strategy is also revealed based on small signal modeling. Finally, the experiment is conducted to verify the effectiveness of the control strategy. Index Terms--input-series and output-parallel, input voltage sharing, output current sharing, inverse-droop.

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Wireless Input-Voltage-Sharing Control Strategy for Input-Series Output-Parallel (ISOP) System Based on Positive Output-Voltage Gradient Method

Cited by 111 publications

References 26 publications

Highly Efficient dc–dc Transformer Based on Multicell Converter Topology for Next Generation dc Distribution System

Highly Efficient dc–dc Transformer Based on Multicell Converter Topology for Next Generation dc Distribution System

Novel bifunctional converter‐based supercapacitor energy storage module with active voltage equalizing technology

Decentralized Inverse-Droop Control for Input-Series–Output-Parallel DC–DC Converters

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