Your search keyword '"Wen, Huiqing"' showing total 8 results

1. Partial Power Processing Multiport DC–DC Converter With Radial Module Connections.

Author

Liu, Yuwei, Hu, Yihua, Chen, Guipeng, and Wen, Huiqing

Subjects

DC-to-DC converters, COMPUTER performance, BRIDGE circuits

Abstract

The partial power processing (PPP) concept has been extensively employed in many two-port converters to achieve high efficiency and high-power density by modifying one of the original converter ports to be connected in series between input and output. This is attractive but is confined to two-port applications, and how to extend it to multiport applications is not clear. Hence, this article aims to explore a generalized PPP multiport scheme by arranging the connection of the module rather than the converter. For a PPP single-input(output)-N-outputs(inputs) converter, one terminal of all N+1 modules is connected together to construct a radial structure, and another terminal is series/parallel connected with the input/output port. Each module only needs to process partial power caused by the voltage or current difference between input and output. Therefore, the required power rating of components is effectively reduced, contributing to low cost as well as low power loss. In this article, a PPP single-input dual-output converter with active bridge modules is also taken as an example to be introduced in detail, designed and experimented upon, which validates that high efficiency and high-power density can be achieved. [ABSTRACT FROM AUTHOR]

Published

2022

2. Minimum-Current-Stress Boundary Control Using Multiple-Phase-Shift-Based Switching Surfaces.

Author

Shi, Haochen, Wen, Huiqing, Cao, Zhenyan, Hu, Yihua, and Jiang, Lin

Subjects

*VOLTAGE references, *MATHEMATICAL models, *BRIDGE circuits, *ALGORITHMS

Abstract

The derivation and implementation of multiple-phase-shift-based switching surfaces for a dual active bridge (DAB) converter is the main focus of this article. First, the mathematical models of multiple natural switching surfaces under different operation states of DAB converters are derived, which lays the foundation to achieve a fast transient response during startup, sudden voltage reference, and load changing conditions. Moreover, in order to improve the overall performance of DAB converters systematically, a minimum-current-stress boundary control (MBC) is proposed that can reduce the inductor peak current stress and achieve fast dynamic response simultaneously by using the multiple-phase-shift-based switching surfaces. The analytical derivation of the proposed MBC is presented together with the simulation and experimental evaluations, which shows the superior performance of the proposed MBC algorithm in terms of the efficiency and dynamic response improvement under various operating conditions. [ABSTRACT FROM AUTHOR]

Published

2021

3. Transient DC Bias Elimination of Dual-Active-Bridge DC–DC Converter With Improved Triple-Phase-Shift Control.

Author

Bu, Qinglei, Wen, Huiqing, Wen, Jiacheng, Hu, Yihua, and Du, Yang

Subjects

*BRIDGE circuits, *MAGNETIC flux, *TRANSIENT analysis, *OSCILLATIONS, *SEX discrimination against women

Abstract

A transient dc-bias current due to the voltage-second imbalance of isolated bidirectional dual-active-bridge (DAB) converters for the disturbance in line or load may result in the transformer saturation and oscillations in both sides dc currents. This article focuses on the transient dc-bias current elimination by using an improved triple-phase-shift (ITPS) control for DAB converters. The inductor peak current stress optimization is adopted in the proposed ITPS to determine the steady-state phase-shift variables. Originated from the dc-bias current model of DAB converters with the TPS control, the transient phase-shift adjustment strategy can be determined, which has the ability to improve the inductor current changing slope and shorten the settling time. Both simulation and experiments for different conditions are provided to evaluate main dynamic indexes such as the transient period, dc-bias current, and inductor current stress for three different transition cases. The proposed ITPS is proved as a promising solution in eliminating the dc-bias current, minimizing the transient current stress. [ABSTRACT FROM AUTHOR]

Published

2020

4. Efficiency Optimization of DC Solid-State Transformer for Photovoltaic Power Systems.

Author

Shi, Haochen, Wen, Huiqing, Hu, Yihua, Yang, Yong, and Wang, Yiwang

Subjects

*DC transformers, *POWER transformers, *PHOTOVOLTAIC power systems, *POWER transmission, *BUILDING-integrated photovoltaic systems, *BRIDGE circuits

Abstract

As the “brain” of the modern photovoltaic power systems, dc solid-state transformers (SSTs) are playing an increasing important role in integrating different photovoltaic modules, batteries, and supercapacitors. This paper aims at improving the conversion efficiency of dc SST for a wide operating range by minimizing the backflow power of the dc SST system. First, the mathematical model of the backflow power from both input and output sides of dc SST is obtained. Then, the penalty function is derived and an enhanced triple phase shift control (ETPS) strategy is proposed to minimize the backflow power for various transmission power and voltage conversion conditions. A comprehensive comparison of the proposed ETPS with other advanced control strategies was carried out through theoretical analysis and experimental tests. Main experimental results are illustrated to verify the effectiveness of the proposed method. [ABSTRACT FROM AUTHOR]

Published

2020

5. Reactive Power Minimization in Bidirectional DC–DC Converters Using a Unified-Phasor-Based Particle Swarm Optimization.

Author

Shi, Haochen, Wen, Huiqing, Hu, Yihua, and Jiang, Lin

Subjects

*REACTIVE power, *CONVERTERS (Electronics), *DIRECT currents, *PARTICLE swarm optimization, *POWER transmission

Abstract

This paper deals with an optimized three-level modulated phase shift control using particle swarm optimization (PSO) strategy based on the unified phasor analysis with an aim to improve the efficiency of the bidirectional dual active bridge (DAB) converter for the whole operation range. A unified mathematical model based on Fourier transform is built for the DAB converter. All possible operation states under the three-level modulated phase shift control are covered. Accurate complex mathematical expressions for the inductor current, the transmission power, and the reactive power are obtained. Both modulus and angle variables are illustrated with respect to the inner and outer phase shift angle with the phasor diagram. The proposed method is able to achieve the minimum reactive power under three-level modulated phase shift control by obtaining the optimal phase-shift angles directly. The cumbersome process of the optimal operation mode selection for different voltage conversion ratio and load conditions in conventional methods is overcome successfully, thus greatly simplifying the theoretical calculation and implementation difficulty. Simulation and experimental results in terms of the reactive power, soft-switching range, and efficiency are provided to verify the practical feasibility of the proposed method for the bidirectional DAB converters. [ABSTRACT FROM AUTHOR]

Published

2018

6. Minimum-Backflow-Power Scheme of DAB-Based Solid-State Transformer With Extended-Phase-Shift Control.

Author

Shi, Haochen, Wen, Huiqing, Chen, Jie, Hu, Yihua, Jiang, Lin, Chen, Guipeng, and Ma, Jieming

Subjects

*PHASE shifters, *SOLID state electronics, *ELECTRIC transformers, *DISTRIBUTED power generation, *BRIDGE circuits, *ELECTRIC power conversion, *POWER transmission, *DC-to-DC converters

Abstract

As key component for the flexible dc distributed power system, the dual active bridge (DAB)-converter-based solid-state transformer (SST) with high efficiency for a wide operating range is essential. However, with the traditional phase-shift control, high backflow power and current stress will significantly affect the conversion efficiency. In this paper, the backflow power characteristics in both sides of DAB-based SST converters are comprehensively analyzed. On this basis, complete transmission power, backflow power, and peak current mathematical models are established. Then, a minimum-backflow-power-based extended-phase-shift control strategy is proposed with the determination of optimal phase-shift pairs by using the Karush–Kuhn–Tucker function for various scenarios. The backflow power and current stress curves with different algorithms are compared. It shows the proposed control can improve the output power regulation flexibility, minimize the backflow power, and improve the efficiency in wide operating range. Finally, a DAB-based SST prototype was developed and the experimental results verified the effectiveness of the proposed control strategy. [ABSTRACT FROM AUTHOR]

Published

2018

7. Minimum-Reactive-Power Scheme of Dual-Active-Bridge DC?DC Converter With Three-Level Modulated Phase-Shift Control.

Author

Shi, Haochen, Wen, Huiqing, Chen, Jie, Hu, Yihua, Jiang, Lin, and Chen, Guipeng

Subjects

*HARMONIC analysis (Mathematics), *REACTIVE power, *ZERO voltage switching, *POWER density, *ELECTRICAL engineering

Abstract

This paper presents a novel reactive-power minimization method under the three-level modulated phase-shift control to improve the efficiency for a wide operation condition. First, in order to unify all operation modes, a mathematic model of the dual-active-bridge converter with the three-level modulated phase-shift control by a harmonic analysis method is obtained. Then, the detailed analysis of the odd-order harmonic components of the active and reactive powers varied with the multiple control dimensions is presented. The soft-switching boundaries with respect to the voltage ratio and unified active power are specified. On this basis, a novel optimal three-level phase-shift (OPS) control strategy for minimizing reactive power is proposed. Experimental results of reactive power and operation efficiency among the proposed OPS method, and other methods are compared to verify the effectiveness of the OPS algorithm. [ABSTRACT FROM PUBLISHER]

Published

2017

8. Nonactive Power Loss Minimization in a Bidirectional Isolated DC–DC Converter for Distributed Power Systems.

Author

Wen, Huiqing, Xiao, Weidong, and Su, Bin

Subjects

*ELECTRIC loss in electric power systems, *DC-to-DC converters, *DIRECT currents, *ZERO voltage switching, *ELECTRIC potential

Abstract

Originated from analyzing nonactive power loss, a novel optimization method and modulation solution for bidirectional isolated dual-active-bridge (DAB) dc–dc converters are proposed in order to achieve high efficiency in a wide operating range. A comprehensive nonactive power loss model is developed, including both the nonactive components delivered back to the source and from the load. This paper points out that when the minimum nonactive power loss is achieved, zero-voltage soft switching can be naturally fulfilled. The optimal phase-shift pair obtained by the proposed method can keep low values of both root mean square (RMS) current and circulating power. Rather than using ideal power flow analysis, the nonactive power loss model directly embodies practical nonideal factors, including device voltage drops. Based on the analysis, an extended dual phase shift is proposed, and different operation cases are analyzed with comparison of performance indices. Experimental tests verify the theoretical analysis and show effectiveness of the proposed approach to achieve nonactive power loss minimization and efficiency improvement. [ABSTRACT FROM PUBLISHER]

Published

2014